portfolio of cogeneration units in...

PORTFOLIO OF COGENERATION UNITS IN UKRAINE

ANNEXES

JOINT IMPLEMENTATION PROJECT PROJECT DESIGN DOCUMENT

ERUPT 5 Kyiv/Berlin, 25 February 2005

PDD – Portfolio of cogeneration units in Ukraine

Annexes -

CONTENTS Annex I Specifications of JMS-620 GS-N.L cogeneration unit...........................................3 Annex II Power consumption of JMS-620 GS-N.L cogeneration unit..................................7 Annex III Scheme of JMS-620 GS-N.L cogeneration unit...................................................10 Annex IV Specifications of LT60s Absorption-Refrigerating Machine ...............................11 Annex V Scheme of LT60s Absorption-Refrigerating Machine .........................................12 Annex VI Specification of Ukrainian natural gas .................................................................13 Annex VII Energy law in Ukraine......................................................................................15 Annex VIII Monitoring model for HekroPET .....................................................................18 Annex IX Monitoring model for Medical Glass & NORD...................................................24 Annex X Monitoring model for Demitex & Tornado..........................................................30 Annex XI Boilers efficiency..................................................................................................36

1.HekroPET ..........................................................................................................................36 2.Medical Glass ....................................................................................................................37 3. Demitex ............................................................................................................................38 4. Tornado.............................................................................................................................39 5. NORD...............................................................................................................................39


Annexes -

Annex I Specifications of cogeneration units

JMS-620 GS-N.L (NORD, HekroPET) Technical Data Data at: Full

load Part Load

Fuel gas LHV kWh/Nm³ 9,5 100% 75% 50% Energy input kW 7.076 5.468 3.860 Gas volume Nm³/h 745 576 406 Mechanical output kW 3.119 2.339 1.559 Electrical output kW el. 3.041 2.275 1.504 Recoverable thermal output ~ Intercooler 1st stage kW 525 271 76 ~ Lube oil kW 326 297 255 ~ Jacket water kW 538 465 386 ~ Exhaust gas cooled to 126 °C kW 1.628 1.421 1.104 Total recoverable thermal output kW 3.018 2.454 1.821 Total output generated kW total 6.059 4.728 3.326 Heat to be dissipated ~ Intercooler 2nd stage kW 188 119 70 ~ Lube oil kW ~ ~ ~ ~ Surface heat ca. kW 266 212 186 ~ Balance heat kW 71 55 39 Spec. fuel consumption of engine kWh/kWh 2,27 2,34 2,48 Lube oil consumption ca. kg/h 0,94 ~ ~ Electrical efficiency % 43,0% 41,6% 39,0% Thermal efficiency % 42,6% 44,9% 47,2% Total efficiency % 85,6% 86,5% 86,2% Hot water circuit: Forward temperature °C 96,0 91,1 85,7 Return temperature °C 70,0 70,0 70,0 Hot water flow rate m³/h 99,8 99,8 99,8


Annexes -

JMS-316 GS-N.L (Tornado)

0.01 Technische Daten Daten bei: Vollast Teillast Treibgas Hu kWh/Nm³ 9,5 100% 75% 50% zugeführte Leistung kW [2] 2.091 1.611 1.132 Gasmenge Nm³/h *) 220 170 119 mechanische Leistung kW [1] 861 646 431 elektrische Leistung kW el. [4] 835 626 415 nutzbare thermische Leistung ~ Gemisch 1.Stufe kW 125 55 5 ~ Öl kW 90 74 63 ~ Motorkühlwasser kW 261 251 214 ~ Abgas bei Abkühlung auf 130 °C kW 508 407 287 Summe nutzbare, thermische Leistung kW [5] 984 787 569 Summe abgegebene Leistung kW total 1.819 1.413 984 abzuführende thermische Leistung ~ Gemisch 2.Stufe kW 43 32 22 ~ Öl kW ~ ~ ~ ~ Oberflächenwärme ca. kW [7] 53 45 44 ~ Restwärme kW 41 31 21 spez. Kraftstoffverbrauch kWh/kWh [2] 2,43 2,49 2,63 Schmierölverbrauch ca. kg/h [3] 0,26 ~ ~ elektrischer Wirkungsgrad % 39,9% 38,9% 36,6%therm. Wirkungsgrad % 47,1% 48,8% 50,3%Gesamtwirkungsgrad % [6] 87,0% 87,7% 86,9% Warmwasserkreis: Vorlauftemperatur °C 100,0 94,0 87,4 Rücklauftemperatur °C 70,0 70,0 70,0 Warmwasserdurchflußmenge m³/h 28,2 28,2 28,2 *) als Richtwert zur Rohrleitungsdimensionierung [_] Erklärungen: siehe 0.10 - technische Randbedingungen Die angegebenen Wärmen beziehen sich auf die Normbezugsbedingungen gemäß Anhang 0.10. Abweichungen von diesen Normbezugsbedingungen können zu Verschiebungen der Wärmebilanz führen, dies ist in der Auslegung der Rückkühlleistungen (Gemisch; Notkühlung; ...) zu berücksichtigen.


Annexes -

JMC-320 GS-N.L (Medical Glass)

0.01 Technical Data (container) Data at: Full

load Part Load

Fuel gas LHV kWh/Nm³ 9,5 100% 75% 50% Energy input kW [2] 2.607 2.009 1.410 Gas volume Nm³/h *) 274 211 148 Mechanical output kW [1] 1.095 821 548 Electrical output kW el. [4] 1.053 787 519 Recoverable thermal output ~ Intercooler 1st stage kW 191 96 21 ~ Lube oil kW 115 98 82 ~ Jacket water kW 342 291 250 ~ Exhaust gas cooled to 120 °C kW 552 462 345 Total recoverable thermal output kW [5] 1.200 947 698 Total output generated kW total 2.253 1.734 1.217 Heat to be dissipated ~ Intercooler 2nd stage kW 64 48 28 ~ Lube oil kW ~ ~ ~ ~ Surface heat ca. kW [7] 91 73 57 ~ Balance heat kW 49 39 28 Spec. fuel consumption of engine kWh/kWh [2] 2,38 2,45 2,57 Lube oil consumption ca. kg/h [3] 0,33 ~ ~ Electrical efficiency % 40,4% 39,2% 36,8%Thermal efficiency % 46,0% 47,1% 49,5%Total efficiency % [6] 86,4% 86,3% 86,3% Hot water circuit: Forward temperature °C 90,0 85,8 81,6 Return temperature °C 70,0 70,0 70,0 Hot water flow rate m³/h 51,6 51,6 51,6 *) approximate value for pipework dimensioning [_] Explanations: see 0.10 - Technical parameters All heat data is based on standard conditions according to attachment 0.10. Deviations from the standard conditions can result in a change of values within the heat balance, and must be taken into consideration in the layout of the cooling circuit/equipment (intercooler; emergency cooling; ...).


