KR20180024580A - Heat exchanger for individual household and installation method thereof - Google Patents

Abstract

The present invention relates to a heat exchange device installed for hot water supply or heating for each household of apartments or buildings, and more specifically, to a heat exchange device for simplifying the connection structure of various pipes connected to a heat exchange device to improve space utilization of a circumferential portion of a heat exchange device and convenience in pipe installation. The present invention comprises: the heat exchange device for generating hot water through heat exchange between the hot water supplied from a heat source producing means and feed water; a flow path plate mounted on the heat exchange device having a plurality of flow paths communicating with an inlet and an outlet of the heat exchange device through which the hot water and the feed water are introduced and discharged; and the plurality of pipes connected to an end portion of the flow path formed in the flow path plate.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a large-sized heat exchanger,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a heat exchanger installed for hot water supply or heating for each household or a building of a building. More specifically, the present invention can simplify the piping structure connected to the heat exchanger, The present invention relates to a large-sized heat exchanger device and a method of installing the same.

Generally, the heating system in each household is divided into centralized heating, district heating and individual heating.

Central heating, that is, centralized heating, is a heating method that supplies heat generated by a heat source such as a boiler to various places in a building. It is circulated through a radiator or pipe (heating piping) installed in the room by using hot water, A method of sending warm air to each room by using a pipe, and a method of generating indoor air by radiation and convection by sending steam to the radiator through a pipe.

The district heating system is a system that supplies high-pressure steam or high-pressure hot water to a large number of buildings scattered over a large area in a central heating machine room (for example, a cogeneration plant) at one or several places as a heat source for heating. The heating method is the same as normal heating, but each building does not have a boiler, so there is no need to set up a chimney for each, which reduces air pollution.

In addition, the individual heating is not a central heating that keeps the house warm, but a method of increasing the temperature by installing a heat source alone in each room or in a specific space (that is, an electric heater, a stove, The boiler is installed in each household, and the heating water and the hot water for controlling the temperature of each room can be supplied at the same time, so that it is easy to install and move, is easy to handle, and has an economical advantage .

In recent years, large-scale apartments and large-scale buildings have not only separate heating and individual hot water supply systems but also installed common heating facilities for the whole, and supply hot water for heating to each household or each floor through a common pipe network. The system is installed in a local and centralized manner in which heat is supplied to each household or each floor through a pipe network after heating the heated water supplied to the heating water to a necessary temperature through heat exchange with the water supply.

Here, the hot water heat exchanger for converting the feed water into the hot water having the proper temperature by heat exchange between the hot water for heating supplied from the heat source and the feed water is characterized in that a plurality of thin plates are combined in a laminated structure, And a flow path is formed between the water supply port and the water supply port.

In this heat exchanger, a pipe connected to the three-way valve is connected to the inlet side of the hot water for heating, and another pipe through which the heating water is circulated is connected to the outlet side of the heat exchanger after the hot water for heating is completely exchanged with the water. In addition, the heat exchanger is connected to the inlet side where the water is supplied, and the pipe is connected to the outlet side where hot water generated by the heating of the water is discharged

In the conventional heat exchanger having such a structure, since various pipes such as a water supply pipe, a hot water supply pipe, a heating water supply pipe and a water return pipe are connected to each other at different positions around the heat exchanger, There is a problem that the work is very cumbersome and takes a lot of time, resulting in poor workability due to piping installation.

In addition, since various pipes are installed at different positions on the periphery of the heat exchanger in a complicated structure, the connection structure of the pipes around the heat exchanger is very complicated and a lot of space is required to connect the heat exchanger and the pipes. Thus, there is a problem that the degree of freedom in the layout of the peripheral portion of the heat exchanger is greatly lowered.

Patent registration No. 10-1369768 (2014.02.26)

The present invention has been made in view of the above problems, and it is an object of the present invention to provide a heat exchanger which can simplify the structure of piping connected to the heat exchanger and improve the space utilization of the periphery of the heat exchanger, And a method of installing the three large heat exchanger devices.

