WO2011153971A1 - Combined heat and power plant - Google Patents

Abstract

The invention relates to a combined heat and power plant (100), comprising a photovoltaic system having flat photovoltaic elements (12), which generate electric energy from solar irradiation (S) of the upper face, said energy being fed into a power grid (14) and/or supplied to a power storage unit, characterized in that a cooling register (20) is arranged under each of the photovoltaic elements (12) and is in communicative connection with a first heat pump via a heat pump circuit, wherein the cooling register (20) supplies the process heat generated during the operation of the photovoltaic elements (12) to the first heat pump, the first heat pump is in communicative connection with a first carrier medium circuit (22) having a first carrier medium, a heat storage unit (24) having a heat storage medium is arranged in the first carrier medium circuit (22), wherein the thermal energy of the first carrier medium within the heat storage unit (24) is transferred to the heat storage medium, and at least one further thermal load circuit (30) having a second carrier medium is in communicative connection with the heat storage unit (24) and the thermal energy of the heat storage medium is transferred to the second carrier medium of the further thermal load circuit (30) as needed, wherein the further thermal load circuit is coupled to a steam generating unit which has a steam turbine (46). Additionally, a solar collector device (86) is present, which can be activated and which is coupled to the steam generating unit (42).

Description

 DESCRIPTION

Combined heat and power plant

TECHNICAL AREA

The present invention relates to a combined heat and power plant with a photovoltaic system with flat photovoltaic elements that generate electrical energy from the top side, which is fed into a power grid and / or a power storage unit is supplied, wherein the cooling coil, the resulting process heat during operation of the photovoltaic element first heat pump feeds, the first heat pump is in communication with a first carrier medium circuit having a first carrier medium, in the first carrier medium circuit, a heat storage unit with a

Heat storage medium is arranged, wherein the heat energy of the first support medium is transferred to the heat storage medium within the heat storage unit, and at least one further heat consumer circuit with a second support medium with the heat storage unit in

Communication connection is and the heat energy of the heat storage medium is transmitted as needed to the second carrier medium of the further heat consumer circuit.

STATE OF THE ART

It is known to convert solar energy into electrical energy

Use photovoltaic systems. The planar photovoltaic elements of such photovoltaic systems are mounted, for example, on sun-oriented roof surfaces of buildings. To the photovoltaic elements are

Inverters connected, which allow that through the

Photovoltaic element generated electrical energy can be fed into a power grid. When operating photovoltaic elements, a considerable process heat is created. Since the inverters can only operate up to a certain maximum temperature (for example 65 °), they are switched off when the maximum temperature is exceeded in order to protect them from damage. This suffers the efficiency of the entire system.

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CONFIRMATION COPY PRESENTATION OF THE INVENTION

Based on the cited prior art is the present

Invention, the technical problem or task to improve the efficiency of a combined heat and power plant with a photovoltaic system of the type mentioned.

The combined heat and power plant according to the invention is given by the features of independent claim 1. Advantageous embodiments and

Further developments are specified in the dependent directly from the independent claim 1 or claims.

The combined heat and power plant according to the invention is accordingly characterized in that the further heat consumer circuit is connected to a steam generating unit, which communicates with a steam cycle, wherein within the steam cycle, a steam turbine is arranged, the steam turbine drives a generator for generating electricity or the steam turbine a nitrogen liquefaction unit, which liquefies the nitrogen of the ambient air, and a nitrogen storage unit is present, in which the generated liquid nitrogen is removably stored, the steam turbine is switchable, so that it with the steam of the steam cycle or with nitrogen taken from the nitrogen storage unit, the over an evaporator is guided, is driven, a collector device with a collector profile and collector mirror is present, which via a second carrier medium circuit to a fourth heat exchanger is closed and the fourth heat exchanger via a second heat consumer circuit is connected to the steam generating unit, wherein a control unit is present, which switches on or off the second heat consumer circuit.

The basic idea of the present invention is to dissipate the process heat arising during operation of the photovoltaic elements and to use it energetically. On the one hand, this has the effect of improving the efficiency of the power generation of the photovoltaic elements, since the shutdown of the inverters as a result of exceeding the maximum operating temperature can be largely prevented. Furthermore, this withdrawn process heat is a

Heat storage unit supplied, which in turn then the stored heat 'if necessary, different consumer circuits, including a steam generating unit, supplies. To increase the efficiency is also an switchable solar collector device available, the energy production is also supplied to the steam generating unit.

The first heat pump serves to ensure that in the heat storage unit

Temperature of 60 ° to 70 ° C (Celsius) is reached.

To increase the efficiency, it is possible according to an advantageous embodiment to arrange an insulating layer below the cooling register.

