KR20170095516A - Determining protection of the absorption type Heat pump - Google Patents

Abstract

The present invention relates to crystallization prevention device of an absorption heat pump comprising an absorber, a condenser, an evaporator, and a regenerator. A solution heat exchanger is installed between the absorber and the regenerator to exchange heat of a high temperature solution supplied from the absorber with heat of a low temperature solution supplied from the regenerator. An auxiliary supply pipe may be provided in an absorption supply pipe installed between the absorber and the solution heat exchanger and in a regeneration supply pipe installed between the regenerator and the solution heat exchanger to supply the high temperature solution in the absorption supply pipe to the regeneration supply pipe. According to the present invention, since the auxiliary supply pipe is installed in the absorption supply pipe installed between the absorber and the solution heat exchanger and the regeneration supply pipe installed between the regenerator and the solution heat exchanger to supply the high temperature solution in the absorption supply pipe to the regeneration supply pipe, it is possible to prevent crystallization of the solution inside the solution heat exchanger. As a result, efficiency of the heat pump may be increased and costs may be reduced.

Description

[0001] The present invention relates to an absorption type heat pump,

[0001] The present invention relates to an apparatus for preventing crystallization of an absorption type heat pump, and more particularly, to an apparatus for preventing crystallization of an absorption type heat pump that prevents solution crystals from being formed in a solution heat exchanger installed between an absorber and a regenerator. .

Generally, the absorption type heat pump is used as a heat source such as heat of wastewater discharged into a sewer, heat of ground water, and heat of cooling water discharged when cooling, thereby increasing the temperature of hot water used for heating, hot water supply and industrial facilities.

That is, the absorption type heat pump can absorb the waste heat of the heat source medium and discard the heat source medium into the sewer, which is eco-friendly, and the refrigerant and the absorption liquid can be used semi-permanently.

The absorption type heat pump includes a regenerator for separating the refrigerant vapor by heating the diluent supplied from the absorber, a condenser for condensing and liquefying the refrigerant vapor transferred from the regenerator, and a refrigerant liquid delivered from the condenser, And an absorber for absorbing the refrigerant vapor transferred from the evaporator to the concentrated solution transferred from the regenerator.

Here, water is used as the refrigerant applied to the absorption type heat pump, and a lithium bromide solution having properties similar to salt is used as the absorption liquid.

However, the conventional absorption type heat pump has a problem that a solution crystal is formed inside the solution heat exchanger due to the concentration of the refrigerant, which is one of the important factors affecting the efficiency.

That is, the conventional absorption type heat pump can operate at an appropriate refrigerant operating condition to produce a desired efficiency and temperature, but the efficiency of the heat pump is deteriorated due to the solution crystals formed in the solution heat exchanger.

Korean Patent Publication No. 10-0666057 Korean Patent Publication No. 10-0750375

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-mentioned problems, and it is an object of the present invention to provide a method and apparatus for regenerating a high-temperature solution of the absorption supply pipe to a regeneration supply pipe provided between an absorber and a solution heat exchanger, And it is an object of the present invention to provide a supplementary absorption supply pipe for supplying a supply pipe to prevent solution crystals from being formed in the solution heat exchanger.

In order to achieve the above object, the apparatus for preventing crystallization of an absorption type heat pump according to the present invention comprises an absorber, a condenser, an evaporator, and a regenerator. Between the absorber and the regenerator, A solution heat exchanger for exchanging heat with the low-temperature solution is installed, an absorption supply pipe provided between the absorber and the solution heat exchanger, and a regeneration supply pipe provided between the regenerator and the solution heat exchanger, The auxiliary absorption supply pipe may be further provided.

A connection valve is connected to the connection pipe between the absorption pipe and the auxiliary absorption pipe, and a high-temperature solution and a low-temperature solution are supplied to the absorption pipe A check valve may be mounted to prevent entry.

Further, the auxiliary absorption supply pipe may be further equipped with a steam line consisting of a steam check valve and a steam pipe so as to supply external hot steam.

Here, a solenoid valve is mounted in place of the open / close valve, and the solenoid valve can be automatically controlled in accordance with a signal from the control section.

At this time, the controller may operate the solenoid valve through a flow rate sensor mounted on a solution transfer pipe provided between the solution heat exchanger and the absorber.

According to the present invention, in the regeneration supply piping provided between the absorber and the solution heat exchanger and between the regenerator and the solution heat exchanger, the high-temperature solution of the absorption supply piping can be supplied to the regeneration supply piping, So that the solution crystals can be prevented from being formed in the solution heat exchanger. In addition, the heat pump efficiency can be increased and the cost can be reduced.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a configuration diagram showing an apparatus for preventing crystallization of an absorption type heat pump according to the present invention; FIG.
2 is an enlarged view of a main part showing an apparatus for preventing the absorption of an absorption type heat pump according to the present invention.
3 and 4 are enlarged views showing another embodiment of the apparatus for preventing the absorption type heat pump according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

1 is a structural view showing an apparatus for preventing crystallization of an absorption type heat pump according to the present invention, and FIG. 2 is a cross-sectional view of the apparatus for preventing crystallization of an absorption type heat pump according to the present invention. And FIGS. 3 and 4 are enlarged views showing another embodiment of the apparatus for preventing the absorption type heat pump according to the present invention.