According to an aspect of the present invention, there is provided a three-large-sized heat exchanger apparatus comprising: a heat exchanger for generating hot water through heat exchange between heated water supplied from a heat source producing means and a water supply; A flow path plate installed in the heat exchanger and having a plurality of flow paths communicating with the inlet and outlet ports of the heat exchanger through which the heating water and the feed water are introduced and discharged; And a plurality of pipes connected to ends of the flow paths formed in the flow path plate.

Here, the flow path plate may include: a first flow path plate having a first flow path groove forming one surface of the flow path; And a second flow path plate having a shape symmetrical with the first flow path groove and having a second flow path groove forming the other surface of the flow path, wherein the mutual joining of the first flow path plate and the second flow path plate ≪ / RTI >

In this case, the bonding operation between the first flow path plate and the second flow path plate may be performed through a brazing process.

The end portions of the respective flow paths may be arranged parallel to one side edge of the flow path plate.

At this time, the first and second flow paths may have a semicircular sectional shape or a polygonal shape.

The method for installing the three large-sized heat exchanger apparatus according to the present invention comprises the steps of: preparing a flow path plate having a plurality of flow paths for inflow and outflow of heating water and water; Joining the flow path plate to the heat exchanger such that the end portions of the flow paths located inside the flow path plate are in communication with the respective inlet and outlet ports formed in the heat exchanger; And connecting each pipe corresponding to the flow path to an end portion of each flow path located at an edge of the flow path plate.

(A) preparing a flow path plate having a plurality of flow paths for the inflow and outflow of heating water and water, and a heat exchanger assembly to be in contact with the flow path plate, the end portions of each flow path located inside the flow path plate, Assembling the flow path plate into the heat exchanger assembly to be in communication with each inlet and outlet port formed in the heat exchanger assembly; (b) bonding the flow path plate and the entire heat exchanger assembly; (c) connecting each pipe corresponding to the flow path to an end of each flow path located at an edge of the flow path plate.

Here, in the production of the flow path plate, a first flow path groove for forming one surface of the flow path is formed in the first flow path plate, a second flow path groove having a shape symmetrical to the first flow path groove is formed in the second plate , And the first flow path plate and the second flow path plate are bonded to each other.

At this time, the joining of the first flow path plate and the second flow path plate may be performed through a brazing process.

In addition, when the flow path plate and the heat exchanger are connected to each other, the end portions of the respective flow paths located inside the flow path plate can be bonded to each other through a brazing process in a state in which the end portions are in contact with the respective inlet and outlet ports formed in the heat exchanger .

According to the structure of the three large-sized heat exchanger of the present invention having the above-described configuration, the flow path plate having the plurality of flow paths communicating with the inlet and outlet portions of the heat exchanger is mounted to the heat exchanger, Since the installation work can be completed only by a simple operation of connecting the fitting pipes, it is possible to quickly and conveniently carry out the connection work of various pipes to the heat exchanger.

In addition, since a variety of piping connected to the periphery of the existing heat exchanger at various positions in a complex structure is replaced by a plurality of flow paths formed in one flow path plate, the piping configuration at the periphery of the heat exchanger can be simplified, There is an advantage that space utilization of the peripheral portion can be enhanced.

In addition, since it is possible to replace the function of various pipes installed in a complicated structure around the existing heat exchanger as one channel plate mounted on the heat exchanger, it is possible to reduce the cost due to the reduction of the number of piping, There is an advantage.

1 is a schematic diagram of a three-large-sized heat exchanger apparatus according to the present invention;
FIG. 2 is an external view of a three-large-sized heat exchanger device according to the present invention. FIG.
3 is a perspective view showing the structure of the flow path plate according to the present invention.
Figure 4 is a plan view of Figure 3;
5 is a sectional view of Fig. 3; Fig.
6 is a flowchart sequentially illustrating a method of installing three large-sized heat exchanger devices according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a three-large-sized heat exchanger device and a method of installing the same will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed.

Fig. 1 is a schematic diagram of a three-large-sized heat exchanger apparatus according to the present invention, and Fig. 2 shows a piping structure around three large-sized heat exchanger apparatuses.

