KR102244626B1 - heat exchanger for improving heat exchange efficiency - Google Patents

Abstract

The present invention relates to a heat exchanger for improving heat exchange efficiency. The heat exchanger includes: a case having vents formed on one side and another side facing the first side; a fluid introduction header placed on the outside of one side of the case, while individually discharging fluids supplied through a fluid supply pipe connected to one end, through a plurality of outlets; a connection pipe connected between the inside and outside of the case, while having one end connected to each of the outlets of the fluid introduction header to provide an individual fluid progress channel; and a fluid discharge header placed on the outside of one side of the case, while discharging the fluids introduced through each of a plurality of inlets individually connected to the other end of the connection pipe, through a fluid discharge pipe connected to one end. The fluid introduction header is formed including a section of which the diameter becomes gradually larger while going in a progressing direction of the fluids, wherein since the outlets are formed radially on one side facing the fluids introduced inward, a distance from the center of the fluid supply pipe connected to one end to the center of each of the outlets is equal.

Description

Heat exchanger for improving heat exchange efficiency

The present invention relates to a heat exchanger, and more particularly, a heat exchange efficiency that enables fluid flow in each connection pipe connected between a fluid input header and a fluid discharge header to be made quickly and uniformly, thereby facilitating heat exchange and improving heat exchange efficiency. It relates to a heat exchanger for improvement.

The vast majority of the population spend a significant amount of time indoors.

At this time, if the indoor temperature is excessively high or low, an air conditioner is installed in the building structure, and the indoor temperature is controlled by the air conditioner.

Meanwhile, as one of the air conditioners, there is a'fan coil unit' as disclosed in Korean Utility Model Publication No. 20-0314043.

In the fan coil unit, a heat exchanger and a blowing fan are installed in the case, and when indoor cooling is required, a cooling fluid is supplied to the heat exchanger while the wind from the blowing fan reaches the heat exchanger to cool the indoor air through heat exchange. When indoor heating is required, a heating fluid is supplied to the heat exchanger in a state where the wind by the blower fan reaches the heat exchanger to heat the indoor air through heat exchange, so that indoor cooling and heating can be achieved.

However, a conventional heat exchanger applied to a fan coil unit or the like has a problem in that the heat exchange efficiency does not meet expectations.

In other words, in the conventional heat exchanger, the fluid flow time inside the fluid flow path connected between the fluid input header and the fluid discharge header, that is, each connection pipe is formed in a zigzag shape (there are a plurality of turn parts) and has a considerable length. For example, when the heating fluid flows along the inside of the connection pipe during the heating process, the fluid maintained high temperature only in the front of the connection pipe, so heat exchange was smooth, but the fluid was cooled in the rear part of the connection pipe, so heat exchange was insignificant. There was a problem that the heat exchange efficiency did not meet expectations.

In addition, in the conventional heat exchanger, while the fluid pressure is concentrated at the end of the fluid input header, the inner diameter of each outlet port of the fluid input header was the same. Since the amount of fluid flow through the inside of the connecting pipes connected to the outlet of the rear portion was small, heat exchange through the corresponding connecting pipes was insignificant, so there was a problem that the overall heat exchange efficiency did not meet expectations.

For the above reasons, the relevant field is attempting to develop a heat exchanger that allows fluid flow in each connection pipe between the fluid input header and the fluid discharge header to occur quickly and uniformly so that heat exchange is smooth and the heat exchange efficiency can be improved. , Until now, satisfactory results have not been obtained.

Republic of Korea Utility Model Publication No. 20-0314043

The present invention has been proposed in order to solve the problems of the prior art as described above, and since the fluid flow in each connection pipe connected between the fluid input header and the fluid discharge header is made quickly and uniformly, heat exchange is smooth and heat exchange efficiency is improved. The purpose of this is to provide a heat exchanger that can be increased.

