453/2012 Sb.
DECREE
of 13 October. December 2012
electricity from the high performance of the combined production of electricity and heat and
electricity from secondary sources
The Ministry of industry and trade shall be determined according to § 53 para. 1 (b). (g)), and
h) Act No. 165/2012 Coll., on supported energy sources and amending
Some laws:
§ 1
The subject of the edit
This Decree regulates the following a directly applicable regulation
The European Union ^ 1)
and determine the amount of electricity) the way of high-performance cogeneration
electricity and heat,
(b)) model application and the conditions for the issue of certificates of origin for electricity from
high-performance of the combined production of electricity and heat,
c) model application and the conditions for the issue of certificates of origin for electricity from
secondary sources.
§ 2
How to specify the quantity of electricity from high-performance cogeneration
electricity and heat
(1) the cogeneration unit for the purposes of this Ordinance means
and the device with the delivery of combined cycle gas turbine) heat,
b) steam turbine, protitlaká
c) condensing turbine specimen,
d) gas turbine,
e) internal combustion engine,
(f)), mikroturbína
g) Stirling engine,
h) fuel cell,
I) steam engine,
j) Organic Rankine cycle, or
the combination of a device) referred to in points (a) to (j))), if it can
work in the mode of combined production of electricity and heat.
(2) the amount of electricity from cogeneration of electricity and heat
sets for
and individual cogeneration unit), or
(b)) a serial report of cogeneration units,
producing electricity or mechanical energy, based on
actually achieved the operational values of the energy consumption in fuel production
electricity or mechanical energy and useful heat.
(3) for electricity from cogeneration of electricity and heat is considered to be
the total amount of electricity produced during the period under the law
governing the reporting and accounting of electricity, heat of the supported
resources and biomethane, quantity and quality of the actually acquired and used
resources and performing certain other provisions of the Act on the supported
energy sources (hereinafter referred to as the "reporting period"), measured at the output
the main generators of electricity the cogeneration unit or serial report
cogeneration units, if the overall efficiency, which is provided for in
the procedure referred to in annex 1 to this notice, for the reporting period
has reached the
and CHP units) in the case referred to in paragraph 1 (b). (b)), and (d)) to
at least 75%),
(b)) in the case of cogeneration units referred to in paragraph 1 (b). a) and (c))
at least 80%.
(4) for the cogeneration unit or serial report of cogeneration
units with overall efficiency for the reporting period is less than the
referred to in paragraph 3, the amount of electricity from cogeneration
electricity and heat for the reported period, the procedure laid down in annex
No 1 to this notice.
(5) in determining the amount of electricity from cogeneration
heat in accordance with paragraphs 3 and 4 shall
and does not count the quantity of heat) without the simultaneous production of electricity
and the amount of energy in the fuel consumed in the production of heat,
(b)) in the case of combined production of electricity and heat from renewable energy
useful heat sources, it's the heat produced in the process of
the combined production of electricity and heat, which is used for the supply of the system
supply of thermal energy or for further use for technological
purposes outside of the heat consumption in the production device and auxiliary plant,
that are directly related to the production of electricity, including the production, transformation or
adjustment of fuel and losses in district heat production of electricity or heat
used to further conversion into electricity or mechanical energy (
"useful heat from renewable energy sources"),
c) in the case of cogeneration units following the upstream
cogeneration unit that will produce electricity or mechanical
energy, in the serial the involvement of cogeneration units, used for
the calculation of the consumption of energy in the fuel quantity of thermal energy at the output of the
front-end of the cogeneration unit in cogeneration units the following.
(6) for electricity from the high performance of the combined production of electricity and heat
It considers the amount of electricity provided for under paragraphs 3 to 5, which
the production is achieved relative primary energy savings of at least 10%
set out the procedure that is listed in annex 2 to this Decree.
(7) in the case of cogeneration units with an installed electrical power
not more than 1 MW for electricity from high-performance cogeneration
electricity and heat considers the amount of electricity from cogeneration
electricity and heat, which ensures a positive value proportional savings
the primary power determined in accordance with Annex 2 to this Decree.
