KR20170126656A - Heat exchange - Google Patents

Abstract

The present invention provides a heat exchanger comprising: a hexahedron frame having penetrated front and rear surfaces; a plurality of cores horizontally arranged in vertical directions at regular intervals at the inside of the frame, and making a thermal medium flow through the inside thereof; a plurality of heat transfer pins vertically arranged to be perpendicular with respect to the cores along a lateral direction with predetermined intervals at the inside of the frame, and exchanging heat of the thermal medium conducted from the cores with air to transfer or lose heat; a pipe-shaped left header disposed on the left side with respect to the frame, connected to the left ends of the cores, and communicating with the left ends of the cores; a pipe-shaped right header disposed on the right side with respect to the frame, disposed to be connected to the right ends of the cores, and communicating with the right ends of the cores; and a breakage prevention valve disposed at each of the left and right headers, and selectively discharging the thermal medium staying in the heat exchanger to the outside. The heat exchanger prevents the breakage of the cores and return bands by automatically draining the thermal medium flowing in the heat exchanger according to the temperature or pressure of the thermal medium in the headers, resolves sudden pressure rising, does not require an conventional electrical means (a heat wire and a solenoid valve) and electrical energy for preventing freezing, and provides improved lifecycle and durability of an apparatus because an additional management is not needed as the valve is automatically opened and closed according to the temperature or pressure.

Description

Heat exchanger {Heat exchange}

[0001] The present invention relates to a heat exchanger, and more particularly to a heat exchanger, and more particularly, to a U-bend connected with an end of cores through which a heat medium flows, a tube header is connected to the header, And a drainage of the heat medium flowing in the heat exchanger is automatically performed according to the temperature and pressure of the heat medium in the header, thereby preventing breakage of the core and the return band.

Generally, an air handling unit (AHU, air conditioner) is installed in each industrial site, computer room, or business office for cooling and heating purposes.

The air conditioner described above is an apparatus for purifying, cooling and heating air. Recently used air conditioners are used for both cooling and heating. In summer, cold water is circulated to the cooling coil, and steam is supplied to the heating coil The air is heated or lowered by heat exchange with the air that is circulated by circulating hot water, and then the conditioned air is blown out by the blower to cool or heat the room.

The cooling and heating coils used in the above-described air conditioner are those in which the heating medium circulating inside the coils undergoes heat exchange with the air passing through the cooling and heating coils to change the temperature and humidity of the air. There is a problem that the heat medium remaining in the coil is not completely discharged when the heat medium in the coil is discharged to prevent the freezing of the coil, so that the heat medium in the coil is frozen in the winter so that the coil in which the heat exchanging medium flows is damaged.

As a result of the above-mentioned problems, in the patent application 10-2010-0000453 (2010.01.06), a header tank is formed at one side and the other side, a coil for connecting the header tanks at both sides is provided, and a heat exchanger Wherein the other side of the heat exchanger is fixed to the shaft and the height adjusting means is formed on one side of the heat exchanger to drain the heat exchange medium therein by the height difference between the one side and the other side.

However, in the conventional technology, since the user had to perform the drainage work directly, frequent occurrence of the sudden occurrence of the coil due to the inadequate management, and the prevention of the freeze by the electric electronic valve and the hot wire, However, in some cases, the frost protection system is turned off to conserve electrical energy, and efforts to prevent frost have been ineffective.

The present invention is characterized in that the left header and the right header connected with the return bands connecting the left and right ends of the cores are respectively provided with breakage prevention valves which are opened according to temperature or pressure so that the temperature or pressure (Heat line and solenoid valve) for preventing the freezing of the frozen wastes as in the conventional method, and the drainage of the heat medium flowing in the heat exchanger is automatically performed to prevent the cores and the return bands from being damaged, And it is an object of the present invention to provide a heat exchanger which does not require electrical energy and which automatically opens and closes a valve according to temperature or pressure and thus does not require any additional maintenance and thereby improves the life and durability of the device .

The heat exchanger according to the present invention comprises a frame constituting a hexahedron through which the front and rear surfaces communicate, a plurality of cores horizontally arranged in the upper and lower directions at a predetermined interval in the frame, A plurality of heat transfer fins disposed perpendicularly to the plurality of cores at regular intervals in the left and right directions to heat or lose heat by exchanging heat of the heat medium transferred from the plurality of cores with air, A plurality of core left ends connected to the left ends of the plurality of cores arranged in the left side with respect to the frame and connected to the left ends of the plurality of cores, And a plurality of right corners of the cores communicating with the right corners of the plurality of cores, And a breakage prevention valve for selectively releasing the heat medium staying in the heat exchanger to the outside.