In order to achieve the above object, the present invention,

A case in which a vent is formed on one side and each of the other side facing it; A fluid injection header disposed on the outside of any one side of the case and discharging the fluid supplied through a fluid supply pipe connected to one end through a plurality of outlets; A connection pipe connected between the inside and the outside of the case, and having one end connected to the outlet of the fluid input header to provide an individual fluid progression path; And a fluid discharge header disposed on the outside of any one side of the case and discharging the fluid flowing through each of the plurality of inlets respectively connected to the other end of the connection pipe to the fluid discharge pipe connected to one end; Is formed including a section that advances in the direction of the fluid and gradually increases in diameter, and the outlet is radially formed on one surface facing the fluid flowing into the interior, and each outlet is connected to one end from the center of the fluid supply pipe. A heat exchanger for improving heat exchange efficiency, characterized in that the distance to the center is the same, is proposed.

The fluid injection header includes a conical protrusion formed in the center of one surface on which the outlet is formed and in contact with the fluid.

Each of the connecting pipes has the same individual length from any one of the outlets to any one of the inlets.

The connection pipe may include a bent section.

The case may include a blower fan installed in front of one vent.

In the heat exchanger for improving heat exchange efficiency according to the present invention, since the outlet of the fluid input header is formed radially on one side, the distance from the center of the fluid supply pipe to the center of each outlet is the same. Since it flows into the outlet at the same time, heat exchange can be made uniform as the fluid flow in each connecting pipe connected to the outlet becomes uniform, thereby increasing heat exchange efficiency.

In addition, in the heat exchanger for improving heat exchange efficiency according to the present invention, since the individual lengths of each connection pipe from any one of the outlet to any one of the inlet are the same, the fluid flow time in each connection pipe becomes the same. As the fluid flow in the tube becomes more uniform, the heat exchange may be more uniform, thereby increasing the heat exchange efficiency.

In addition, in the heat exchanger for improving heat exchange efficiency according to the present invention, a conical protrusion is formed in the center of one surface of the fluid input header to contact the fluid, and the fluid is guided to the edge of one surface by the conical protrusion. Since the inflow can be smooth, heat exchange through the connection pipe can be smooth.

In addition, in the heat exchanger for improving heat exchange efficiency according to the present invention, a connection pipe connected between any one outlet port and any one corresponding inlet port is formed in an approximately'U' shape. Shorten, so fluid flows quickly, and heat loss in the fluid flow process can be minimized, and heat exchange efficiency can be improved.

1 is a perspective view showing the appearance of a heat exchanger for improving heat exchange efficiency according to the present invention.
2 is a cross-sectional view showing the internal structure of a heat exchanger for improving heat exchange efficiency according to the present invention.
3 is an exemplary view showing fluid discharge through an outlet of a fluid input header in a heat exchanger for improving heat exchange efficiency according to the present invention.
4 is an exemplary view showing a connection form of a fluid injection header and a connection pipe in a heat exchanger for improving heat exchange efficiency according to the present invention.
5 is an exemplary view showing an outlet arrangement of a fluid input header in a heat exchanger for improving heat exchange efficiency according to the present invention.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1 and 2, a heat exchanger (A) for improving heat exchange efficiency according to the present invention includes a case 10; Fluid input header 20; Connector 30; And a fluid discharge header 40;

In the case 10 of the present invention, vents 11 are formed on one side and each of the other side facing it.

Accordingly, the connection pipe 30 disposed between the vents 11 on both sides of the case 10 comes into contact with the air introduced into the case 10.

On the other hand, the case 10 includes a blowing fan 12 installed in front of the one side ventilation opening 11, so that the case 10 flows in one direction by rotation of the blowing fan 12, that is, through the one side ventilation opening 11. Air introduced into the interior is discharged to the outside through the vent 11 on the other side.

The fluid injection header 20 of the present invention is disposed on the outside of one side of the case 10 and discharges the fluid supplied through the fluid supply pipe 100 connected to one end through the plurality of outlets 21.

Therefore, the fluid is injected into the connection pipe 30 by discharging the fluid through each outlet 21 of the fluid injection header 20.