Referring to FIGS. 1 and 2, the three large-sized heat exchanger apparatus according to the present invention includes a central heating system using oil and gas boilers, a district heating system using a heat source produced at a cogeneration plant or a waste incinerator, It can be used for heating and hot water supply systems. It supplies heat sources from various heat source production means and provides them to the use areas of each household. In addition, it elevates the water supply to the proper temperature by heat exchange function by heat exchanger, .

That is, as shown in FIG. 1, the three-large-sized heat exchanger apparatus according to the present invention is a system in which high-temperature district heating water supplied from various heat source producing means is heated in a machine room or a relay facility through a heat- The heating water is supplied to the required heating use place, that is, to the various heating loads 120 to perform the heating action, and when hot water supply is required, the heating water is supplied into the heat exchanger 110 through another heating water supply pipe 101 Water supplied from the outside through the water supply pipe 103 is converted into warm hot water having a proper temperature for use through a heat exchange action and supplied to each household through the hot water supply pipe 105. Then, the heating water whose temperature has been lowered after passing through the heating load 120 and the heat exchanger 110 is returned again through the respective heating water return pipes 106 and 107.

A temperature control valve 130 is installed in the heating water return pipe 107 connected to the outlet of the heat exchanger 110. The temperature control valve 130 senses the temperature of the hot water supply pipe 105, It operates so as to keep it at a preset hot water temperature.

A pressure differential control valve (PDCV) 140 is installed in the heating water return pipe 106 connected to the outlet of the heating load 120. The differential pressure control valve 140 senses the differential pressure between the heating water supply pipe 102 connected to the inlet side of the heating load 120 and the heating water return pipe 106 connected to the outlet side, And a predetermined flow rate is maintained at a constant level regardless of variations in pressure or load.

In addition, when hot water is used in the summer when the amount of heating and hot water usage is small, the flow rate of the heating supply pipe 101 flows finely through the bypass pipe 150 to the heating water return pipe 106 so that the waiting time for hot water supply can be minimized.

2, the three-large-sized heat exchanger apparatus according to the present invention includes a single flow path plate 200 mounted on one side of the heat exchanger 110, in which heating water, water, A plurality of flow paths 210 for entrance and exit are formed and various piping 100 are connected to end portions of the flow paths 210 to simplify the piping configuration around the heat exchanger 110.

That is, the heat exchanger 110 is connected to the inlet ports 112 and 116 and the outlet ports 114 and 118 of the heat exchanger 110 through which the heating water and the water are introduced and discharged, and the flow path 210 formed inside the flow path plate 200, The flow path plate 200 is mounted on the flow path plate 200. The flow path plate 200 is provided with heat transfer water supply pipes 101 and 102 and water supply pipes 103 and 104, (105), and heating water return pipes (106, 107) are connected to each other.

An air vent (not shown) for removing air remaining in the heating water is disposed at one side of the heating water return pipe 107 connected to the outlet side of the heat exchanger 110 by discharging the air generated in the heating system to the outside. 160 are installed. Here, the reference numeral 132 is a ball valve for opening and closing.

3 is an exploded perspective view showing a specific configuration of the flow path plate according to the present invention, and FIGS. 4 and 5 are a plan view and a sectional view of FIG.

3 to 5, the flow path plate 200 according to the present invention includes a plurality of pipes, each of which is formed in a complicated form in which the heating water and the water of the existing heat exchanger are entangled with the oil inlet and outlet, It has been simplified to a thin plate form.

That is, in the flow path plate 200 according to the present invention, a plurality of flow paths 210 for heating water, feed water, and entering and exiting flows are formed to have the form of a flow path as shown in FIG. 4, And the piping 100 is connected to the end thereof so that the heating water, the water supply, and the hot water supply can be transferred along the flow path.

The flow path plate 200 is formed by mutually joining two thin plates having one side surface and the other side surface of the longitudinal cross-section of the flow path 210. The two thin plates are the same in the heat exchanger brazing operation Lt; RTI ID = 0.0 > brazing < / RTI >

That is, the first flow path plate 200a has a first flow path groove 212 having a semicircular cross-sectional shape similar to that shown in FIGS. 3 and 4 on the first flow path plate 200a, A second flow path groove 232 having a shape symmetrical to the first flow path plate 212 is formed and a plurality of flow paths 210 having a circular cross section or a polygonal cross section are formed by joining between the first and second flow path plates 200a, Is formed.

