Electrical Notes & Articles

Method for Installation of HVAC System (Part-1)

January 14, 2021 1 Comment

Purpose:

This method explains the Procedures or sequence of activity for safely and efficiently installation and Testing of Refrigerant Pipes , Drain Pipes ,Indoor and Out Door Unit of HVAC System as per standard Practice and Code.

General Equipment & Tools:

The equipment that will be engaged for Installation of Cable works will be
Lifting crane , Transportation vehicle, Fork Lift
Winches, Pulling Rope , Welding machine
Lubricant (Soap based, wax based), Cleaning agent (CRP)
Copper pipe Flaring tools
Vacuum Pump,
Brazing Torch , Brazing Rod , Oxy-Acetylene Brazing Kit ,Wire Brush
Nitrogen Cylinders , Soldering Tools
Crimping tool, Drilling Machine with various Bits , Grinding Machine , Cutting Machine
Electrical Tool Box, Cable Cutter, Screwdriver, Pliers, Spanner.
Ladder , Scaffolding / Mobile scaffold
Nylon rope, Marker , Leveling device , Tape measure
Removable Barricades , Portable Lights
Testing Equipment for System
Multi meter ,Clamp Meter
Refrigerant / Nitrogen cylinder,
Vacuum Gauge

Storage & Material Handling:

The storage area must be free from dust and Water leakages / seepages.
Manufacturer recommendation shall always be followed in loading/unloading and storing of Material.
Material and its accessories shall be unloaded handle with care in designated area of the Store (Do not directly drop to Ground) to avoid any damages.
Materials shall be stored in a dry place which is free from water or from weather effects and protection should be given to the material by means of covering the material with Tarpaulin sheet.
The Material will be stacked / unload in the site store on a proper stand on wooden loft on a flat surface at a sufficient height from Ground.
The A/C Units should be kept on the wooden platform and covering with polythene to protected from any dust or mechanical damages
For storing the copper pipes:
If pipes will be used soon, nozzle should be sealed by plastic bag or tape.
If pipes will be stored for a long time, the pipes should be charged into 0.2 to 0.5MPa Nitrogen and the nozzle should be sealed by welding.

Inspection of Materials:

Check The Material according to its Type, Size, Make
Physical Damages Inspection:
Damage on Pipes and Units.
Damage on insulation of Cable
In case of any damages observed during inspection, the Material shall be returned to the supplier for replacement.

Installation of Outdoor Units :

(a) Transporting / Lifting the Outdoor Unit

Use appropriate moving equipment to transport outdoor Unit, ensure the equipment is capable of supporting the weights. When lifting the unit, use lifting straps and place around the unit.
Always lift the unit using appropriate size of lifting straps rated to carry the unit weight and long enough to maintain a maximum of a 40° angle as shown.
When moving / adjusting the placement of the outdoor unit, always hold the unit by the corners. Moving the outdoor unit using the side intake holes on the frame may damage the frame.
Consider the unit’s center of gravity before lifting. Hoist the unit with the center of gravity centered among the lifting straps. There is a risk of the product falling and causing physical injury.
Lift the outdoor unit from the base at specified locations. Support the outdoor unit at a minimum of six points to avoid slippage from the rigging apparatus.
Do not lay the unit on its side and do not slant the unit more than 30 degrees.

On a supporting structure that can bear the weight of the outdoor unit. The supporting structure can be a base on the ground, on a waterproof roof, or in a pit. With sufficient clearances around the unit for service and repairs. In a well-ventilated location. Away from strong wind.
Away from direct exposure to rain or snow. Where there is no risk of flammable vapor leakage. Where there is no exposure to salt, machine oil, sulfide gas, or corrosive environmental conditions.

(b) Selecting the Best Location for the Outdoor Unit(s)

Don’ts:
Do not install the unit in an area where combustible gas may generate, flow, stagnate, or leak. These conditions can cause a fire.
Do not install the unit in a location where acidic solution and spray (sulfur) are often used or in environments where oil, steam, or sulfuric gas are present.
A location that allows for optimum air flow and is easily accessible for inspection, maintenance, and Where piping between the outdoor unit and indoor unit(s) / heat recovery units are within allowable Limits.
Avoid placing the outdoor unit in a low-lying area where water could accumulate.
If the outdoor unit is installed in a highly humid environment (near an ocean, lake, etc.), ensure that the site is well-ventilated and has a lot of natural light (Example: Install on a rooftop).
Where operating sound from the unit will disturb inhabitants of surrounding buildings.
Where the unit will be exposed to direct, strong winds.
Where the discharge of one outdoor unit will blow into the inlet side of an adjacent unit (when installing multiple outdoor units).

If the outdoor unit is not placed on a roof, place it on the leeward side of the building or in a location where the unit will not be exposed to constant wind.
If placement exposes the unit to constant wind activity, construct a wind break in front of the unit. Follow the placement guidelines set

Avoid installing the outdoor unit where it would be directly exposed to ocean winds.
Install the outdoor unit on the side of the building opposite from direct ocean winds.
Select a location with good drainage and periodically clean dust or salt particles off of the heat exchanger with water.
Ocean winds may cause corrosion, particularly on the condenser and evaporator fins, which, in turn could cause product malfunction or inefficient performance.
If the outdoor unit must be placed in a location where it would be subjected to direct ocean winds, install a concrete windbreaker strong enough to block any winds. Windbreaker height and width must be more than 150% of the outdoor unit, and be installed at least 27.5 inches away from the outdoor unit to allow for airflow.

Rubber anti-vibration pads are necessary to avoid vibration.

Foundation can be made of channel steel or concrete.

Reserve the space for discharging condensate water from outdoor units.
The outdoor unit should be placed neatly, and reserve enough space for maintenance.
The outdoor unit should be installed in the place that is dry, well-ventilation and close to the indoor units.

Filed under Uncategorized

Method for Installation of Cable & Wire (Part-2)

January 3, 2021 1 Comment

(A) Cable Laying in Excavated Ground:

(a) Formation of Cable Trench.

Check the area of excavation by referring As Built drawing to find out crossing of any underground Services i.e. Gas Line, Water Line or other Cable. Check the indication marks, signs, manholes nearby area and find out the path of old services.
If there are structures adjacent to the work area, proper temporary supports shall be provided to the adjacent structure prior to start excavation.
Excavation near the existing electrical cables, instrumentation and control cables, sewer line, gas lines and any other service line shall take all necessary precautions to protect the services with proper supports & covers.
Ensure the working area at any confined space is free from any Hazardous Gas by proper Gas testing using the Gas testing instrument.
Required sign boards such as “DEEP EXCAVATION” “MEN WORKING”, “DANGER” and warning boards will be placed to indicate the excavation work. The area of excavation will be cordoned by using safety barricading to stop trespassers.
In open areas the excavation shall be carried out by using the machineries.
If the excavation level is below the local water table level suitable dewatering system shall be designed and installed in such a way that alterations and extensions to the system during operations are possible.
The width of the excavated Cable trench shall be as per specification or as per approved Drawings.
The trench shall be excavated up to the required depth of 0.76 Meter from the existing ground level or as per Specification or as per approved Drawing.
The Cable trench shall be kept dry during cable installation operation. The contractor shall deal with the dispose of water so as to prevent any risk to the cables and other materials.
Debris, rocks and unusable materials shall be removed from Excavated Trench on daily basis and it will dump at the approved dumping Location of from the site.

(b) First Layer of Sand:

The bottom of the trench shall be backfilled with a layer of clean and fine sand bedding of 100mm thickness or as per the approved Drawing.
The fill material shall be tamped. Any hard material which could damage the cable will be removed
Inspection of sand bed will be carried out prior to commencement of cable pulling.

(c) Cable Laying:

Cables are laid over the clean and fine First Layer of sand bedding.
Rollers must be used where cables are installed in an open trench using a pulling rope and eye; cable rollers are to be used at frequent intervals to support the cables and must never be more than 3 meters apart.
Care must be taken to ensure that the cable does not enter or leave the rollers at an angle that exceeds the bending radius of the cable.
The Pulling rope must be attached to the cable by a stocking grip with pulling eye.
The cable shall be drawn into the trench manually, before the pull commences, to prevent the winch to move along with the cable.
The cable shall be drawn into the trench smoothly with a minimum of stops and at an average speed of between 9 to 12 meters per minute, to avoid irregular movement.
Cables shall be arranged properly to minimize crossovers, twists.
All Cable shall be laying parallel to each other and cable dressing should be done properly
Cable identification tags shall be installed on both end of cable after the cable pulling.

(d) Second Layer of Sand:

The cables shall be backfilled with approved clean and fine Sand / backfill Material of 100mm thickness or as per the approved Drawing.
The fill material shall be tamped. Any hard material which could damage the cable will be removed
Inspection of sand bed will be carried out prior to commencement of Cable Protection layer.

(e) Cable Protection:

Cable protection tiles / Bricks / Warning Taps are laid above the second layer of dune sand filling.

(f) Back Filling:

Backfilling materials shall be free from stones or rocks (larger than 50 mm), fossil content, vegetation and its roots, waste materials, Material containing gypsum or other soluble salts greater than the allowable limits which might prevent proper compaction or cause to inadequately of performance.
Backfilling area shall be backfilled with approved material compacted in layers by suitable equipment like plate compactors, vibratory roller compactors, etc., until the specified density has been obtained.
Sufficient Water is poured to match the required Moisture content.
Intermediate cable markers to be firmly attached to the cables.
The thickness of fill material shall not exceed 150 mm where manual compaction methods are adopted.

(B) Cable Laying in Cable Tray / Trunking:

Before laying of Cable , Cable Tray work should be completed form the one end to other end of the Cable route
The cable tray must be cleaned and free from any dust or water dampness, before pulling the cables.
Use cable rollers in cable trays to avoid damage on cables during the pulling process.
From cable reel to cable tray, the cable is fed from the top of the reel to maintain required curvature. Sheaves, or a shoe, may be used to guide the cable into the tray.

Cable rollers shall be placed at every 6-12 meters or less if required to avoid touching of the cable to tray.
Cable laying will generally start from one end of the route length from other suitable point if required.
The number and size of cables drawn in to a particular cable tray shall not be exceed that allowed in specifications.
At any time of Cable laying only one cable should be laid on cable tray, after laying first cable necessary dressing and cable tie should be fixed than after that second cable should be lay.
Cut the cables to required length at both ends, seal the ends with adhesive insulation tape roll and keep in the box or enclosures to ensure no damage can occur to cables.
Cables shall be arranged properly to minimize crossovers, twists
Control cables will be laid along the LV cables. HV cables to be laid in separate trays
All control cables will be installed at a minimum distance of 100mm from power cables unless otherwise agreed with consultant as per site conditions.
After completion of all cables in the same route the cables shall be dressed and clamped.
All cables in horizontal or vertical runs will be secured to the trays by nylon fasteners / ties.
Cable identification tags as per specifications shall be installed on both end (at sending and receiving ends) of cable after the cable pulling.

(C) Cable Laying in the Building

In case of Cable lay inside the buildings, the drums will be placed outside the buildings and the cable pulled in the opposite direction. After reaching the other end the length of the cable required for reaching the location inside the building will be measured and then cut the cable.
The cable is fed from the cable reel directly into the conduit at floor level.
The cable is fed from the bottom of the reel so that its curvature is continuous with no reversed bends.

Do not pull cable directly across short, sharp angles. After pulling completely out of one side of the enclosure, feed cable into the other side of the enclosure and pull that segment
Unloading equipment should not come in contact with the cable or its protective covering.

(7) Wires Pulling in Conduit:

Proper marking / selection of location on site to be done prior to commencement of installation works.
Complete a mockup installation before main works and get its approval.
Make sure that all conduits and boxes in both ends are free from damages and blockages etc and installation is approved.
Blockage shall be checked by inserting the draw wire and checking that it reaches to the other end without any disturbance.
Use of Steel fish wire shall be made for drawing of wires. Wires shall be drawn with adequate care.
Once the conduit is not blocked the wires shall be pulled using the draw wires while ensuring no damage occurs while pulling.
Pulling compound or lubricant shall be used for pulling the wires where required.
Use soap based pulling compound for short runs i.e. less than 20 meters for semi conductive insulated wires.
Use wax based pulling compound for the runs greater than 20 meters for semi conductive insulated wires.
While pulling the wires care should be taken to not insert the pull tension greater than the manufacturer allowed limits.
Separate conduits shall be run for lighting and power circuits and also for telephone cables. To avoid any cross talk and extraneous interference in the telephone circuits, all telephone wiring conduits shall be run with a sufficient clearance from the power and lighting conduits.
All separate circuits from DB’s shall have separate neutral to the points. Common neutral between separate circuits are not permissible.
As far as possible wiring shall be run in conduits. All conduit wiring shall be complete with continuous earth as per I.E.R.
The wiring shall be carried out as specified. ‘Power’ and ‘heating’ wiring shall be kept separate and distinct from ‘Lighting’ wiring. The wiring shall be done on the distribution system with main and branch distribution boards at convenient physical and electrical centers and consideration shall be given for neatness and good appearance.
The wiring shall be done in the ‘Looping System. ‘Phase’ or ‘live’ conductors shall be looped at the switch box and neutral conductor can be looped from the light fan or socket outlets.
5 sq. mm PVC wires in green color are to be run continuously in conduits for continuous earthing. The earth wire should be connected to GI Switch boxes and DB boxes by tapped screws.
No bare or twist joints shall be made at intermediate points in the through run of cables.
Bare or twist joints shall be carried out with due care and preferably through proper junction boxes.
If any joint becomes unavoidable such joints shall be made through proper cutouts or through proper junction boxes open to easy inspections.
Electrical Load should be balance on all the three phases for an even distribution. Before commencement of work, the contractor shall seek the approval of the Consultants / Site Engineer on the distribution of balancing of loads and circuits. The wiring shall be done by the process of looping the live conductors and the neutral wires.
Color coding of wires
Phase : Red, Blue, Yellow,
Neutral: Black,
Earth: Green.
Adequate extra length shall be left at termination points.

