KR102630282B1 - High Efficiency Heat Transfer Tube for Heat Exchanger - Google Patents

Abstract

The present invention relates to a high-efficiency heat transfer pipe for a heat exchanger, the structure of which is a long rod-shaped pipe penetrated inside so that a first fluid flows therein; and a heat exchanger formed in a spiral shape on the outer peripheral surface of the pipe and protruding outward. A pin; and a groove formed in a spiral shape on the inner peripheral surface of the pipe to induce rotation and eddy currents of the first fluid flowing inside the pipe to induce efficient heat exchange between the pipe and the first fluid.
Heat exchange fins are formed on the outer circumferential surface of the pipe, and vortex-type grooves along with streamlined grooves are formed on the inner circumferential surface of the pipe. The refrigerant flowing inside the pipe exchanges heat efficiently with the pipe due to the streamlined and vortex-shaped grooves, and the pipe is connected to the heat exchange fin. This has the effect of efficiently exchanging heat with the external fluid.
In addition, the vortex of the first fluid flowing inside the pipe is induced through the vortex induction means and the vortex induction piece so that the entire first fluid can evenly contact the inner peripheral surface of the pipe, so that the first fluid and the second fluid use the pipe as a medium. This has the effect of allowing very efficient heat exchange to be performed.

Description

High Efficiency Heat Transfer Tube for Heat Exchanger}

The present invention relates to a high-efficiency heat transfer pipe for a heat exchanger. More specifically, the present invention relates to a high-efficiency heat transfer pipe for a heat exchanger. In more detail, heat exchange fins are formed on the outer peripheral surface of the pipe, and a vortex-type groove along with a streamlined groove are formed on the inner peripheral surface of the pipe, so that the refrigerant flowing inside the pipe is streamlined and vortex-shaped. It relates to a high-efficiency heat transfer pipe for a heat exchanger that can efficiently exchange heat with a pipe due to grooves, and the pipe can efficiently exchange heat with an external fluid through heat exchange fins.

In general, a heat transfer tube is a heat transfer tube that transfers heat between fluids flowing inside and outside the pipe, and may be formed in the shape of a straight pipe or a curved pipe.

The heat transfer tube may be installed inside a heat exchanger such as a condenser or evaporator, and can exchange heat between the first fluid passing inside and the second fluid outside.

Additionally, the heat transfer tube may be installed in an absorption refrigerator, vapor compression refrigerator, boiler, etc.

It is preferable that the heat transfer tube installed in the absorption refrigerator or vapor compression refrigerator is made of a material and shape that can secure high heat transfer performance and has high corrosion resistance and wear resistance.

The present invention was proposed to solve the problems described above, and its purpose is to form heat exchange fins on the outer peripheral surface of the pipe and form a vortex-type groove along with a streamlined groove on the inner peripheral surface of the pipe, thereby preventing the refrigerant flowing inside the pipe. provides a high-efficiency heat transfer pipe for a heat exchanger that efficiently exchanges heat with a pipe due to streamlined and vortex-shaped grooves, and the pipe can efficiently exchange heat with an external fluid through heat exchange fins.

In addition, the vortex of the first fluid flowing inside the pipe is induced through the vortex induction means and the vortex induction piece so that the entire first fluid can evenly contact the inner peripheral surface of the pipe, so that the first fluid and the second fluid use the pipe as a medium. The aim is to provide a high-efficiency heat transfer tube for a heat exchanger that enables highly efficient heat exchange.

A high-efficiency heat transfer pipe for a heat exchanger according to the present invention to achieve the above object is a long rod-shaped pipe penetrated inside to allow the first fluid to circulate therein; and formed in a spiral shape on the outer peripheral surface of the pipe, protruding outward. It includes a heat exchange fin; and a groove formed in a spiral shape on the inner peripheral surface of the pipe to induce rotation and eddy currents of the first fluid flowing inside the pipe to induce efficient heat exchange between the pipe and the first fluid,
It further includes a vortex inducing means that is formed inside the pipe and induces a vortex of the first fluid flowing inside the pipe,
The vortex inducing means includes an installation groove formed in an annular shape on the inner peripheral surface of the pipe, is inserted into and fixed to the installation groove, and has an inclined body formed in the front of the pipe in the shape of a hat to guide the first fluid flowing through the pipe outward. , a central through hole is formed in the center of the inclined body, an outer through hole is formed at the edge of the inclined body through which the first fluid flowing outward along the inclined body passes, and at the rear, the center of the inclined body and A vortex body in which a distribution hole is formed that guides and transports the first fluid passing through the outer through hole to the rear, and extends and protrudes from the rear center of the vortex body toward the inclined body to guide the forward and backward transport of the vortex rotating member, and at the end of the vortex body, the A guide rod on which a stopper is formed to prevent the vortex rotation member from leaving, rotatably bound to the guide rod, and a hat-shaped vortex body positioned in front and spaced apart from the inclined body are formed to form a central through hole of the inclined body. The first fluid flowing through is guided outward and collides with the first fluid passing through the outer through hole of the inclined body. At the same time, the vortex body is made up of a plurality of vortex blades and is directed to the first fluid passing through the central through hole. A vortex rotation member that induces a vortex of the first fluid while being rotated, and the vortex rotation member is elastically supported forward by relying on the guide rod so that the vortex rotation member is transferred backward or forward depending on the flow rate of the first fluid. It is composed of an adjustment spring that induces elastic return.

