KR102048704B1 - Heat exchanger with spiral heat media guidance - Google Patents

Abstract

The present invention relates to a heat exchanger widely used for air conditioning and, more specifically, to a heat exchanger with a spiral thermal medium guide means which is inserted into a heat exchange pipe constituting the heat exchanger to guide rotation of a thermal medium, such that heat exchange efficiency of the heat exchanger is increased. According to the present invention, the heat exchanger includes a spiral thermal medium guide means inserted into a heat exchange pipe forming the heat exchanger to allow the guided thermal medium to be moved with rotation. The spiral thermal medium guide means comprises: a thermal medium introduction section part (A) formed to rotate and move only the thermal medium of the central part of the heat exchange pipe; a thermal medium rotating section part (B) extended from the thermal medium introduction section part (A) and rotating and moving the guided thermal medium; and a thermal medium diffusion section part (C) extended from the thermal medium rotation section part (B) and guiding the rotated and outwardly moved thermal medium from the central part of the heat exchange pipe.

Description

Heat exchanger with spiral heat media guidance

The present invention relates to a heat exchanger widely used for heating and cooling.

More particularly, the present invention relates to a heat exchanger having spiral heat medium guide means configured to increase the heat exchange efficiency of the heat exchanger by guiding the heat medium inserted into the heat exchange tube forming the heat exchanger to rotate.

In general, an air conditioner is equipped with an air filter, a cooling / heating heat exchanger, a humidifier, and a blower to cool an indoor space using a cooling heat exchanger in summer, and to heat a heating using a heat exchanger for heating in winter. Office buildings, hospitals, Widely used in department stores, theaters, factories, research institutes, subway stations, etc.

Such an air conditioner supplies a heat medium to a heat exchanger and supplies artificially harmonized air to a room through a blower.

1 is a schematic diagram of a heat exchanger that is generally widely used.

As shown in FIG. 1, the heat exchanger HE includes a heat exchange tube 1 for guiding a heat medium, and a heat transfer fin 2 composed of a plurality of thin thin plates provided on an outer surface of the heat exchange tube 1. When the heat medium moves along the heat exchange tube 1, heat is transferred to the heat transfer fins 2, and the heat transferred to the heat transfer fins 2 is heat-exchanged with air.

Various techniques are provided to increase the efficiency of the heat exchanger made as described above, and among them, techniques for improving efficiency by rotating the heating medium or generating a vortex phenomenon are provided in the heat exchange tube similarly to the present invention. It is provided with the patent document.

In Patent No. 10-1003377, as shown in FIG. 2, the heat exchanger of the heat exchanger itself is included to include a technical configuration for the spiral distribution plate 3, which allows the heat medium guided in the heat exchange tube 1 to rotate and move. Techniques are provided to increase the efficiency.

(KR) Patent 10-1003377 (KR) Registration Room 20-0395007

The present invention has an object to increase the heat exchange efficiency of the heat exchanger itself.

That is, the present invention is to provide a spiral heat medium guide means provided in the heat exchange tube that can increase the heat exchange efficiency of the heat exchanger itself, and to provide a heat exchanger having the spiral heat medium guide means.

In the heat exchanger having a spiral heat medium guide means of the present invention having the above object, the heat exchanger is provided with a spiral heat medium guide means for rotating and moving the heat medium is inserted into the heat exchange tube, the spiral heat medium guide means , The heat medium introducing section (A) configured to rotate only the heat medium of the heat exchanger tube center portion, and the heat medium rotating section configured to rotate the heat medium that is extended and guided by the heat medium introducing section (A) ( B) and a heat medium diffusion section (C) configured to guide the heat medium, which extends with the heat medium rotation section (B), to rotate outwardly from the central portion of the heat exchange tube.

The spiral heating medium guide means is made of a spiral heating medium guide formed with a spiral heating medium guide wing, the spiral heating medium guide is made of a plastic material or non-ferrous metal material.

The spiral heating medium guide includes a heating medium rotation diffusion section including a heating medium introduction section (A), a heating medium rotation section (B), and a heating medium diffusion section (C), and a flow of the heating medium passing through the heating medium rotation diffusion sphere. It has a stabilization section to be stabilized, the heat medium rotation diffusion section and the stabilization section may be formed repeatedly.

It is formed to have an obtuse angle of obtuse angle with respect to the axis center line in the moving direction of the heat medium of the heat medium guide diffusion blades formed in the heat medium diffusion section (C), between the inner peripheral surface of the heat exchange tube and the outer peripheral surface of the heat medium guide diffusion blades. It is characterized by having a gap through which the heat medium, which is guided outward by the diffusion wing for guiding the heat medium, can pass.