Annexes -

JMC-612 GS-N.L (Demitex)

0.01 Technical Data (at module) Data at: Full

load Part Load

Fuel gas LHV kWh/Nm³ 9,5 100% 75% 50% Energy input kW [2] 4.200 3.245 2.291 Gas volume Nm³/h *) 442 342 241 Mechanical output kW [1] 1.871 1.403 936 Electrical output kW el. [4] 1.815 1.358 900 Recoverable thermal output ~ Intercooler 1st stage kW 347 183 47 ~ Lube oil kW 183 166 149 ~ Jacket water kW 290 266 220 ~ Exhaust gas cooled to 120 °C kW 988 829 638 Total recoverable thermal output kW [5] 1.808 1.444 1.054 Total output generated kW total 3.623 2.802 1.954 Heat to be dissipated ~ Intercooler 2nd stage kW 92 76 58 ~ Lube oil kW ~ ~ ~ ~ Surface heat ca. kW [7] 164 133 118 ~ Balance heat kW 42 32 23 Spec. fuel consumption of engine kWh/kWh [2] 2,24 2,31 2,45 Lube oil consumption ca. kg/h [3] 0,56 ~ ~ Electrical efficiency % 43,2% 41,9% 39,3%Thermal efficiency % 43,0% 44,5% 46,0%Total efficiency % [6] 86,3% 86,4% 85,3% Hot water circuit: Forward temperature °C 90,0 86,0 81,7 Return temperature °C 70,0 70,0 70,0 Hot water flow rate m³/h 77,7 77,7 77,7 *) approximate value for pipework dimensioning [_] Explanations: see 0.10 - Technical parameters All heat data is based on standard conditions according to attachment 0.10. Deviations from the standard conditions can result in a change of values within the heat balance, and must be taken into consideration in the layout of the cooling circuit/equipment (intercooler; emergency cooling; ...).


Annexes -

Annex II Power consumption for auxiliries of CHP Plant

HekroPet

Medical Glass

Auxiliaries of the CHP plant Sinapse-GlassNo. Description Type Producer Q-ty Рnom, kW Pinst, kW Pcalc, kW1 Aggregate fitting pump 111 m3/h NP 65/200V WILO 3 22,0 66,0 52,82 Oil pump R 25/16 71M Rickmeier 3 0,25 0,8 0,23 Input ventilation set Jenbacher 3 1,4 4,2 3,44 Module interface panel +М Jenbacher 3 1,5 4,5 3,65 Module control panel +А Jenbacher 3 1,0 3,0 2,46 Synchronization panel +SY Jenbacher 1 1,0 1,0 0,87 Master control panel +ST Jenbacher 1 1,0 1,0 0,88 Lighting 1 10,0 10,0 6,09 Socket networks 1 25,0 25,0 10,0

80

100% 75% 50%7 821 6 027 4 2303 159 2 361 1 557

3 079 2 351 1 547

39,4% 39,0% 36,6%

Total for the CHP "Sinapse-Glass", kW

Module loadSupplied fuel powerElectric power at generator terminals

Output electric power including auxiliaries

Electric efficiency of the plant

Efficiency of the whole plant (3хJMS320):

No. Description Type Producer Q-ty Рnom, kW Pinst, kW Pcalc, kW1 Water pump, capacity 350 m3/h NP 100/250V WILO 6,0 75,0 450,0 202,5

2 Fan cooler 600 m3/h with control system БВГ-600 2,0 16,0 32,0 28,83 Cooled water pump 306 m3/h NP 100/250V WILO 4,0 75,0 300,0 169,54 Aggregate fitting pump 111 m3/h NP 65/200V WILO 2,0 22,0 44,0 39,65 Oil pump R 25/16 71M Rickmeier 2,0 0,3 0,5 0,46 Input ventilation set KLG 500 FRIVENT 4,0 12,0 48,0 38,47 Module interface panel +М Jenbacher 2,0 14,0 28,0 22,48 Module control panel +А Jenbacher 2,0 45,0 90,0 72,09 Synchronization panel +SY Jenbacher 1,0 9,0 9,0 7,2

10 Master control panel +ST Jenbacher 1,0 3,0 3,0 2,411 Water treatment 1,0 2,0 2,0 1,612 Lighting 1,0 10,0 10,0 8,013 Socket networks 1,0 25,0 25,0 20,014 Oil system ventilation Maico 1,0 1,5 1,5 1,215 Refrigerating machine LT 60S Thermax 2,0 4,5 9,0 7,2

621 Total for the CHP and absorption chillers, kW


Annexes -

Demitex

Tornado

No. Description Type Producer Q-ty Рnom, kW Pinst, kW Pcalc, kW1 Water pump, capacity 350 m3/h NP 100/250V WILO 3 75,0 225,0 120,02 Fan cooler 600 m3/h with control sys. БВГ-600 1 16,0 16,0 12,84 Aggregate fitting pump 111 m3/h NP 65/200V WILO 2 22,0 44,0 35,25 Oil pump R 25/16 71M Rickmeier 2 0,25 0,5 0,16 Input ventilation set KLG 500 FRIVENT 2 1,8 3,5 2,87 Module interface panel +М Jenbacher 2 1,5 3,0 2,48 Module control panel +А Jenbacher 2 1,0 2,0 1,69 Synchronization panel +SY Jenbacher 1 1,0 1,0 0,8

10 Master control panel +ST Jenbacher 1 1,0 1,0 0,811 Lighting 1 10,0 10,0 6,012 Socket networks 1 25,0 25,0 10,013 Refrigerating machine LT 60S Thermax 1 4,5 4,5 4,1

197

100% 75% 50%8400 6490 45823622 2710 1792

Output electric power including auxiliaries 3425 2513 1595

Electric efficiency of the plant 40,8% 38,7% 34,8%

Electric power at generator terminals

Efficiency of the whole plant (2хJMS612):Module loadSupplied fuel power

Auxiliaries of the CHP plant Demitex

Total for the CHP Demitex, kW

No. Description Type Producer Q-ty Рnom, kW Pinst, kW Pcalc, kW1 Water pump, capacity 350 m3/h NP 100/250V WILO 3 75,0 225,0 120,02 Fan cooler 600 m3/h with control sys. БВГ-600 1 16,0 16,0 8,04 Aggregate fitting pump 111 m3/h NP 65/200V WILO 3 22,0 66,0 52,85 Oil pump R 25/16 71M Rickmeier 3 0,25 0,8 0,26 Input ventilation set KLG 500 FRIVENT 3 1,8 5,3 4,27 Module interface panel +М Jenbacher 3 1,5 4,5 3,68 Module control panel +А Jenbacher 3 1,0 3,0 2,49 Synchronization panel +SY Jenbacher 1 1,0 1,0 0,8

10 Master control panel +ST Jenbacher 1 1,0 1,0 0,811 Lighting 1 10,0 10,0 6,012 Socket networks 1 25,0 25,0 10,013 Refrigerating machine LT 60S Thermax 1 4,5 4,5 4,1

