KR101423647B1 - Dissipating Heat Collection System of Steam Turbin Generator Room - Google Patents

Abstract

In particular, the present invention relates to a heat recovery and recovery system for a steam turbine power generation room, and more particularly, to a heat recovery and recovery system for a steam turbine power generation room, which includes a boiler for generating high temperature steam, a steam turbine for receiving high- An absorption type heat pump connected to a pipe connecting the steam turbine and the heat exchanger, and an indoor heat exchanger connected to the absorption heat pump by a pipe to be installed in the steam turbine power generation room, ≪ / RTI > The indoor unit of the air conditioner receives low-temperature water from the absorption type heat pump and discharges low-temperature air into the steam turbine power generation room, exchanges heat with high temperature air in the steam turbine power generation room, Pump; The absorption heat pump is adapted to supply a portion of high temperature steam supplied from the steam turbine to the heat exchanger and supply the steam to the indoor unit of the air conditioner from the high temperature steam supplied from the high temperature steam to the indoor unit of the air conditioner. The heat generated when the temperature of the steam turbine is converted into low-temperature water is used to heat the water whose temperature has dropped through the district heating to supply the heat to the heat exchanger. .

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a steam turbine generator room,

The present invention relates to a heat recovery and recovery system of a steam turbine power generation room, and more particularly, to a steam turbine power generation system capable of reducing the driving power by preheating low temperature water recovered after district heating using heat generated in a steam turbine power generation room, And a heat recovery and recovery system of the power generation room.

Generally, the steam turbine power generation room maintains a high temperature regardless of the summer and the winter due to the heat generated by various machinery and computer rooms.

If the high temperature condition continues, the life of the equipment installed in the machinery and the computer room is shortened and malfunction occurs. Therefore, the air conditioner unit including the indoor unit and the outdoor unit is separately installed to lower the temperature of the steam turbine power generation room. This results in the disposal of the hot heat of the steam turbine power generation room as it is, and the additional power for operating the air conditioning system is consumed, resulting in a total cost and power consumption.

SUMMARY OF THE INVENTION The present invention has been conceived to solve the problems of the prior art described above, and it is an object of the present invention to provide a steam turbine power generation system in which a low temperature water recovered after district heating is preheated using heat generated in a steam turbine power generation room, And to provide a heat recovery and recovery system of a steam turbine power generation room capable of reducing the number of steam turbines.

It is another object of the present invention to provide a heat recovery and recovery system of a steam turbine power generation room that can convert hot air in a steam turbine power generation room to a low temperature to prolong the life of mechanical equipment installed in the steam power generation room.

According to an aspect of the present invention, there is provided a heat recovery / recovery system for a steam turbine power generation room, including a boiler for generating high temperature steam, a steam turbine for receiving high temperature steam from the boiler, An absorption type heat pump connected to the piping connecting the steam turbine and the heat exchanger, and an absorption heat pump connected to the absorption heat pump and connected to the steam turbine power generation room, An indoor unit of the air conditioner; The indoor unit of the air conditioner receives low-temperature water from the absorption type heat pump and discharges low-temperature air into the steam turbine power generation room, exchanges heat with high temperature air in the steam turbine power generation room, Pump; The absorption heat pump is adapted to supply a portion of high temperature steam supplied from the steam turbine to the heat exchanger and supply the steam to the indoor unit of the air conditioner from the high temperature steam supplied from the high temperature steam to the indoor unit of the air conditioner. The heat generated when the temperature is converted into low-temperature water is supplied to the heat exchanger by heating the water whose temperature has dropped through the district heating system.

Here, the absorption type heat pump includes: an evaporator that supplies low-temperature water to the indoor unit of the air conditioner and is supplied with water having a high temperature; An absorber for receiving water whose temperature has dropped through the district heating facility; A regenerator for receiving a portion of the high-temperature steam supplied from the steam turbine to the heat exchanger; A heat amount corresponding to a temperature difference between the water having a high temperature supplied from the indoor unit of the air conditioner and the low temperature water supplied to the indoor unit of the air conditioner in the evaporator and the water heated by the high temperature steam supplied to the regenerator are supplied to the heat exchanger And a second heat exchanger by condensation.

The heat recovery and recovery system of the steam turbine power generation room of the present invention configured as described above cools the high temperature air of the steam turbine power generation room by the indoor unit of the air conditioner and simultaneously generates heat and hot steam, After the heating, the recovered water is heated and sent to the heat exchanger, so that the consumption power can be reduced.

