clfr thailand

5/23/2018 CLFR Thailand

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Solar Collector System, Low Pressure Turbine, Multifunction Tank

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500-550 w/m2 () 900 1,000 w/m2 ()

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Solar Collector System, LowPressure Turbine, Multifunction Tank

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. Solar Dish, Solar Trough,

Solar Tower, Compact Linear Fresnel Reflector (CLFR)

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CSP Reference Plant @ 1,000 w/m2

1 MW = 12,800 Sqm = 8 Rai

= 1.3 Hectares

Rais SqmSolar Cell 16 25,600

Thin Film 24 38,400

Solar Trough 12 19,200

CLFR 8 12,800

Solar Tower 16 25,600


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Technology Owner USD/m2Overall

eff

Effective

cost

Seasonal

variation

Photovoltaic 80 10 800 1:2.5Trough SEGSVI 250 14 1430 1:5

Trough EURO 206 12 1470 1:5

CLFR AUSRA 110 10 1100 1:5

Jack Wong 100 15 1500 1:5

Redressable

Trough

Xiao50 20 250 1:2.5

Tower DPT1200 150 24 350 1:7

Dish Stirling SOLO 150 29.5 200 1:8

Dish Turbine Jack Wong 80 35 180 1:8


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CLFR Trough

Area 1 1.5

Solar Receiver Linear Multi Tube

Method HTF Direct Steam

Tracking Power Lowest Medium

Structure Lightest Medium

Pipe Length Shortest Long

Insulator Min Moderate

Heat Losses Lowest Medium

Universal Joint Leakage None Yes

Receiver Glass Break None Yes

Reflector Twisting None Yes

Operation Time hrs 12 6

Minimum Working

Insolation

500 650

Price Lowest Medium

CLFR Chonburi, Thailand

Karnchanaburi, Thailand

CLFR VS Trough


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. (Multifunction Tank)

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. (CLFR) (Parabolic Trough)


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15

16

1. 2. 3. 4. 5. 6. 7. VCI8.

9. 10. 11. 12. 13. 14. 15. 16. Compact Linear Fresnel Reflector

CLFR, Water (H2),


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.Solar Collector System

.Low Pressure Turbine

.Multifunction Tank System

. Structure


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Solar Collector

(Solar Collector Tube) (Solar Reflector)

(Solar Collector Tube) , (Solar Reflector)

450 C 450 PSI


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Solar Linear Receiver Specification

Surface Emittance 0.03

Surface Absorption r0.87

Specular Reflectance 0.95Transmittance of Glass Cover g

0.90

Max. Temperature C 600

Max. Working Pressure PSI 400

Insulation Thermal Conductivity W/mK 0.05

Min. Direct Insolation 400 W/m2

Max. Direct Insolation 1,100 W/m2

Max. Wind Speed 160 Km/hr

Overall Efficiency 80 %


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Low Pressure Turbine 550 w/m2

(180 C @ 150 PSI)

10, 50, 100,250, 350 kW


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Low Pressure Turbine Version 1


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Multifunction Tank

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Delta Truss

Software Analysis

- Linear First Order

- Linear Second Order

- Non-linear First Order

- Non-linear Second Order

- Dynamic Harmonic

- Dynamic Seismic

- Dynamic Modal

- Bucking

- Stiffness

- Own weight

- Shell Stress

- Torsion

- Thermal expansion

- Moment

Antirust treatment

Easy to transport and erection


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Solar Steam Performance @ 1 MW

Temperature Up to 750 F (180 C)

Up to 900 F (200 C)

Pressure Up to 150 PSIa (10 BARa)Up to 230 PSIa (16 BARa)

Annual Energy per

8 Rais (12,800 Sq.m)

1,500 MWh

@ 1,000 W/m2

(Hydrogen)

System Efficiency 15 %1,500 MWhr/300 = 5 MWhr/day = 1 MW for 5 hr12,800 m2 @ 1 kW/m2 = 12.8 MWhrThermal= 2 MWhrelectricEquivalent to 1 MWhrelectric for 10 hoursWith Hydrogen Feed could increase fuel consumption 30 %At Night Time Thermal Energy will use as fuel economizer to

preheat feed water from 80 C to 120 CUse Back Up fuel 25 % for 8 hours 120 C to 180 CUse Back Up fuel 100 % for 6 hours 120 C to 180 C


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Biomass, Biogas, LPG, CNG, Hydrogen (Water)24/7 365 /

500 1,000 w/m2


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Efficiency %

Reflector 90

Receiver 80

Multifunction Tank 85

Turbine 30

Generator 85

Thermal to Electrical 15


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clfr thailand

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