§ 3
Certificate of origin of electricity from high-performance cogeneration
electricity and heat
(1) a certificate of origin of electricity from high-performance cogeneration
electricity and heat shall be issued for the cogeneration unit or serial
report of cogeneration units.
(2) for the purpose of issuing a certificate of origin of electricity from high-performance
the combined production of electricity and heat the applicant shall estimate the amount of electricity from
high-performance of the combined production of electricity and heat according to § 2
for the first calendar year of operation under the production envisaged and how
operation of the cogeneration unit or serial report.
(3) the model applications for the issue of certificates of origin of electricity from high-performance
the combined production of electricity and heat is given in annex 3 to this
the Decree.
§ 4
Certificates of origin for electricity from secondary sources
(1) a certificate of origin of electricity from secondary sources is produced for
the manufacture of electricity.
(2) the model applications for the issue of certificates of origin for electricity from secondary
resources for offshore electricity from secondary sources is given in annex No.
4 to this notice.
§ 5
Regulation (EEC)
Decree 344/2009 Coll., on details of how to determine electricity from
high-performance of the combined production of electricity and heat based on demand
After a useful heat energy of secondary energy
resources, is hereby repealed.
§ 6
Transitional provision
It was granted the certificate of origin of electricity from high-performance combined
production of electricity and heat for other than serial report of cogeneration
units before the date of entry into force of this order, it shall apply to
specify the quantity of electricity from cogeneration of electricity and heat
the reporting period for this report as a whole procedure according to § 2 (2). 4
by analogy.
§ 7
The effectiveness of the
This Decree shall enter into force on 1 January 2000. January 1, 2013.
Minister:
Mudr. Cuba in r.
Annex 1
The method of determining the overall efficiency, the amount of mechanical energy and
specify the quantity of electricity from cogeneration of electricity and heat
1. The overall efficiency of the cogeneration unit or serial report
cogeneration units? total shall be determined according to the formula:
étacelk = (Esv + EM + Quž)/(QPAL KJ)
where:
The eeas is the total amount of electricity produced in combined heat and power unit or serial report of cogeneration units
measured at the generator terminals [MWh]
EM is the amount of mechanical energy obtained by transformation of energy in the steam turbine, which is further transformed
on electricity [MWh]
QUŽ is the amount of useful heat [MWh]
QPAL KJ is the total amount of energy consumed to produce electricity, mechanical energy and useful heat in combined heat and power
the unit or serial report of cogeneration units that make up the energy in the fuel consumption, determined on the basis of
its calorific value and, where appropriate, the supplied thermal energy from external sources without the inclusion of the returned condensate heat [MWh].
2. in the event that the CHP units or combined heat and power units and steam
condensing turbine use common steam bus, the
the total amount of energy in the fuel consumed in production between the
each cogeneration unit or individual cogeneration units and
individual steam condensing turbine in proportion to the amount of steam
consumed steam or condensation units backed up
turbines.
3. If some of the energy of the fuel entering the cogeneration process
electricity and heat rekuperována in chemicals and used, can be
before calculating the overall efficiency to deduct from the total energy consumption
in the fuel.
4. the quantity of mechanical energy EM is determined according to the formula:
EM = MP (iVST-iVÝST)/3.6,
where:
EM is the amount of mechanical energy [MWh]
Mp is the amount of steam that has passed through the turbine, turbine parts, where appropriate, between the entry and the collection of the turbine [t]
iVST steam enthalpy is the input to the turbine [MJ/kg]
iVÝST is the enthalpy of steam at the output of the turbine, or of the receipt of the turbines [MJ/kg].
5. The determined value of the EM is used as the input for the calculation of the total
efficiency cogeneration units or their serial report.
6. In the case that it is the mechanical energy generated at the same time with
production of useful heat for a steam turbine or counter-pressure
the cogeneration section steam condensing turbines, it shall apply this
the value of mechanical energy as an input for the calculation referred to in point 1 of the annex
No 2 to this Decree.