213

100% 75% 50%6273 4833 33962505 1878 1245

Output electric power excluding auxiliaries 2292 1665 1032

Electric efficiency of the plant 36,5% 34,5% 30,4%

Electric power at generator terminals

Auxiliaries of the CHP plant TC "Tornado"

Total for the CHP TC "Tornado", kW


Module loadSupplied fuel power


Annexes -

Nord

Auxiliaries of the CHP plant "NORD"No. Description Type Producer Q-ty Рnom, kW Pinst, kW Pcalc, kW1 Aggregate fitting pump 111 m3/h NP 65/200V WILO 4 22,0 88,0 70,42 Oil pump R 25/16 71M Rickmeier 4 0,25 1,0 0,23 Input ventilation set KLG 500 FRIVENT 4 12,0 48,0 38,44 Module interface panel +М Jenbacher 4 1,5 6,0 4,85 Module control panel +А Jenbacher 4 1,0 4,0 3,26 Synchronization panel +SY Jenbacher 1 1,0 1,0 0,87 Master control panel +ST Jenbacher 1 1,0 1,0 0,88 Booster Jenbacher 4 5,5 22,0 17,69 Lighting 1 10,0 10,0 6,0

10 Socket networks 1 25,0 25,0 10,0152

100% 75% 50%28 304 21 872 15 44012 164 9 100 6 016

12 012 8 948 5 864

42,4% 40,9% 38,0%

Total for the CHP "NORD", kW


Module loadSupplied fuel powerElectric power at generator terminals

Output electric power including auxiliaries

Electric efficiency of the plant


Annexes -

Annex III Scheme of JMS-620 GS-N.L cogeneration unit Инв

.№ подл.

Подпись

и дата

СОГЛ

АСОВАНО

:

Взам.

инв

.№

Формат А2

D

DT

425

C A B

G

E

N

M

JI

70 °C

110 °С

Fuel gas

Air

Hot water

Engine cooling water

Engine oil

Streiner

Key to lines and komponents

Ball valve

Non-return valve

Three-way valve

Pump

Flexible hoseRow water

Exhaust gas


Annexes -

Annex IV Specifications of LT60s Absorption-Refrigerating Machine


Annexes -

Annex V Scheme of LT60s Absorption-Refrigerating Machine Инв

.№ подл.

Подпись

и дата

СОГЛ

АСОВАНО

:

Взам.

инв

.№

Формат А2

NON RETURN VALVE

STRAINER

GATE VALVE

CONTROL VALVE

Н 4.1, 4.2

ХМ 1

COLLING WATER OUTLET

CO

LLIN

G W

ATE

R IN

LET

HOT WATER INLET

HOT WATER OUTLET

CHILED WATER OUTLET

CH

ILED

WA

TER

INLE

T

CHILED WATER PUMPS(1 working + 1 std. by)

COLING WATER PUMPS(2 working + 1 std. by)

COLING TOWER

BLOW DOWN

SINAPSE

Н 5.1... 5.3


Annexes -

Annex VI Specification of Ukrainian natural gas

Gas composition, %, volume Gas pipeline CH4 C2H6 C3H8 C4H10

C5H12 (more) N2 CO2

CHQ ,

МJ/m3 (kcal/m3)

ρ, kg/m3

Dashava-Kyiv 98.9 0.3 0.1 0.1 0 0.4 0.2 35.88 (8570) 0.712

Middle Asia-Center 93.8 3.6 0.7 0.2 0.4 0.7 0.6 37.56

(8970) 0.776

Ugersko-Stry, Ugersko-

Gnesdychy, Ugersko-Lviv

98.5 0.2 0.1 0 0 1.0 0.2 35.50 (8480) 0.722

Shchebelinka-Ostrogozhsk, Shchebelinka-

Dnipropetrovsk, Shchebelinka-

Kharkiv

92.8 3.9 1.0 0.4 0.3 1.5 0.1 37.31 (8910) 0.781

Shchebelinka-Bryansk-Moscow

94.1 3.1 0.6 0.2 0.8 1.2 - 37.87 (9045) 0.776


Annexes -


Annexes -

Annex VII Energy law in Ukraine

Introduction After dissolution of the USSR, Ukraine as an independent state met a necessity to reconstruct its energy sector. Restructuring of the Ukrainian energy sector started in 1994-1995. In the course of the restructuring process, important changes in the legal framework were implemented in accordance with the Presidential Decrees No. 244/94 and 282/95 and the follow-up legislative documents. These documents have introduced separation of all electricity business activities (generation, transmission, distribution and supply); creation of the Wholesale Electricity Market (WEM); corporatization and start of the privatization process of energy companies; establishment of the National Electricity Regulatory Commission (NERC) as the Regulator in the power industry; concentration of the management functions over electricity, oil and gas industries in the Ministry of Power Industry as the central body of executive power. The structure of electricity market The "Law of Ukraine on Power Industry" from October 1997 created the new structure. Article 15 of this law establishes the wholesale electricity market, authorizes third party’s access to the transmission and distribution systems and requires the Market to serve as the single buyer of all generated or imported electricity. The new structure can be characterized as follows:

Thermal power Gen Co’s

Hydro Power Gen Co’s

Nuclear Gen Co’s

CHP plants

Competitive pricing with price caps

regulated by NERC

Prices, determined by ENERGOMARKET

ENERGOMARKET

Transmission charges regulated by NERC

27 State Power

DisCo’s (Oblenergos)

Independent Electricity Suppliers

2 Municipal Power DisCo’s

(Oblenergo Kiev and

Sevastopl)

Tariffs regulated

by NERC Non-regulated

prices Tariffs regulated

by NERC

Final Consumers/Customers

The structure consists of: • The Wholesale Market Operator, ENERGOMARKET (ENERGORYNOK), the

company totally owned by the government, manages the single buyer function, and arranges the necessary transmission services. ENERGOMARKET was established as a branch of UKRENERGO during the first stage of restructuring in 1995, simultaneously with the creation of Wholesale Electricity Market. In May 2000 the Government of Ukraine separated the functions carried out by UKRENERGO and established ENERGORYNOK as the state enterprise. Major


Annexes -

functions of this new enterprise are organization and maintenance of the functioning of the wholesale electricity market; administration of ENERGOMARKET's settlements and funds; purchase of electricity from electricity generators and electricity importers; wholesale supply of electricity to distributors.

• The National Dispatch Center (NDC) is the state enterprise in charge of overall dispatch and metering; it has become a part of the ENERGOMARKET state enterprise. The NDC in Kiev is SCAD A-equipped with eight regional dispatch centers.

• Four joint stock corporations8 own and operate the 14 largest thermal power stations.

• Two joint stock corporations own and operate 8 hydropower stations on the Dnieper River and 3 hydropower stations on the Dniester River.