The heat exchanger provided with the spiral heating medium guide means of the present invention as described above has a heating medium introduction section (A), a heating medium rotating section (B) and a heating medium diffusion section (A) made of a screw blade in the spiral heating medium guide that is the spiral heating medium guide means ( C) is formed to rotate the heat medium to be guided to increase the heat exchange efficiency of the heat exchanger itself, the rotation is made from the heat medium in the center of the heat exchange tube in the introduction section (A) to minimize the generation of noise, heat medium rotation The heat medium that rotates through the section portion B is guided to diffuse outwardly from the center portion of the heat exchange tube in the heat medium diffusion section C, thereby increasing the efficiency of heat exchange.

In addition, the spiral heating medium guide is made of a plastic material or a non-ferrous metal material, it is easy to manufacture, especially when made of a plastic material can lower the production cost and has the advantage of high durability due to the corrosion resistance characteristics.

In addition, it is determined that the heat transfer efficiency of the heat exchanger itself is formed by forming a plurality of heat medium rotation diffusion sections that are repeatedly spaced at predetermined intervals in the spiral heat medium guide. That is, when the heat medium moves or rotates along the heat exchange tube as in the related art, a temperature difference is generated between the center portion of the heat exchange tube and the inner wall of the outer tube so that the heat exchanger efficiency may be lowered. However, as in the present invention, the process of repeatedly rotating, diffusing, and stabilizing the heat medium has an advantage of increasing the efficiency of the heat exchanger. In particular, when the diameter of the heat exchange tube is large, there is a difference in efficiency.

1 is a schematic view of a heat exchanger used in the prior art.
Figure 2 is a schematic cross-sectional view of the main part of the heat exchanger used in the prior art.
Figure 3 is a schematic cross-sectional view of a heat exchanger, a schematic diagram of a spiral heating medium guide means inserted into the heat exchange tube showing an embodiment of the present invention.
Figure 4 is a schematic cross-sectional view of the main part of the heat exchanger having a spiral heat medium guide means showing an embodiment of the present invention.
Figure 5 is a schematic cross-sectional view illustrating the movement state of the heat medium in the main part of the heat exchanger having a spiral heat medium guide means showing an embodiment of the present invention.

Terms or words used in the present specification and claims should not be construed as being limited to the common or dictionary meanings, the embodiments described in the specification and the configuration shown in the drawings are only the most preferred embodiments of the present invention. Since not only represents the technical spirit of the present invention, it should be understood that there may be various equivalents and modifications that may substitute them at the time of the present application.

The present invention relates to a heat exchanger widely used for heating and cooling, the heat exchanger having a spiral heating medium guide means made to increase the heat exchange efficiency of the heat exchanger itself by guiding the heat medium is inserted into the heat exchange tube forming the heat exchanger to rotate. It is about.

The spiral heat medium guide means which is provided in the heat exchanger of the present invention so as to increase the heat exchange efficiency of the heat exchanger itself is inserted into the heat exchange tube (1) having a plurality of heat transfer fins (2) on the outside. 10).

The spiral heat medium guide 10 is inserted into the heat exchange tube 1 for guiding the heat medium to increase the heat exchange efficiency of the heat exchanger itself, and is used in a conventional heat exchanger including the heat exchange tube 1. It can be (see Figure 3).

The spiral heating medium guide 10 is inexpensive to facilitate manufacturing, and is usually made of a plastic material to have corrosion resistance, or may be made of a non-ferrous metal material such as aluminum, copper, and the like spiral The heat medium guide 10 is usually molded and then inserted into the heat exchange tube 1.

4 and 5,

The spiral heating medium guide 10 has a heating medium rotation diffusion section 20 and the stabilization section 30 formed by using a screw blade 21, the heating medium rotation diffusion section 20 and the stabilization section 30 is It is formed to be repeated at a set interval.

The heat medium rotation diffusion section 20 is a heat medium introducing section (A) made to rotate only the heat medium of the heat exchanger tube center portion, and the heat medium is extended and guided to the heat medium introduction section (A) It consists of a heat medium rotating section (B) and a heat medium spreading section (C) extending to the heat medium rotating section (B) made to be able to guide the heat moving in the outward direction from the central portion of the heat exchange tube. .

The heat medium introduction section (A) is made of a screw blade 21a for introduction is formed only in the central portion of the pipe body made to rotate only the heat medium of the central pipe portion. The introduction screw blade (21a) is made in the form of gradually increasing from the central portion of the tube, such as the screw thread of the screw.