7. If the overall efficiency of the cogeneration unit or serial report
cogeneration units lower than provided for in § 2 (2). 3, the
the total amount of electricity produced in combined heat and power unit or serial
report of cogeneration units for quantities of electricity from combined
production of electricity and heat and the amount of electricity that from this factory
It does not come. The amount of electricity from cogeneration of electricity and heat
determined according to the following formula:
EKVET = QUŽ * CSKUT,
where:
EKVET is the amount of electricity from cogeneration of electricity and heat [MWh]; If the calculated value is EKVET
greater than the total amount of electricity produced, the value of the total quantity of electricity produced
QUŽ is the amount of useful heat [MWh]
CSKUT is the actual power to heat ratio expressing the relationship between the quantity of electricity from cogeneration
and the heat and the amount of useful heat when its highest production in běžnémprovozu; in the case of cogeneration
electricity and heat from renewable sources instead of useful heat it's the useful heat from renewable
energy sources [-].
8. the actual power to heat ratio is determined based on CSKUT
actually measured the amount of useful heat output and electricity per
the production of useful heat at a time when the cogeneration unit is working in the
full cogeneration mode only with the delivery of useful heat.
9. in the event that, having regard to the demand for useful heat or
the properties of the cogeneration unit or serial report of cogeneration
drives is not the mixed-mode operation in full with a delivery only
useful heat possible, the actual power to heat ratio
CSKUT according to the formula:
CSKUT = (Esv1-Esv2)/QUŽ,
where
Esv1 is the quantity of electricity produced in combined heat and power unit or serial report of cogeneration units measured at the terminal of the generator when working condition with the highest achievable in normal operation, the production of useful heat and QUŽ at the same time when the highest obtainable in normal operation, the input of the energy in the fuel [MWh]
Esv2 is the quantity of electricity produced in combined heat and power unit or serial report of cogeneration units measured at the terminal of the generator in operating condition operating condition of measuring Esv1, when the shortage of useful heat and power consumption input energy in the fuel is reduced in such a way that produkcejiného than useful heat was the same as the production status when determining the Esv1 [MWh]
QUŽ is the amount of useful heat when determining the Esv1 [MWh].
10. Measurements shall be made for the same period for both operating modes when
outdoor temperature below 10 ° c. If possible, the outdoor temperature
the same for both conditions.
11. the actual power to heat ratio CSKUT down to 1. January 2013
or on the date of entry of the cogeneration unit or serial report to
traffic and at the same time immediately after each change of the cogeneration unit
or their serial report that may significantly affect actual
the ratio of electricity and heat.
12. For cogeneration units or their serial reports that are in the
construction or in the first year of operation and for which you cannot get measured
the data can be used instead of the value CSKUT the value of design to the ratio of electricity and
heat in full cogeneration mode indicated by the manufacturer of the cogeneration
unit.
13. Until 31 December 2006. December 2013 is in the case of condensing power turbines
possible for the calculation of the quantity of electricity from cogeneration
heat use the power to heat ratio as set out in the following way:
EKVET = URQuž.yko. Xp [MWh]
where
EKVET is the amount of electricity from cogeneration of electricity and heat [MWh]; If the calculated value of EKVET is greater than the total amount of electricity produced, the value of the total quantity of electricity produced
Quž is the amount of useful heat [MWh]
yko is guide number whose values are set out in table 1 of this annex
Table 1-baseline Values numbers yko
---------------------------------------------------------------------------------------------------------
tr P1
--------------------------------------------------------------------------------------------
1.6 2.0 2.5 3.5 6.0 9.0 13.0 16.0
---------------------------------------------------------------------------------------------------------