In this case, the flow path 210 formed in the flow path plate 200 includes a first heating water supply flow path (not shown) connecting the heating water supply pipe 101 and the heating water inflow port 112 of the heat exchanger 110 A second heating water supply passage 202 branched from the first heating water supply passage 201 and connected to the heating load 120 side and a water supply inlet port 116 of the heat exchanger 110, A first water supply passage 203 connected to the water supply port 116 and supplied with water from the outside into the water supply inlet port 116 and a second water supply passage 203 branched from the first water supply passage 203 to supply cold water to the generation side, The hot water supply system includes a flow path 204 and a water supply port 118 connected to the water discharge port 118 of the heat exchanger 110 to supply hot water having a temperature raised by heat exchange with the hot water in the heat exchanger 110 to the generation side And a flow path 208.

The flow path 210 is connected to the heating water discharge port 114 side of the heat exchanger 110 and is connected to the first heating water return flow paths 205 and 207 through which the lowered temperature water is returned through the heat exchanger 110. [ And a second heating water return flow path 206 connecting the heating load 120 side and the first heating water return flow paths 205 and 207 and returning the heating water in a lowered temperature state through the heating load 120, .

At this time, the end portion 201a of the first heating water supply passage 201, the end portion 205a of the first heating water return flow path 205, and the first water supply flow path The heating water inflow and outflow ports 112 and 114 and the water inflow and outflow ports 116 and 118 of the heat exchanger 110 are communicated with the end portion 203a of the hot water supply flow path 208 and the end portion 208a of the hot water supply flow path 208, As shown in FIG.

The first heating water supply passage 201, the second heating water supply passage 202, the first water supply passage 203 and the second water supply passage 204, which are disposed at one side edge of the flow path plate 200, The hot water supply flow path 208, the first heating water return flow path 206, and the second heating water return flow path 207 are arranged so as to be parallel to each other, forming a certain spacing distance from each other. The first and second heating water supply pipes 101 and 102, the first and second water supply pipes 103 and 104, the hot water supply pipe 105, And the end portions of the second heating water supply water pipes 106 and 107 are coupled and connected to each other through pipe fitting means.

Accordingly, when the heat exchanger 110 is installed in the piping for hot water supply and heating, the end portions of the flow paths 210, which are parallel to one side edge of the flow path plate 200, Only a simple operation of connecting the supply pipes 101, 102, the first and second water supply pipes 103, 104, the hot water supply pipe 105 and the first and second water supply pipes 106, The piping construction around the heat exchanger 110 can be quickly and easily performed.

6, a method for installing a three-large-sized heat exchanger apparatus according to the present invention will be described with reference to FIG. 6. Referring to FIG. 6, a method for installing a three- The first and second flow path plates 200a and 200b formed with the flow grooves 212 and 232 are joined to each other through a brazing process so that a plurality of flow paths 210 (S232). ≪ / RTI >

The end portion 201a of the first heating water supply passage 201 located at the inner side of the manufactured flow path plate 200, the end portion 205a of the first heating water return flow path 205, The end portion 203a of the hot water supply passage 208 and the end portion 208a of the hot water supply passage 208 are connected to the heating water inflow and outflow ports 112 and 114 of the heat exchanger 110 and the water inflow and outflow ports 116 And the flow path plate 200 is coupled to the heat exchanger 110 through a brazing process so as to communicate with each other in a state where the flow path plate 200 is assembled to the heat exchanger 110 (S234)

Also, the flow path plate 200 and the heat exchanger 110 can be simultaneously manufactured in the process of manufacturing the flow path plate 200, the heat exchanger 110, and the flow path plate 200 and the heat exchanger 110 (S232 and S234)

When the flow path plate 200 is installed in the heat exchanger 110 as described above, the ends of the flow paths 210 positioned at the edge of the flow path plate 200 are connected to the flow paths 210 The piping installation of the heat exchanger 110 can be easily completed by connecting the piping 100 through the piping system (S236)

As described above, according to the three-large-sized heat exchanger apparatus and the installing method of the present invention, the flow path plate 200, in which the plurality of flow paths 210 communicating with the inlet and outlet portions of the heat exchanger 110 are formed, The piping structure around the heat exchanger 110 can be quickly and conveniently installed by simply brazing the piping to the flow path plate 110 and then connecting the pipes to the end of each flow path 210 formed in the flow path plate 200. [ .