• Twenty-seven joint stock companies (Oblenergos) own and operate the low-voltage networks and some generation capacity in the oblasts (regions) and two city administrations (Kiev and Sevastopol).

• The national electricity generation company ENERGOATOM operates five nuclear power plants.

Each member of the ENERGOMARKET is to sell all electricity produced and imported for sale in Ukraine exclusively to ENERGOMARKET except for:

• electricity used for its own needs or electricity generation needs of each electricity producer;

• electricity produced at CHPs which are a subdivision of the power distribution company for consumers of the region where their licensed activity is carried out;

• electricity used for own production of goods or salvaging of waste products of each electricity producer;

• electricity produced at power stations with the installed capacity and annual electricity output lower than the determined limit indices of 20 MW and 100 GWh respectively.

The National Electricity Regulatory Commission (NERC) is a formally independent public agency founded by the Presidential Decree No.734 (1994) to ensure the efficient operation of the power sector and to promote the establishment of an electricity market. The main responsibilities of NERC are the following: issuing licenses in the oil and gas sector and monitoring compliance with license requirements for electricity generation, high-voltage transmission, low-voltage distribution, wholesale market operations, and tariff and non-tariff supply. The licenses stipulate the methodology for calculating high and low-voltage network fees, the National Dispatch Center's margin, and retail tariffs applied by the Oblenergos; regulating natural monopoly activities; promoting competition in the fields of gas supply, gas and oil production, storage and marketing of gas and oil; implementing the pricing and tariff policy; securing effective operations of commodity markets by means of trade-offs between the interests of society, natural monopoly entities and consumers of their goods and services; protecting the rights of consumers of gas, oil and oil products; coordinating the activities of public agencies related to fuel market regulation. NERC settles the prices for power generation, transmission, and distribution. The approved actual prices are price caps that are maximum prices, which may not be surpassed by the offers to ENERGOMARKET. Thus the actual average market prices calculated by ENERGOMARKET are not higher, but usually lower than these price caps. The price cap for electricity sold to ENERGOMARKET is currently 12 kopeks/kWh (22,6 US$/MWH).


Annexes -

The draft Law of Ukraine "On corrective action to the Law of Ukraine ,On power energy'" has been approved by the Cabinet of Ministers and has been submitted to the Verkhovna Rada (registration No. 3504 from 16.05.2003). This draft Law was developed according to the schedule of works on adaptation of the Ukrainian legislation to the EU legislation. The subject of legislative regulation is improvement of relations on the power market, guaranty of power quality, in the sphere of construction of new generating capacities and free access to the power grids, stimulation of power production from renewable energy sources. Minister of Fuel and Power will present draft Law in Verkhovna Rada. According this draft Law power supply companies must guarantee access to the power grids for small hydropower stations, and power stations producing power from renewable energy sources. New chapter IV "Stimulation of power production from renewable energy" is included into the draft Law. This stimulation includes:

• Purchase on the whole sale market of Ukraine power produced from RES; • Guarantee access to the power grids for producers of power from RES; • Establishment of special tariffs for the transportation of power from RES in the

grids; • Providing RES power generating companies with subsidies, grants, tax, credit

and other concessions.


Annexes -

Annex VIII Monitoring model for HekroPET

HekroPET Plant vs CHP&abs.chillers

Annual consumptio

n Natural gas for CHP, x1000 Nm3 Month 2006 2007 2008 2009 2010 2011 2012

Jan Feb Mar Apr May Jun Jul

Aug Sep Oct

Nov Dec

Total (1000 Nm3) 0 0 0 0 0 0 0 Generated electricity from CHP, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0


Annexes -

next... Consumed electricity for auxiliary of CHP, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Generated cool energy from abs. chillers, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Generated cool energy from comp. chillers, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec 0 0 0 0 0 0 0

Total (MWh) 0 0 0 0 0 0 0


Annexes -

next… Consumed electricity for comp. chillers, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Consumed electricity for HekroPET from grid, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 LHV (Calorific value) of NG, kcal/Nm3 Quarter 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Average (kcal/Nm3) 0 0 0 0 0 0 0


Annexes -

next…

HekroPET Plant, LTDBaseline scenario Baseline calculationEmissions from electricity

Electricity from CHP, generated

Electricity consumption for auxiliary of

CHP

Net electricity from CHP

|col.1-col.2|

Electricity from("+")

/to("-") grid

Total electricity consumption by

HekroPET|col.3+col.4|

Avoided electricty due

cool production on abs.chillers

|col.14|

Electricity: total consumption+

avoided on abs. chillers

|col.5+col.6|

EF

CO2 emissions(electricity

grid)|col.7*col.8

/1000|MWh MWh MWh MWh MWh MWh MWh kg/MWh t/year

1 2 3 4 5 6 7 8 92006 0 0 0 0 0 0 0 876 02007 0 0 0 0 0 0 0 856 02008 0 0 0 0 0 0 0 836 02009 0 0 0 0 0 0 0 816 02010 0 0 0 0 0 0 0 796 02011 0 0 0 0 0 0 0 776 02012 0 0 0 0 0 0 0 756 0

Subcalculation of avoided electricity due to cool production on abs. chillers:

Cool production

on CHP&abs.

chillers

Electricity consumption

for comp.chillers

Cool energy from comp.

chillers

Specific el.consumption

for cool production in comp.chillers|col.11/col.12|

but no more 0.51


cool production on abs.chillers|col.10*col.13|

MWh MWh MWh kWhel/kWhc MWh10 11 12 13 14

2006 0 0 0 0 02007 0 0 0 0 02008 0 0 0 0 02009 0 0 0 0 02010 0 0 0 0 02011 0 0 0 0 02012 0 0 0 0 0

Year

Year


Annexes -

next…

HekroPET Plant vs CHP&abs.chillers Project emissions

EFNG = 56 kg/GJDirect on site emissions (NG combustion)

Natural gas for CHP

LHV of NG, average annual

CHP, fuel (NG) consumption|col.1*col.2* 0.0041868|

CO2 emissions(NG combustion)|col.3*56/1000|

x1000 Nm3 kkal/Nm3 GJ/y t/year1 2 3 4

2006 0 0 0 02007 0 0 0 02008 0 0 0 02009 0 0 0 02010 0 0 0 02011 0 0 0 02012 0 0 0 0

Direct off site emissions (electricity from grid) avoided "-"Electricity from grid

|0 if export|

EF (for reducing el. consumptio

CO2 emissions(electricity from grid)

|col.5*col.6/1000|Electricity to grid

|0 if import|

EF (for generating

el.)