(8) Excess or Spare Cable Storage:

Store Cable reels on hard surface so that the flanges will not sink and allow reel weight to rest on cable.

(9) Cables Identification / Marking of Cables:

Install the tags / labels as per project specifications and as per approved material submittals.
Cable marking shall be positioned properly to read and identify
For Buried / Surface mounted cables tagging / Labeling will be corrosion resistant tags (with engraved or stamped for the identification number of the cable, voltage Rating, conductor size and make) or as per project specifications and as per approved material submittals.
Cables shall be identified at feeders i.e. the sending and receiving ends (outgoing cables in SMDB’s and final DB’s) about 50mm below the gland.
All termination shall be provided with tight fitting covering sleeves.

(10) Duct Seals:

After installation of all Cables, all cable ducts / Hume Pipes / Sleeves entering substations and buildings to be duct sealedto prevent the ingress of water and gas.

(11) REFERENCES

IEC 60228, BS 6360.
BS 5467.

(12) Flow Chart:

Filed under Uncategorized

Method for Installation of Cable & Wire (Part-1)

December 3, 2020 1 Comment

Purpose:

The method explains the Procedures or activity for safely installation and Testing of MV cable in directly buries in ground, in trenches, in to cable trays or in underground ducts as per the standard Practice and Code.

General Equipment & Tools:

Testing Equipment for Cable
LV / HV Insulation Resistance tester (250V to 5KV)
Multi-meter
Continuity Tester
AC High Voltage Test Kit

Storage & Material Handling:

The storage area must be free from dust and Water leakages / seepages.
Manufacturer recommendation shall always be followed in loading/unloading and storing of Material.
Material and its accessories shall be unloaded handle with care in designated area of the Store (Do not directly drop to Ground) to avoid any damages.
Materials shall be stored in a dry place which is free from water or from weather effects and protection should be given to the material by means of covering the material with Tarpaulin sheet.
The Material will be stacked / unload in the site store on a proper stand on wooden loft on a flat surface at a sufficient height from Ground.
If Material are dispatch in packs or pallets, each pack or pallet shall be lifted individually with suitable lifting equipment.
The material shall be transported / Shifted in their original packing to Site location.
The cable drums shall be off-loaded at the site locations.

The cable drum should be visually inspected for damage, which may have occurred during transport.
During storage periodical rolling of drums once in 3 months done. Rolling shall be done in the direction of the arrow marked on the drum.
It should be ensured that both ends of the cable are properly sealed to prevent ingress/absorption of moisture by the insulation.
Protection from rain and sun shall be ensured. Sufficient ventilation between cable drums, should be ensured during storage.
The drums shall always be rested on the flanges and not on the flat sides. f. Damaged battens of drums etc. should be replaced, if necessary.
When cable drums have to be moved over short distances, they should be rolled in the direction of the arrow, marked on the drum
While transferring cable from one drum to another, the barrel of the new drum shall have a diameter not less than that of the original drum.
The manufacturer’s seal on the inner and outer cable ends should be examined and the condition of the sheath inspected for mechanical damage.
If the cable is found defective it shall not be installed and the cable shall be returned to the supplier for replacement.

Inspection of Materials:

Check The Material according to its Type, Size, Make
Inspection of Cable:
Type of Cable (HT /MV /LV)
Cable Operating Voltage
No of Cable Core (1 core,2core,3 core, 3.5 Core,4 core)
Type of Cable Core (Cu, Alu)
Type of Cable Material (PVC,XLPE)
Size of Cable
Length of Cable
Physical Damages Inspection:
Damage on Cable Drum
Damage on insulation of Cable
In case of any damages observed during inspection, the concern report will be issued and Material shall be returned to the supplier for replacement.

Testing and of Cable:

(1) Insulation resistance test:

Following Insulation resistance test will be carried out by approved calibrated equipment.
At the Time of Cable drum receiving at the Store
Before Installation of Cable on Site.
After Installation of Cable on Site.
The Insulation Resistance values will be noted for Core to Core and Armor by DC High Voltage Tester (Megger) before following activities.

Voltage Class	Test instrument	Acceptance Value
L/V Cable	1000 VDC	>20 Mega ohm
M/V Cable	5000 VDC	>100 Mega ohm
Control, Instrumentation, Communication cable	250 VDC	>1 Mega ohm

The cables and conductors must discharged after Insulation Resistnce test.

(2) The continuity test:

The continuity test would be carried out between
Phase to Phase,
Phase to Neutral,
Phase to earth and
Neutral to Earth.
The results would be recorded for records and future reference.
After the test, the end of the cable shall be sealed to prevent the ingress of moisture.

General Steps for Cabling Laying

Shifting of Cable Drum at Working Location:
If a crane is used to unload / Shift cable, a shaft through the arbor hole or a cradle supporting both reel flanges should be used.
Forklifts must lift the reel by contacting both flanges.
Check and ensure that approved drawings, the correct size and type of Cable & accessories are ready for installation.
Ensure that Cable and accessories received from site store for the installation are free of rusty parts and damages.
Installation of Cable Drum on Jacks:
Check and ensure that the Correct Size and Type of Cable Drum and accessories are transported at the Site locations.
Ensure that cable and its accessories received from site store for the installation are free from rust, corrosion and damages
Location of cable drum should be planned before transportation of cable drum. (Practically could differ at one or two places for easy installation of cable).
The cable drums shall be un-packed.
Depending on the weight and size of the drum, suitable size of the cable spindle shall be placed inside the central axis of the drum.
Suitable jacks shall be placed firmly on the ground and jacked-up the Drum to allow sufficient clearance from the ground. Ensure that the cable drum on a jack is free for rotation.
The cable drum will be correctly positioned and the direction of cable pulling as indicated by arrow on the drum shall be complied.
Drum control during pulling
Cable winch, if required, shall be positioned in proper place for cable pulling.
The cable shall be fixed to the winch, if used, by means of a cable sock or gripper. Required number of persons will be posted at winch and near the drum.
At all times during the pulling operation, at least one member of the team shall be stationed at the drum to control its rotation and check on the stability of the drum and jacks.
Cable Roller:
Cable rollers shall be placed as required on the cable route.
Cable rollers will be placed not more than more than 3 meters apart under the M.V cable during pulling over longer distances and standoff rollers for acute bends to ensure that the cable is pulled with minimum effort and the cable outer jacket is free of scouring lines.
Cable Pulling Speed:
The required cable pulling speed and tension requirement shall be maintained according to the manufacturer’s specification. If any problem arises during the pulling, the proceedings shall be stopped immediately and restarted only after the problem has been cleared.
The pulling speed shall be controlled during the cable pulling and it will be assured by observing the indication of the tension meter.
Cable pulling shall be done under strict supervision during the entire period of operation. Safety norms shall be observed and shall stick to the standard requirements
Identify Cable Laying Route:
Location of the panels / equipment shall be identified.
Cable laying will generally start from one end of the route length or at any suitable point if required.
In case of cable lengths which are more than one drum length, all cables which can be laid from original position will be completed. And then the cable pulling set-up will be re-positioned to the next location, from where the next length will be pulled.
Cables shall be cut from the drums as per the actual cable length in accordance to the drum schedule and drum allocation sheets
Before cutting the cable, both ends must be inspected to ensure sufficient length is for proper dressing and end termination.
The cable schedule and drum schedule will be updated with the information on cable pulling.
Cable rollers shall be positioned properly in to the cable trench. The intervals for the rollers are to be kept approximately 2 to 3 meters.
The rollers shall be maintaining its smooth rotation. If the cable will run through the curves and edges the, curve rollers should be used at the proper position in order to keeps a safe cable bending.
Precaution while laying of Cable:
Where bends are encountered in a run, cables shall be lubricated with a cable pulling lubricant (without Petroleum based) to facilitate easy movement.
Ensure excessive force and twisting of cables is avoided
Proper spacing will be maintained between the cables
Cables are protected from mechanical damage during pulling
Protection shall be provided to the cables at crossings with pipes, civil works to prevent mechanical damage.
PVC sleeves shall be installed for all cables passing through brick, block or concrete or similar structures in case there is need for future withdrawal.
After the Insulation Resistance Test, the open ends of the cable will be sealed till termination to prevent entry of Moisture and water.
After completion of all cables in the same route the cables shall be dressed and clamped.
Unless the lengths exceed the maximum drum lengths joints shall be avoided. Joint markers indicating joint positions shall be provided above ground and also shown on the drawings.
Empty cable drums will be transported back to stores.
Measure Insulation Resistance before Laying Cable
Insulation resistance of the cables shall be checked before laying cables.
Measure Insulation Resistance After Laying Cable
Soon after completion of every cable laying the cables will be tested for insulation resistance.
Cable Bending Radius:
During installation process cable can not be bent to a radius of less than 6D for unarmored cable and 8D for armored cable or bending radius of cables shall comply with cable manufacturer’s recommendation. These conditions shall be strictly follow to, particularly where cables turn into road crossings, conduit entry etc
Eliminate Sharp Edge:
While pulling, in order to eliminate sharp bend and crossovers, always have a person feed the cable(s) straight into the conduit by hand or, for larger cables, over a large diameter sheave.

Do not pull cable directly across short, sharp angles. After pulling completely out of one side of the enclosure, feed cable into the other side of the enclose and pull that segment.

Cable Laying Arrangements:

The configuration of three single-conductor cables in a conduit is determined by the ratio of the conduit inner diameter (D) to the outer diameter (d) of one of the single cables (D/d ratio).

A cradled configuration develops when three single-conductor cables are pulled into a conduit where the D/d ratio is 2.5 or greater.
A triangular configuration develops when three single conductor cables are pulled into a conduit where the D/d ratio is less than 2.5.
These cables may be pulled from individual reels, tandem reels, or a single reel with parallel wound cables.

Filed under Uncategorized

Quick Reference -HVAC (Part-2)

November 17, 2020 2 Comments

A.C Capacity
Ton	KW	H.P
0.64	2.1	0.8
0.80	2.8	1
1.00	3.7	1.25
1.28	4.6	1.6
1.60	5.6	2
2.00	7.31	2.5
2.56	9.35	3.2
3.20	11.6	4
4.00	14.4	5
4.48	16.7	5.6
6.40	22.1	8
8.00	29.1	10
1TON=	1TON=3000 K.Cal/Hr
	1TON=1200 BTU/Hr
	1TON=3.516 KW
	1TON=1.25 HP (VRV / VRF Only)
	1TON=4.7 HP
	1TON=12660 KJ/Hr

Split AC Copper Pipe Size (Blue Star)
A.C Capacity	Suction Pipe	Discharge Pipe (Liquid)
Up to 1 Ton	12.7mm (1/2″)	6.4mm (1/4″)
1 To 4 Ton	15.9mm (5/8″)	9.5mm (3/8″)
5 To 6 Ton	19.1mm (3/4″)	9.5mm (3/8″)
7 To 8 Ton	22.2mm (7/8″)	12.7mm (1/2″)
9 To 11 Ton	28.6mm (1 1/8″)	12.7mm (1/2″)
12 To 19 Ton	28.6mm (1 1/8″)	15.9mm (5/8″)
20 To 27Ton	34.9mm (1 3/8″)	19.1mm (3/4″)
28 To 42Ton	41.5mm (1 5/8″)	19.1mm (3/4″)
Normal Split A.C Copper Pipe Maximum Length = 15Meter
VRV System Copper Pipe Maximum Length = 150Meter

Split AC Copper Pipe Length
A.C Capacity	Maximum Pipe Length	Maximum Indoor & Outdoor Height Difference
0.5 Ton	15 Meter	5 Meter
0.6 Ton	15 Meter	5 Meter
0.75 Ton	15 Meter	5 Meter
1 Ton	20 Meter	10 Meter
1.5 Ton	25 Meter	10 Meter
2 Ton	25 Meter	10 Meter
2.5 Ton	30 Meter	10 Meter
3 Ton	30 Meter	20 Meter
3.5 Ton	30 Meter	20 Meter
4 Ton	30 Meter	20 Meter

Split AC Copper Pipe Additional Refrigerant Charge
Total Pipe Length	50 Meter	60 Meter	70 Meter
Additional Refrigerant	None	250 gm (25gm/Meter)	500 gm (25gm/Meter)

Copper Pipe Thickness
Pipe Size	Thickness	Tube Gauge	Type
6.4mm (1/4″)	0.8 mm	21	Soft
9.5mm (3/8″)	0.8 mm	21	Soft
12.7mm (1/2″)	0.8 mm	21	Soft
15.9mm (5/8″)	1 mm	19	Soft
19.1mm (3/4″)	1 mm	19	Soft
22.2mm (7/8″)	1 mm	19	Hard
28.6mm (1 1/8″)	1.2 mm	18	Hard
34.9mm (1 3/8″)	1.2 mm	18	Hard
41.5mm (1 5/8″)	1.3 mm	18	Hard
De-Oxidized Copper Tubes (DHP) , Copper 99.9%
Soft Copper as per ASTM B68
Hard Copper as per ASTM B75 / ASTM280 / BS 2871

