1. ECOLOGIC SOLUTIONS FOR URBAN TRANSIT
SYSTEMS
Hala Mohtasseb
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2. SUMMARY
1- URBAN TRANSIT SYSTEMS THE SOLUTION FOR TRAFFIC CONGESTION
2- CONCERNS RELATED TO URBAN TRANSIT SYSTEMS
 ENERGY SAVING
 HEAT EVACUATION
3-MAIN SYSTEMS ONBOARD THE TRAIN INVOLVED
4-AIR CONDITIONING SYSTEM
 AIR-AIR EXCHANGER SOLUTION
5- BRAKING RESISTOR
 ‘SUPER CAPACITORS ‘ SOLUTION
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3. URBAN TRANSIT SYSTEMS
THE SOLUTION FOR TRAFFIC CONGESTION
TRAFFIC CONGESTION
MORE AND MORE TRAFFIC CONGESTION
 INCREASE OF CO2 EMISSION
 NEED TO FIND A TRANSPORTATION SOLUTION TO MINIMIZE CO2 EMISION
URBAN TRANSIT SYSTEMS ( METRO AND LRT VEHICLES) IS THE
SOLUTION !
FULLY ELECTRICAL SOLUTION
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4. CONCERNS RELATED
TO TRANSIT URBAN SYSTEMS
CONCERNS RELATED TO URBAN TRANSIT SYSTEMS
THOUGH NUMBER OF METRO & LRT TRAINS WORLDWIDE IS
CONTINOULSLY INCREASING , SOME CONCERNS REMAIN UNSOLVED :
1-ENERGY SAVINGS
DAILY CONCERN FOR EUROPEAN COUNTRIES
2-REDUCTION OF HEAT EVACUATED BY SYSTEMS ONBORAD THE TRAIN
CONCERN EXPRESSED BY COUNTRIES WITH HIGH TEMPERATURES
 ESPECIFICALLY GULF COUNTRIES
SOLUTIONS TO COVER BOTH CONCERNS
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5. CONCERNS RELATED TO
TRANSIT URBAN SYSTEMS
MAIN EQUIPEMENTS ONBOARD URBAN TRANSIT SYSTEMS
METRO SYSTEM
AIR CONDITIONING
.
BOGIE
BRAKING RESISTOR TRACTION SYSTEM
BRAKE SHOES
BRAKING SYSTEM
MOTORS
AUXILIRAY INVERTES
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6. CONCERNS RELATED
TO TRANSIT URBAN SYSTEMS
MAIN EQUIPEMENTS ONBOARD URBAN TRANSIT SYSTEMS
LRT SYSTEMS AIR CONDITIONING
BRAKING RESISTOR
TRACTION SYSTEM
. BRAKING SYSTEM
AUXILIARY INVERTER
BOGIE
BRAKING SHOES
MOTORS
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7. CONCERNS RELATED
TO TRANSIT URBAN SYSTEMS
ENERGY SAVING TOPIC
EQUIPEMENTS ONBOARD WITH HIGHEST ENERGY CONSUMPTION
1-TRACTION SYSTEM
TO ENSURE DYNAMIC PERFORMANCE REQUESTED
2-AIR CONDITIONING SYSTEM
HEAT EVACUATION TOPIC
TOTAL HEAT DISSIPACTION IS MOSTLY DUE TO BRAKING RESISTOR SYSTEM
FIND NEW ECOLOGIC SOLUTIONS FOR AIR CONDITIONING SYSTEM
AND BRAKING RESISTOR SYSTEM
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8. AIR CONDITIONING SYSTEM
CALCULATION OF AIR CONDITIONING SYSTEM CAPACITY
TWO POSSIBILITIES
1- FOLLOWING RECOMMENDATIONS OF EUROPEAN STANDARD EN 14750 -1
“Air conditioning for urban and suburban rolling stock – comfort parameters“
COUNTRIES ARE CLASSIFIED BY ZONES ;
FOR FIXED EXTERIOR PARAMETERS REPRESENTING MOST SEVERE CONDITIONS
(Temperature , humidity , solar load )
 MAXIMUM INTERIOR TEMPERATURE RECOMMENDED BY THE STANDARD EN
14750-1 SHALL NOT BE EXCEEDED
CALCULATION OF THE AIR CONDITIONING SYSTEM CAPACITY NEEDED ,
WITH RESPECT OF STANDARD EN 14750-1 RECOMMENDATIONS
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9. AIR CONDITIONING SYSTEM
Zone(summer) Maximum ext temper Relative humidity
I + 40 40 %
II + 35 50%
III + 28 45%
Maximum mean interior temperature at the design condition °C
Zone Categ A Categ B category A : fresh air flow rate between 10 and 15 m3/h/passenger
I + 30 + 32 category B : fresh air flow rate between 8 and 12 m3/h/passenger
II + 30 + 33
III + 26 + 29
Country Summer
Austria Zone II
Belgium Zone II
France Zone II
Greece Zone I
Germany Zone II
Italy Zone I
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10. AIR CONDITIONING SYSTEM
CALCULATION OF AIR CONDITIONING SYSTEM CAPACITY
2-FOLLOWING CLIENT REQUIRMENTS IN TENDER DOCUMENTS
THIS APPLIES TO COUNTRIES NOT REFERRED IN STANDARD EN 14750-1
THIS APPLIES TO GULF COUNTRIES
DUBAI METRO / RTA REQUIREMENTS IN TENDER DOCUMENTS
Long Term Climate Information Book 2001 (dpt of Civil Aviation of Dubai):
From 1984 until 2001 the maximum temperature is 47.5°C 23%.