In addition, since the temperature inside the steam turbine generator room is lowered by the indoor unit of the air conditioner, there is no need to provide a separate air conditioner composed of an outdoor unit and an indoor unit in order to lower the temperature inside the steam turbine generator room. There is an advantage.

In addition, since the hot air inside the steam turbine power generation room falls to low temperature by heat exchange, there is an advantage that the life of the mechanical equipment inside the steam turbine power generation room is prolonged.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a heat recovery and recovery system of a steam turbine power generation room according to the present invention;
BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an absorption type heat pump for a steam turbine generator room.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of a heat recovery and collection system of a steam turbine power generation room according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic view of a heat recovery and recovery system of a steam turbine generator room according to the present invention, and FIG. 2 is a schematic view of an absorption heat pump constituting a heat recovery and recovery system of a steam turbine generator room according to the present invention.

The heat recovery and recovery system of the steam turbine power generation room according to the present invention is for recovering the amount of heat radiated from various mechanical equipment installed in the steam turbine power generation room and supplying the heat to the district heating, A heat exchanger 30 connected to the steam turbine 20 by piping and an absorption type heat pump 40 connected to the heat exchanger 30 by piping, And an indoor unit 50 of the air conditioner connected to the absorption type heat pump 40 by piping.

The boiler 10 generates high-temperature steam, and is installed in a steam turbine generator room for district heating to generate high-temperature steam of about 500 ° C. by heating water.

The steam turbine 20 is supplied with steam at a temperature of 500 ° C. generated by the boiler 10 through a pipe. When the steam having a temperature of 500 ° C. passes through the steam turbine 20, It is lowered to about 130 ° C, but it still maintains a high temperature.

The heat exchanger 30 receives hot water of up to 130 ° C. from the steam turbine 20 and supplies the water to the district heating system 60 for heating.

The absorption type heat pump 40 is connected to a pipe connecting the steam turbine 20 and the heat exchanger 30 and separates a portion of the high temperature steam supplied from the steam turbine 20 to the heat exchanger 30, . More specifically, the absorption heat pump 40 converts the high-temperature steam of about 130 ° C., which is supplied from the steam turbine 20 to the heat exchanger 30, into a part of the steam from the steam turbine 20 %).

The indoor unit (50) of the air conditioner is connected to the absorption heat pump (40) by piping and installed inside the steam turbine power generation room. The air conditioner is generally installed in the outdoor and indoor units with a set of outdoor units and indoor units, respectively. In the present invention, only the indoor unit 50 of the air conditioner is installed without installing the outdoor unit.

The indoor unit (50) of the air conditioner is supplied with low temperature water from the absorption type heat pump (40). The indoor unit 50 of the air conditioner, which receives the low-temperature water, discharges low-temperature air into the steam turbine power generation room, exchanges heat with hot air inside the steam turbine power generation room, . That is, the inside of the steam turbine power generation room is filled with high-temperature air of 40 ° C or more due to the heat radiated by various mechanical equipments. The high temperature air in the steam turbine power generation room and the low temperature water (About 7 ° C) is heat-exchanged and the indoor unit 50 of the air conditioner supplies the hot water (about 14 ° C) to the absorption type heat pump 40. The indoor unit 50 of the air conditioner is cooled And the inside of the steam turbine generator room is cooled by discharging the wind.

Here, the absorption type heat pump 40 will be described in more detail.

The absorption type heat pump 40 supplies water (about 7 ° C) of low temperature to the indoor unit 50 of the air conditioner and then heat-exchanges the indoor heat from the indoor unit 50 of the air conditioner, (About 14 degrees Celsius), which is generated when the inside of the absorption type heat pump 40 is converted from water having a high temperature (water having a temperature of about 14 degrees Celsius) to water having a low temperature (water having a temperature of about 7 degrees Celsius) The absorption heat pump 40 is heated to a temperature lowered through the district heating system 60 by using steam and some high temperature steam 130 ° C. added from the steam supplied from the steam and heat exchanger 30 to the steam turbine 20, And supplies the heated water to the heat exchanger (30).

That is, the high-temperature steam of 130 ° C supplied to the heat exchanger 30 is heat-exchanged with water in the heat exchanger 30, and high-temperature water of about 115 ° C is supplied to the district heating system 60 The hot water is used for heating while passing through the district heating system 60, and as a result, the temperature is lowered to about 55 ° C and supplied to the absorption heat pump 40.