> = 5 0.230 0.255 0.280 0.320 0.380 0.430 0.480 0.500
(0.230) (0.255) (0.280) (0.320) (0.380) (0.430) (0.480) (0.500)
---------------------------------------------------------------------------------------------------------
3 0.220 0.245 0.270 0.310 0.360 0.415 0.465 0.485
(0.225) (0.250) (0.275) (0.315) (0.365) (0.420) (0.475) (0.495)
---------------------------------------------------------------------------------------------------------
1 0.210 0.235 0.260 0.295 0.350 0.400 0.450 0.465
(0.220) (0.245) (0.270) (0.305) (0.360) (0.410) (0.465) (0.480)
---------------------------------------------------------------------------------------------------------
0 0.200 0.233 0.255 0.285 0.340 0.395 0.440 0.455
(0.215) (0.240) (0.270) (0.300) (0.355) (0.410) (0.460) (0.480)
---------------------------------------------------------------------------------------------------------
-1 0.195 0.220 0.250 0.280 0.335 0.385 0.435 0.455
(0.210) (0.235) (0.265) (0.295) (0.350) (0.400) (0.460) (0.470)
---------------------------------------------------------------------------------------------------------
-3 0.185 0.210 0.230 0.265 0.325 0.370 0.420 0.435
(0.205) (0.230) (0.260) (0.287) (0.345) (0.395) (0.450) (0.465)
---------------------------------------------------------------------------------------------------------
-5 0.175 0.200 0.225 0.250 0.310 0.355 0.400 0.410
(0.200) (0.225) (0.255) (0.280) (0.335) (0.385) (0.440) (0.450)
---------------------------------------------------------------------------------------------------------
-7 0.160 0.185 0.215 0.235 0.295 0.340 0.384 0.400
(0.190) (0.215) (0.250) (0.270) (0.330) (0.375) (0.432) (0.440)
---------------------------------------------------------------------------------------------------------
Notes to table 1:
P9-the input pressure [MPa]
TR-is the average temperature of the air in the reporting period [° c]
The values for the parameters are established yko thermal network 150/70 ° c, in parentheses are values for the 120/50 ° c.
XP is the coefficient of the influence of load steam turbines, the values are listed in table 2 of this annex.
Table 2-values of the factor of influence of steam turbine load Xp
---------------------------------------------------------------------
Load (%) 100 80 60 40 20 10
---------------------------------------------------------------------
XP 1.00 0.98 0.95 0.90 0.75 0.6
---------------------------------------------------------------------
14. in the case of combined production of electricity and heat from renewable energy
resources for the calculation referred to in the preceding points instead of useful heat
It's the useful heat from renewable energy sources.
Annex 2
Way of determining the relative primary energy savings in the combined production of
electricity and heat
1. the amount of primary energy savings of the UPE in the combined production of electricity and
heat shall be calculated according to the formula:
UPE = (1-1/(étaqT/étarV + étaeT/étarE)) * 100 [%]
While the partial efficiency of heat and electricity étaqT étaeT shall be determined according to the formula:
étaqT = QUŽ/QPAL CHP [-]
étaeT = EKVET/QPAL CHP [-]
where:
étaqT is the efficiency of heat supply of the combined production of electricity and heat is defined as the amount of useful
the heat produced in a cogeneration unit or serial report cuts power consumption in fuel
used in the process of combined production of electricity and heat [-]
étaeT is the electrical efficiency of combined production of electricity and heat is defined as the quantity of electricity produced
in a CHP unit or serial report bound to supply useful heat output divided by the fuel consumption
the energy in the fuel used in the process of combined production of electricity atepla; electricity from cogeneration
electricity and heat for the calculation may be increased by the amount of mechanical energy set out under point 4
Appendix No. 1 to this notice [-]
étarV is the resulting harmonised efficiency reference value for separate heat production [-]
étarE is the resulting harmonised efficiency reference value for separate production of electricity [-]
EKVET is the amount of electricity from cogeneration of electricity and heat [MWh]
QUŽ is the amount of useful heat [MWh]
QPAL CHP is the consumption of energy in the fuel used in the process of combined výrobyelektřiny and heat [MWh].