The thermal energy transfer from the first carrier medium to the storage medium is preferably carried out by means of a first heat exchanger. Likewise, the thermal energy transfer from the storage medium to the further heat consumer circuits within the heat accumulator can take place in each case by a further second heat exchanger.

To control the temperature conditions in the first carrier medium circuit, it is particularly advantageous to use a first circulating pump, which preferably from within the first carrier medium circuit and at the

Heat storage unit existing thermostat is acted upon or switched. The power of the circulation pump can be set variably in an advantageous manner.

As a further heat consumer circuit, for example, a circuit for a space heating or a hot water treatment comes into question.

Furthermore, the further heat consumer circuit can be supplied to a heat pump, wherein according to a particularly advantageous embodiment, a steam generating unit is connected to the heat pump, which communicates with a steam circuit, and in the steam cycle a steam turbine is arranged, which is acted upon by the generated steam.

The steam turbine may be connected, for example, to a generator for generating electricity.

In an alternative advantageous embodiment, the steam turbine drives a Stickstoffverflüssigungsaggregat, which is the nitrogen of the ambient air liquefied, wherein a nitrogen storage unit is present, in which the generated liquid nitrogen is removably stored.

A particularly preferred embodiment of the system according to the invention is characterized in that the steam turbine can be switched so that it with the steam of the steam cycle or with from the nitrogen storage unit

extracted nitrogen, which is passed through an evaporator, is driven. With this configuration, it is possible that the steam turbine at night or when no heat is removed elsewhere is driven by the nitrogen previously generated and can be fed via the generator power into the grid without process heat is needed by the photovoltaic elements or that this process heat not available.

The collector profile is preferably designed as a tube device.

In an advantageous manner, a second heat accumulator is connected to the fourth heat exchanger unit.

Further embodiments and advantages of the invention will become apparent from the features further listed in the claims as well as by the embodiments given below. The features of the claims may be combined in any manner as far as they are not obviously mutually exclusive.

BRIEF DESCRIPTION OF THE DRAWING

The invention as well as advantageous embodiments and developments thereof are described below with reference to the drawing

Examples are described and explained in more detail. The description and the

Drawing to be taken features can be applied individually according to the invention or to several in any combination according to the invention. Show it:

1 is a highly schematic representation of a combined heat and power plant with a photovoltaic system with a first carrier medium circuit to which the process heat of the photovoltaic system is supplied, and stores this process heat within a storage unit, wherein the storage unit is connected at least one further heat consumer circuit and a solar collector device and

1, wherein before the first carrier medium circuit, a first heat pump is connected and a total of three more heat consumer circuits for space heating, a heat pump and a hot water treatment are connected, wherein the Heat pump and the solar collector device are connected to a steam generating unit whose steam is fed to a steam turbine.

WAYS FOR CARRYING OUT THE INVENTION

In Fig. 1, a cogeneration plant 100 with a photovoltaic system 10 is shown with a photovoltaic element 12 shown by way of example, which is acted upon by the sun's rays S on the upper side. The

Photovoltaic element 12 is in line with an inverter 16 in

A compound which feeds the electrical energy generated by the photovoltaic element 12 in a power supply 14 shown symbolically in Fig. 1.

On the underside of the photovoltaic element 12, a cooling register 20 is arranged, which communicates via a heat pump circuit 34 with a first heat pump 36 in communication. The first, in Fig. 1 highly schematic illustrated heat pump 36 is further involved in a first carrier medium circuit 22 with a flow VI and a return Rl, wherein the first carrier medium circuit 22 partially within a with a

Heat storage medium filled heat storage unit 24 is guided. The first heat pump 36 serves to achieve a temperature of about 60 ° to 70 ° C (Celsius) in the heat storage unit 24.

Within the heat storage unit 24, the first carrier medium circuit 22 has a first heat exchanger 28.

To the heat storage unit 24 is shown in Fig. 1 schematically another

Heat consumer circuit 30 connected to its flow V2 and its return R2, wherein the further heat consumer circuit 30 within the heat storage unit 24 has a second heat exchanger 32. The further heat consumer circuit 30 is - optionally via a heat pump - connected to a steam generating unit 52, which has a

Steam circuit 44 with flow V4 and return R4 is connected to a steam turbine 46, by means of which a generator 48 is operable.

Furthermore, a solar collector device 86 is connected to the steam generating unit via a third heat exchanger 90, which will be described below with reference to FIG. 2.

When operating the combined heat and power plant 100, this works as follows. The process heat standing in the photovoltaic element 12 is transferred by the cooling register 20 to the first carrier medium of the first carrier medium circuit 22. About the first heat exchanger 28, the heat energy of the first

Carrier medium within the heat storage unit 24 on the

Transfer thermal storage medium.