At this time, a water inlet pipe for introducing the heat medium from the outside is formed on the upper side of the right header according to the present invention, and a drain pipe for draining the heat medium from the outside is formed on the lower side of the right header.

In addition, it is possible to selectively open and close the inlet pipe according to the present invention to discharge the air staying in the right header and the plurality of coils to the outside, or to relieve the internal vacuum of the coil constituting the closed circuit And an air vent for introducing outside air.

Further, the breakage prevention valve according to the present invention is automatically opened according to the temperature or pressure of the heat medium flowing in the header, and the drainage of the heat medium staying in the heat exchanger is respectively performed.

The heat exchanger according to the present invention has the following effects.

First, the left header and the right header connected to the return bands connecting the left and right ends of the cores are respectively provided with breakage prevention valves which are opened in accordance with temperature or pressure. The drainage of the thermal medium flowing in the heat exchanger is automatically performed to prevent the cores and the return bands from being damaged by the freezing of the thermal medium and the pressure rise, and the sudden pressure rise can be solved.

Second, since the breakage prevention valve and the air vent which are automatically opened and closed according to the internal temperature or pressure of the heat exchanger are provided, electric means (hot wire and solenoid valve) and electric energy for preventing the freeze wave are not needed and temperature or pressure Since the valve is automatically opened and closed, no additional maintenance is required, and the lifetime and durability of the device are improved.

FIG. 1 is a view illustrating an example of a heat exchanger according to an embodiment of the present invention. Referring to FIG.
FIG. 2 is a graph showing a state in which the breakage prevention valve according to an embodiment of the present invention is automatically opened / closed according to the temperature of a heating medium in a time-dependent header.
3 is a graph showing a state in which the breakage prevention valve according to an embodiment of the present invention is automatically opened / closed according to the pressure of the heating medium in the time-dependent header.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately The present invention should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention, and not all of the technical ideas of the present invention are described. Therefore, at the time of the present application, It should be understood that variations can be made.

In the present invention, a header is connected to a return band (U-bend) of the heat exchanger cores, and a breakage prevention valve is provided in the header, and the heat medium flowing in the heat exchanger The present invention relates to a heat exchanger for preventing the core and the return band from being damaged due to the freezing of the thermal medium and the pressure rise by automatically performing drainage, and will be described with reference to the drawings.

As shown in FIG. 1, a frame 10, which is a hexahedron having front and rear surfaces, is provided. A core 20 and a heat conductive fin 30 are provided in the frame 10.

The core 20 is made of copper, which is one of materials having high thermal conductivity. The core 20 is a tube having a hollow and flows the thermal medium through the inside thereof. The core 20 has an upward and downward direction And a plurality of them are arranged horizontally and constantly.

At this time, both left and right ends of the cores 20 are exposed through the left and right sides of the frame, and the exposed ends of the cores 20 are connected to each other by a return band U-bend, , The core 20 will heat or lose heat through heat exchange with the air passing between the cores 20 while flowing the thermal medium along the left and right longitudinal direction through the inner hollow.

The heat conductive fins 30 are made of copper or aluminum, which is one of high thermal conductive materials. The heat conductive fins 30 are arranged in the frame 10 at regular intervals, As shown in Fig.

A plurality of heat transfer fins 30 vertically disposed in the frame are connected to each other in such a manner that a plurality of horizontally arranged cores 20 penetrate through the heat transfer fins 30, Exchanges heat with air through the heat transfer fins 30 to heat or lose heat.

A left header 40 and a right header 50 are disposed on the left and right sides of the frame 10, respectively. The left and right headers 40 and 50 are vertically arranged in a hollow tube having a copper- The left and right return bands of the plurality of cores 20 are connected to the left header 40 and the right header 50 so as to connect the left header 40 and the right header 50, .

A breakage prevention valve 60 is provided in the left and right headers 40 and 50. The breakage prevention valve 60 is selectively opened to drain a part of the heat medium staying in the heat exchanger to the outside.

The breakage prevention valve 60 includes an automatic valve 61 for opening a flow path according to a predetermined temperature or pressure and a drain pipe for guiding the drainage direction of the heat medium staying in the heat exchanger as the flow path of the automatic valve is opened 62).