2. The consumption of energy in the fuel on the combined production of electricity and heat
QPAL CHP shall be determined by the formula:
QPAL CHP = QPAL KJ-QPAL NEKVET [MWh]
where:
QPAL KJ is the total amount of energy consumed to produce electricity, mechanical energy and useful heat
in a CHP unit or serial report of cogeneration units that make up the power consumption
the fuel provided for on the basis of its calorific value and, where appropriate, the supplied thermal energy from external sources
without the inclusion of the returned condensate heat [MWh]
QPAL NEKVET is the consumption of energy in the fuel to produce electricity, not originating from the combined production of electricity and heat [MWh].
3. the value of QPAL NEKVET down from the relation:
QPAL NEKVET = ENEKVET/étaE NEKVET [MWh]
where:
ENEKVET, electricity is not originating from the combined production of electricity and heat [MWh]
étaE NEKVET is a specific non-electricity production efficiency of combined production of electricity and heat on the device [-]
ENEKVET = Esv-EKVET [MWh]
where:
The eeas is the total amount of electricity produced in combined heat and power CHP unit nebosériové report
units measured at the terminals of generators [MWh].
4. the value of étaE NEKVET
and device) by the combined production according to § 2 (2). 1 (b).
(b)), and (d))) on the basis of the operating data of the cogeneration unit or
serial reports of cogeneration units for the reporting period by
formula: étaE NEKVET = Esv/QPAL KJ [-] where: Esv is the total amount
of electricity produced in combined heat and power unit or serial report
cogeneration units measured at the generator terminals [MWh] QPAL KJ's
the total amount of energy used to produce electricity, mechanical
energy and useful heat in a cogeneration unit or serial report
cogeneration units that make up the power consumption of the fuel provided for
on the basis of its calorific value and, where appropriate, delivered by the thermal energy of the
external sources without the inclusion of the returned condensate heat [MWh]
(b)) shall be determined for the combined production of the device according to § 2 (2). 1 (b).
a) and (c)) on the basis of the operating data of the cogeneration unit or serial
report of cogeneration units operating at a maximum attainable
electrical performance in normal use and at the same time operating without
the supply of useful heat in full condensing mode of operation when
the outdoor temperature is lower than 10 ° c according to the formula as referred to in point (a)),
(c)), in the event that the cogeneration unit or serial report
cogeneration units pursuant to § 2 (2). 1 (b). a) and (c)) in the reporting
the period involved in the provision of support services in accordance with other legal
prescription), determined according to the formula:
étaE NEKVET = (Esv-EKVET)/(QPAL KJ-asleep * (QUŽ + EKVET/(étam * étag))) [-]
where:
The eeas is the total amount of electricity produced in combined heat and power unit or serial report measured
at the terminals of generators [MWh]
EKVET is the amount of electricity from cogeneration of electricity and heat [MWh]
QPAL KJ is the total amount of energy consumed to produce electricity, mechanical energy and useful heat
in a CHP unit or serial report of cogeneration units that make up the power consumption
the fuel provided for on the basis of its calorific value and, where appropriate, the thermal energy supplied from external
without the inclusion of sources returned condensate heat [MWh]
QUŽ is the amount of useful heat [MWh]
sleep is the specific energy consumption of fuel for production of heat [MWh/MWh]
étam is the mechanical efficiency of the turbines [-]
étag is the efficiency of the generator [-].
In the event that the manufacturer proves that achieves higher efficiency, it
for mechanical efficiency of the turbine for the effectiveness and value of 0.99
the value of the generator 0.98.
5. in the case of combined production of electricity and heat from renewable energy
resources for the calculation referred to in the preceding points instead of useful heat
It's the useful heat from renewable energy sources.
6. the harmonised efficiency reference values for separate production
electricity in percent related to the net calorific value of the fuel, temperature
environment of 15 ° c, atmospheric pressure of 1.013 bar (1 013 hPa), the relative
humidity of 60% in the table no. 1 in this annex.