In the heat medium introduction section A formed as described above, the heat medium to be guided can be gradually rotated from the center portion of the pipe to suppress the occurrence of noise and impact phenomenon.

The heating medium rotating section (B) is formed to extend with the heating medium introducing section (A) is a rotating screw blade (21b) is formed so that the heating medium guided to the heat exchange tube (1) can rotate and move in the tube body. Is done. The rotating screw blade 21b is preferably formed of a heat medium having the same size as the inner diameter of the tubular body 10. That is, by forming the rotating screw blade 21b to the same size as the inner diameter of the tubular body 10, the heat medium minimizes the occurrence of gaps between the inner circumferential surface of the tubular body 10 so that there is no heat medium passing between the gaps, so that Reduce the occurrence, and the spiral heating medium guide 10 allows the heating medium to be fixed in the tubular body 10.

The heating medium diffusion section (C) is a section for allowing the heating medium to rotate by passing through the heating medium rotating section (B) to spread outward from the central portion of the heat exchange tube in the outward direction, and the heating medium rotating section (B). It consists of a screw blade for rotation (21b) formed in the diffusion blade for guiding the heating medium extending (21c).

The heat medium guide diffusion blade 21c is formed to have an obtuse angle θ with an obtuse angle about an axis center line in the moving direction of the heat medium, and the inner circumferential surface of the heat exchange pipe body 1 and the diffusion wing 21c for heat medium guide. Between the outer circumferential surface is made to have a gap (L) through which the heat medium guided outward by the heat medium guide diffusion blade 21c (see Fig. 5).

The angle of inclination θ of the obtuse angle formed on the heat medium guide diffusion blade 21c is preferably in the range of 120 to 160 degrees, and preferably in the range of 145 to 155 degrees.

If the obtuse angle (θ) of the obtuse angle is greater than 160 degrees, the vortex generation phenomenon is not well made and does not cause a large difference from when not formed,

When the oblique angle θ of the obtuse angle is 120 degrees or less, a differential pressure phenomenon may occur, which may adversely affect the movement of the heat medium, thereby reducing the efficiency of the heat exchanger.

The stabilization section 30 is a section in which the screw blade 21 is not formed to stabilize the flow of the heating medium, which is rotated and diffused and guided and moved by the screw blade 21.

The heating medium rotation diffusion section 20 and the stabilization section 30 is formed to repeat the heating medium rotation diffusion section 20 and the stabilization section 30 at a predetermined interval that is set to repeatedly move the heating medium.

1: tube for heat exchange 2: heat transfer fin
10: spiral heating medium guide
20: heating medium rotation diffusion section 21: screw blade
21a: screw blade for introduction 21b: screw blade for rotation
21c: guide diffusion wing
30: stabilization section

Claims (5)

In the heat exchanger having a spiral heating medium guide means for rotating and moving the heating medium is inserted into the heat exchange tube, the guide,
The spiral heating medium guide means,
Heat medium introduction section (A) configured to rotate only the heat medium of the heat exchange tube central portion, and heat medium rotation section (B) configured to rotate the heat medium that is extended and guided by the heat medium introduction section (A). ), And a heat medium diffusion section (C) having a diffusion wing to spread and rotate the heat medium that rotates through the heat medium rotation section (B) to rotate outward from the central portion of the heat exchange tube. Meanwhile,
The heating medium rotating section (B) has a screw blade having the same size as the inner diameter of the tube, the diffusion wing of the heating medium diffusion section (C) has a gap between the inner circumferential surface of the tube and the outer peripheral surface of the diffusion wing, heat medium also A spiral heating medium comprising repeatedly forming a stabilizing section in which a heating medium rotation diffusion section consisting of an inlet section A, a heating medium rotating section B, and a heating medium diffusion section C and a screw wing are not formed. A heat exchanger having guide means. The method of claim 1,
The spiral heating medium guide means is made of a spiral heating medium guide 10 is formed a spiral heating medium guide wing,
The spiral heat medium guide 10 is a heat exchanger having a spiral heat medium guide means, characterized in that made of a plastic material or non-ferrous metal material. The method according to claim 1 or 2,
The heat medium guide diffusion blade 21c formed in the heat medium diffusion section C is formed to have an inclination angle θ of 120 to 160 degrees about an axis center line in the moving direction of the heat medium, Between the inner circumferential surface and the outer circumferential surface of the heat medium guide diffusion blade 21c is provided with a spiral heat medium guide means characterized by having a gap (L) through which the heat medium guided outward by the heat medium guide diffusion wing 21c. Heat exchanger. delete delete

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