Gas Pressure For any Ton Capacity
Refergerent	Suction Pressure (PSI)	Discharge Pressure (PSI)	Standing Pressure (PSI)
Refergerent	M/C ON	M/C ON	M/C OFF
R 22	60 To 70	250To 300	156
R 32	120	490	260
R 134A	35	158 To 199	95
R 290	65	275 To 300	125
R 404A	87	270 To 356	190
R 407C	63	247 To 307	153
R 410A	110 To 120	400 To 500	250
R 417A	65	261	140

Nitrogen Pressure Test		Vacuum
3 Minutes	150 PSI	<= 500 Micron	for 24 Hours
5 Minutes	325 PSI
24 Hours	500 PSI
vacuum	< 500 Micron

System Problems
System Problem	Discharge Line Pressure	Suction Line Pressure	Suction Line Temperature	Compressor Amp
Over Gas Charge	High ↑	High ↑	Low ↓ (Ice on Suction Pipe)	High ↑
Under Gas Charge	Low ↓	Low ↓	High ↑	Low ↓
Capillary Block	Low ↓	Low ↓	High ↑	Low ↓
Less Air Flow on Evaporator (Indoor Unit)	Low ↓	Low ↓	Low ↓	Low ↓
Less Air Flow on Condenser (Outdoor Unit)	High ↑	High ↑	High ↑	High ↑
Dirty Condenser (Outdoor Unit)	High ↑	High ↑	High ↑	High ↑
Low Ambient Temperature	Low ↓	Low ↓	Low ↓	Low ↓
High Ambient Temperature	High ↑	High ↑	High ↑	High ↑
Insuffient Compressor	Low ↓	High ↑	High ↑	Low ↓

Insulation Thickness
Refrigerant Pipe	Insulation	Drain Pipe	Insulation
22.22mm To 28.58mm	19mm	25mm / 32mm /40mm	6mm
12.7mm To 19.05mm	13mm / 19mm
6.35mm To 9.2mm	9mm / 13mm

Referent Pipe Insulation
Pipe	Pipe size	Insulation Type (EPDM or NBR)
Pipe	Pipe size	Standard conditions 86°F (30°C), < 85%	High humidity conditions(a) 86°F (30°C), >85%
Liquid Pipe	1/4″ (6.35 mm) To 3/8″ (9.52 mm)	3/8″ (9 mm)	3/8″ (9 mm)
Liquid Pipe	1/2″ (12.70 mm) To 2″ (50.80 mm)	1/2″ (13 mm)	1/2″ (13 mm)
Vapor Pipe	1/4″ (6.35 mm) To 7/8″ (22.23)	1/2″ (13 mm)	3/4″ (19 mm)

The distance between the supports of the copper pipes.
Diameter	Distance (m)
≤ 20 mm	1 Meter
20 To 40 mm	1.5 Meter
≥ 40 mm	2 Meter

The permitted length and drop difference
Pipe length	Max. pipe length	<= 240 Meter
Pipe length	Equivalent length from the first branch to the farthest indoor unit	<= 40 Meter
Drop height	Drop height between indoor unit and outdoor unit	<= 110 Meter
Drop height	Drop height between indoor units	<= 30 Meter

Factory Fabricated
Duct Size	Gauge of GI sheet
1 – 900 mm	26
901 -1200 mm	24
1201 -1800 mm	22
1801 – 2100 mm	20
2101 – above	18

Site Fabricated
Duct Size	Gauge of GI sheet
Upto 750mm	24
750mm- 1500 mm	22
1510 mm- 2250 mm	20
above 2250 mm	18

Horizontal Ductwork
Ducts Size		Maximum Spacing
Area (m2)	Diameter	Maximum Spacing
less than 0.4	less than 125 mm	2.5 Meter
0.4 to 1	125 to 1000 mm	2 Meter
more than 1	more than 1000 mm	1.2 Meter

Vertical Ductwork
Ducts Type	Maximum Spacing (Meter)
round	3.6 Meter
rectangular	3 Meter

Rectangular Duct Sheet Thickness as per CPWD
Longest side (mm)	Minimum sheet thickness
Longest side (mm)	Galvanized Sheet Steel (GSS) IS: 277	For Aluminum IS:737
750 mm and below	0.63mm (22 Gauge)	0.8mm (20 Gauge)
751 mm to 1500 mm	0.8mm (20 Gauge)	1mm (18 Gauge)
1501 mm to 2250 mm	1mm (18 Gauge)	1.5 mm (15 Gauge)
2251 mm & above	1.25mm (16 Gauge)	1.8 (13 Gauge)

Round Duct Sheet Thickness as per CPWD
Longest side (mm)	Minimum sheet thickness
Longest side (mm)	Galvanized Sheet Steel (GSS) IS: 277	For Aluminum IS:737
150 mm to 500 mm	0.63mm (22 Gauge)	0.8mm (20 Gauge)
501 mm to 750 mm	0.8mm (20 Gauge)	1mm (18 Gauge)
751 mm to 1000 mm	0.8mm (20 Gauge)	1mm (18 Gauge)
1001 mm to 1250 mm	1mm (18 Gauge)	1.5 mm (15 Gauge)
1251 mm and above	1.25mm (16 Gauge)	1.8 (13 Gauge)

DUCT Support OR Gripple Wire Support
Duct Size (mm)	Spacing (M)	Size of MS Angle (mm x mm)	Size of Rod Dia (mm)
Up to 750	2.4	32x32x3	8
751 to 1000	2	40x40x5	10
1000 to 1500	2	40x40x5	10
1501 to 2250	2	50x50x6	12
2251 to above	2	50x50x6	12

Round Duct Support
Round Duct Size (mm)	Spacing of Supports (m)	Size of M.S. Angle (mm)	Dia. of Hanger Rod (mm)
Up to 500	1.5	40 x 40 x 6	12
501 to 1200	1.5	40 x 40 x 6	12
1201 to 2250	1.5	50 x 50 x 6	15

Normal Ducting:
Larger duct-dimension	Spacing of Supports (m)	Sheet thickness, SWG (mm)
Up to 750 mm	1.5 To 2	2 24 G (0.63 mm) (25×25 GI flanges acceptable)
751 to 1500 mm	1.5 To 2	22 G (0.80 mm) (25x25x3 MS flanges up to 1000mm; 40x40x5 MS flanges beyond 1000mm)
1501 mm to 2250 mm	1.5 To 2	20 G (1.00 mm) (40x40x5 MS flanges)
Above 2250 mm	1.5 To 2	18 G (1.20 mm) (50x50x6 MS flanges)

Supporting details for Low-Pressure system
LARGER SIDE OF DUCT mm	SUPPORTING ANGLE mm	VERTICAL ROD DIAMETER mm	MAXIMUM SPACING BETWEEN SUPPORTS mm
Upto 900	40x40x6	10	3000
901 to 1500	50x50x6	10	3000
1501 to 2400	50x50x6	10	2400
2401 and above	65x65x6	12	2400

Supporting details for Round Duct
DUCT DIAMETER mm	STRAP			ROD
DUCT DIAMETER mm	No	WIDTH mm	THICKNESS G	No	DIAMETER mm
Upto 600	1	25	22	1	7
601 to 900	1	25	20	1	10
901 to 1250	2	25	20	2	10
1251 t o1500	2	25	18	2	10
1501 to 2100	2	25	18	2	10

Diffuser size
Area	Ceiling Height	Diffuser size(dia.)
Up to 12 sqmm	2.4 – 2.7m	200mm
Up to 12 sqmm	3m	250mm
Up to 20 sqmm	2.4m – 2.7m	250mm
Up to 20 sqmm	3m	300mm
Over 20 sqmm		multiple diffusers

Additional refrigerant charged volume
Liquid pipe Size	R410A (kg/m)
6.4 mm	0.022
9.5 mm	0.057
12.7 mm	0.11
15.9 mm	0.18
19.1 mm	0.26
22.2 mm	0.37
25.4 mm	0.45

Drain Pipe Capacity
Condensate water volume : V (L/h)=Indoor Unit (HP)x2	I.D (mm)	Thickness (mm)
V ≤ 14	Φ 25	3
14 ＜ V ≤ 88	Φ 30	3.5
88 ＜ V ≤ 175	Φ 40	4
175 ＜ V ≤ 334	Φ 50	4.5
334 ＜ V	Φ 80	6
*If Slop is <1% than select next higher Size of Drain Pipe

Filed under Uncategorized

How to Design Efficient Street Lighting-Part-4

October 18, 2020 2 Comments

(F) Lighting Pollutions

Light pollution is an unwanted consequence of outdoor lighting and includes such effects as sky glow, light trespass, and glare.
30 to 50% of all light pollution is produced by roadway lighting that shines wasted light up and off target.

(1) Glare:

Glare is the condition of vision in which there is discomfort or a reduction in the ability to see significant objects. Glare affects human vision and it is subdivided into four components, Disability Glare, Discomfort Glare, Direct Glare and Indirect Glare.
By origin

Direct Glare
Indirect (reflected) Glare

By effect on people

Disability Glare
Discomfort Glare

Disability glare:
Disability glare is the glare that results in reduced visual performance and visibility.
Since disability glare reduces the ability to perceive small contrasts.
It can impair important visual tasks in traffic such as detecting critical objects, controlling headlights, and evaluating critical encounters, making glare a potential danger for road users.
LED light sources can provide very high luminance levels which may cause glare. For this reason, LED lamps are commonly equipped with diffusers to reduce this luminance.
Disability glare may vary for different individuals and it can be calculated objectively.
In a particular illuminated environment, the human eye will be able to detect differences in luminance down to a certain threshold. This threshold can be compared for a situation in the same environment when a source of glare is added. By comparing these thresholds, the threshold increment can be derived.
Discomfort glare:
Discomfort glare is the glare producing discomfort. It does not necessarily interfere with visual performance or visibility.
As vertical light angles increase, discomforting glare also increases
Discomfort glare, on the other hand, is a subjective phenomenon and there is no method for its Rating.
Although the 9-point De Boer scale (ranging from “1” for “unbearable” to “9” for “unnoticeable”) is the most widely used in the field of automotive and public lighting.
Direct Glare:
Direct glare is caused by excessive light entering the eye from a bright light source. The potential for direct glare exists anytime one can see a light source. With direct glare, the eye has a harder time seeing contrast and details.
A system designed solely on lighting levels, tends to aim more light at higher viewing angles, thus producing more potential for glare.
Exposed bright light source, for example a dropped lens cobra head or floodlight causes of direct glare.
Direct glare can be minimized with careful equipment selection as well as placement.

Figure illustrates two examples of exterior lighting that results in glare.

Fig shows how full cutoff luminaries (Shielded Luminaires) can minimize this direct glare. In exterior applications, use fully shielded luminaires that directs light downwards towards the ground.
Indirect Glare:
Indirect glare is caused by light that is reflected to the eye from surfaces that are in the field of view – often in the task area.
Indirect Glare can be minimized with the type and layout of lighting equipment. Direct the light away from the observer with the use of low glare, fully shielded luminaries.
As the uniformity ratio increases (poor uniformity), object details become harder to see.
For roadway lighting, good uniformity shows evenly lighted pavement. However, to meet small target visibility criteria, a non uniform roadway surface may be better.
There should be a balance between uniform perception and detecting objects on the road. Also, emphasis is put on horizontal surface uniformity. In reality, vertical surfaces may require more lighting in order to improve guidance.
How to Reduce Glare:
Glare and light trespass are more concern when installing floodlights.
Use shielded Light should be use to reduce Glare.
Higher mounting heights can more effective in controlling spill light, because floodlights with a more controlled light distribution (i.e., narrower beam) may be used, and the floodlights may be aimed in a more downward direction, making it easier to confine the light to the design area.
Lower mounting heights increase the spill light beyond the property boundaries. To illuminate the space satisfactorily, it is often necessary to use floodlights with a broader beam and to aim the floodlights in directions closer to the horizontal than would occur when using higher mounting heights.
Lower mounting heights make bright parts of the floodlights more visible from positions outside the property boundary, which can increase glare.

(2) Sky glow:

Sky Glow is brightening of the night sky caused by outdoor lighting.
Light that is emitted directly upward by luminaries or reflected from the ground is scattered by dust and gas molecules in the atmosphere, producing a luminous background. It has the effect of reducing one’s ability to view the stars in Night.

How to Reduce Sky Glow
While it is difficult to accurately model sky glow, at this point it is presumed that the most important factors are light output and lamp spectral characteristics, light distribution from the luminaire, reflected light from the ground, and aerosol particle distribution in the atmosphere.
If the quantity of light going into the sky is reduced, then sky glow is reduced. Thus, to reduce sky glow by
By using full cutoff luminaires to minimize the amount of light emitted upward directly from the luminaire.
Reduce Lighting Level.
Make practice to Turn off unneeded lights
Limited Lighting hours in outdoor sales areas, parking areas, and signages
Installing Low-Pressure Sodium light sources, which allow astronomers to filter the line spectra from telescopic images.

(3) Light Trespass:

Light trespass is condition when spill (Unwanted or Unneeded) light from a streetlight or floodlight enters a window and illuminates an indoor area.
How to Reduce Trespass
Select luminaries, locations, and orientations to minimize spill light onto adjacent properties.
Use well-shielded luminaries.
Keep floodlight aiming angles low so that the entire beam falls within the intended lighted area.