Table 1-
Harmonised efficiency reference values for separate production
electricity in percentage
----------------------------------------------------------------------------------------------------------------------------------------
Fuel cogeneration unit put into operation by the end of the year
2001 2002 2003 2004 2005 and previously 2006-2011 2012-2015
étaripalE étaripalE étaripalE étaripalE étaripalE étaripalE étaripalE
----------------------------------------------------------------------------------------------------------------------------------------
Hard coal/coke 42.7 43.1 43.5 43.8 44.0 44.2 44.2
Brown coal, lignite briquettes 40.3 40.7 41.1 41.4 41.6 41.8 41.8
Peat, peat briquettes 38.1 38.4 38.6 38.8 38.9 39.0 39.0
Woodfuels ^ 1) 30.4 31.1 31.7 32.2 32.6 33.0 33.0
Agricultural biomass 23.1 23.5 24.0 24.4 24.7 25.0 25.0
Biodegradable nerozložitelná
even biodegradable folder
municipal and industrial
Waste 23.1 23.5 24.0 24.4 24.7 25.0 25.0
----------------------------------------------------------------------------------------------------------------------------------------
Other biomass not elsewhere specified 23.1 23.5 24.0 24.4 24.7 25.0 25.0
----------------------------------------------------------------------------------------------------------------------------------------
Liquid fuel oils, LPG 42.7 43.1 43.5 43.8 44.0 44.2 44.2
Biofuels 42.7 43.1 43.5 43.8 44.0 44.2 44.2
Biodegradable waste 23.1 23.5 24.0 24.4 24.7 25.0 25.0
Non-recoverable waste 23.1 23.5 24.0 24.4 24.7 25.0 25.0
----------------------------------------------------------------------------------------------------------------------------------------
Gaseous natural gas 51.7 51.9 52.1 52.3 52.4 52.5 52.5
Gas from the refining/hydrogen 42.7 43.1 43.5 43.8 44.0 44.2 44.2
Coke oven, blast furnace
and other waste gases,
waste heat obtained 35.0 35.0 35.0 35.0 35.0 35.0 35.0
Biogas 40.1 40.6 41.0 41.4 41.7 42.0 42.0
----------------------------------------------------------------------------------------------------------------------------------------
Note for table 1:
1 wood) with relative humidity up to 30% and fuel with the predominant share of noble wood.
7. For the calculation of primary energy savings shall apply harmonised
efficiency reference value as referred to in table 1 of this annex
in reference to the year of entry into service of the cogeneration unit. This
harmonised efficiency reference value shall apply for the period of ten
years from the year of putting into operation of the cogeneration unit. The year of the entry into
operation of the cogeneration unit shall mean the calendar year in which the
the production of electricity.
8. From the eleventh year of putting into operation of the cogeneration unit is
It's the harmonised efficiency reference value for separate production
electricity, which is referred to in section 7 shall apply for the cogeneration unit,
that is 10 years old. These harmonised efficiency reference value
shall apply for a period of one year.
9. In the case that a CHP unit was technically evaluated
(the modernization or reconstruction) and the investment cost of the her
technical improvements exceed 50% of the investment costs for new
comparable cogeneration unit shall be deemed for the purpose of section 7
calendar year of the first generation of electricity in the improved cogeneration
the unit for the year of its entry into service.
10. If a cogeneration unit uses only one type of fuel,
substitutes the value ÉTArpalE value directly from the table of étaripalE No. 1 in
of this annex. In the case of joint use of more types of fuel with
down the resulting harmonised efficiency reference value for
separate production of electricity as a weighted average, where individual
the amount of energy in the fuel.
n n
étarpalE = sum (Qpal, i * étaripalE)/SUM Qpal, i [%],
i=1 i=1
where:
Qpal, and shares power in the fuel of individual types of fuel consumed for the combined production of electricity
and heat [MWh]
étaripalE are harmonised efficiency reference values for separate production of electricity referred to in table 1 of the
in this annex for each type of fuel [%].
11. The harmonised efficiency reference value for separate production
electricity is increased by the correction factor for the climatic conditions in the delta
étartepE, which is the territory of the Czech Republic established in the amount of + 0.7%.
12. Correction factor for climatic conditions does not apply to
CHP units based on fuel cells.
13. The harmonised efficiency reference value for separate production
electricity shall be further adjusted, depending on the network losses that are directly
related to the voltage level of the connection of the cogeneration unit using the
the correction factor k connection voltage levels. If CHP
the unit delivers electricity to one voltage levels, substitutes for
the value of k value directly from the table of kinap No. 2 in this annex.