By means of the second heat exchanger 32, if necessary, the heat energy of the heat storage medium of the heat storage unit 24 to the second

Carrier medium of the other consumer cycle 30 transmitted.

By such a system, on the one hand, process heat of the photovoltaic element 12 is used and at the same time the photovoltaic element 12 is cooled, so that a failure or switching off of the inverter 16 due to high temperature can be largely avoided.

2, the combined heat and power plant with a photovoltaic plant according to FIG. 1 is shown in greater detail, wherein a total of three further heat consumer circuits 30.1, 30.2, 30.3 are present, the respective second heat exchangers 32.1 corresponding within the heat storage unit 24 , 32.2, 32.3. The same components bear the same reference numerals and will not be explained again.

In the flow VI of the first carrier medium circuit 22 a variable in their performance circulating pump 18 is connected with downstream check valve 54. Furthermore, a thermostat 56 is provided, which measures the temperature in the flow VI, the return Rl of the first carrier medium circuit 22 and the temperature of the storage medium within the heat storage unit 24, and in Dependence of the measured temperature adjusts the performance of the circulation pump 18. The thermostat 56 also monitors the maximum allowable temperature.

In the return Rl of the first carrier medium circuit 22 is still a

Expansion tank 28 connected with upstream pressure relief valve 60.

In the upper right area in the interior of the heat storage unit 24 is a first second heat exchanger 32.1 of a first further heat consumer circuit

30.1 available, which is used for example for a space heating.

Below this, a second second heat exchanger 32.2 of a second further heat consumer circuit 30.2 (refrigerant circuit) is arranged, which belongs to a heat pump 40.

Including finally a third second heat exchanger 32.3 is present, which leads to a third additional heat consumer circuit 30.3, which is used for example for a hot water treatment. The headers and returns of the three other heat consumer circuits are indicated by V21, V22, V23 and R21, R22 and R23, respectively. To the heat storage unit 24, a further expansion tank 72 is connected.

The flow V22 of the second further heat consumer circuit 30.2 is supplied to a compressor 62 within the heat pump 40, wherein between the input and output of the compressor 62, a bypass valve 64 is connected. In the further course of the second heat consumer 30.2 this is fed to a steam generating unit 42, wherein the temperature of the second

Carrier medium (refrigerant) of the second heat consumer circuit 30.2 via a third heat exchanger 66 to the vapor pressure medium of

Steam generation unit 42 is transferred. To the steam generation unit is a steam cycle 44 with a flow V4 and a return R4

connected. Via the return R2, the second carrier medium of the further second heat consumer circuit 30.2 is fed back to the heat exchanger 32.2. In the return R22 of the second additional heat consumer cycle

30.2, an expansion valve is arranged.

The flow V4 of the steam cycle 44 is passed to a steam turbine 46 and then the resulting condensate is passed to a condensate reservoir 68. A pump 70 in the return R4 of the steam cycle 44 returns the condensate to the steam generating unit 42.

The steam turbine 46 drives a generator 48, which feeds the generated electrical energy into a network.

Alternatively (dashed line in FIG. 2) or in addition, the

Steam turbine 46 drive a nitrogen liquefaction unit 50, which extracts nitrogen from the ambient air and liquefies. Subsequently, the liquid nitrogen is removably stored on a nitrogen storage unit 52. The liquid nitrogen can be used for example for driving nitrogen engines, such nitrogen engines are very environmentally friendly, since no polluting gases.

The steam turbine 46 is adapted to be selectively operated with the steam of the steam cycle 44 or with nitrogen. For this purpose, the steam turbine 46 is formed switchable with respect to the choice of the operating medium. In FIG. 2, the steam turbine 46 is connected to the nitrogen storage unit 52 via an evaporator 76. Control components that the

Control switching process are not shown in Fig. 2. By the switchable steam turbine 46, it is possible that at night, that is, when no activity of the photovoltaic elements 12, or if no heat is removed elsewhere via the generator 48 electricity is generated, which is fed into the network.

The illustrated embodiment shows three examples of the

Heat storage unit 24 connectable additional consumer circuits 30.1, 30.2, 30.3. Other heat consumer circuits can be easily arranged for other purposes.