The apparatus 100 for preventing the absorption type heat pump of the present invention includes a regenerator 300 for heating and separating the solution supplied from the absorber 200 and a condenser 400 for condensing and liquefying the solution transferred from the regenerator 300, An evaporator 500 for evaporating the solution transferred from the condenser 400 and an absorber 200 for absorbing the solution transferred from the evaporator 500 into the solution transferred from the regenerator 300.

 The absorber 200, the regenerator 300, the condenser 400 and the evaporator 500 constituting the absorption prevention device 100 of the absorption type heat pump are not limited to those shown in the drawings and may be a known absorber, regenerator, condenser, An evaporator may be selected, and a detailed description thereof will be omitted.

The apparatus 100 for preventing the absorption type heat pump of the present invention is characterized in preventing solution crystals from being formed in the solution heat exchanger 600 mounted between the absorber 200 and the regenerator 300.

That is, the apparatus 100 for preventing absorption of heat of the absorption type heat pump may be configured such that a solution crystal is formed inside a solution heat exchanger 600 for exchanging heat between the high temperature solution supplied from the absorber 200 and the low temperature solution supplied from the regenerator 300 .

The absorption prevention system 100 of the absorption type heat pump includes an absorbing supply pipe 220 provided between the absorber 200 and the solution heat exchanger 600 and an absorption supply pipe 220 provided between the regenerator 300 and the solution heat exchanger 600 The auxiliary supply pipe 700 is further installed in the regeneration supply pipe 320 installed in the regeneration supply pipe 320 so that the high temperature solution of the absorption pipe 200 can be supplied to the regeneration supply pipe 320.

That is, the apparatus 100 for preventing absorption of heat of the absorption heat pump is configured to supply the hot solution supplied from the absorption supply pipe 200 to the regeneration supply pipe 320 located in the inflow portion of the solution heat exchanger 600 to the auxiliary absorption supply pipe 700, So that solution crystals can be prevented from being formed in the solution heat exchanger 600.

An opening / closing valve 720 is installed at a connection portion between the absorption supply pipe 220 and the auxiliary absorption supply pipe 700 so as to supply or block the hot solution to the auxiliary absorption supply pipe 700, The pipe 740 is equipped with a check valve 740 to prevent the hot and cold solution from flowing into the absorption supply pipe 220.

That is, the high-temperature solution supplied through the absorption supply pipe 220 is supplied only to the solution heat exchanger 600 when the on-off valve 720 is closed, and when the on-off valve 720 is opened, the solution heat exchanger 600 And is simultaneously supplied to the regeneration supply pipe 320 via the auxiliary absorption supply pipe 740.

The opening and closing valve 720 may be installed in the middle of the auxiliary absorption supply pipe 700 in addition to the connection portion between the absorption supply pipe 220 and the auxiliary absorption supply pipe 700.

Next, the apparatus 100 for preventing the absorption type heat pump can be constructed as shown in FIGS. 3 and 4.

3 shows an example in which the steam line 800 is installed so as to supply hot steam to the auxiliary absorption supply pipe 700. [

The steam line 800 includes a steam pipe 820 connected to the auxiliary absorption supply pipe 700 and a steam check valve 840 installed in the steam pipe 820.

That is, the apparatus 100 for preventing absorption of the absorption heat pump is capable of supplying the steam through the steam line 800 when providing heat for a short time or higher than the temperature of the hot solution supplied through the absorption supply pipe 220.

At this time, it is effective that the steam line 800 is disposed between the check valve 740 and the regeneration supply pipe 320.

4, a solenoid valve 940 is mounted in place of the on-off valve 720, and the solenoid valve 940 is connected to the signal of the control unit 920 And can be automatically controlled in accordance with the present invention.

That is, the apparatus 100 for preventing the absorption type heat pump can automatically control the solenoid valve 940 according to a signal from the controller 920.

The control unit 920 transmits an operation signal to the solenoid valve 940 through a flow rate sensor 960 mounted in the solution transfer pipe 340 provided between the solution heat exchanger 600 and the absorber 200 .

That is, the flow rate of the solution discharged from the solution heat exchanger 600 is sensed in real time through a flow rate sensor 960 mounted on the solution transfer pipe 340, and the flow rate sensor 960 is connected to the solution transfer pipe 340 The controller 920 controls the flow rate of the refrigerant to be transferred through the solution transfer pipe 340 until the amount of the refrigerant transferred through the solution transfer pipe 340 reaches the set value The solenoid valve 940 is opened and then the solenoid valve 940 is closed.