Difference between full cutoffs and fully shielded:

The full cutoff has is luminaries that have no direct up light (no light emitted above horizontal) and 10% of light intensity between 80° and 90°.
The term full cutoff is often substituted for the term fully shielded.
The both terms are not equivalent. Fully shielded luminaires emit no direct up light, but have no limitation on the intensity in the region between 80° and 90°
Luminaires that are full cutoff, cutoff, semi cutoff, and non cutoff , may also qualify as fully shielded.

There is also a confusing assumption that a luminaire with a flat lens qualifies as a full cutoff luminaries. While this may be true or not in some Lighting Fixtures case.

Fully shielded means, a lighting fixture constructed in such a manner that the bulb should be fully recessed into Fixture so that all light is directed downward below the horizontal.
The fixture is angled so the lamp is not visible below the barrier (no light visible below the horizontal angle).

(G) Selection of Luminas:

(1) Types of Lighting Source

Street Lights are mostly Low-pressure sodium (LPS), High-pressure sodium (HPS), Metal halide and Light emitting diodes (LED).
LPS is very energy efficient but emits only a narrow spectrum of pumpkin-colored light that some find to be undesirable.
LPS is an excellent choice for lighting near astronomical observatories and in some environmentally sensitive areas.
HPS is commonly used for street lighting in many cities. Although it still emits an orange-colored light, its coloring is more “true to life” than that of LPS.
Where it’s necessary to use white light, there are metal halide and LEDs.

High-pressure sodium lamps should be used for expressways, main roads, secondary roads and branch roads.
Low-power metal halide lamps should be used in mixed traffic roads for motor vehicles and pedestrians in residential areas.
Metal halide lamps can be used for motor vehicle traffic, such as city centers and commercial centers, which require high color identification.
Metal halide lamps, CFL lamps are used at Pedestrian streets in industrial areas, sidewalks in residential areas, and sidewalks on both sides of motorway traffic.
LED streetlights are more durable, longer lasting, efficiency, dimmable capacity and cost effective than traditional lights.
LED also enhances public safety by delivering superior visible light while providing the environmental advantage of using less energy.

(2) Color Rendering Index (CRI):

CRI Measures the ability of the artificial light to show or reproduce the colors of the road or objects on the road, relative to a natural light source.
The natural light source (the sun) has CRI of 100. The higher
This index the better the visibility will be. For all types of road CRI ≥ 70 is recommended.
Efficacy
At the low end LED efficacy starts at 70 lumens per watt (lm/W) and reaches as high as 150 lm/W.
While the mean efficacy for outdoor area fixtures is slightly lower than common indoor fixtures such as troffers and linear lighting about 100 lm/W for area lights compared to about 110 lm/W for troffers and linear fixtures this difference is not significant. It may be the result of outdoor area lights requiring more precise luminous intensity distributions and other factors unique to outdoor lighting.

(3) Fixture Protection:

When using sealed road lighting, the protection level of the light source cavity should not be lower than IP54.
For roads and places with dangerous environmental pollution and heavy maintenance, the protection level of the light source cavity should not be lower than IP65.
The degree of protection of the lamp electrical appliance cavity should not be lesser than IP43.
Lamps with excellent corrosion resistance should be used in areas or places with high levels of corrosive gases such as acid and alkali in the air.

(H) Effective Road Lighting:

Sufficient illumination.
Good uniformity.
No Glare.
Low consumption.
No Color Temperature abnormalities
No Zebra effect
Shielded lighting to ensure light is pointed downwards
Completely uniform illuminance.
No requirement for over lighting to obtain sufficient average illumination.
Absence of glare.
Absence of low angle radiation that causes sky glow.
Control of light trespass.
High redundancy.

Effective Road Lighting
Features	Benefits
Proper pole height & spacing	Provide uniform light distribution
Proper Luminaire aesthetics	Blends in with the surroundings
Good maintenance	Reduce problems in lightning
High lamp efficiency	Minimize energy cost
Life of Luminaire	Reduce lamp replacement cost
Good color rendering	Helps object appear more natural
Proper light distribution	Provide required light on roads
Cost effectiveness	Lowers operating cost
Minimizing light pollution & glare	Reduce energy use

Effective Energy-efficient Street Lighting Systems (NYSERDA, 2002)
Features	Benefits
Proper pole height and spacing	Provides uniform light distribution, which improves appearance for safety and security Meets recommended light levels Minimizes the number of poles, reducing energy and maintenance costs
Proper luminaire aesthetics	Blends in with the surroundings
High lamp efficacy and Luminaire efficiency	Minimizes Energy cost
Life of the luminaire and other components	Reduces lamp replacement costs
Cost effectiveness	Lowers operating cost
High Lumen Maintenance	Reduces lamp replacement costs
Good color rendering	Helps object appear more natural and pleasing to the public Allows better recognition of the environment, improves security
Short lamp Re strike	Allows the lamp to quickly come back after a power interruption
Proper light distribution	Provides required light on the roads and walkways
Proper Cutoff	Provides adequate optical control to minimize light pollution
Minimizing light pollution and Glare	Reduces energy use
Automatic Shutoff	Saves energy and maintenance costs by turning lamps off when not needed

Minimum Value of Street Light Designing
Descriptions	Min Value
Watt	400
Lumens Per Watt	80 To 140
Voltage	230Volt
Frequency	50 To 60Hz
Power Factor	More than 95
THD	< 20%
Life Hours	70,000 hours
Color Temperature	4000K To 5000K
CRI	More than 75
Beam Angle / Beam Pattern	Type 2,3,4,5
Operating Temperature	(-)25°C To (+)50°C
Working Humidity	10% To 90% RH
IP Rating	IP67
Dimmable	0-10V
Optic Lens Material	High Polycarbonate (PMMA)
Forward Current	>600mA
Housing	IP65 – Aluminum Alloy and PC Lens
Dimension	18.23″ X 13.58″ X 4.57″
Weight	15.30 lbs – 34.39 lbs
Warranty	10 Years

Filed under Uncategorized

How to Design Efficient Street Lighting-Part-3

October 2, 2020 1 Comment

(C) Lighting Factor:

(1) Maintenance Factor (Light Loss Factors) (MF)

The Maintenance Factor (Light loss factor) is the combination of factors used to denote the reduction of the illumination for a given area after a period of time compared to the initial illumination on the same area.
The efficiency of the luminaire is reduced over time. The designer must estimate this reduction to properly estimate the light available at the end of the lamp maintenance life.
Luminaire maintenance factors vary according to the intervals between cleaning, the amount of atmospheric pollution and the IP rating of the luminaire.
However, it is proposed to consider maintenance factor of not less than 0.5 for LED Road lighting installations for IP66 rated luminaires.
The maintenance factor may range from 0.50 to 0.90, with the typical range between 0.65 To 0.75
These maintenance factor values shall be adopted for the purposes of producing the lighting simulation design.
The maintenance factor is the product of the following factors.
LLF = LLD x LDD x EF
Mostly We consider Maintenance factor from 0.8 to 0.9
We have to choose Maintenance factor carefully by increasing maintenance factor 0.5 the spacing of pole increasing 2 meter to 2.5 meter

Maintenance Factor	Max. Spacing of Pole (Meter)
0.95	43
0.9	40.5
0.85	38
0.8	36

(a) Lamp Lumen Depreciation Factor (LLD)

As the lamp progresses through its service life, the lumen output of the lamp decreases. This is an inherent characteristic of all lamps. The initial lamp lumen value is adjusted by a lumen depreciation factor to compensate for the anticipated lumen reduction.
This assures that a minimum level of illumination will be available at the end of the assumed lamp life, even though lamp lumen depreciation has occurred. This information should be provided by the manufacturer. For design purposes, a LLD factor of 0.9 to 0.78 should be used.

(b)Luminaire Dirt Depreciation Factor (LDD).

Dirt on the exterior and interior of the luminaries and to some on the lamp reduces the amount of light reaching the roadway.
Various degrees of dirt accumulation may be anticipated depending upon the area in which the luminaire is located. Industry, exhaust of vehicles, especially large diesel trucks, dust, etc, all combine to produce the dirt accumulation on the luminaries.
Higher mounting heights, however, reduce the vehicle-related dirt accumulations.

LDD factor of 0.87 to 0.95 should be used. This is based on a moderately dirty environment and three years exposure time.

(c) Equipment Factor (EF).

Allows for variations inherent in the manufacture and operation of the equipment (i.e., luminaries, system voltage and voltage drop).
It is generally assumed to be 95%.

(2) Coefficient of Utilization (CU):

Coefficient of Utilization is the ratio of the luminous flux from a luminaire received on the surface of the roadway to the lumens emitted by the luminaire’s lamps alone.
Coefficient of Utilization should be maximum.
Coefficient of Utilization differs with each luminaire type, and depends upon mounting height, road width, and overhang.
The coefficient of utilization (K) should be over 30% or the utilance above 40% for the road, highway, square or enclosure. Luminaires or floodlights should not by placed far from the area to be lit or, where appropriate, light projection beyond the useful zone should be minimized (K = average maintained illuminance multiplied by the surface calculation and divided by the lumens installed).

Various Factors
Type	Luminaries Dirt Depreciation	Luminaire Lumen Depreciation	Total Light Loss Factor
LED	0.9	0.85	0.765
HPS	0.9	0.9	0.81
LPS	0.9	0.85 (0.7 for 180W)	0.765 (0.63 for 180W)

Light Loss Factors
Type of Lamp	Laminar Dirt description	Light Loss Factor
HPS	0.88	0.74
Induction	0.88	0.62
LED	0.88	0.72

Maintenance factors
Cleaning intervals (months)	Pollution category
Cleaning intervals (months)	High	Medium	Low
12	0.53	0.62	0.82
18	0.48	0.58	0.8
24	0.45	0.56	0.79
36	0.42	0.53	0.78

Maintenance Factors for 36 month cleaning interval
Factors	IP5X			IP6X
	Pollution category			Pollution category
	Low	Medium	High	Low	Medium	High
LMF	0.88	0.82	0.76	0.9	0.87	0.83
LLMF	0.89	0.89	0.89	0.89	0.89	0.89
MF	0.78	0.73	0.68	0.80	0.77	0.74

(E) Lighting Uniformities

(1) Lighting Uniformities

Uniformity is a description of the smoothness of the lighting pattern or the degree of the intensity of bright and dark areas on the road.
Uniformity is a measure of how evenly distributed the light on the road is, which can be expressed as Overall Uniformity (UO) and Longitudinal Uniformity (UL).
The uniformity ratio shall not exceed 4:1 and preferably should not exceed 3:1 except on residential streets, where 6:1 may be acceptable.

(a) Overall uniformity:

In design, the overall uniformity (UO) is expressed as a ratio of the minimum to the average luminance on the road surface of the carriageway within the calculation area.
UO=Lmin / Lave

It is a measure of how evenly or uniformly illuminate on the road surface.
A good overall uniformity ensures that all spots and objects on the road are sufficiently lit and visible to the motorist.
The industry accepted value for UO is 30 to 0.40.

(b) Longitudinal uniformity:

The longitudinal uniformity (UL) is expressed as the ratio of the minimum to maximum luminance along the center line of a lane within the calculation area.
UL=Lmin / Lmax.
Longitudinal uniformity is a measure to reduce bright and dark bands of light appearing on road lit surfaces. The effect can be somewhat hypnotic and present confusing luminance patterns.

It is a measure to reduce the intensity of bright and dark banding on road lit surface.
A good level of longitudinal uniformity ensures comfortable driving conditions by reducing the Pattern of high and low luminance levels on a road (i.e. zebra effect).
It is applicable to long continuous roads.

Combination of Overall Uniformity and Longitudinal Uniformity:

The picture on the left shows a road with good UO while the picture on the right has low level of UO. The Road is more visible in the road with higher UO. Having higher UO allows the motorist to see the road clearly and anticipate potential road hazards (e.g. open manholes, road excavations, sharp objects on the road, people crossing the street).
The picture on the right shows a road with low level of UL demonstrating the ‘Zebra Effect’ while the picture on the left has high level of UL without ‘Zebra Effect’.
The ‘zebra effect’ can cause discomfort to motorists, posing a risk to road safety. Ensuring good level of uniformity can reduce the luminance level needed.

Lighting Levels
Category	Eave ( LUX)	Emin LUX)	Uniformity ratios
Category	Eave ( LUX)	Emin LUX)	Emax : Emin	Eave : Emin
Express & Main street	30	15	3:01	2.5:1
Suburban shopping street	25	10	5:01	3:01
Subsidiary street	15	10	5:01	3:01
Other streets	15	5	10:01	5:01

Lux Level
Road Classification	Area Classification	Average Lux	Uniformity Ratio (Aver./Min.)
Arterial (Minor & Major)	Commercial	12	3 to 1
	Intermediate	9
	Residential	6
Collector (Minor & Major)	Commercial	8
	Intermediate	6	4 to 1
	Residential	4
Local	Commercial	6
	Intermediate	5	6 to 1
	Residential	3
Alleys	Commercial	4
	Intermediate	3	6 to 1
	Residential	2	6 to 1
Sidewalks (Roadside)	Commercial	3	3 to 1
	Intermediate	6	4 to 1
	Residential	2	6 to 1
Pedestrian Ways		15	3 to 1

Illumination for Intersections
Functional Classification	Average Maintained Illumination at Pavement by Pedestrian Area Classification in Lumen			Uniformity
Functional Classification	High	Medium	Low	Eavg/Emin
Major/Major	37	28	19	32
Major/Collector	31	24	16	32
Major/Local	28	22	14	32
Collector/Collector	26	19	16	43
Collector/Local	23	17	11	43
Local/Local	19	15	9	65

Illumination for Pedestrian Areas
Maintained Illuminance Values for Walkways
Area Classification	Description	E avg (Lux)	EV min (Lux)	E avg/Emin
High Pedestrian Conflict	Mixed Vehicle and Pedestrian	22	11	43
Areas	Pedestrian Only	11	5	43
Medium Pedestrian	Pedestrian Areas	5	2	43
Conflict Areas	Pedestrian Areas	5	2	43
Low Pedestrian	Rural/Semi-Rural Areas	2	1	108
Conflict Areas	Low Density Residential (2 or fewer dwelling units per acre)	3	1	65
	Medium Density Residential (2.1 to 6.0 dwelling units per acre)	4	1	43
Pedestrian Portion of Pedestrian/Vehicular Underpasses	Day	108	54	43
Pedestrian Portion of Pedestrian/Vehicular Underpasses	Night	43	22	32

(2) Surround Ratio (SR):

Road lighting should be illuminate not only the road, but also the adjacent areas so motorists can see objects in the periphery and anticipate potential road obstructions (e.g., a pedestrian about to step onto the road).
The SR is the visibility of the road’s periphery relative to that of the main road itself.
As per industry standards, SR should be at least 50.
Figure show how road lighting should illuminate both the main road and its periphery.