At this time, the fluid injection header 20 is formed including a section that advances in the direction of the fluid and gradually increases in diameter, and the outlet 21 is formed radially on one side facing the fluid flowing into the interior and connected to one end. Since the distance from the center of the fluid supply pipe 100 to the center of each outlet 21 is the same, the fluid supplied through the fluid supply pipe 100 can be simultaneously introduced into each of the outlet ports 21.

In addition, the fluid injection header 20 includes a conical protrusion 22 in contact with a fluid formed in the center of one surface on which the outlet 21 is formed, so that the flow of the fluid to the edge of one surface is carried out by the conical protrusion 22. It is guided so that fluid inflow into each outlet 21 formed radially on one side may be smooth.

Meanwhile, in the fluid injection header 20, the fluid is a heating fluid having a higher temperature than room temperature or a cooling fluid having a lower temperature than room temperature, so that the fluid flows in the connection pipe 30 and flows into the case 10. Heat exchange occurs between the air.

The connection pipe 30 of the present invention is connected between the inside and the outside of the case 10, and one end is connected to the outlet 21 of the fluid injection header 20, respectively, to provide an individual fluid progression path.

Therefore, during the fluid flow process in the connection pipe 30, heat exchange with air flowing into the case 10 is performed.

At this time, the connection pipe 30 has the same individual length from any one of the outlets 21 to any one of the inlets 41 described below, so that the fluid flow time in each of the connection pipes 30 may be the same. .

Here, the connection pipe 30 may include a bent section 30a.

Therefore, as shown in FIG. 4, as the length of the bent section 30a increases or decreases according to the individual height of the connecting pipe 30 disposed in the case 10 with a height difference, the inlet port 21 (41) The individual length of each connecting pipe 30 reaching any one may be the same.

And the connection pipe 30 is formed in an approximately'U' shape, so that one end is connected to any one of the outlet 21 and the other end can be connected to any one of the inlet 41 of the fluid discharge header 40 described below. In addition, the length can be shortened as the turn portion is minimized in each.

In addition, the connection pipe 30 may increase a contact area with air introduced into the case 10 by the radiating fins 31 by forming at least one radiating fin 31 on the outer circumferential surface thereof.

Here, the radiating fins 31 may be formed in any conventional shape as long as the contact area with air can be increased, so a detailed description of the radiating fins 31 will be omitted.

The fluid discharge header 40 of the present invention is disposed on the outside of one side of the case 10, and the fluid flowing in through a plurality of inlets 41 respectively connected to the other end of the connection pipe 30 is connected to one end. Discharge through the discharge pipe (200).

Therefore, fluid circulation is achieved by the fluid discharge from the fluid discharge header 40.

The heat exchange in the heat exchanger (A) for improving heat exchange efficiency according to the present invention will be described in detail as follows.

In the present invention, a fluid supply pipe 100 is connected to one end of the fluid injection header 20, and the fluid supplied through the fluid supply pipe 100 is supplied to the fluid injection header 20.

In addition, in the present invention, the fluid input header 20 has a plurality of outlet ports 21, and the fluid is discharged through each outlet 21 as shown in FIG. 3.

At this time, a connection pipe 30 is coupled to each of the outlets 21, so that the fluid discharged through the outlet 21 is introduced into the connection pipe 30 to flow.

Therefore, since heat exchange is performed between a fluid flowing along the connection pipe 30, for example, a heating fluid or a cooling fluid and the surrounding air, the air heated or cooled by the heat exchange is allowed to reach the indoor space, thereby heating or cooling the indoor space. Cooling is achieved.

At this time, when the fluid flow in each of the connecting pipes 30 is uniform, for example, when the fluid flow is concentrated in some of the connecting pipes 30, the heat exchange in the other connecting pipes 30 is relatively reduced. Heat exchange efficiency may decrease.

However, in the present invention, the outlet 21 of the fluid input header 20 is formed radially on one surface facing the fluid flowing into the fluid input header 20 as shown in FIG. Since the distance from the outlet 21 to the center of each of the outlets 21 is the same, the fluid supplied through the fluid supply pipe 100 flows into each outlet 21 at the same time, so in each connection pipe 30 connected to the outlet 21 As the fluid flow of the fluid becomes uniform, heat exchange may be uniform, thereby increasing heat exchange efficiency.

