KR20150095082A - A heat-pump system assembled expansion-tank and boiler-house - Google Patents

Abstract

Disclosed is an integrated heat pump system including a boiler house and an expansion tank. The system includes a heat storage tank storing a heated heat medium; a heat exchanger installed in the heat storage tank to supply hot water by exchanging heat of supplied cold water; a low water level sensor installed in an upper part of the heat storage tank; a safety valve installed in the upper part of the heat storage tank; a compressed gas discharge part discharging compressed gas by being installed in the upper part of the heat storage tank; a heat medium discharge line connected to the upper part of the storage tank to supply the heat medium to a place for heating; a heat medium returning line returning the heat medium of the place for heating to the heat storage tank; a circulation pump installed in the heat medium discharging line; a supplement line connecting a cold water inlet of the heat exchanger with the heat medium returning line; and a boiler house in which the heat storage tank is installed.

Description

[0001] The present invention relates to an integrated heat pump system having a boiler house and an expansion tank,

The present invention relates to a heat pump system in which an expansion tank is installed separately from an outside but installed in an expansion tank, and a booster house is integrally coupled.

Generally, a heat pump system stores heated heating medium (including hot water) in a heat storage tank, circulates the heating medium in the heat storage tank and uses it for heating, and can supply hot water through heat exchange in the heat storage tank.

An example of such a heat pump system is shown in FIG.

Referring to FIG. 1, a conventional heat pump system has a structure in which cold water is hot-watered in a heat storage tank 10 in which a heating medium heated from an external energy source (solar heat, geothermal heat, queues, heat generated by an electric heater, An expansion tank (supplementary tank 20) for receiving a heating medium overflowed by an over line 12 and accommodating the overflowing heating medium in order to supplement the deficient heating medium, Is installed. A so-called ball tower 21 is installed for selectively applying water according to the level of the expansion tank 20.

The outlet line 31 and the water return line 32 of the heating circulation line 30 are connected to the heat discharge tank 10 so that heating can be performed using the heating medium of the heat storage tank 10, A circulation pump 33 is installed to forcibly circulate the heating medium. The storage medium of the expansion tank 20 can be replenished to the storage tank 10 through the water return line 31 through the replenishment line 23 when the storage medium in the storage tank 10 is short.

According to the conventional heat pump system, since the expansion tank is installed outside the heat storage tank, heat loss is generated. Therefore, there is a problem of occurrence of a frozen wave such as an expansion tank, an over-line, and a supplementary line in winter, and there is a problem that a separate boiler room must be installed.

If a separate boiler room is installed as described above, a large installation space is required, a period required for installation work and piping work is increased, and the installation cost is increased.

Korean Patent Laid-Open No. 10-2012-0084955 (Hybrid Heating /

The present invention has been made in view of the above problems, and it is an object of the present invention to provide an improved boiler house and expansion tank capable of reducing heat loss and reducing installation space by integrating an expansion tank in a heat storage tank, And an object of the present invention is to provide an integrated heat pump system with built-in heat pump.

To achieve the above object, an integrated heat pump system incorporating a boiler house and an expansion tank according to the present invention includes a heat storage tank in which a heated heat medium is accommodated; A heat exchanger installed inside the heat storage tank to heat-exchange the cold water supplied and supply hot water to hot water; A low water level sensor installed on an upper portion of the heat storage tank; A safety valve provided on an upper portion of the heat storage tank; A compressed gas discharge unit installed at an upper portion of the heat storage tank to discharge compressed gas; A heating medium discharge line connected to an upper part of the heat storage tank to supply the heating medium to a place for heating; A heating medium return line for returning the heating medium at a location for heating to the heat storage tank; A circulation pump installed in the heating medium discharge line; A supplementary line connecting the cold water inlet of the heat exchanger and the heating medium return line; And a boiler housing for receiving and storing the heat storage tank.

Here, the boiler house may include a frame having a frame shape to support the outside of the heat storage tank; And a prefabricated panel provided outside the frame.

Further, it is preferable that the heating medium discharge line is connected to a position lower than the low water level sensed by the low water level sensor.

It is also preferable that the supplementary line is provided with a decompression side.

According to the integrated heat pump system incorporating the boiler house and the expansion tank of the present invention, the expansion tank can be integrated with the heat storage tank to reduce the installation space and shorten the installation period, thereby reducing the cost.

Further, by eliminating the installation of the external expansion tank, it is possible to solve the problem of winter wave freezing and to reduce the heat loss, thereby improving the overall thermal efficiency of the heat pump system.

In addition, by installing an integrated boiler house on the outside of the heat storage tank with frame and prefabricated panel, it is not necessary to install a separate boiler room, and it is easy to install and install.

1 is a schematic diagram showing a conventional heat pump system.
FIG. 2 is a block diagram showing an integrated heat pump system incorporating a boiler house and an expansion tank according to an embodiment of the present invention.
3 is a view showing an example of a boiler house.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an integrated heat pump system incorporating a boiler house and an expansion tank according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Referring to FIG. 2, an integrated heat pump system 100 incorporating a boiler house and an expansion tank according to an embodiment of the present invention includes an expansion tank built-in heat storage tank 110 and a heat storage tank 110 installed inside the heat storage tank 110 A low temperature sensor 130 installed at an upper portion of the heat storage tank 110, a safety valve 140, a compressed gas discharge portion 150, and a heating medium discharge portion 150. The heat exchanger 120, A discharge line 160 and a heating medium return line 170, a circulation pump 180 and a replenishment line 190.