Hereinafter, an embodiment of the absorption prevention apparatus of the absorption type heat pump constructed as above will be described with reference to the drawings.

First, a regenerator 300 for heating and separating the solution supplied from the absorber 200, a condenser 400 for condensing and liquefying the solution conveyed from the regenerator 300, An absorber 200 for absorbing the solution conveyed from the evaporator 500 into a solution transferred from the regenerator 300 and an evaporator 500 installed between the absorber 200 and the regenerator 300 And a heat exchanger (600) for cooling the absorption heat pump (100).

The absorption supply pipe 220 provided between the absorber 200 and the solution heat exchanger 600 and the regeneration supply pipe 320 provided between the regenerator 300 and the solution heat exchanger 600 are connected to the absorption / The auxiliary absorption supply pipe 700 is further mounted so that the hot solution of the pipe 200 can be supplied to the regeneration supply pipe 320.

At this time, an opening / closing valve 720 is installed in the connection portion between the absorption / supply pipe 220 and the auxiliary absorption / supply pipe 700 so that the high temperature solution can be supplied or blocked to the auxiliary absorption / supply pipe 700, The pipe 740 is provided with a check valve 740 so as to prevent the hot solution and the low temperature solution from flowing into the absorption supply pipe 220.

Next, the use state of the apparatus for preventing the absorption type heat pump constructed as described above will be described.

First, the evaporator 500 heats and evaporates the solution using waste heat, and then supplies the solution to the absorber 200 through a pipe. The absorber 200 heats the solution supplied to the regenerator 300, And the high temperature solution is supplied to the regenerator 300 through the solution heat exchanger 600. [

The high temperature solution delivered to the regenerator 300 is sent to the condenser 400 and the low temperature solution is heat-exchanged with the high temperature solution through the solution heat exchanger 600 through the regeneration supply pipe and then supplied to the absorber 200 .

Next, the condenser 400 heats the heating water, hot water, etc., supplied through the pipe using the hot solution, and then supplies the condensed solution to the evaporator 500.

Here, the solution circulates in the absorber 200, the regenerator 300, the condenser 400, the evaporator 500, and the solution heat exchanger 600.

When crystals are formed in the solution heat exchanger 600 by the low temperature solution discharged through the solution heat exchanger 600, the opening / closing valve 720 of the auxiliary absorption supply pipe 700 is opened, The high temperature solution supplied through the regeneration delivery line 220 is supplied to the regeneration delivery line 240.

Next, the high-temperature solution supplied to the regeneration delivery pipe 240 is inserted into the solution heat exchanger 600 to dissolve the solution crystals formed therein, thereby forming solution crystals in the solution heat exchanger 600 And the refrigerant can be circulated uniformly. Therefore, the efficiency of the heat pump can be maintained uniformly.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And should be construed as being included in the scope of the invention.

100: a device for preventing the absorption of an absorption heat pump,
200: absorber,
300: regenerator, 400: condenser,
500: an evaporator, 600: a solution heat exchanger,
700: auxiliary absorption supply pipe, 720: opening / closing valve,
740: Check valve, 800: Steam line,
920: control unit, 940: solenoid valve,
960: Flow sensor.

Claims (5)

An absorption type heat pump comprising an absorber, a condenser, an evaporator, and a regenerator,
Between the absorber and the regenerator, a solution heat exchanger for exchanging heat between the high temperature solution supplied from the absorber and the low temperature solution supplied from the regenerator is mounted,
An auxiliary supply pipe is further provided in the regeneration supply pipe provided between the absorber and the solution heat exchanger and the regeneration supply pipe provided between the regenerator and the solution heat exchanger so as to supply the hot solution of the absorption supply pipe to the regeneration supply pipe Wherein the absorption of the heat of the absorption pump is controlled by the control unit.
The method according to claim 1,
And an opening / closing valve is installed in the connection portion between the absorption pipe and the auxiliary absorption pipe so that the high-temperature solution can be supplied to or blocked from the auxiliary pipe. The high-temperature solution and the low-temperature solution are introduced into the absorption pipe And a check valve is mounted so as to prevent the refrigerant from flowing out of the heat pump.
3. The method according to claim 1 or 2,
Wherein the auxiliary absorption supply pipe is further provided with a steam line including a steam check valve and a steam pipe so as to supply external high-temperature steam.
3. The method of claim 2,
Wherein a solenoid valve is mounted in place of the on-off valve, and the solenoid valve is automatically controlled according to a signal from the control unit.
5. The method of claim 4,
Wherein the control unit operates the solenoid valve through a flow rate sensor mounted on a solution transfer pipe provided between the solution heat exchanger and the absorber.

Images