However, since the outlet 21 is located at an edge of one surface of the fluid injection header 20, it may be difficult to inflow a fluid flowing toward the center of one surface of the fluid injection header 20.

However, the fluid injection header 20 of the present invention includes a conical protrusion 22 formed in the center of one surface on which the outlet 21 is formed, and the fluid supplied into the fluid injection header 20 is a circular protrusion ( Because it flows to the edge of one side by contact with 22), fluid inflow into each outlet 21 may be smooth.

And in the present invention, the connection pipe 30 has the same individual length from any one of the outlet 21 to any one of the inlet 41, so that the fluid flow time in each connection pipe 30 becomes the same, each connection As the fluid flow in the pipe 30 becomes more uniform, heat exchange may be more uniform, and thus heat exchange efficiency may be further increased.

In addition, in the present invention, since the connection pipe 30 is formed in an approximately'U' shape, the length may be shortened as the turn portion in each connection pipe 30 is minimized. Since this can be done quickly, heat exchange can further increase the efficiency.

In the present invention, one end of the connection pipe 30 is connected to each inlet 41 of the fluid discharge header 40, and after heat exchange, the fluid flows into the fluid discharge header 40 and is connected thereto. Since it is discharged through, the fluid can be circulated.

On the other hand, in the present invention, the case 10 for accommodating the connector 30 has a vent 11 formed on one side and each of the other side facing it, and the case 10 by any one of the vents 11 ) As air is introduced into the interior and heat exchange is performed in the process of passing through the connection pipe 30 by the other vent 11, the heated or cooled air is discharged.

At this time, the case 10 may include a blowing fan 12 installed in front of the vent 11 adjacent to the fluid injection header 20, and the case 10 from the outside by rotation of the blowing fan 12 In addition to smooth air inflow into the interior, air may be smoothly discharged from the inside of the case 10 to the outside, so that indoor heating and cooling may be smoothly performed.

The present invention as described above is not limited to the above-described embodiments, and thus can be changed within the scope not departing from the gist of the present invention claimed in the claims, and such changes are defined by the following claims. It is within the scope of the invention.

10: case 11: vent
12: blowing fan 20: fluid input header
21: outlet 22: conical projection
30: connector 30a: bending section
31: radiating fin 40: fluid discharge header
41: inlet 100: fluid supply pipe
200: fluid discharge pipe A: heat exchanger

Claims (5)

A case in which a vent is formed on one side and each of the other side facing it;
A fluid injection header disposed on the outside of any one surface of the case and discharging the fluid supplied through a fluid supply pipe connected to one end through a plurality of outlets;
A connection pipe connected between the inside and the outside of the case, one end being connected to the outlet of the fluid input header to provide an individual fluid progression path; And
A fluid discharge header disposed on the outside of any one side of the case and discharging the fluid flowing through each of the plurality of inlets respectively connected to the other end of the connection pipe to the fluid discharge pipe connected to one end of the case, and including,
The fluid injection header is formed to include a section that advances in the direction of the fluid and gradually increases in diameter, and the outlet is radially formed on one side facing the fluid flowing into the interior from the center of the fluid supply pipe connected to one end. The distance to the center of each of the outlets is the same, and the fluid flowing into the inside including a conical protrusion formed in the center of one surface on which the outlet is formed and in contact with the fluid is guided to the edge of one surface by contact with the conical protrusion Is introduced into each of the outlets,
The connecting pipe is disposed with a height difference in the case, and is irrelevant to the placement height in the case due to the difference in length of the bent section, including a bent section that varies in length according to the placement height in the case. Heat exchanger for improving heat exchange efficiency, characterized in that the individual length from any one of the outlet to any one of the inlet is the same. delete delete delete The method of claim 1,
The case is a heat exchanger for improving heat exchange efficiency, characterized in that it comprises a blower fan installed in front of one side vent.

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