DE102011087227A1 - Block type thermal power station used in industrial field, has heat exchanger that is provided to transfer primary heat flow from housing of gas turbine to building heating system by primary side of heat exchanger - Google Patents

Abstract

The power station has a gas turbine (10) that is provided to generate electric current and feed into provider network (11). The gas turbine is provided with housing (12) to reduce sound emissions from gas turbine. A heat exchanger (13) is provided to transfer primary heat flow (14) from housing of gas turbine to building heating system (18) by a primary side (15) of heat exchanger. The heat exchanger is provided to transfer secondary heat flow (16) from housing of gas turbine to heating system by a secondary side (17) of heat exchanger.

Description

The gas turbines of a gas turbine power plant for the generation of electric power are usually provided on the basis of emission and safety regulations with enclosures that should reduce in particular the sound emission of the gas turbine. In the operation of the gas turbine fall into the enclosure large amounts of heat that must be dissipated to protect the gas turbine from damage due to overheating. It can generate heat outputs in the order of a few hundred kilowatts at high temperatures. The removal of heat is usually done via a suction in the environment. The heat is not used sensibly.

Summary of the invention

The invention therefore introduces a combined heat and power plant with a gas turbine, which is designed to generate electric power and to feed it into a supply network. The gas turbine has an enclosure, which is designed to reduce a noise emission of the gas turbine. According to the invention, a heat exchanger is provided, which is designed to transfer heat from a first mass flow, which flows from within the housing of the gas turbine through a primary side of the heat exchanger, to a second mass flow through a secondary side of the heat exchanger and to direct the second mass flow to a building heater ,

The invention makes it possible to use the heat generated during operation of the gas turbine in the housing of the gas turbine for the building heating of the location of the gas turbine power plant, whereby the building heating in turn acts as a cooling system for the gas turbine. As a result, the energy expenditure which is otherwise operated for the heating of the building can be omitted or at least greatly reduced. The use of the heat exchanger makes it possible to lower the temperature in the secondary circuit - that is, the second mass flow heated in the heat exchanger by the transfer of heat - to temperatures that are normal for the operation of a building heating system. Thus, the flow temperature in a hot water heating between 30 and 80 degrees Celsius and in a hot air heating between 25 and 40 degrees Celsius. In order to heat the second mass flow to a selected temperature within these intervals, a correspondingly larger second mass flow is used in relation to the first mass flow. A large amount of water or air on the secondary side of the heat exchanger is thus heated by a relatively lower, but heated to a higher temperature amount of a heat transfer medium on the primary side of the heat exchanger (first mass flow).

The first mass flow may be an air stream, but it is also conceivable to use a liquid heat transfer medium such as water or a suitable oil. Such oil has the advantage over water of a higher boiling point, whereby evaporation of the heat transfer medium is reduced or prevented. If the heat transport medium evaporates, this can lead to problems due to the associated increase in pressure. Also, only partial evaporation of the heat transfer medium can lead to difficulties in transporting the heat transfer medium through the heat exchanger.

The heat exchanger can be arranged for example within the enclosure of the gas turbine or else at the location of the building heating.

The second mass flow is preferably an air flow of a hot air heating. Alternatively, the second mass flow but also be a water flow of a hot water heater.

Preferably, the primary side of the heat exchanger is connected on the output side to an outlet in the atmosphere, in which case the first mass flow is an air flow. By the first mass flow is discharged into the atmosphere, a residual heat remaining in the first mass flow after passing through the heat exchanger is removed from the housing of the gas turbine.

A second aspect of the invention relates to the use of waste heat generated in a sound enclosure of a gas turbine for generating electric power for heating a building. In this case, according to the invention, a first mass flow is conducted from within the housing of the gas turbine through a primary side of a heat exchanger, thereby transferring heat to a second mass flow conducted through a secondary side of the heat exchanger. The second mass flow is directed to a building heating of the building.

The invention will be described in more detail below with reference to an illustration of an embodiment.

The figure shows an inventive combined heat and power plant, which is a gas turbine 10 which is configured to generate electrical power and into a utility network 11 feed. The gas turbine 10 has an enclosure 12 that produces a sound emission of the gas turbine 10 reduced. Inside the enclosure 12 falls during operation of the gas turbine 10 a large amount of heat that must be dissipated. This will be a first mass flow 14 from the enclosure 12 to a heat exchanger 13 directed, its primary side 15 the first mass flow 14 flows through. The first mass flow transfers 14 those in the enclosure 12 absorbed heat to a secondary side 17 of the heat exchanger 13 flowing through the second mass flow 16 which may be, for example, an air stream of hot air heating or a water flow of hot water heating. The thus cooled first mass flow 14 is in the illustrated embodiment via an outlet 19 released to the atmosphere. But it is also conceivable a closed circuit, in which the cooled first mass flow 14 back to the enclosure 12 the gas turbine 10 is directed.

This is particularly useful if for the first mass flow 14 a heat transfer medium other than air is used.

The thus heated second mass flow 16 becomes a building heating 18 fed to a building 20 heated. By heating the building 20 the second mass flow cools down 16 off, allowing it to recycle through the secondary side 17 of the heat exchanger 13 can be performed.

The invention allows the excess heat from the enclosure 12 the gas turbine 10 dissipate and the gas turbine 10 so to cool, according to the invention energetic resources for heating the building 20 be spared.

Although the invention has been described and described in detail by the preferred embodiment, the invention is not limited by the disclosed examples. Variations of the invention may be derived from the description by those skilled in the art without departing from the scope of the invention as defined by the claims.

Claims (6)

A combined heat and power plant with a gas turbine ( 10 ), which is designed to generate electrical power and into a supply network ( 11 ), wherein the gas turbine ( 10 ) over an enclosure ( 12 ), which is formed, a sound emission of the gas turbine ( 10 ), characterized by a heat exchanger ( 13 ), which is formed, heat from a first mass flow ( 14 ) from within the enclosure ( 12 ) of the gas turbine ( 10 ) through a primary page ( 15 ) of the heat exchanger ( 13 ) to a second mass flow ( 16 ) by a secondary side ( 17 ) of the heat exchanger ( 13 ) and the second mass flow ( 16 ) to a building heating ( 18 ). The combined heat and power plant of the preceding claim, wherein the first mass flow ( 14 ) is an airflow. The combined heat and power plant of any one of the preceding claims, wherein the second mass flow ( 16 ) is an air flow of a hot air heater. The combined heat and power plant of one of claims 1 or 2, wherein the second mass flow ( 16 ) is a water flow of a hot water heater. The combined heat and power plant of one of the preceding claims, wherein the primary side ( 15 ) of the heat exchanger ( 13 ) on the output side with an outlet ( 19 ) is connected to the atmosphere. Use of in a sound enclosure ( 12 ) a gas turbine ( 10 ) for the production of electric power accumulating waste heat for the heating of a building ( 20 ), wherein a first mass flow ( 14 ) from within the enclosure ( 12 ) of the gas turbine ( 10 ) through a primary page ( 15 ) of a heat exchanger ( 13 ) and thereby heat to a through a secondary side ( 17 ) of the heat exchanger ( 13 ) second mass flow ( 16 ) and the second mass flow ( 16 ) to a building heating ( 18 ) of the building ( 20 ).

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