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In addition, the front penetrates the guide rod and is connected to the vortex rotating member, the rear is exposed to the rear of the vortex body and rotates with the vortex rotating member, and the front is connected to the rear of the rotating rod and is connected to the rotating rod. It is characterized in that it includes a long strip-shaped vortex guide piece that rotates together and is formed in a spiral shape with a plurality of dispersion holes formed therein.

As described above, according to the high-efficiency heat transfer pipe for a heat exchanger according to the present invention, heat exchange fins are formed on the outer peripheral surface of the pipe, and a vortex-type groove along with a streamlined groove are formed on the inner peripheral surface of the pipe, so that the refrigerant flowing inside the pipe is streamlined and vortex-shaped. The groove effectively exchanges heat with the pipe, and the pipe effectively exchanges heat with the external fluid through the heat exchange fin.

In addition, the vortex of the first fluid flowing inside the pipe is induced through the vortex induction means and the vortex induction piece so that the entire first fluid can evenly contact the inner peripheral surface of the pipe, so that the first fluid and the second fluid use the pipe as a medium. This has the effect of allowing very efficient heat exchange to be performed.

1 is a perspective view of a high-efficiency heat transfer tube for a heat exchanger according to an embodiment of the present invention.
Figure 2 is a cross-sectional view taken along AA of the high-efficiency heat exchanger tube shown in Figure 1.
Figure 3 is a state diagram of the use of the high-efficiency heat exchanger tube shown in Figure 1
Figure 4 is a longitudinal cross-sectional view of a high-efficiency heat transfer tube for a heat exchanger according to another embodiment of the present invention.
Figure 5 is a state diagram of the use of the high-efficiency heat exchanger pipe shown in Figure 4

A high-efficiency heat transfer tube for a heat exchanger according to a preferred embodiment of the present invention will be described in detail based on the attached drawings. Detailed descriptions of well-known functions and configurations that are judged to unnecessarily obscure the gist of the present invention are omitted.

1 to 5 show a high-efficiency heat transfer tube for a heat exchanger according to an embodiment of the present invention. Figure 1 is a perspective view of a high-efficiency heat exchanger tube for a heat exchanger according to an embodiment of the present invention, and Figure 2 is a perspective view of a high-efficiency heat transfer tube for a heat exchanger shown in Figure 1. Figure 3 is a cross-sectional view of the high-efficiency heat exchanger tube A-A, Figure 3 is a state diagram of the high-efficiency heat exchanger shown in Figure 1, Figure 4 is a longitudinal cross-sectional view of the high-efficiency heat exchanger tube according to another embodiment of the present invention, and Figure 5 is Figure 4. This diagram shows the usage state of the high-efficiency heat pipe for the heat exchanger.

As shown in the drawing, the high-efficiency heat pipe 100 for a heat exchanger according to an embodiment of the present invention includes a pipe 10, heat exchange fins 20, and grooves 30.

As shown in Figures 1 and 2, the pipe 10 is formed in the shape of a long rod with a penetrating inside so that the first fluid flows therein.

Here, the pipe 10 is ultimately manufactured as a heat transfer tube for heat exchange. It is preferably manufactured from a copper tube with excellent heat exchange performance and processing, but it is of course not limited to this material.

As shown in Figures 1 and 2, the heat exchange fin 20 is formed in a spiral shape on the outer peripheral surface of the pipe 10 and protrudes outward.

Here, as shown in FIG. 3b, the heat exchange fins 20 are formed to facilitate heat exchange between the pipe 10, which has exchanged heat with the refrigerant flowing inside the pipe 10, and an external fluid. In order to secure an area capable of exchanging heat with the fluid, the heat exchange fin 20 is formed in a spiral shape with an inclination of 3°, but of course, manufacturing is not limited to this inclination.

In addition, the heat exchange fins 20 are preferably implemented in a shape that secures a large area in order to efficiently exchange heat with an external fluid.

As shown in Figures 1 and 2, the groove 30 is formed in a spiral shape on the inner peripheral surface of the pipe 10 to induce rotation and eddy currents of the first fluid flowing inside the pipe 10, thereby forming the pipe ( 10) and to induce efficient heat exchange of the first fluid,

The inner peripheral surface of the pipe 10 is cut in a spiral shape, and the inner peripheral surface of the pipe 10 is cut to a predetermined depth d1 at an inclination θ1 of 45° based on the center C of the pipe 10. A streamlined groove 31 is formed to have a height H1, and is cut spirally on the inner peripheral surface of the pipe 10, with an inclination θ2 of -30° based on the center C of the pipe 10. It is composed of a vortex-shaped groove 32 that is cut to a predetermined depth (d2) and formed to have a predetermined height (H2) on the streamlined groove (31),

The cutting depth d1 of the streamlined groove 31 is such that the height H1 of the streamlined groove 31 is formed higher than the height H2 of the vortex-shaped groove 32. Make sure it is formed deeper than the depth (d2).