CO2 emissions(electricity to grid)|col.8*col.9/1000|

MWh kg/MWh t/year MWh kg/MWh t/year5 6 7 8 9 10

2006 0 876 0 0 725 02007 0 856 0 0 710 02008 0 836 0 0 695 02009 0 816 0 0 680 02010 0 796 0 0 666 02011 0 776 0 0 651 02012 0 756 0 0 636 0

Year

Year


Annexes -

next…

HekroPET Plant vs CHP&abs.chillers Reduction CO2

emissions EFNG = 56kg/GJ Direct on site emissions (NG combustion) Base Line Project Line Reduction


grid)

CO2 emissions(NG combustion)


CO2 emissions (electricity to grid),

avoided "-"

Total CO2 emissions reduction

|col.1-col.2-col.3-col.4|Year

t/year t/year t/year t/year t/year 1 2 3 4 5

2006 0 0 0 0 0 2007 0 0 0 0 0 2008 0 0 0 0 0 2009 0 0 0 0 0 2010 0 0 0 0 0 2011 0 0 0 0 0 2012 0 0 0 0 0


Annexes -

Annex IX Monitoring model for Medical Glass & NORD

"NORD" (and the same for "Sinapse-Glass") Annual

consumption Natural gas for CHP, x1000 Nm3 Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (1000 Nm3) 0 0 0 0 0 0 0 Natural gas for boilers, x1000 Nm3 Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (1000 Nm3) 0 0 0 0 0 0 0


Annexes -

next… Generated heat from boilers, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Generated electricity from CHP, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Consumed electricity for auxiliary of CHP, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0


Annexes -

next… Generated heat energy from CHP, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Consumed electricity from/to grid, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 LHV (Calorific value) of NG, kcal/Nm3 Quarter 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec



Annexes -

next… "NORD" (and the same for "Sinapse-Glass") Baseline calculationEmissions from electricity



CHP


|col.1-col.2|


/to("-") grid


"NORD" ("Sinapse-Glass")

|col.3+col.4| EF

CO2 emissions(electricity grid)

|col.5*col.6 /1000|MWh MWh MWh MWh MWh kg/MWh t/year

1 2 3 4 5 6 72006 0 0 0 0 0 876 02007 0 0 0 0 0 856 02008 0 0 0 0 0 836 02009 0 0 0 0 0 816 02010 0 0 0 0 0 796 02011 0 0 0 0 0 776 02012 0 0 0 0 0 756 0

Heat emissions EFNG = 56 kg/GJ

Heat energy supplied by

the CHP

Heat energy supplied by the back up

boilers

Volume of burned NG at back up

boilersLHV of NG,

average

Thermal efficiency of back up boilers|col.9/(col.10*

*col.11*0,001163)|, in case of data absence 0,92

Total heat consumption|col.8+col.9|

Fuel NG energy for production of the

whole heat|col.13*3.6/col.12|

CO2 emission (NG combustion)|col.14*56/1000|

MWh MWh х1000 Nm3 kkal/Nm3 MWh GJ t/year

8 9 10 11 12 13 14 152006 0 0 0 0 0,92 0 0 02007 0 0 0 0 0,92 0 0 02008 0 0 0 0 0,92 0 0 02009 0 0 0 0 0,92 0 0 02010 0 0 0 0 0,92 0 0 02011 0 0 0 0 0,92 0 0 02012 0 0 0 0 0,92 0 0 0

Year

Year


Annexes -

next…

"NORD" (and the same for "Sinapse-Glass") Project emissionsEFNG = 56 kg/GJDirect on site emissions (NG combustion)

Natural gas for CHP

Natural gas for back up boilers


CHP+back up boilers fuel (NG)

consumption|(col.1+col.2)*col.3*

0.0041868|

CO2 emissions(NG

combustion)|col.4*56/1000|

x1000 Nm3 x1000 Nm3 kkal/Nm3 GJ/y t/year1 2 3 4 5

2006 0 0 0 0 02007 0 0 0 0 02008 0 0 0 0 02009 0 0 0 0 02010 0 0 0 0 02011 0 0 0 0 02012 0 0 0 0 0

Direct off site emissions (electricity from/to grid) avoided "-"

Electricity from grid

|0 if export|EF (for reducing el. consumption)

CO2 emissions(electricity from

grid)|col.6*col.7/1000|

Electricity to grid|0 if import|

EF (for generating el.)



2006 0 876 0 0 725 02007 0 856 0 0 710 02008 0 836 0 0 695 02009 0 816 0 0 680 02010 0 796 0 0 666 02011 0 776 0 0 651 02012 0 756 0 0 636 0

Year

Year


Annexes -

next…

"NORD" (and the same for "Sinapse-Glass") Reduction CO2


CO2 emissions (electricity

grid)

CO2 emissions (NG combustion)


CO2 emissions (electricity from grid)

CO2 emissions (electricity to

grid), avoided "-"


|col.1+col.2- -col.3-col.4-col.5|

Year

t/year t/year t/year t/year t/year t/year 1 2 3 4 5 6

2006 0 0 0 0 0 0 2007 0 0 0 0 0 0 2008 0 0 0 0 0 0 2009 0 0 0 0 0 0 2010 0 0 0 0 0 0 2011 0 0 0 0 0 0 2012 0 0 0 0 0 0


Annexes -

Annex X Monitoring model for Demitex & Tornado

"TORNADO" (and the same for "DEMITEX") Annual consumption Natural gas for CHP, x1000 Nm3 Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (1000 Nm3) 0 0 0 0 0 0 0 Natural gas for boilers, x1000 Nm3 Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (1000 Nm3) 0 0 0 0 0 0 0


Annexes -

next… Generated heat from boilers, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Generated electricity from CHP, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Consumed electricity for auxiliary of CHP, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0


Annexes -

next… Generated heat energy from CHP for TORNADO (DEMITEX), MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0 Generated cool energy from abs. chillers, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec 0 0 0 0 0 0 0

Total (MWh) 0 0 0 0 0 0 0 Consumed electricity for "TORNADO" (for DEMITEX) from grid, MWh Month 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec

Total (MWh) 0 0 0 0 0 0 0


Annexes -

next… LHV (Calorific value) of NG, kcal/Nm3 Quarter 2006 2007 2008 2009 2010 2011 2012


Aug Sep Oct

Nov Dec



Annexes -

next…

"TORNADO" (and the same for "DEMITEX") Baseline calculationEmissions from electricity



CHP


|col.1-col.2|


/to("-") grid


Tornado (Demitex)|col.3+col.4|


cool production on abs.chillers

|col.12|

Electricity: total consumption+

avoided on abs. chillers

|col.5+col.6| EF


grid)|col.7*col.8

/1000|MWh MWh MWh MWh MWh MWh MWh kg/MWh t/year

1 2 3 4 5 6 7 8 92006 0 0 0 0 0 0 0 876 02007 0 0 0 0 0 0 0 856 02008 0 0 0 0 0 0 0 836 02009 0 0 0 0 0 0 0 816 02010 0 0 0 0 0 0 0 796 02011 0 0 0 0 0 0 0 776 02012 0 0 0 0 0 0 0 756 0

Cool emissions

Cool production

on CHP&abs.