- Data from the Dubai airport (detailed data for year 2003).
Maximum temperature in 2003 was 46°C 10%
The system must work at 52°C 10%RH with an internal temperature of 27°C.
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11. AIR CONDITIONING SYSTEM
CALCULATION OF AIR CONDITIONING SYSTEM CAPACITY
DUBAI EL SAFOUH TRAMWAY / RTA REQUIREMENTS IN TENDER DOCUMENTS
The outside conditions to be considered in the design are the following:
 Dry bulb temperature: 47°C
For the other conditions, refer to Appendix B attached to the General Specifications (Annual
Climate and weather in Dubai).,
The A/C shall maintain a temperature of less than 25°C during at least 95% of the
operation time in Dubai, at 4 passengers/m2.
The tripping value for A/C above 53oC is guaranteed (maximum value 54 oC).
=> Difference of temperature of 22°C requested between the interior and
exterior
 High capacity needed for the Air conditioning system to comply with
above requirements
 HIGHER IS THE CAPACITY HIGHER WILL BE ENERGY CONSUMPTION
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12. AIR CONDITIONING SYSTEM
REDUCTION OF ENERGY CONSUMPTION DUE TO AIR CONDITIONING SYSTEM
 REDUCTION OF AIR CONDITIONING CAPACITY
 REDUCTION OF DIFFERENCE BETWEEN THE EXTERIOR TEMPERATURE AND
INTERIOR TEMPERATURE
 REDUCTION OF AIR INLET TEMPERATURE
SOLUTION :
AIR CONDITIONING SYSTEM + AIR-AIR EXCHANGER SYSTEM
AIR-AIR EXCHANGER ROOF MOUNTED TO BE INSTALLED NEXT TO THE AIR
CONDIONNING SYSTEM
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13. AIR CONDITIONING SYSTEM
AIR-AIR EXCHANGER SOLUTION
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14. AIR CONDITIONING SYSTEM
AIR-AIR EXCHANGER SOLUTION
ADVANTAGES OF AIR CONDITIONING + AIR-AIR EXCHANGER :
1-ENERGY SAVING ( LOWER CAPACITY NEEDED FOR AIR CONDITIONING)
3- MTBF DECREASED FOR AIR CONDITIONING SYSTEM
 TEMPERATURE OF AIR INLET WILL REMAIN LOWER THAN 40°C
 NO AIR CONDITIONING FAILURES DUE TO HIGH TEMPERATURES
2-TOTAL WEIGHT SAVING LEADING TO ADDITIONAL ENERGY SAVINGS
 WEIGHT DECREASED FOR AIR CONDITIONING SYSTEM
 WEIGHT DECREASED FOR AUXILIARY INVERTER
( system that provides necessary current to onboard equipment)
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15. BRAKING RESISTOR
USE OF BRAKING RESISTOR
TRAIN BRAKING PROCESS BY PRIORITY ORDER :
1- REGENERATIVE BRAKING
MAINLY ELECTRICAL BRAKING (complemented by mechanical braking at low speeds)
Braking energy is regenerated to the line ( voltage 1500 Vd or 750 Vdc)
 provides energy to the train behind .
 Total energy saving
1500Vdc
REGENERATIVE BRAKING PROCESS
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16. BRAKING RESISTOR
USE OF BRAKING RESISTOR
TRAIN BRAKING PROCESS BY PRIORITY ORDER
2-HEAT EVACUATION THROUGH BRAKING RESISTOR
WHEN THE LINE IS NOT RECEPTIVE
( case where there is no trains behind to receive energy )
 ENERGY MUST BE EVACUATED
 ENERGY TO BE SEND TO ONBOARD TRAIN BRAKING RESISTORS
 BRAKING RESISTOR WILL EVACUATE ENERGY BY PRODUCING HEAT
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17. BRAKING RESISTOR
DISADVANTAGES OF BRAKING RESISTOR
AT TRAIN LEVEL
 IMPORTANT INCREASE OF AIR TEMPERATURES AT BRAKING RESISTOR
LOCATION
 ENERGY WASTE
 HIGH WEIGHT OF BRAKING RESISTORS
WHEN THE TRAIN RUNS IN A TUNNEL
TUNNEL TO BE EQUIPPPED WITH ADEQUATE VENTILATORS
THERMODYNAMIC STUDY IS A MOST TO DETECT MOST CRITICAL
AREAS AT TRAIN LEVEL AND IN TUNNEL
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18. BRAKING RESISTOR
SUPER CAPACITORS SOLUTION
TO COVER ABOVE ISSUES SUPER CAPACITORS IS THE SOLUTION !
 ENERGY STORAGE
ENERGY STORED COULD BE USED TO SUPPLY OTHER EQUIPMENTS
ONBOARD THE TRAIN
 LOW WEIGHT
 VERY HIGH RATES OF CHARGE AND DISCHARGE
 IMPROVED SAFETY BY LOW TOXICITY OF MATERIAL
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19. THANK YOU !
Hala Mohtasseb
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