In the heat storage tank 110, a certain amount of heating medium (hot water) is accommodated therein, and the accommodated heating medium is maintained in a heated state by an unillustrated energy source. As the energy source not shown, various energy sources such as solar heat, geothermal heat, expansion heat by a compressor, and heat generated by an electric heater using night electricity can be applied.

A certain amount of heat medium is accommodated in the heat storage tank 110 and a low water level sensor 130 is installed on the upper part of the heat storage tank 110 to prevent the capacity of the heat medium from being reduced below the set water level.

A safety valve 140 and a compressed gas discharging unit 150 are installed in the upper part of the heat storage tank 110 so that the pressure and the overflow in the storage tank 110 can be controlled in place of the conventional function of the expansion tank. do. The safety valve 140 may control the pressure of the heat storage tank 110 to maintain a safe pressure range.

The compressed gas discharging unit 150 installed in the upper part of the heat storage tank 110 serves to discharge the compressed gas generated in the heat storage tank 110 to the outside so as to secure the safety of the heat storage tank 110, It is possible to replace the function of an expansion tank provided separately.

The heat exchanger 120 may be installed in the heat storage tank 110 to discharge cold water introduced into the cold water inlet 121 by hot water supply and discharge it to the hot water outlet 122 to use hot water for hot water supply.

The heating medium outlet line 160 and the heating medium return line 170 are connected to the upper and lower portions of the heat storage tank 110 for circulating the heating medium to use in heating the predetermined space. The heating medium outlet line 160 is connected to the upper part of the heat storage tank 110 and is connected to a position lower than the low water level controlled by the low water level sensor 130 so that the heating medium of high temperature can be discharged for heating. A circulation pump 180 is installed in the heating medium outlet line 160 so that the heating medium can be circulated by forcibly pumping and the valves 161 and 163 can be installed upstream and downstream of the circulation pump 180.

In addition, a valve 171 is also provided in the heating medium return line 170 to control the return of the heating medium.

The supplemental line 190 connects the cold water inlet 121 of the heat exchanger 120 and the heating medium return line 170 so that the cold water flowing into the cold water inlet 121 flows through the heat medium return line 170, (110).

The supplementary line 190 is installed downstream of the valve 171 and the supplementary line 190 is provided with a pressure-reducing side 193 to control the pressure.

The heat pump system 100 having the above-described structure is constructed by integrating the functions of the conventional expansion tank in the heat storage tank, so that it is not necessary to provide an expansion tank on the outside.

Therefore, heat loss can be reduced, space and piping for installing a separate expansion tank are unnecessary, and installation space can be reduced as well as being installed in a narrow space.

In addition, since it is not necessary to provide an external expansion tank separately, the apparatus can be downsized and compact, and therefore, it can be manufactured integrally with the boiler house 200 as shown in FIG. That is, the boiler house 200 in which the heat storage tank 110 can be accommodated can be formed as a frame 210, and the outer side of the frame 210 can be finished with the assembled panel 220 to increase the waterproofing and thermal insulation rate , It is possible to replace the boiler room and install it in a necessary place without installing a separate boiler room. Therefore, it is possible to solve the problem of the winter wave and to install the boiler room separately, so that the installation period can be shortened and the cost can be reduced.

100 .. Heat pump system 110 .. Storage tank
120 .. Heat exchanger 130 .. Low water level sensor
140 .. Safety valve 150 .. Compressed gas discharge part
160 .. heating medium outlet line 170 .. heating medium return line
180 .. Circulation pump 190 .. Replacement line
200 .. Boiler House 210 .. Frame
220 .. Prefabricated panel

Claims (4)

A heat storage tank in which a heated heating medium is accommodated;
A heat exchanger installed inside the heat storage tank to heat-exchange the cold water supplied and supply hot water to hot water;
A low water level sensor installed on an upper portion of the heat storage tank;
A safety valve provided on an upper portion of the heat storage tank;
A compressed gas discharge unit installed at an upper portion of the heat storage tank to discharge compressed gas;
A heating medium discharge line connected to an upper part of the heat storage tank to supply the heating medium to a place for heating;
A heating medium return line for returning the heating medium at a location for heating to the heat storage tank;
A circulation pump installed in the heating medium discharge line;
A supplementary line connecting the cold water inlet of the heat exchanger and the heating medium return line; And
And a boiler housing for receiving and storing the heat storage tank. The integrated heat pump system incorporates a boiler house and an expansion tank. The method according to claim 1,
The boiler house,
A frame having a frame shape for supporting the outside of the heat storage tank;
And a prefabricated panel installed outside the frame. The integrated heat pump system incorporates a boiler house and an expansion tank. 3. The method of claim 2,
Wherein the heating medium discharge line is connected to a position lower than the low water level sensed by the low water level sensor. 4. The method according to any one of claims 1 to 3,
Wherein the supplementary line is provided with a decompression side, and the integrated heat pump system incorporates a boiler house and an expansion tank.

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