Table 2-connection voltage levels correction factors
---------------------------------------------------------------------------------------------------
The voltage Value of the correction factor kinap connection voltage levels
---------------------------------------------------------------------------------
Electricity delivered to the transmission Electricity supplied for your own
or consumption or distribution system, direct line
---------------------------------------------------------------------------------------------------
200 kV 1.000 0.985 >
100-200 kV 0.985 0.965
50-100 kV 0.965 0.945
0.4-50 kV 0.945 0.925
0.4 kV < 0.925 0.860
---------------------------------------------------------------------------------------------------
In the case that the cogeneration unit supplied electricity to more voltage
levels, the correction factor connection voltage levels will be evaluated on the
the basis of the weighted average of supplied electricity.
n n
k = sum (a kinap * Ei)/SUM of Ei [-]
I = 1 i = 1
where:
EI are the individual shares of the quantities of electricity supplied to different voltage levels [MWh]
the values of the correction factor kinap voltage levels connection [-].
14. the resulting harmonised efficiency reference value for separate
the production of electricity for the calculation of primary energy savings, in point 1, the
determined according to the formula:
étarE = (étarpalE + delta étartepE) * k/100 [-].
15. Correction factors for climatic conditions and voltage levels
the connection will only apply to the harmonised reference values
efficiency for separate production of electricity.
16. the harmonised efficiency reference values for separate production
heat in the percentage related to the net calorific value of the fuel, temperature
environment of 15 ° c, atmospheric pressure of 1.013 bar (1 013 hPa), the relative
humidity 60%, the table 3 of this annex.
Table 3-harmonised efficiency reference values for separate
heat production as a percentage of
-------------------------------------------------------------------------------------------------------------
Fuel type of media
-------------------------------------------------------------------
Steam/hot water to direct the exhaust gases
-------------------------------------------------------------------
étaripalV étaripalV
-------------------------------------------------------------------------------------------------------------
Hard coal 88 80
Brown coal, lignite 86 78
Woodfuels ^ 1) 86 78
Agricultural biomass 80 72
Biologically and nerozložitelná
biodegradable component of municipal
and industrial waste 80 72
Other biomass not elsewhere specified 80 72
-------------------------------------------------------------------------------------------------------------
Liquid fuel oils 89 81
Biofuels 89 81
Biodegradable waste 80 72
Non-recoverable waste 80 72
-------------------------------------------------------------------------------------------------------------
Gaseous natural gas 90 82
Gas from the refining/hydrogen 89 81
Coke oven, blast furnace and
other waste gases, waste heat 80 72
Biogas 70 62
-------------------------------------------------------------------------------------------------------------
Note to table 3:
1 wood) with relative humidity up to 30% and fuel with the predominant share of noble wood.
17. the resulting harmonised efficiency reference value for separate
heat production shall be determined according to the formula:
n n
étarV = sum (Qpal, i * étaripalV)/(sum of Qpal, i * 100) [-]
i=1 i=1
where:
Qpal, and shares power in the fuel of individual types of fuel consumed for the combined production of electricity and heat [MWh]
étaripalV are the harmonised efficiency reference values for separate production of heat listed in table 3 of this annex for each type of fuel [%].
Annex 3
MODEL APPLICATION FOR ISSUE OF A CERTIFICATE OF ORIGIN OF ELECTRICITY FROM HIGH-PERFORMANCE
KOMBINOVÉ COMBINED PRODUCTION
Annex 4
MODEL APPLICATION FOR THE ISSUE OF CERTIFICATES OF ORIGIN FOR ELECTRICITY FROM SECONDARY SOURCES
1) Commission implementing decision 2011/877/EC of 19 June 2000. December 2011,
establishing harmonised efficiency reference values for
separate production of electricity and heat in application of Directive of the European
Parliament and Council Directive 2004/8/EC and repealing Commission decision
2007/74/EC, as amended.