2, a solar collector device 86 with a collector mirror 88 and a collector hollow profile 87 is shown above the steam generation unit 42, which is connected to a fourth heat exchanger 90 via a second carrier medium circuit 92 with feed V2 and return R3. In the second carrier medium circuit 92, a second pump 78 is arranged. The fourth heat exchanger 90 is connected via a second heat consumer 94 with a flow V5 and a return R5 with the steam generating unit 42 in communication. Via a control unit 84, the second heat consumer circuit 94 of the steam generating unit 42 can be switched on or off. Furthermore, a second heat accumulator 82 is connected to the fourth heat exchanger 90 via a circuit with third pump 80, in which heat energy can be stored as needed and retrieved. The connection of the SonnenkoUektoreinrichtung 86 to the steam generating unit 42 improves the efficiency of the entire combined heat and power plant 100. Both the second pump 78 and the third pump 80 are temperature controlled. Overall, therefore, there is a photovoltaic system with combined heat and power, which has a high efficiency and by means of which in a simple manner can be produced practically close to without environmental pollution large amounts of electricity.

The illustrated combined heat and power plant 100 shows against the

known photovoltaic systems significantly improved efficiency. In addition to the longer possible service life of the photovoltaic system as such (the

Exceeding of the maximum temperature for the failure of the inverter is prevented), the resulting process heat is used for further heat consumer circuits. The use of an additional solar control device additionally increases the efficiency of the system.

Claims

claims

Combined heat and power plant (100) with a photovoltaic system (10) with flat photovoltaic elements (12), the upper side

Solar radiation (S) generate electrical energy, which is fed into a power grid (14) and / or a power storage unit is supplied, wherein

 in each case a cooling register (20) is arranged below the photovoltaic elements (12) and is in communication communication with a first heat pump (36) via a heat pump circuit (34), wherein the cooling register (20) controls the operation of the photovoltaic element (12)

supplies the resulting process heat to the first heat pump (36),

 the first heat pump (36) is in communication communication with a first carrier medium circuit (22) with a first carrier medium,

 - In the first carrier medium circuit (22) a heat storage unit (24) is arranged with a heat storage medium, wherein the

Heat energy of the first support medium within the heat storage unit (24) is transferred to the heat storage medium, and

- At least one further heat consumer circuit (30) with a second carrier medium with the heat storage unit (24) in

Kommunikätions connection stands and the heat energy of the

Heat storage medium is transmitted as needed to the second carrier medium of the further heat consumer circuit (30),

 - characterized in that the following features are present in combination:

 - The further heat consumer circuit (30) to a steam generating unit (42) is connected, which is in communication with a steam circuit (44), wherein within the steam cycle (44) a steam turbine (46) is arranged,

- The steam turbine (46) drives a generator (48) for generating electricity or the steam turbine (46) drives a Stickstoffverflüssigungsaggregat (50), which liquefies the nitrogen of the ambient air, and a nitrogen storage unit (52) is present, in which the generated liquid Nitrogen is stored removably,

 - The steam turbine (46) is switchable so that it is with the steam of the steam cycle (44) or with nitrogen from the nitrogen storage unit (52) removed nitrogen, which is passed through an evaporator (76) driven,

 - A collector means (86) having a collector profile (87) and collector mirror (88) is present, which is connected via a second carrier medium circuit (92) to a fourth heat exchanger (90) and the fourth heat exchanger (90) via a second heat consumer circuit (94 ) is connected to the steamer generating unit (42), wherein a control unit (84) is present, which switches on or off the second heat consumer circuit (94).

Cogeneration plant according to claim 1,

 - characterized in that

 - Below the cooling register (20) an insulating layer (26) is arranged.

Combined heat and power plant according to claim 1 or 2,

 - characterized in that

 - The first carrier medium circuit (22) within the

Heat storage unit (24) has a first heat exchanger (28).

Combined heat and power plant according to one or more of

previous claims,

 - characterized in that

 - The further heat consumer circuit (30) within the

Heat storage unit (24) has a second heat exchanger (32).

Cogeneration plant according to claim 1,

 - characterized in that

- Within the first carrier circuit (22), a first circulating pump (18) is present.

06. combined heat and power plant according to one or more of

 previous claims,

 - characterized in that

 - The further heat consumer circuit (30.1) within a

 Space heating is used.

07. combined heat and power plant after one or more of

 previous claims,

 - characterized in that

 - The further heat consumer circuit (30.3) within a

 Hot water treatment plant is used.

08. combined heat and power plant according to one or more of

 previous claims,

 - characterized in that

 - The further heat consumer circuit (30.2) via a heat pump (40) to the steam generating unit (42) is connected.

09. combined heat and power plant according to one or more of the preceding claims,

 - characterized in that

 - The collector profile (87) is designed as a tube device.

10. combined heat and power plant according to one or more of the preceding claims,

 - characterized in that

 - To the fourth heat exchanger (90), a second heat storage (82) is connected.