Filed under Uncategorized

How to Design Efficient Street Lighting-Part-2

September 4, 2020 2 Comments

(C) Lighting Fixture:

(1) Fixture’s Mounting Height:

Higher mounting heights used in conjunction with higher wattage luminaries enhances lighting uniformity and typically reduces the number of light poles needed to produce the same illumination level.
In general, higher mounting heights tend to produce a more cost-effective design. For practical and aesthetic reasons, the mounting height should remain constant throughout the system.
The manufacturer’s photometric data is required to determine an appropriate mounting height.
Typical mounting heights for highway lighting purposes range from 30 ft to 55 ft (9.1 meter to 16.8 meter).
Mounting heights for light towers or High mast is typically 80 ft (24 m) or greater.
The installation height is too low, the glare of the lamp increases.
As the installation high increase, glare decreases, but the lighting utilization rate decreases.

(2) Fixtures Classification:

The Illuminating Engineering Society of North America (IESNA, IES or BIS1981) provides classifications for luminaires according to their glare control and high-angle brightness.

(a) Full Cutoff (F):

A luminaire light distribution is designated as full cutoff (F) when Zero intensity at or above horizontal (90° above nadir) and Less than 10% of lamp lumens at or above 80°.
Full-cutoff fixtures reduce glare dramatically and eliminate direct up light by sending all their light toward the ground .This efficiency should translate into lower bulb wattages if the existing poles are used. However, some lighting engineers believe that to achieve the same illumination uniformity as their semi-cutoff counterparts, full-cutoff fixtures need to be mounted either on taller poles or closer together
Benefits:
Limits spill light on to adjacent property, reduces glare. No light is emitted directly from the luminaries into the sky.
Reduce Lighting Pollution.
Limitations:
May reduce pole spacing to maintain uniformity and increase pole and luminaire quantities.
Application:
Use for roadway, parking, and other vehicular lighting applications. Minimizes glare and light pollution and light trespass.

(b) Cutoff (C):

A luminaries light distribution is designated as cutoff (C) when Less than 2.5% Intensity at or above horizontal (90° above nadir) and Less than 10% of lamp lumens at or above 80°.
The direction of maximum intensity may vary but should be below 65º.
Benefits:
Small increase in high-angle light allows increased pole spacing.
Cutoff system is the reduction of glare.
Limitations:
May allow some up light (Sky Light) from luminaries. Typically a small overall impact on sky glow.
Application:
Interchange lighting and rural intersections due to the ability to reduce glare.
Use in applications where pedestrians are present. Provides more vertical illuminance than Full Cutoff luminaires.
Lamp rating should be less than 3200 lumens.
The cutoff design is where the luminaire light distribution is less than 25,000 lm at an angle of 90° above nadir (vertical axis) and 100,000 lm at a vertical angle of 80° above nadir.

(c) Semi Cutoff (S) (Medium Beam Angle):

A luminaire light distribution is designated as Semi cutoff (S) when Less than 5% Intensity at or above horizontal (90° above nadir) and Less than 20% of lamp lumens at or above 80°.
The direction of maximum intensity may vary but should be below 75º.
Benefits:
High-angle light accents taller vertical surfaces such as buildings. Most light is still directed downward.
Limitations:
Little control of light at property line.
Potential for increased glare when using high wattage luminaries. Typically directs more light into the sky than cutoff.
Application:
Used for standard road lighting. Adequate glare control is obtained with reasonable spacing.
The principal advantage of the semi-cutoff system is a greater flexibility in sitting.
Use in pedestrian areas. If using in residential areas, provide with house side shields to minimize light trespass. Lamp rating should be less than 3200 lumens.
For the semi-cutoff design, the luminous flux numbers become 50,000 lm for 90° above nadir and 200,000 lm at a vertical angle of 80° above nadir.
Semi-cutoff fixtures create broad cones of light that permit wide spacing between poles. But such fixtures create harsh glare and send some light directly into the sky.

(d) Non Cutoff (N) (Higher Beam Angle):

A luminaries light distribution is designated as Non Cutoff (N) when Emit light into all directions.
No limitations on light distribution at any angle.
There is considerable output near the horizontal plane.
Benefits:
Uniform luminous surfaces such as internally illuminated signs or globes. Wattage should be limited. Suitable for sports lighting, facade, landscape or other applications where luminaires are tilted due to limitations in pole or fixture locations
Limitations:
Location and aiming are critical. Most likely of all categories to produce offensive brightness and sky glow.
Application:
Used in areas with a lot of background light. Non-cutoff luminaries shall not be used at lower mounting heights because of glare.
Use for decorative applications only. Lamp rating should be less than 3200 lumens.
“Full cut off” fixtures must be installed properly, so that the bottom of the fixture is level with the ground.
“Fully Shielded” fixtures do not allow any light to be emitted above the lowest light emitting
part, but do not restrict light output in the “glare” zone, 90-80 degrees below horizontal.

(3) Fixtures Distributions (Optical System):

The Illuminating Engineering Society classified series of Fixture distribution patterns as Types I, II, III, IV, and V.

(a) Type I (Two-way):

The lateral distribution having a preferred lateral width of 15 degrees in the cone of maximum Lumen.
Illumination Pattern: Narrow, symmetric luminance pattern.
Fixture Location: This type is generally applicable to a luminaire location near the center of a roadway where the mounting height is approximately equal to the roadway width.
Type of Road: The luminaire is placed on the side of the street or edge of the area to be lighted. Most 1or 2 Lane Road
Application:

(b) Type II (Two Way) :

Light distributions have a preferred lateral width of 25 degrees.
Illumination Pattern: Slightly wider illuminance pattern than Type I.
Fixture Location: They are generally applicable to luminaires located at or near the side of relatively narrow roadways, where the width of the roadway does not exceed 1.75 times the designed mounting height.
Type of Road: The luminaire is placed on the side of the street or edge of the area to be lighted. It produces a long, narrow, oval-shaped lighted area which is usually applicable to narrower streets.

(c) Type III (Bat Wing) :

Type III light distributions have a preferred lateral width of 40 degrees.
Illumination Pattern: It produces an oval-shaped lighted
Fixture Location: This distribution is intended for luminaires mounted at or near the side of medium width roadways, where the width of the roadway does not exceed 2.75 times the mounting height.
Type of Road: The luminaire is placed on the side of the street or edge of area to medium width streets.

(d) Type IV (Forward throw “Asymmetric”):

Type IV light distributions have a preferred lateral width of 60 degrees.
Illumination Pattern: Widest luminance pattern.
Fixture Location: This distribution is intended for side-of-road mounting and is generally used on wide roadways where the roadway width does not exceed 3.7 times the mounting height.
Type of Road: very wide roadway (4 to 6 Lane)
Applications: Type IV often use at perimeters where Spill Light is required and there is no place to add Pole.

(e) Type V:

Type V light distributions have a circular symmetry of candlepower that is essentially the same at all lateral angles.
Illumination Pattern: It produces a circular, wider lighted area and is usually applicable to wide streets.
Fixture Location: The luminaries are mounting at or near center of roadways, center islands of parkway, and intersections.
Type of Road: very wide roadway (4 to 6 Lane)
Applications: Type V often applies to high-mast lighting.

GUIDE FOR LUMINAIRE LATERAL LIGHT TYPE AND PLACEMENT
Pole Arrangement	Road Width	Type of Distribution
One Side or Staggered	up to 1.5 x Mounting Height	Types II-III-IV
Staggered or Opposite	Beyond 1.5 x Mounting Height	Types III & IV
Center of the Roadway Mounting	up to 2 x Mounting Height	Type I

Type of Classification
AREA CLASSIFICATION	CUTOFF TYPE
Commercial	Full Cutoff or Semi Cutoff
Intermediate	Full Cutoff or Semi Cutoff
Residential	Full Cutoff

THE SELECTION OF LUMINAIRE MOUNTING HEIGHTS
Lamp Lumens	Mounting Height
≤20,000 Lumen	≤35 Foot
20,000 To 45,000 Lumen	35 To 45 Foot
45,000 To 90,000 Lumen	45 To 60 Foot

Fixture Mounting Height
Type of LED Luminaries	Type of Road	Lamp mounting height from the floor level (Meters)	Minimum Illumination Level (Lux) at centre of road	Color of Illumination
250-260W		Above 18	(20 To 22)	5000K-6500K
190W	A1	Between 11 To 15	(20 To 22)	5000K-6500K
140-170W	A1	Between 9 To 15	(18 To 20)	5000K-6500K
90-120W	A2/B1	07 To 11	(15 To 18)	4300K-5600K
70-120W	A2/B1	07- To 11	(15 To 18)	4300K-5600K
70-120W	B1/B2	06 To 09	(15 To 18)	4300K-5600K
70-50W	B1/B2/C1	7 To 9	(12 To 15)	4300K-5600K
45-50W	B1/B2/C1	5 To 7	(12 To 15)	4300K-5600K
25-30W	B1/B2/C1	5 To 7	(10 To 12)	4300K-5600K

Relationship between mounting height and spacing
Mounting Height	Width of road	6 Meter to 7 Meter		9 Meter to 10.5 Meter		12 Meter to 14 Meter
Mounting Height	Pole arrangement	Cut-off Type	Semi Cutoff Type	Cut-off Type	Semi Cutoff Type	Cut-off Type	Semi Cutoff Type
8 Meter	Single side	24	28	–	–	–	–
	Staggered	24	28	–	–	–	–
	Opposite	–	–	28	28	–	–
10 Meter	Single side	30	30	–	–	–	–
	Staggered	35	35	30	35	–	–
	Opposite	–	–	35	40	30	35
12 Meter	Single side	42	48	36	42	–	–
	Staggered	–	–	36	42	36	42
	Opposite	–	–	42	48	42	48

GUIDE FOR LUMINAIRE LATERAL LIGHT TYPE AND PLACEMENT
SIDE OF THE ROADWAY MOUNTING			CENTER OF THE ROADWAY MOUNTING
One Side or Staggered	Staggered or Opposite	Local Street Intersection	Single Roadway	Twin Roadways (Median Mounting)	Local Street Intersections
Road Width up to 1.5 x Mounting Height	Road Width beyond1.5 x Mounting Height	Road Width up to 1.5x Mounting Height	Road Width up to 2x Mounting Height	Road Width up to 1.5x Mounting Height (each pavement)	Width up to 2.0x Mounting Height
Types	Types	Type	Type	Types	Types
II, III, IV	III & IV	II (4-way)	I	II & III	I (4-way) & V

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How to Design Efficient Street Lighting-Part-1

August 20, 2020 1 Comment

Introduction:

The basic idea of roadway and Highway lighting is to provide uniform level of illumination on road at horizontal and vertical level and provide a safe and comfortable environment for the night time driver.
Lighting design is basic idea of the selection and the location of lighting equipment to provide improved visibility and increased safety.
Street lighting systems should be designed in a way to avoid significant differences in luminance levels at the light source and on road areas. Furthermore, continuous variation of lighting levels can cause eye strain and should be avoided, in particular on long roads.
Road lighting provides visual conditions for safe, quick and comfortable movement of Road users.

Designing Factor for Street Light:

The factors that are playing a vital role in the Road Lighting are following.