The low temperature (about 55 deg. C) water supplied to the absorption heat pump 40 is converted from the additionally high temperature steam and the high temperature water (about 14 deg. C water) to the low temperature water (about 7 deg. The temperature is raised to about 75 DEG C through the process of heating by the generated heat, and then is supplied to the heat exchanger 30 again.

The supply of the water (about 75 캜 water) heated by the absorption type heat pump 40 to the heat exchanger 30 is carried out without passing the absorption type heat pump 40 through the low temperature water It is possible to improve the power efficiency because the amount of the driving power for operating the heat radiation recovery system is less than that for supplying the heat to the heat exchanger 30. [

The absorption heat pump 40 of the present invention which realizes the above effect is distinguished by an evaporator 41, an absorber 42, a regenerator 43 and a second heat exchanger 44 by condensation. Since the absorbing heat pump 40 of the present invention is the same as the function of the general absorbing heat pump 40, description of each of those functions is omitted here, and only the incoming steam or water is associated with the discharged water Brief explanation will be given.

The evaporator 41 supplies low-temperature water to the indoor unit 50 of the air conditioner, while the indoor unit 50 of the air conditioner discharges low-temperature air, exchanges heat with the hot air of the steam turbine generating room, Is supplied with increased water. That is, water at about 7 ° C is supplied to the indoor unit 50 of the air conditioner, and the supplied water is heat-exchanged with the hot air to be supplied with water heated to 14 ° C.

The absorber 42 is supplied with water (about 55 ° C water) whose temperature has dropped through the district heating system 60.

The regenerator 43 is supplied with a part of high temperature steam (steam at about 130 ° C.) supplied from the steam turbine 20 to the heat exchanger 30.

The second heat exchanger 44 due to condensation corresponds to the temperature difference between the high temperature water supplied from the indoor unit 50 of the air conditioner and the low temperature water supplied to the indoor unit 50 of the air conditioner in the evaporator 41 And the water heated by the high temperature steam supplied to the regenerator 43 is supplied to the heat exchanger 30. That is, the heat of 14 ° C flowing into the evaporator 41, the heat corresponding to the temperature difference of 7 ° C water supplied to the indoor unit 50 of the air conditioner, and the 55 ° C flowing into the absorber 42 ° C., and as a result, the water heated to 75 ° C. is supplied to the heat exchanger (30).

10: boiler 20: steam turbine
30: heat exchanger 40: absorption heat pump
41: evaporator 42: absorber
43: regenerator 44: second heat exchanger by condensation
50: indoor unit 60: district heating

Claims (2)

A steam turbine 20 supplied with high temperature steam from the boiler 10 and a steam generator 40 for supplying high temperature steam from the steam turbine 20 to the district heating 60, An absorption type heat pump 40 connected to a pipe connecting the steam turbine 20 and the heat exchanger 30 and an absorption type heat pump 40 connected to the absorption type heat pump 40, And an indoor unit 50 of the air conditioner installed inside the steam turbine power generation room,
The indoor unit 50 of the air conditioner receives low-temperature water from the absorption type heat pump 40, discharges low-temperature air into the steam turbine generator room, exchanges heat with hot air inside the steam turbine generator room, The increased water is supplied to the absorption type heat pump 40,
The absorption type heat pump 40 is adapted to supply a portion of high temperature steam supplied from the steam turbine 20 to the heat exchanger 30 and supply the steam to the indoor unit 50 of the air conditioner. The water cooled down through the district heating system 60 is heated by the heat generated when the water is converted into low-temperature water to be supplied from the high-temperature water to the indoor unit 50 of the air conditioner, And the heat recovery and recovery system of the steam turbine power generation room.
The method according to claim 1,
The absorption type heat pump (40) includes an evaporator (41) for supplying low temperature water to the indoor unit (50) of the air conditioner and for receiving water having a high temperature by heat exchange;
An absorber 42 for receiving water whose temperature has dropped through the district heating system 60;
A regenerator 43 for adding a portion of high temperature steam supplied from the steam turbine 20 to the heat exchanger 30;
The amount of heat corresponding to the difference between the temperature of the water supplied from the indoor unit 50 of the air conditioner and the temperature of the low temperature water supplied to the indoor unit 50 of the air conditioner from the evaporator 41, And a second heat exchanger (44) by heating the water introduced into the absorber (42) by the received high temperature steam and then supplying the heated water to the heat exchanger (30) Heat recovery and recovery system of steam turbine generator room.

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