chillers

Specific el.consumptio

n for cool production in comp.chillers


cool production on abs.chillers|col.10*col.11|

MWh kWhel/kWhc MWh10 11 12

2006 0 0,37 02007 0 0,37 02008 0 0,37 02009 0 0,37 02010 0 0,37 02011 0 0,37 02012 0 0,37 0

Heat emissions EFNG = 56 kg/GJ

Year Heat energy

supplied by the CHP

Heat energy supplied by the back up

boilers

Volume of burned NG at

back up boilersLHV of NG,

average

Thermal efficiency of back up boilers|col.14/(col.15*

*col.16*0,001163)|, in case of data absence 0,92

Total heat consumption

|col.13+col.14|

Fuel NG energy for production of the

whole heat|col.18*3.6/col.17|

emission (NG

combustion)

|col.19*56/1000|

MWh MWh х1000 Nm3 kkal/Nm3 MWh GJ t/year13 14 15 16 17 18 19 20

2006 0 0 0 0 0,92 0 0 02007 0 0 0 0 0,92 0 0 02008 0 0 0 0 0,92 0 0 02009 0 0 0 0 0,92 0 0 02010 0 0 0 0 0,92 0 0 02011 0 0 0 0 0,92 0 0 02012 0 0 0 0 0,92 0 0 0

Year

Year


Annexes -

next…

next…

"TORNADO" (and the same for "DEMITEX") Reduction CO2



grid)




CO2 emissions (electricity to

grid), avoided "-"


|col.1+col.2- -col.3-col.4-col.5|

Year

t/year t/year t/year t/year t/year t/year 1 2 3 4 5 6

2006 0 0 0 0 0 0 2007 0 0 0 0 0 0 2008 0 0 0 0 0 0 2009 0 0 0 0 0 0 2010 0 0 0 0 0 0 2011 0 0 0 0 0 0 2012 0 0 0 0 0 0

"TORNADO" (and the same for "DEMITEX") Project emissionsEFNG = 56 kg/GJDirect on site emissions (NG combustion)

Natural gas for CHP

Natural gas for back up boilers


CHP+back up boilers fuel (NG)

consumption|(col.1+col.2)*col.3*0.

0041868|

CO2 emissions(NG

combustion)|col.4*56/1000|

x1000 Nm3 x1000 Nm4 kkal/Nm3 GJ/y t/year1 2 3 4 5

2006 0 0 0 0 02007 0 0 0 0 02008 0 0 0 0 02009 0 0 0 0 02010 0 0 0 0 02011 0 0 0 0 02012 0 0 0 0 0

Direct off site emissions (electricity from grid) avoided "-"

Electricity from grid

|0 if export|EF (for reducing el. consumption)

CO2 emissions(electricity from

grid)|col.6*col.7/1000|

Electricity to grid|0 if import|

EF (for generating el.)



2006 0 876 0 0 725 02007 0 856 0 0 710 02008 0 836 0 0 695 02009 0 816 0 0 680 02010 0 796 0 0 666 02011 0 776 0 0 651 02012 0 756 0 0 636 0

Year

Year


Annexes -

Annex XI Boilers efficiency

1.HekroPET Котел Vitoplex 300, 1750 кВт.


Annexes -

2.Medical Glass Котел Vitoplex 100, 985 кВт.


Annexes -

Котел Братск-1Г Параметр Значение

Марка котла Братск-1 Г Завод изготовитель АО «Теплоприбор» г. Караганда,

Кыргызстан Мощность 1 МВт Топливо Природный газ КПД 90,3% Срок изготовления 1981

3. Demitex Котел ДКВР 10/13

Заводское обозначение

Вид топлива

Паро- произво-

Давле-ние

Температура пара, оС

РасчетныйКПД, %

Габаритные размеры собственно котла, мм

Масса котлав объеме

котла дитель- ность, т/ч

пара, МПа

(кгс/см2)

на- сыщен-ного

пере-гре- того

на газе/мазуте

длина ширина высота заводской поставки, кг

Котлы, работающие на жидком и газообразном топливе ДКВр-2,5-13ГМр,б Газ, мазут 2,5 1,3 (13) 194 — 90,0/88,8 5913 4300 5120 6886 ДКВр-4-13ГМр,б ” 4,0 1,3 (13) 194 — 90,0/88,8 7203 4590 5018 8577 ДКВр-4-13-225ГМр ” 4,0 1,3 (13) — 225 89,8/88 7203 4590 5018 9200 ДКВр-6,5-13ГМр,б ” 6,5 1,3 (13) 194 — 91,0/89,5 8526 4695 5170 11447 ДКВр-6,5-13-225ГМб ” 6,5 1,3 (13) — 225 90/89 8526 5275 5018 11923 ДКВр-10-13ГМр ” 10,0 1,3 (13) 194 — 91,0/89,5 8850 5830 7100 15420 ДКВр-10-13-225ГМр ” 10,0 1,3 (13) — 225 90/88 8850 5830 7100 15396 ДКВр-10-23ГМр ” 10,0 2,3 (23) 220 — 91/89 8850 5830 7100 17651 ДКВр-10-23-370ГМр ” 10,0 2,3 (23) — 370 90/88 8850 5830 7100 18374 ДКВр-10-39ГМ ” 10,0 3,9 (39) 247 — 89 11030 5450 5660 30346 ДКВр-10-39-440ГМ ” 10,0 3,9 (39) — 440 89 11030 5450 5660 32217 ДКВр-20-13ГМ ” 20,0 1,3 (13) 194 — 92/90 9776 3215 6246 44634 ДКВр-20-13-250ГМ ” 20,0 1,3 (13) — 250 91/89 9776 3215 6246 45047 ДКВр-20-23-370ГМ ” 20,0 2,3 (23) — 370 91/89 9776 3215 6253 44440

Котел Е-25-14 (ДЕ – синоним)

Техническая характеристика паровых котлов типа Е (ДЕ) с газомазутными топками Заводское обозначение

Вид топлива

Паро- производи-

Давлениепара,

Темпе-ратура

РасчетныйКПД, %,

Габаритные размеры собственно котла, мм

Число транспорта-

Масса котла в объеме

котла тельность,т/ч

МПа (кгс/см2)