(A) Type of Road

Road Classification

(B) Street Light Pole

Street Light Pole Arrangements
Placement of Pole

(C) Lighting Fixture

Lighting Fixture Mounting Height
Lighting Fixture Classification
Lighting Fixture Distributor

(D) Lighting Factors

Maintenance Factor
Coefficient of Utilization

(E) Lighting Uniformity

Lighting Uniformity
Surrounding Ratio

(F) Lighting Pollution

Glare
Sky Glow
Trespass

(G) Selection of Luminas

Type of Light
Watt
Lumen
CRI
Efficiency

(A) Classification As per Road:

Table 4 : Road Classes as per SP 72 (Part 8), IS 1944 (Part 1) and IS 1970
Class A1	Important routes with rapid and dense traffic where safety, traffic speed, and driving comfort are the main considerations
Class A2	Main Roads with considerable volume of mixed traffic, such as main city streets, arterial roads and thoroughfares.
Class B1	Secondary roads with considerable traffic such as main local traffic routes, shopping streets
Class B2	Secondary roads, with light traffic
Class C	Lighting for residential and unclassified roads not included in previous groups
Class D	Lighting for bridges and flyovers
Class E	Lighting for town and city centers
Class F	Lighting for roads with special requirement such as roads near air fields, railways and docks

TYPE OF ROAD
TYPE OF ROAD	DENSITY OF TRAFFIC	TYPE	EXAMPLE
A	Heavy and high speed motorized traffic	Road with fixed separators, No crossings for very long distance	National highways or state highways or called interstate highways, express ways or motor ways
B	Slightly lower density and lower speed traffic termed	Road which is made for vehicular traffic with adjoining streets for slow traffic and pedestrians as we find in metros	Trunk road or major road in a city
C	Heavy and moderate speed traffic	Important urban roads or rural roads. they do not interfere with the local traffic within the town	Ring roads
D	Slow traffic, pedestrians	Linking to shopping areas and invariably the pedestrians, approach road	Shopping street, trunk road
E	Limited speed. Slow or mixed traffic predominantly pedestrians,		Local streets, collectors road

(B) Street Light Pole:

(1) Street Light Arrangement:

There are four basic types of street lighting layout arrangements used for streets or highways illumination.

(a) One Side Pole Layout:

Arrangement: In One Side Pole Layout, all luminaries are located on one side of the road.
Road Width: For narrower roads.
Pole Height: The installation height of the lamp be equal to or less than the effective width of the road surface.

Advantage: There are good indelibility and low manufacturing cost.
Disadvantage: The brightness (illuminance) of the road on the side where the lamp is not placed is lower than the on which side the light pole is placed.

(b) Both Side Staggered Pole Layout:

Arrangement: In the staggered arrangement, the luminaires are placed alternately on each side of the road in a “zig-zag” or staggered fashion.
Road Width: For Medium Size roads.
Pole Height: The installation height of the lamp is equal or 1.5 time the effective width of the road.

Advantage: This type of arrangement is better than single side arrangement.
Disadvantage: Their longitudinal luminance uniformity is generally low and creates an alternating pattern of bright and dark patches. However, during wet weather they cover the whole road better than single-side arrangements.

(c) Both Side opposite Pole Layout:

Arrangement:
In Both Side Opposite Pole Layout, the luminaries located on both sides of the road opposite to one another.
Road Width: For Medium Size roads.
Pole Height: The installation height of the lamp will be 2 to 2.5 time the effective width of the road.

Advantage: opposite arrangements may provide slightly better lighting under wet conditions.
Disadvantage:
If the arrangement is used for a dual carriageway with a central reserve of at least one-third the carriageway with, or if the central reserve includes other significant visual obstructions (such as trees or screens), it effectively becomes two single-sided arrangements and must be treated as such.

(d) Twin-central Pole Layout:

Arrangement: In Twin central arrangement, the luminaries are mounted on a T-shaped in the middle of the center island of the road. The central reserve is not too wide, both luminaires can contribute to the luminance of the road surface on either lane.
Road Width: For Large Size roads.
Pole Height: The installation height of the lamp be equal to the effective width of the road.

Advantage: This arrangement generally more efficient than opposite arrangements. However, opposite arrangements may provide slightly better lighting under wet conditions.

(2) Proper Placement of Pole:

(i) Setback

Set back is the horizontal distance between the face of a light pole and the edge of traveled way.
Placing luminaries too close to a vertical surface results in hotspots at its base.
A setback of 3 foot to 4 foot works well for many applications.
Light from luminaires at extremely short setbacks grazes the surface and enhances its texture.
Light from luminaries at Long setbacks (Luminaries too far from a vertical surface) cause shadows at low levels.
Longer setbacks may be required for taller surfaces.
Scallops between fixtures become more noticeable as setback increases.
As setback (or spacing) distance increases, Light levels and uniformity decrease.

Set Back (BS 5489)
Design Speed	Pole Set Back
50 Km/Hr	0.8 Meter
80 Km/Hr	1 Meter
100 Km/Hr	1.5 Meter
120 Km/Hr	1.5 Meter

(ii) Overhang

Overhang is the horizontal distance between the center of a luminaries mounted on a bracket (Nadir) and the adjacent edge of a carriage way or traveled way.
In general, overhang should not exceed one fourth of the mounting height to avoid reduced visibility of curbs, obstacles, and footpaths.

(iii) Outreach

Outreach is the horizontal distance between the center of the column and the center of the luminaries and is usually determined for architectural aesthetic considerations.

(iv) Pole Boom(Arm) Length:

The use of an arm places the light source closer to the traveled way while allowing the pole to be located further from the edge of the traveled way.
Depending on the application, Pole arms may be single and/or double mast arms or davit arms at the top of the pole.
There are several different arm lengths and styles of arms that are used.

(v) Arm Type:

Type A bracket an arm has a single member arm. It is used when the Arm length is less than 3.5 Meter.
Type B bracket arm has a two member truss arm design. Type B arms are used when the Arm length is more than 3.5 Meter.

(vi) Arm Lengths:

The length of the bracket arm is dependent upon a street width, pole location in relation to the curb and the presence of a median.
Type A (Single member bracket) arms are available in 2 Meter and 2.5 Meter lengths.
Type B (Twin member bracket) arms are available in 3.5 Meter, 4 Meter and 5 Meter Lengths.
Pole Height is 10 Meter: On typical streets that are 12 Meter’ wide from curb to curb, either a 2 Meter or 2.5 Meter arm is used. Depending on whether the pole is located behind the sidewalk or in the grass parkway between the sidewalk and the curb, the arm length may need to be increased to 4 Meter.
Pole Height is 13 Meter: On an undivided street, generally Meter, 2.5 Meter or 4 Meter arms are used.
Pole Height is 13 Meter: divided Street, typically have a 8 Meter wide center median to divide opposing lanes of traffic. On streets where the light poles are installed in a raised median, two 4 Meter arms oriented 180° apart are used.

(vii) Boom Tilt Angle (Boom Angle)

When the angle of tilt is larger, a uniformity ratio is increasing. Otherwise discomfort glare is increasing because strong light comes into driver’s eyes. So the angle of tilt shall be kept from 15° to 30°.

Tilt Angle
Pole Height	Arm Length	Arm Tile Angle
6 Meter	0.5 Meter	5°,10°,15°
8 Meter	1 Meter	5°,10°,15°
10 Meter	1.5 Meter	5°,10°,15°
>=12 Meter	2 Meter	5°,10°,15°

(viii) Pole Height:

Light poles for conventional highway lighting applications support luminaire mounting heights ranging from approximately 30 ft to 50 ft (9.1 m to 15.2 m).
Light towers for high-mast lighting applications generally range from 80 ft to 160 ft (24.4 m to 48.8 m) and are designed in multiple sections.
Weathering steel is a common material choice for light towers.
Ornamental light Poles used for local streets generally range in height for 8 ft to 15 ft (2.4 m to 4.5 m).

Pole Height	Application
< 6 Meter	Majority of side streets or alleys, Public gardens and parking Area to make people feel safe
8 Meter	Urban traffic route , the multiplicity of road junctions
10 Meter	Urban traffic routes
12 Meter	Heavily used routes
18 Meter	High mast lighting poles shall be installed at large-scale area such as airports, dockyards, large industrial areas, sports areas and road Intersections.

(ix) Poles distance from Curb (Offset):

The lighting poles should not be installed very close to the pavement edge, because the capacity of the roadway is decreased and the free movement of traffic is obstructed.
For roads with raised curbs (as in urban roads) =Min. 0.3 meter and desirable 0.6 meter from the edge of raised curb.
For roads without raised curbs (as in rural roads)=Min. 1.5 meter from the edge of the carriageway, subject to min. 5.0 meter from the center line of the carriageway.
Height and overhang of mounting
The glare on eyes from the mounted lights decreases with increases in the height of mounting. Usually, mounting height range from 6 to 10m.
Overhangs on the lighting poles would keep the poles away from the pavement edges, but still allow the lamp to be held above the curb or towards the pavements.

(x) Pole to Pole Spacing

Spacing is the distance, measured along the center line of the road, between successive luminaries in an installation.
To preserve longitudinal uniformity, the space height ratio should generally be greater than 3.
Placing luminaries too far apart creates scallops at the base of the surface.
Spacing distances that are equal to 3 to 4 times the setback work well for many applications.
Placing luminaries closer together eliminates scallops.
Uniformity and light levels increase as spacing (or setback) distances decrease.
Spacing of luminaires normally does not exceed five to six mounting heights.
The span must not be more than 45 meters and for an average of 20-30 meters.

Lighting Pole details as per Road
Road	Road Width (Meter)	Pole Arrangement	Lamp (Watts)	Pole to Pole Spacing (Meters)	Mounting Height, (Meters)	Arm Length, (Meters)
Expressway	10	Twin Central	250	25 To 35	12	1.5
	15	Twin Central	250	20 To 35	12	3.0
	20	Opposite	250	20 To 45	12	1.5
	25		250	20 To 40	12	1.5
	30		250	20 To 30	12	1.5
	36		250	20 To 25	12	1.5
	40		250	20 To 22	12	1.5
Major	10	One-side	250	10 To 40	10	1.5
	15	One-side	250	10 To 45	12	3.0
	10	Twin Central	150	20 To 37	10	1.5
	15	Twin Central	250	20 To 43	12	3.0
	20	Opposite	150	20 To 40	10	3.0
	25		250	20 To 45	10	1.5
	30		250	20 To 45	10	1.5
	36		250	20 To 45	12	3.0
	40		250	20 To 45	2	3.0
Collector	10	One-side	150	10 To 40	10	1.5
	15	One-side	250	10 To 50	12	3.0
	10	Twin Central	150	20 To 40	10	1.5
	15	Twin Central	150	20 To 37	12	3.0
	20	Opposite	150	20 To 47	10	1.5
	25		250	20 To 48	10	1.5
Rural Highway	8	One-side	150	10 To 38	8	1.5
	10		150	10 To 37	8	3.0
	15		150	15 To 38	10	3.0
	10	Twin Central	150	20 To 45	10	3.0
	15		150	20 To 39	12	3.0
	20					1.5
Minor	4	One-side	70	10 To 40	8	1.5
	6		70	10 To 40	8	1.5
	8		70	10 To 40	8	1.5
	10		70	10 To 39	8	1.5
	10	Twin Central	70	20 To 35	8	1.5
	15	Staggered	70	10 To 20	8	1.5
	15	Opposite	70	20 To 40	8	1.5

Illumination Level
Classification	Average Illumination (lux)	Ratio Minimum to average illumination
Class A1	30	0.4
Class A2	15	0.4
Class B1	8	0.3
Class B2	4	0.3

Relationship between Mounting Height and Spacing of Fixtures
Pole Arrangement	Cut-off type		Semi cutoff type
Pole Arrangement	Height	Spacing	Height	Spacing
Single side	>=0.7 X Width of Road	<=3 X Fixture Mounting Height	>=0.8 X Width of Road	<=3.5 X Fixture Mounting Height
Both Side Staggered	>=1.5 X Width of Road	<=3.5 X Fixture Mounting Height	>=1.7 X Width of Road	<=4 X Fixture Mounting Height
Both Side Opposite	>=0.5 X Width of Road	<=3 X Fixture Mounting Height	>=0.6 X Width of Road	<=3.5 X Fixture Mounting Height
Twin central	>=0.7 X Width of Road	<=3.5 X Fixture Mounting Height	>=0.8 X Width of Road	<=4 X Fixture Mounting Height

Pole to Pole Distance vs Lux Level
Pole Height	Lamp	Pole to Pole Distance	Max. Illumination (Lux)	Average (Lux)
4 Meter	15 watt	12 to 18 Meter	25	18
5 Meter	18 watt	14 to 20 Meter	30	18
6 Meter	30 watt	18 to 24 Meter	32	20
7 Meter	50 watt	21 to 28 Meter	32	20
8 Meter	100 watt	24 to 32 Meter	40	22
9 Meter	110 watt	27 to 35 Meter	34	20
10 Meter	140 watt	30 to 40 Meter	35	22
12 Meter	180 watt	30 to 40 Meter	33	23
14 Meter	200 watt	30 to 40 Meter	30	21

Lux Vs Mounting Height
Fixtures (Lux)	Mounting Height
3000 to 10000 Lux	6 to 7 Meter
10000 to 20000 Lux	7 to 9 Meter
More than 20000 Lux	More than 9 Meter

Road – Pole Details
Road	Road Type	Type of Pole positions	Individual Carriageway Width (Meter)	Central Verge (Meter)	Pole Height above Ground (Meter)	Maximum Pole to Pole Spacing (Meter)	Clearance from Road Edge (Meter)	Bracket Length (Meter)	Tilt Angle	Lighting Specifications	Lamp (Watt)
A1	Dual Carriage	Central Verge	10	1.2	12	40	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Dual Carriage	Central Verge	11	1.2	12	40	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Dual Carriage	Central Verge	12	1.2	12	40	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Dual Carriage	Central Verge	14	1.2	12	40	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Dual Carriage	Central Verge	16	1.2	12	40	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Single Carriage	Opposite	12	0	12	35	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 250W
A1	Single Carriage	Opposite	14.5	0	12	35	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 250W
A1	Single Carriage	Opposite	16	0	12	40	0.6	Around one meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Single Carriage	Opposite	18	0	12	40	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Single Carriage	Opposite	21	0	12	40	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Single Carriage	Opposite	25	0	12	40	0.6	1 meter	10°	35 lux /0.4/ 0.33	HP SV 400W
A1	Single Carriage	Opposite	31	0	12	40	0.6	1 meter	10°	35 lux/ 0.4/ 0.33	HP SV 400W
A2	Single Carriage	Single Sided	10		11	30	0.6	< 1.0 meter	10°	25 lux /0.4/ 0.33	HP SV 250W
A2	Single Carriage	Single Sided	9		11	30	0.6	< 0.5 meter	10°	25 lux /0.4/ 0.33	HP SV 250W
A2	Single Carriage	Single Sided	7		11	30	0.6	< 0.5 meter	10°	25 lux /0.4/ 0.33	HP SV 250W
A2	Single Carriage	Single Sided	7		11	30	0.6	< 0.5 meter	10°	25lux /0.4/ 0.33	HP SV 250W
A3	Single Carriage	Single Sided	7		8	20	0.6	< 0.5 meter	10°	20lux /0.4	HP SV 150W
Pedestrian Pathway	Single Carriage	Single Sided	3m-6m		7.5	20-25	0.6	<0.5 meter	10°	20 lux /0.4	HP SV 150W