At this time, the inside of the automatic valve 61, which is a component of the breakage prevention valve 60, is automatically opened and closed by using the elasticity of the wax and the spring using the thermal expansion coefficient and does not require electrical energy. The valves are automatically opened (Open) and closed (Closed), so no additional maintenance is required.

A water inlet pipe 51 is formed on the upper side of the right header 50 to draw fluid from the outside and a drain pipe 52 is formed below the right header 50 to drain the heating medium to the outside .

In addition, the inlet pipe 51 includes an air vent 70. The air vent 70 selectively opens and closes the flow path of the piston, which moves up and down according to internal pressure or buoyancy or water level of the heating medium. The air is drawn in such a manner that the air staying in the plurality of coils 20 is discharged to the outside (that is, air is removed) or the internal vacuum of the coil constituting the closed circuit of the winter is dissolved.

The air vent 70 selectively opens and closes the flow path of the piston moving up and down according to internal pressure or buoyancy and water level of the heat medium. When the heat medium is not filled in the heat exchanger, the piston descends to communicate with the outside The flow path is maintained in an open state, and air is allowed to flow in and out.

In this case, when the heating medium is drawn into the heat exchanger for cooling, since the piston that opens and closes the flow path of the air vent 70 is maintained in a lowered state, the air remaining in the heat exchanger 70. When the heat medium is sufficiently drawn in, the piston of the air vent 70 gradually closes the flow path that rises according to the internal pressure or the buoyancy or the water level of the heat medium, 51 and the drain pipe 52, the left header 40 and the right header 50, and the plurality of cores 20 form a closed circuit.

When the temperature or pressure in the header matches the preset temperature and pressure, the breakage prevention valve 60 is opened, and the drainage of the thermal medium is made, the internal pressure or the buoyancy or the water level of the thermal medium is lowered, 70 is lowered, and the outside air is drawn into the heat exchanger through the flow path, and the outside air is drawn into the closed circuit of the vacuum, so that the drainage is smoothly performed.

The air vent 70 may be opened or closed by a user's operation as needed.

Therefore, in the heat exchanger according to the embodiment of the present invention, the left header and the right header connected to the U-bend connecting the left and right ends of the cores are respectively provided with breakage prevention valves which are opened according to temperature or pressure, As shown in FIGS. 2 and 3, the drainage of the heat medium flowing in the heat exchanger is automatically performed according to the temperature or pressure of the thermal medium in the header, thereby preventing breakage of the cores and return bands, (Heat wire and solenoid valve) and electric energy are not required for preventing the freezing of the air as in the conventional method and the automatic opening (opening) and closing (closing) of the freezing prevention valve are performed according to the temperature or pressure. The lifetime and durability of the device are improved.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: frame
20: Core
30:
40: Left header
50: Right header
60: Breakage prevention valve
70: Air vent

Claims (4)

A frame that forms a hexahedron with front and rear surfaces;
A plurality of cores disposed horizontally along the upward and downward directions at regular intervals in the frame and flowing the thermal medium through the cores;
A plurality of heat transfer fins vertically disposed perpendicularly to the plurality of cores along a left and right direction at regular intervals in the frame to heat or lose heat by exchanging heat of the heat medium transferred from the plurality of cores with air;
A left header disposed on the left side of the frame and connected to the left ends of the plurality of cores and communicating with the left ends of the cores;
A right header disposed on the right side with respect to the frame and communicating with the plurality of core right ends, the right header communicating with the plurality of core right ends; And
And a breakage prevention valve provided in the left and right headers, respectively, for selectively discharging the heat medium staying in the heat exchanger to the outside.
The method according to claim 1,
A water inlet tube formed on the upper side of the right header for introducing a heat medium from the outside;
And a drain pipe formed below the right header for draining the heat medium from the outside.
The method of claim 2,
The inlet pipe
And an air vent which is selectively opened and closed to discharge the air staying in the right header and the plurality of coils to the outside or to draw in the outside air so that the internal vacuum of the coil constituting the closed circuit is released at the time of the breakage prevention valve operation Heat exchanger.
The method according to claim 1,
The breakage prevention valve
Wherein the heat medium is automatically opened and closed in accordance with the temperature or pressure of the heat medium flowing in the header, and the heat medium staying in the heat exchanger is discharged in accordance with the temperature or the pressure.

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