пара,оС

на газе/мазуте

длина ширина высота бельных блоков, шт

заводскойпоставки, кг

ДЕ-1-14Г Газ 1 1,4(14) 194 93,0 3240 1900 2645 1 6660 ДЕ-1-14ГМ Газ, мазут 1 1,4(14) 194 93,0/88,6 3240 1900 2645 1 6660 ДЕ-4-14ГМ-О ” 4 1,4(14) 194 90,8/89,5 4200 3980 5050 1 12506 ДЕ-6,5-14ГМ-О ” 6,5 1,4(14) 194 91,1/89,8 4800 3980 5050 1 13908 ДЕ-10-14ГМ-О ” 10 1,4(14) 194 93,0/90,0 6530 3980 5050 1 17681 ДЕ-10-14-225ГМ-О ” 10 1,4(14) 225 93,0/90,0 6530 3980 5050 1 18581 ДЕ-10-24ГМ-О ” 10 2,4(24) 220 93,0/90,0 6532 3980 5050 1 20254 ДЕ-10-24-250ГМ-О ” 10 2,4(24) 250 93,0/90,0 6573 3980 5050 1 21286 ДЕ-16-14ГМ-О ” 16 1,4(14) 194 93,1/90,1 8655 5205 6050 1 20743 ДЕ-16-14-225ГМ-О ” 16 1,4(14) 225 93,1/90,1 8655 5205 6050 1 21600 ДЕ-16-24ГМ-О ” 16 2,4(24) 220 93,1/90,1 8655 5205 6050 1 23658 ДЕ-16-24-250ГМ-О ” 16 2,4(24) 250 93,1/90,1 8655 5205 6050 1 25695 ДЕ-25-14ГМ-О Мазут, газ 25 1,4(14) 194 93,05/91,3 10195 5315 6095 1 27843 ДЕ-25-14-225ГМ-О ” 25 1,4(14) 225 93,05/91,3 10195 5315 6095 1 27361 ДЕ-25-24ГМ-О ” 25 2,4(24) 220 93,05/91,3 10195 5315 6095 1 30836 ДЕ-25-24-250ГМ-О ” 25 2,4(24) 250 93,05/91,3 10195 5315 6095 1 31430 ДЕ-25-15-270ГМ-О ” 25 1,5(15) 270 93,05/91,3 10195 5480 6120 1 29199 ДЕ-25-24-380ГМ-О ” 25 2,4(24) 380 93,05/91,09 10195 5450 6205 1 32756


Annexes -

4. Tornado Котел Viessmann Vitoplex 100 3x1120 кВт, характеристики см. п.1

5. NORD Котел ДКВР 10/13 (4 шт), ДЕ 16/14 (2 шт) – см.п.3 Тепловентилятор Kroll, 6xSKE 340 (http://www.kroll.de/content/en/products/heizgeraete.htm)

Technical data SKE 40 SKE 60 SKE 80 SKE 100 SKE 170 SKE 230 SKE 340

Rated heat load kW 46,8 71,1 93,0 104,6 190,0 258,8 391,0

Rated heating power kW 42,2 64,4 83,9 94,2 168,2 230,3 347,6

Air rate m3/h 2800 4500 5300 6300 11500 15300 23000

Efficiency % 90,1 90,5 90,1 90,1 88,5 89,0 88,9

Temperature rise (∆t) Kelvin 43 41 45 45 43 45 45

Power connection Volt/Hz 230/50 230/50 230/50 230/50 400/50 400/50 400/50

Absorption of electrical power kW 0,25 0,6 0,7 0,7 2,2 3,0 4,0

Width mm Depth mm Height mm

460 750

1600

540 800

1700

680 900

1885

760 1080 2000

1300 900

2470

1500 1000 2520

1700 1200 2850

Weight without burner kg 112 140 151 214 437 525 734


Annexes -

Annex XII TK Tornado's project parameters

Extract from the Explanatory Note of the «П»-stage S e c t i o n 3 H E A T I N G , V E N T I L A T I O N A N D A I R

C O N D I T I O N I N G

1 . 1 . B A S I C P R O J E C T R A T E S

Business and other places (manufactured goods shops, supermarket, supermarket warehouse, offices and accommodation space, boiler house) Usable area, m² 12482,2Total heat consumption for heating and ventilation, kW, including: 1600

For heating, kW 545For ventilation, kW 1055

Cold consumption, kW 1849Cultural and entertaining places (vestibule, cinema, bowling, bar with a hall) Usable area, m² 5483,8Total heat consumption for heating and ventilation, kW, including: 1250


Cold consumption, kW 551Total heat consumption for heating and ventilation of the whole building, kW, including: 2850


Total cold consumption for the complex, kW 2400Building usable area 17966

1 . 2 . 3 . 5 . КОНДИЦИОНИРОВАНИЕ ВОЗДУХА

В магазинах промтоваров, супермаркете, вестибюле, складе супермаркета, административных помещениях, зрительных залах, фойе, кинопроекционной, боулинге, баре с холлом в тёплый период года предусмотрено комфортное кондиционирование воздуха с оптимальными параметрами воздушной среды:

▪ температура - 23-25°С; ▪ относительная влажность - 60 – 30 %; ▪ скорость движения воздуха - не более 0,2 м/с.

Воздухообмены по помещениям приведены в таблице 3.4.1.

В качестве установок систем кондиционирования воздуха предусмотрено оборудование фирмы «VTS Clima» типа CV-A и CV-P.

Для супермаркета предусмотрены вентиляторные доводчики канального типа типа FWD, для вестибюля - кассетные типа CWS (фэн-койлы) фирмы «TRANE», присоединяемые к системе отопления по 4-х трубной схеме.

Холодоснабжение кондиционеров и фэн-койлов, обслуживающих все выше перечисленные помещения, кроме магазинов промтоваров, осуществляется от парокомпрессионных холодильных машин (чиллеров) с воздушным охлаждением конденсатора типа RTAC 300 фирмы «TRANE».


Annexes -

Чиллеры установлены на открытой кровле здания.

Расчётный расход холода 2400 кВт, из них:

• на супермаркет – 354 квт; • на склад супермаркета – 17 кВт; • административно-бытовые помещения - 18 кВт; • на вестибюль – 86 квт; • на залы кинотеатра – 236 кВт; • фойе кинотеатра – 54 кВт; • кинопроекционную – 50 кВт; • боулинг – 105 кВт; • бар с холлом – 140 кВт; • магазины промтоваров составляет 1340 кВт.

Расчетная температура холодной воды 7-12 °С. Охлаждение воды осуществляется газом-хладоносителем в испарителе в результате процесса прямого испарительного охлаждения. Охлаждение конденсаторов – воздушное.

Работа чиллеров предусматривается в автоматическом режиме.

На каждый чиллер установлены по два насоса холодной воды: один рабочий, один резервный. Производительность каждого насоса 95,3 м³/ч.

Заполнение системы холодоснабжения осуществляется водой от системы водоподготовки.

Трубопроводы системы холодоснабжения выполняются из стальных водогазопроводных труб.

Трубопроводы системы холодоснабжения теплоизолируются.

Наружные блоки поставляются отдельно от приточных систем и установлены на перекрытии галереи.