In addition, various pipes connected to the periphery of the existing heat exchanger at various positions in a complicated structure are replaced by the shape of a plurality of flow paths 210 formed in one flow path plate 200, so that the piping configuration at the periphery of the heat exchanger 110 The space utilization of the peripheral portion of the heat exchanger 110 can be increased.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

101: first heating water supply pipe 102: second heating water supply pipe
103: first water pipe 104: second water pipe
105: hot water supply pipe 106: first heating water supply pipe
107: second half water return pipe 110: heat exchanger
112: heating water inlet port 114: heating water outlet port
116: water inlet port 118: water outlet port
120: Heating load 130: Temperature control valve
140: Differential pressure flow control valve 150: Bypass pipe
160: air vent 200: flow plate
200a, b: first and second flow path plates 201: first heating water supply flow path
202: second heating water supply channel 203: first water supply channel
204: second water supply channel 206: first heating water flow channel
205, 207: second heating water-receiving-water flow path 208:

Claims (10)

A heat exchanger for generating hot water through heat exchange between the heating water supplied from the heat source producing means and the supply water supplied from the outside;
A flow path plate installed in the heat exchanger and having a plurality of flow paths communicating with the inlet and outlet ports of the heat exchanger through which the heating water and the feed water are introduced and discharged;
A plurality of pipes connected to ends of the flow paths formed in the flow path plate;
Three large heat exchanger devices
The flow path plate according to claim 1,
A first flow path plate having a first flow path groove forming one side of the flow path;
And a second flow path plate having a shape symmetrical with the first flow path groove and having a second flow path groove forming the other surface of the flow path,
Wherein the first flow path plate and the second flow path plate are bonded to each other.
The large-sized heat exchanger device according to claim 2, wherein the first flow path plate and the second flow path plate are joined by brazing.
The large-sized heat exchanger device according to claim 1, wherein the end portions of the respective flow paths are disposed parallel to each other at one side edge of the flow path plate
The large-sized heat exchanger device according to claim 2, wherein the first and second flow grooves have a semicircular cross section or a polygonal shape
(a) preparing a flow path plate having a plurality of flow paths for inflow and outflow of heating water and feed water;
(b) joining the flow path plate to the heat exchanger such that an end portion of each flow path located inside the flow path plate communicates with each of the inlet and outlet ports formed in the heat exchanger;
(c) connecting each pipe corresponding to the flow path to an end of each flow path located at an edge of the flow path plate;
To install three large heat exchanger devices
(a) preparing a flow path plate having a plurality of flow paths for the inflow and outflow of heating water and water and a heat exchanger assembly to be in contact with the flow path plate, an end of each flow path located inside the flow path plate is formed in the heat exchanger assembly Assembling the flow path plate into the heat exchanger assembly to be in communication with each inlet and outlet port;
(b) bonding the flow path plate and the entire heat exchanger assembly;
(c) connecting each pipe corresponding to the flow path to an end of each flow path located at an edge of the flow path plate;
To install three large heat exchanger devices
[7] The method according to claim 6 or 7, wherein in the step (a)
A first flow path groove for forming one side surface of the flow path is formed in the first flow path plate and a second flow path groove having a shape symmetrical to the first flow path groove is formed in the second plate, Wherein the two flow path plates are mutually bonded to each other.
The method as claimed in claim 8, wherein the first flow path plate and the second flow path plate are bonded to each other through a brazing process.
The method as claimed in claim 6 or 7, wherein the joining of the flow path plate and the heat exchanger in the step (b)
Wherein the ends of each flow path located inside the flow path plate are joined to each other through the brazing while being in contact with the respective inlet and outlet ports formed in the heat exchanger.

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