Pole Data
Poles (Meter)	Top Dia (mm)	Bottom Dia (mm)	Thickness (mm)	Base plate (mm)	Single Arm Bracket (mm)	Double Arm Bracket (mm)
3	70	130	3	200x200x12	1000	NA
3	70	130	3	200x200x12	NA	1000
4	70	130	3	200x200x12	1000	NA
4	70	130	3	200x200x12	NA	1000
4	70	130	3	200x200x12	1000	NA
5	70	130	3	200x200x12	NA	1000
5	70	130	3	200x200x12	1000	NA
6	70	130	3	200x200x12	NA	1000
6	70	130	3	200x200x12	1000	NA
7	70	135	3	225x225x16	1000	NA
7	70	135	3	225x225x16	NA	1000
8	70	135	3	225x225x16	1000	NA
8	70	135	3	225x225x16	NA	1000
9	70	155	3	260x260x16	1000	NA
9	70	155	3	260x260x16	NA	1000
9	70	175	3	275x275x16	1000	NA
9	70	175	3	275x275x16	NA	1000
10	70	175	3	275x275x16	1000	NA
10	70	175	3	275x275x16	NA	1000
10	70	200	3	290x290x16	1000	NA
10	70	200	3	290x290x16	NA	1000
11	70	210	3	320x320x20	1000	NA
11	70	210	3	320x320x20	NA	1000
12	70	230	3	325x325x20	1000	NA
12	70	230	3	325x325x20	NA	1000

Recommended Levels of Illumination (BIS 1981) (IS 1944)
Type of Road	Road Characteristics	Road Width (Meter)	Average Level of Illumination on Road Surface in Lux	Ratio of Minimum/Average Illumination	Ratio of Minimum/Max Illumination	Type of Luminaire Preferred	Luminas Mounting Height
A-1	Important traffic routes carrying fast traffic	>10.5,12,14,16,18,20,30	30	0.4	33	Cutoff	9 To 10 Meter
A-2	Main roads carrying mixed traffic like city main roads/streets, arterial roads, throughways	> 7 m up to 10 m	15	0.4	33	Cutoff	9 To 10 Meter
B-1	Secondary roads with considerable traffic like local traffic routes, shopping streets	< 7m Colony Roads	8	0.3	20	Cutoff or semi-cutoff	7.5 To 9 Meter
B-2	Secondary roads with light traffic	4m,5m, 6m	4	0.3	20	Cutoff or semi-cutoff	7.5 To 9 Meter

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Quick Reference Lighting Power Densities

August 2, 2020 1 Comment

Lighting Power Densities for Building Exteriors
ASHRAE 90.1-2004, Table 9.4.5
Tradable Surfaces	LPD
Uncovered Parking Areas –Parking Lots and drives	0.15 W/ft²
Building Grounds –Walkways less than 10 feet wide	1.0 W/linear foot
Building Grounds –Walkways 10 feet wide or greater; Plaza areas; Special Feature Areas	0.2 W/ft²
Building Grounds –Stairways	1.0 W/ft²
Building Entrances and Exits –Main entries	30 W/linear foot of door width
Building Entrances and Exits –Other doors	20 W/linear foot of door width
Canopies and Overhangs –free standing and attached	1.25 W/ft²
Outdoor Sales –Open areas (including vehicle sales lots)	0.5 W/ft²
Outdoor Sales –Street frontage for vehicle sales lots in addition to “open area” allowance	20 W/linear foot

Lighting Power Density
AS per CPWD
Building Area Type	LPD (W/m2)
Automotive Facility	9.7
Multifamily Residential	7.5
Convention Centre	12.9
Museum	11.8
Dining : Bar Lounge/ Leisure	14
Office	10.8
Dining : Cafeteria/ Fast Food	15.1
Parking Garage	3.2
Dining : Family	17.2
Performing Arts Theatre	17.2
Dormitory/ Hostel	10.8
Police/ Fire Station	10.8
Gymnasium	11.8
Post Office/ Town Hall	11.8
Health care-Clinic	10.8
Religious Building	14
Hospital/ Health Care	12.9
Retail/ Mall	16.1
Hotel	10.8
School/ University	12.9
Library	14
Sports Arena	11.8
Manufacturing Facility	14
Transportation	10.8
Motel	10.8
Motion Picture Theatre	12.9
Warehouse	8.6
Workshop	15.1

Interior Lighting Power Space Density As per Function Method
AS per CPWD
Building Area Type	LPD (W/m2)
Office-enclosed	11.8
Office-open plan	11.8
Conference/ Meeting/ Multipurpose	14
Classroom/Lecture/ Training	15.1
Lobby	14
• For Hotel	11.8
• For Performing Arts Theatre	35.5
• For Motion Picture Theatre	11.8
Audience/ Seating Area	9.7
• For Gymnasium	4.3
• For Convention Centre	7.5
• For Religious Buildings	18.3
• For Sports Arena	4.3
• For Performing Arts Theatre	28
• For Motion Picture Theatre	12.9
• For Transportation	5.4
Atrium-first three floors	6.5
Atrium-each additional floor	2.2
Lounge/ Recreation	12.9
• For Hospital	8.6
Dining Area	9.7
• For Hotel	14
• For Motel	12.9
• For Bar Lounge/ Leisure Dining	15.1
• For Family Dining	22.6
• Food Preparation	12.9
Laboratory	15.1
Restrooms	9.7
Dressing/ Lockers/ Fitting Room	6.5
Corridor/ Transition	5.4
• For Hospital	10.8
• For Manufacturing facility	5.4
Stairs-active	6.5
Active Storage	8.6
• For Hospital	9.7
Inactive Storage	3.2
• For Museum	8.6
Electrical/ Mechanical Facility	16.1
For Indoor Field Area	15.1
Warehouse
• For Fine Material Storage	15.1
• For Medium/ Bulky Material
Storage	9.7
Workshop	20.5
Convention Centre – Exhibit Space	14
Library
• For Card File & Cataloguing	11.8
• For Stacks	18.3
• For Reading Area	12.9
Hospital
• For Emergency	29.1
• For Recovery	8.6
• For Nurse Station	10.8
• For Exam Treatment	16.1
• For Pharmacy	12.9
• For Patient Room	7.5
• For Operating Room	23.7
• For Nursery	6.5
• For Medical Supply	15.1
• For Physical Therapy	9.7
• For Radiology	4.3
• For Laundry – Washing	6.5
Automotive – Service Repair Manufacturing Facility	7.5
• For Low Bay (<8m ceiling)	12.9
• For High Bay (>8m ceiling)	18.3
• For Detailed Manufacturing	22.6
• For Equipment Room	12.9
• For Control Room	5.4
Hotel/ Motel Guest Rooms	11.8
Dormitory – Living Quarters	11.8
Museum
• For General Exhibition	10.8
• For Restoration	18.3
Bank Office – Banking Activity Area	16.1
Retail
• For Sales Area	18.3
• For Mall Concourse	18.3
Sports Arena
• For Rising Sports Area	29.1
• For Court Sports Area	24.8
Parking Garage – Garage Area	2.2
Transportation
• For Airport – Concourse	6.5
• For Air/ Train/ Bus-Baggage Area	10.8
• For Ticket Counter Terminal	16.1

Exterior Lighting Power Space Density
AS per CPWD
Exterior Lighting Applications	Power Limits
Building entrance (with canopy)	13 W/m2 of canopied area
Building entrance (without canopy)	90 W/linear meter of door width
Building exit	60 W/linear meter of door width
Building facades	2 W/m2 of vertical facade area2

Lighting Power Densities for Buildings Except Low-Rise Residential Buildings
ANSI/ASHRAE/IES Standard 90.1-2010: Table 9.6.11
Common Space Type	LPD (W/ft²)
Conference/Meeting/Multipurpose	1.23
Corridor/Transition	0.66
Dining Area	0.65
Electrical/Mechanical	0.95
Food Preparation	0.99
Lobby	0.99
Lobby for Elevator	0.64
Lounge/Recreation	0.73
Office: Enclosed	1.11
Office: Open Plan	1.11
Restrooms	0.98
Stairway	0.69
Storage	0.63
Workshop	1.59

Lighting Power Densities Using the Building Area Method
ASHRAE-TABLE 9.5.1
Building Area Type	*LPD*
Automotive facility	0.82W/ft2
Convention center	1.08W/ft2
Courthouse	1.05W/ft2
Dining: bar lounge/leisure	0.99W/ft2
Dining: cafeteria/fast food	0.90W/ft2
Dining: family	0.89W/ft2
Dormitory	0.61W/ft2
Exercise center	0.88W/ft2
Fire station	0.71W/ft2
Gymnasium	1.00W/ft2
Health-care clinic	0.87W/ft2
Hospital	1.21W/ft2
Hotel	1.00W/ft2
Library	1.18W/ft2
Manufacturing facility	1.11W/ft2
Motel	0.88W/ft2
Motion picture theater	0.83W/ft2
Multifamily	0.60W/ft2
Museum	1.06W/ft2
Office	0.90W/ft2
Parking garage	0.25W/ft2
Penitentiary	0.97W/ft2
Performing arts theater	1.39W/ft2
Police station	0.96W/ft2
Post office	0.87W/ft2
Religious building	1.05W/ft2
Retail	1.40W/ft2
School/university	0.99W/ft2
Sports arena	0.78W/ft2
Town hall	0.92W/ft2
Transportation –Airport	0.77W/ft2
Warehouse	0.66W/ft2
Workshop	1.20 W/ft2

Maximum Illumination Power Densities
Building Code of Australia (BCA)
Lux Level of Rooms	LPD
< 80 Lux:	7.5 Watt/M2
80 To 160 Lux	9 Watt/M2
160 To 240 Lux	10 Watt/M2
240 To 320 Lux	11 Watt/M2
320 To 400 Lux	12 Watt/M2
400 To 480 Lux	13 Watt/M2
480 To 540 Lux	14 Watt/M2
540 To 620 Lux	15 Watt/M2

ILLUMINATION POWER DENSITY
Building Code of Australia (BCA)
Space	LPD
Auditorium, church and public hall	10 Watt/M2
Boardroom and conference room	10 Watt/M2
Carpark – general	6 Watt/M2
Carpark – entry zone (first 20m of travel)	25 Watt/M2
Common rooms, spaces and corridors in a Class 2 building	8 Watt/M2
Control room, switch room, and the like	9 Watt/M2
Corridors	8 Watt/M2
Courtroom	12 Watt/M2
Dormitory of a Class 3 building used for sleeping only	6 Watt/M2
Dormitory of a Class 3 building used for sleeping and study	9 Watt/M2
Entry lobby from outside the building	15 Watt/M2
Health-care – children’s ward	10 Watt/M2
Health-care – examination room	10 Watt/M2
Health-care – patient ward	7 Watt/M2
Health-care – all patient care areas including corridors	13 Watt/M2
Kitchen and food preparation area	8 Watt/M2
Laboratory – artificially lit to an ambient level of 400 lx or more	12 Watt/M2
Library – stack and shelving area	12 Watt/M2
Library – reading room and general areas	10 Watt/M2
Lounge area for communal use in a Class 3 building or Class 9c	10 Watt/M2
Museum and gallery – circulation, cleaning and service lighting	8 Watt/M2
Office – artificially lit to an ambient level of 200 lx or more	9 Watt/M2
Office – artificially lot to an ambient level of less than 200 lx	7 Watt/M2
Plant room	5 Watt/M2
Restaurant, Cafe, bar, hotel lounge and a space for the serving of food or drinks	18 Watt/M2
Retail space including a museum and gallery whose purpose is the sale of objects	22 Watt/M2
School – general purpose learning areas and tutorial rooms	8 Watt/M2
Sole-occupancy unit of a Class 3 building	5 Watt/M2
Sole-occupancy unit of a Class 9c building	7 Watt/M2
Storage with shelving no higher than 75% of the height of the aisle lighting	8 Watt/M2
Storage with shelving higher than 75% of the height of the aisle lighting	10 Watt/M2
Service area, cleaner’s room and the like	5 Watt/M2
Toilet, locker room, staff room, rest room and the like	6 Watt/M2
Wholesale storage and display area	10 Watt/M2

MAXIMUM ILLUMINATION POWER DENSITY
Building Code of Australia (BCA)
Illumination	LPD (Watt/M2)
Rooms to achieve
<80 lux	7.5
80 – 160 lux	9
160 – 240 lux	10
240 – 320 lux	11
320 – 400 lux	12
400 – 480 lux	13
480 – 540 lux	14
540 – 620 lux	15
>620 lux	80