Annexes -

Параметр Значение

1 Режим работы оборудовнаия:

1 ▪ количество рабочих дней в неделю, max дней 7

▪ ▪ расчетное значение по Проекту дней 5

▪ ▪ планируемое значение к реализации дней 7

2 ▪ количество рабочих часов в неделю, max час/неделя max 112


▪ ▪ планируемое значение к реализации дней 84 - max 112

3 ▪ сменность работы основного оборудовнаия смен 2

4 ▪ продолжительность отопительного периода суток/год 175

5 ▪ продолжительность периода интенсивного охлаждения суток/год 150

6 ▪ количество рабочих часов в сутки, max час/сутки max 16


▪ ▪ планируемое значение к реализации дней 12 - max 16

2 Общая установленная мощность, в том числе кВт 5 133,0

1 Низковольтные потребители, в том числе: кВт 4 033,0

▪ Электродвигатели низкого напряжения кВт 1 900,0

▪ Прочее оборудование кВт 1 077,6

▪ Неучтенное оборудование кВт 1 055,4

2 Электрическое освещение кВт 1 100,0

3 Степень надежности электроснабжения по ПУЭ

▪ Потребители 1 категории кВт 877,4

▪ Потребители 2 и 3 категорий кВт 4 459,6

4 Расчетная нагрузка, в том числе кВт 3 916,0

1 Низковольтные потребители кВт 2 950,4

2 Электрическое освещение кВт 965,6

5 Параметры сети

▪ Напряжение силовой сети Вольт 380

▪ Напряжение сетей управления Вольт 220

▪ Напряжение сети общего освещения тип сети TN-C-S Вольт 360 / 220

▪ Частота сети Гц 50

6 Годовой расход электроэнергии мВТхчас 17 699,5

в том числе для электрического совещения мВТхчас 2 282,5

7 Коэффициент мощности (тангенс ФИ)

1 естественный 0,94

2 принятый в проекте (нормируемый) 0,14

МЕТОДЫ РАСЧЕТА ПРОЕКТНЫХ НАГРУЗОК

1 ВСН59-88 "Энергооборудование жилых и общественных зданий"

2 Аналоговый - ЦУМ / Grand Plaza / ТПЦ "Калиновая" - Днепропетровск

ПРОЕКТ СТРОИТЕЛЬСТВА ТОРГОВОГО КОМПЛЕКСА В КРИВОМ РОГЕ

ЭЛЕКТРОСНАБЖЕНИЕ ТОРГОВОГО КОМПЛЕКСА


Annexes -

Температура, С Расход тепла, кВт

1 Расход теплоты на вентиляцию (контур 1) 90 - 70 1 550,00

2 Расход теплоты на местные отопительные приборы (контур 2) 90 - 70 160,00

3 Расход теплоты на фэн-койлы (контур 3) 60 - 40 140,00

4 Расход теплоты на вентиляцию (контур 4) 90 - 70 950,00

5 Расход теплоты на отпление и вентиляцию котельной 91 - 70 50,00

Расход теплоты ИТОГО: 2 850

6 Горячее водоснабжение 55 700

Всего по Проекту: 3 550

7 Котельное оборудование по Проекту:

1 Котлы WIESSMANN марка VITOPLEX 100 3 3 х 1 120 кВт

Суммарная мощность 3 360 кВт

КПД 94,00%

2 Установка сигнализатора горючих газов GS-500-C-CH4

3 Установка умягчения воды ES 42 ECOWATER systems

Производительность установки 1,8 м.куб./час

4 Качество подпиточной воды В соответствии с п.13.5 ДНАОП 0.00.-1.26-96

5 Теплообменнки KOLBI-10-700-4.37-1-K

Производительность теплообменника 700 кВт

6 Вертикальные баки накопители WIESSMANN марка VITOCELL-L 100 2 2 х 1 000 л.

Суммарная емкость 2 000 литров

7 Система управления Vititronic 333

8 Проектные параметры газоснабжения котельной:

1 Точка врезки - газопровод среднего давления по пр.Мира диаметр газопровода - 350 мм

2 Давление газа в точке врезки в соответствии с ТУ 3,0 кгс/см.кв.

3 Расход газа на котельную 402 м.куб./час

9 Отопление и вентиляция котельной:

1 Расчетные параметры наружного воздуха Температура, С Энтальпия, кдж/кгТеплый А 26,5 56

Холодный Б -23 -22

2 Продолжительность отопительного периода 175 суток

3 Скорость ветра 7 м/с

4 Нормируемая внутренняя температура в котельной 12 град.С

5 Вытяжная естественная вентиляция 1 350 м.куб./час

6 Механическая приточная вентиляция 4 833 м.куб./час

7 Приточные установки VTS CLIMA тип CV-P

10 Электрооборудование котельной:

1 Установленная мощность Руст. 25 кВт

2 Расчетная нагрузка Ррасч. 22 кВт

3 Степень надежности первая категория по ПУЭ

4 Годовой расход электроэнергии 80 000 кВт.час.

11 Водоснабжение котельной:

1 Подпитка котельной 0,01 м.куб./сутки

2 Собственные нужды ХВО 220 литров/месяц

Горяче водоснабжение - максимальный расход 5,212 м.куб./час

Количество сточных вод (промывка фильтров) 220 литров/месяц

12 Технико-экономические показатели крышной котельной по Проекту:

1 Расчетная производительность 3,053 Гкал/час 3 550 кВт

2 Установленная производительность 2,89 Гкал/час 3 360 кВт

3 Годовая выработка тепла, в том числе: 2 734 Гкал 3 179 130 кВт

на отопление 300 х 1 932 579 600 кВт

на вентиляцию 25 501 х 875,8 2 233 290 кВт

на горячееводоснабжение 700 х 175 х 2 х 0,8 + 700 х 190 х 2 х 0,64 366 240 кВт

4 Годовой расход условного топлива 415,5 т.у.т.

5 Годовой расход топлива, в природном газе 351 423 нм.куб./год

6 КПД котла 0,94

7 Теплотворная способность условного топлива 7 000 ккал/кг

8 Теплотворная способность природного газа 8 300 ккал/нм.уб.

9 Годовой расход электроэнергии 80 000 кВт.час

10 Удельный расход условного топлива на1 Гкал отпущенного тепла 152 кг.у.т./Гкал

ПРОЕКТ СТРОИТЕЛЬСТВА ТОРГОВОГО КОМПЛЕКСА В КРИВОМ РОГЕ

ТЕПЛОСНАБЖЕНИЕ ТОРГОВОГО КОМПЛЕКСА


Annexes -

Annex XIII Cool equipment

HEKRO PET RPW

1600

RPW

3200 kcal/h 120000 240000

Cooling capacity kW 140 280

Total intalled power kW 63.3 126.7

Evaporator water flow m³/h 31.2 62.5

Evaporator pressure drop bar 0.5 0.6

Condenser water flow m³/h 37.5 2x37.5

Condensing power kcal/h 158000 2x158000

Nominal compressor power HP 60 2x60

m³/h 30/66 48/120

bar 2.3/1.5 2.6/1.3 standart pump (for re circulation)

kW 4 7.5

B mm 900 1000

W mm 2690 2850 Dimension H mm 1590 2030

Weight kg 980 1700


Annexes -


Annexes -

Demitex, Tornado (RTAC 300)

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