Recommended LPD for Buildings
ECBC-2007
Building Area	LPD (Watt/M2)
Automotive Facility	9.7
Convention Center	12.9
Dining: Bar Lounge/Leisure	14.0
Dining: Cafeteria/Fast Food	15.1
Dining: Family	17.2
Dormitory/Hostel	10.8
Gymnasium	11.8
Healthcare-Clinic	10.8
Hospital/Health Care	12.9
Hotel	10.8
Library	14.0
Manufacturing Facility	14.0
Motel	10.8
Motion Picture Theater	12.9
Multifamily Residential	7.5
Museum	11.8
Office	10.8
Parking Garage	3.2
Performing Arts Theatre	17.2
Police/Fire Station	10.8
Post Office/Town Hall	11.8
Religious Building	14.0
Retail/Mall	16.1
School/University	12.9
Sports Arena	11.8
Transportation	10.8
Warehouse	8.6
Workshop	15.1

Lighting Power Density
BEC-Table 5.4
Building Area	LPD (Watt/M2)
Atrium / Foyer with headroom over 5m	17
Bar / Lounge	14
Banquet Room / Function Room / Ball Room	20
Canteen	11
Car Park	5
Classroom / Training Room	12
Clinic	15
Computer Room / Data Centre	15
Conference / Seminar Room	14
Corridor	8
Court Room	15
Dormitory	8
Entrance Lobby	14
Exhibition Hall / Gallery	17
Guest room in Hotel or Guesthouse	13
Gymnasium / Exercise Room	13
Kitchen	13
Laboratory	15
Lecture Theatre	13
Library – Reading Area, Stack Area or Audio Visual Centre	15
Lift Car	11
Lift Lobby	11
Loading & Unloading Area	8
Office, enclosed (Internal floor area at or below 15m2)	13
Office, open plan or with internal floor area above 15m2	12
Passenger Terminal Building	14
Arrival Hall /Departure Hall with headroom not exceeding 5m	18
Arrival Hall / Departure Hall with headroom over 5m	13
Passenger circulation area
Patient Ward / Day Care	15
Plant Room / Machine Room / Switch Room	10
Public Circulation Area	13
Railway Station
Concourse / Platform / Entrance / Adit / Staircase, with headroom not exceeding 5 m	14
Concourse / Platform / Entrance / Adit / Staircase, with headroom over 5 m	18
Refuge Floor	11
Restaurant	17
Retail	17
School hall	14
Seating Area inside Theatre / Cinema /Auditorium / Concert Hall / Arena	10
Server Room / Hub Room	10
Sports Arena, Indoor, for recreational purpose	17
Staircase	7
Storeroom / Cleaner	9
Toilet / Washroom / Shower Room	11
Workshop	13

Lighting Power Densities
ASHRAE –TABLE- 9.6.1
Building Area Type LPD (W/m2)	LPD (W/m2)
Atrium (First 40 ft in height )	0.03
Atrium (Above 40 ft in height )	0.02
Audience/Seating Area
Permanent For auditorium	0.79
For Performing Arts Theater	2.43
For Motion Picture Theater	1.14
Classroom/Lecture/Training	1.24
Conference/Meeting/Multipurpose	1.23
Corridor/Transition 0.66 Width<8 ft
Dining Area	0.65
For Bar Lounge/Leisure Dining	1.31
For Family Dining	0.89
Dressing/Fitting Room for Performing Arts Theater	0.40
Electrical/Mechanical	0.95
Food Preparation	0.99
Laboratory
For Classrooms	1.28
For Medical/Industrial/Research	1.81
Lobby	0.90
For Elevator	0.64
For Performing Arts Theater	2.00
For Motion Picture Theater	0.52
Locker Room	0.75
Lounge/Recreation	0.73
Office
Enclosed	1.11
Open Plan	0.98
Restrooms	0.98
Sales Area	1.68
Stairway	0.69
Storage	0.63
Workshop	1.59
Automotive
Service/Repair	0.67
Bank/Office
Banking Activity Area	1.38
Convention Center
Audience Seating	0.82
Exhibit Space	1.45
Courthouse/Police Station/Penitentiary
Courtroom	1.72
Confinement Cells	1.10
Judges’ Chambers	1.17
Penitentiary Audience Seating	0.43
Penitentiary Classroom	1.34
Penitentiary Dining	1.07
Dormitory
Living Quarters	0.38
Fire Stations
Engine Room	0.56
Sleeping Quarters	0.25
Gymnasium/Fitness Center
Fitness Area	0.72
Gymnasium Audience Seating	0.43
Playing Area	1.20
Hospital
Corridor/Transition Width < 8 ft	0.89
Emergency	2.26
Exam/Treatment	1.66
Laundry/Washing	0.60
Lounge/Recreation	1.07
Medical Supply	1.27
Nursery	0.88
Nurses’ Station	0.87
Operating Room	1.89
Patient Room	0.62
Pharmacy	1.14
Physical Therapy	0.91
Radiology/Imaging	1.32
Recovery	1.15
Hotel/Highway Lodging
Hotel Dining	0.82
Hotel Guest Rooms	1.11
Hotel Lobby	1.06
Highway Lodging Dining	0.88
Highway Lodging Guest Rooms	0.75
Library
Card File and Cataloging	0.72
Reading Area	0.93
Stacks	1.71
Manufacturing
Corridor/Transition Width < 8 ft	0.41
Detailed Manufacturing	1.29
Equipment Room	0.95
Extra High Bay (>50 ft Floor to Ceiling Height)	1.05
High Bay (25–50 ft Floor to Ceiling Height)	1.23
Low Bay (<25 ft Floor to Ceiling Height)	1.19
Museum
General Exhibition	1.05
Restoration	1.02
Parking Garage
Garage Area	0.19
Post Office
Sorting Area	0.94
Religious Buildings
Audience Seating	1.53
Fellowship Hall	0.64
Worship Pulpit, Choir	1.53
Retail
Dressing/Fitting Room	0.87
Mall Concourse	1.10
Sales Area (for accent lighting)	1.68
Sports Arena
Audience Seating	0.43
Court Sports Arena—Class 4	0.72
Court Sports Arena—Class 3	1.20
Court Sports Arena—Class 2	1.92
Court Sports Arena—Class 1	3.01
Ring Sports Arena 2.68
Transportation
Air/Train/Bus—Baggage Area	0.76
Airport—Concourse	0.36
Audience Seating	0.54
Terminal—Ticket Counter	1.08
Warehouse
Fine Material Storage	0.95
Medium/Bulky Material Storage	0.58

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Calculation of Crippling (Ultimate Transverse) Load on Electrical Pole

July 19, 2020 2 Comments

Calculation of Crippling (Ultimate Transverse) Load on Electrical Pole

Wind Speed = 89 Mile/Hr.
Height of Pole=10 Meter
Type of Pole =RCC
Height of Pole in Ground=1.5 Meter.
Pole Section on Bottom of Pole (Length x Width)=400mm x 150mm
Pole Section on Top of Pole (Length x Width)=127mm x 150mm
Conductor Mounting from top of Pole(g)=0.5 Meter.
Distance between Two Pole(s) =20 Meter.
No of Conductor on Pole(n)=3No’s
Size of Conductor(r)= 30mm

Calculations:

Wind Pressure = 00256 x 2x Wind Speed
Wind Pressure = 00256 x 2x 90 = 20.506 Pound /Sq.Foot
Wind Pressure(Wp) =4.882×20.506 = 100 Kgf/M2
Wind Load on Conductor/Span(ws)=2/3 x Wp x s x r x n
Wind Load on Conductor/Span(ws)=2/3 x 100 x 20 x 30 x 3 =120 Kg———–(I)
Height of Pole Above Ground (h)= 10-1.5 =8.5 Meter
Total Bending Movement at Ground Level due to Wind Load on All Conductor=ws x h
Total Bending Movement at Ground Level due to Wind Load on All Conductor(b)=120 x 8.5= 960 Kg.Mt
Equivalent Safe Working Load at said Meter from TOP of The Pole corresponding to Wind Load on All Conductors =b / (h- g) = 960 / 8.5-0.5 =120 Kg
Wind Load on Pole Surface above Ground Level (p1)=Wp x h /((l1+w1)/(2×1000))
Wind Load on Pole Surface above Ground Level (p1)=100×8.5/(400+150/2×1000) =233.75 Kg
Centre of Gravity of Tapering rectangular section of Pole(p2)= (h/3)x((l2+(l1*2))/(l1+l2))
Centre of Gravity of Tapering rectangular section of Pole(p2)= (5/3)x((127+(400×2)) /(127+400))=4.98Mt
Bending Movement at Ground Level due to Wind Load on Pole(p) =p1 x p2
Bending Movement at Ground Level due to Wind Load on Pole(p) =233.75×4.98=1164.98 Kg.Mt
Equivalent Safe Working Load at said meter from Top of The Pole corresponding to Wind Load on Pole(wt) = p /(h-g) =1164.98 / (8.5-0.5) = 62 Kg——————————(II)
Total Transverse Load at said meter from Top of The Pole (Due to wind Load on Conductors + Wind Load on Pole Surface) (T)=Ws + Wt = 120+145.62 =256.62 Kg

Type of Pole	Safety Factor
Wooden Pole	3.5
RCC Pole	2.5
PCC Pole	2.5
Steel Tubular Pole	2
Rail/RSJ Pole	2
Struts (Steel Pole)	2.5
Struts (RCC/PCC)	3
PCC Pole for 33 KV	2

From Above Table Safety Factor=2.5
Total Transverse Load (Crippling Load) of Pole = T x Safety Factor
Total Transverse Load (Crippling Load) of Pole = 256 x 2.5 =664 Kg.
Total Transverse Load (Crippling Load) of Pole=664 Kg

Max. Length of Pole (Meter)	Min. Ultimate Transverse Load from 0.6meter from Top (Kg)
17	3000
17	2300
17	2000
17	1400
16	1100
15	1050
14	1050
13	1000
12	800
11	600
10	500
9	300
8	200
7	200
6	200
5	150
4	150
3	150

From Above Table Min. Ultimate Transverse Load for 10 Meter Pole = 500 Kg and as per our calculation it is 664 Kg hence Selection of Pole if O.K

Results:

Calculated Transverse Load (Crippling Load) of Pole = 664 Kg

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About Jignesh Parmar:

Jignesh Parmar has completed M.Tech (Power System Control), B.E(Electrical). He is FIE ,MIE and CEng from Institution of Engineers,India. Membership No:F-1264873 ,M-1473586.He has more than 19 years experience in Transmission -Distribution-Electrical Energy theft detection-Electrical Maintenance-Electrical Projects (Planning-Designing-Technical Review-coordination -Execution). He is Presently associate with one of the leading business group as a Deputy Manager at Ahmedabad,India. He has published numbers of Technical Articles in “Electrical Mirror”, “Electrical India”, “Lighting India”,”Smart Energy”, “Industrial Electrix”(Australian Power Publications) Magazines. He is Freelancer Programmer of Advance Excel and design useful Excel base Electrical Programs as per IS, NEC, IEC,IEEE codes. He is Technical Blogger and Familiar with English, Hindi, Gujarati, French languages. He wants to Share his experience & Knowledge and help technical enthusiasts to find suitable solutions and updating themselves on various Engineering Topics.

Purpose:

General Equipment & Tools:

Storage & Material Handling:

Inspection of Materials:

Installation of Outdoor Units :

(a) Transporting / Lifting the Outdoor Unit

(b) Selecting the Best Location for the Outdoor Unit(s)

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(A) Cable Laying in Excavated Ground:

(a) Formation of Cable Trench.

(b) First Layer of Sand:

(c) Cable Laying:

(d) Second Layer of Sand:

(e) Cable Protection:

(f) Back Filling:

(B) Cable Laying in Cable Tray / Trunking:

(C) Cable Laying in the Building

(7) Wires Pulling in Conduit:

(8) Excess or Spare Cable Storage:

(9) Cables Identification / Marking of Cables:

(10) Duct Seals:

(11) REFERENCES

(12) Flow Chart:

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Purpose:

General Equipment & Tools:

Storage & Material Handling:

Inspection of Materials:

Testing and of Cable:

(1) Insulation resistance test:

(2) The continuity test:

General Steps for Cabling Laying

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(F) Lighting Pollutions

(1) Glare:

(2) Sky glow:

(3) Light Trespass:

Difference between full cutoffs and fully shielded:

(G) Selection of Luminas:

(1) Types of Lighting Source

(2) Color Rendering Index (CRI):

(3) Fixture Protection:

(H) Effective Road Lighting:

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(C) Lighting Factor:

(1) Maintenance Factor (Light Loss Factors) (MF)

(2) Coefficient of Utilization (CU):

(E) Lighting Uniformities

(1) Lighting Uniformities

(2) Surround Ratio (SR):

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(C) Lighting Fixture:

(1) Fixture’s Mounting Height:

(2) Fixtures Classification:

(a) Full Cutoff (F):

(b) Cutoff (C):

(c) Semi Cutoff (S) (Medium Beam Angle):

(d) Non Cutoff (N) (Higher Beam Angle):

(3) Fixtures Distributions (Optical System):

(a) Type I (Two-way):

(b) Type II (Two Way) :

(c) Type III (Bat Wing) :

(d) Type IV (Forward throw “Asymmetric”):

(e) Type V:

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Introduction:

Designing Factor for Street Light:

(A) Classification As per Road:

(B) Street Light Pole:

(1) Street Light Arrangement:

(2) Proper Placement of Pole:

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