That is, as shown in FIG. 3A, the streamlined groove 31 guides the refrigerant flowing inside the pipe 10 to rotate and flow along the spiral of the streamlined groove 31, thereby securing the flow rate of the refrigerant. At the same time, it induces efficient heat exchange between the refrigerant and the pipe 10,

The vortex-shaped groove 32 rotates along the streamlined groove 31 and collides with the circulating refrigerant, thereby inducing a vortex of the refrigerant and causing the refrigerant to evenly exchange heat with the pipe 10, thereby reducing the heat exchange between the refrigerant and the pipe 10. This leads to very efficient heat exchange.

Therefore, the vortex groove 32 is formed with an inclination θ2 slightly opposite to the streamline groove 31 to easily induce a vortex with the refrigerant flowing while rotating along the streamline groove 31.

However, if the cutting depth d2 for forming the vortex groove 32 is equal to or deeper than the cutting depth d1 for forming the streamlined groove 31, the vortex groove 32 causes the cutting depth d2 to be deeper than the cutting depth d1 for forming the streamlined groove 31. Since the space between the streamlined grooves 31 may be disconnected (broken), thereby interfering with the flow of refrigerant flowing through the streamlined groove 31, the cutting depth d2 of the vortex-shaped groove 32 is adjusted to the thickness of the streamlined groove 31. It is preferable that it is formed small compared to the cutting depth (d1).

On the other hand, as shown in Figure 4, it is formed inside the pipe 10 and is configured to further include a vortex inducing means 40 for inducing a vortex of the first fluid flowing inside the pipe 10,

The vortex inducing means 40 has an installation groove 41 formed in an annular shape on the inner peripheral surface of the pipe 10, and is internally fixed to the installation groove 41, and is formed in the shape of a hat at the front of the pipe 10. An inclined body (42a) is formed to guide the first fluid flowing through to the outside, and a central through hole (42aa) is formed in the center of the inclined body (42a), and the edge of the inclined body (42a) is formed. An outer through-hole (42ab) is formed through which the first fluid flowing outward along the inclined body (42a) passes, and at the rear, the first fluid passes through the center and outer through-holes (42aa, 42ab) of the inclined body (42a). A vortex body 42 in which a distribution hole 42b is formed that guides and transports the first fluid to the rear, and a vortex rotation member 44 that extends and protrudes from the rear center of the vortex body 42 toward the inclined body 42a. A guide rod 43 is rotatably bound to the guide rod 43, and has a stopper 43a formed at the end to prevent the vortex rotation member 44 from deviating from the guide rod 43, which guides the forward and backward transfer of the vortex rotation member 44. A hatch-shaped vortex body 44a positioned spaced apart from the inclined body 42a is formed to guide the first fluid flowing in through the central through hole 42aa of the inclined body 42a outward to the inclined body 42a. At the same time as colliding with the first fluid passing through the outer through hole (42ab) of (42a), the vortex body (44a) is composed of a plurality of vortex wings (44a') and the first fluid passing through the central through hole (42aa) A vortex rotation member 44 that is rotated by the fluid and induces a vortex of the first fluid, and elastically supports the vortex rotation member 44 forward by relying on the guide rod 43 to form a vortex rotation member 44. It is configured to include an adjustment spring 45 that guides the fluid to be moved backward or elastically returned to the front depending on the flow rate of the first fluid.

That is, the vortex inducing means 40 induces a vortex of the first fluid flowing inside the pipe 10, thereby inducing efficient heat exchange between the entire first fluid and the pipe 10, making the pipe 10 a medium. This leads to effective heat exchange between the first fluid and the external second fluid, and the process is as follows.

First, as shown in FIG. 4A, the first fluid flowing through the pipe 10 penetrates the center and outer edge of the inclined body 42a in the process of passing through the inclined body 42a in front of the vortex body 42. Passing through the holes 42aa and 42ab, it is divided into two flows. One is the first flow that passes through the inclined body 42a and flows outward through the outer through hole 42ab, and the other is the inclined body (42a) is divided into a second flow passing through the central through hole (42aa),

Afterwards, the first fluid of the second flow that has passed through the central through hole (42aa) is guided outward on the vortex body (44a) of the vortex rotation member 44 and collides with the first fluid of the first flow. As a result, a vortex is naturally induced to form,

At the same time, as shown in Figure 4b, in the process of transporting the first fluid of the second flow along the vortex body 44a, the vortex blades 44a' of the vortex body 44a are moved by the flowing first fluid. As it rotates, the first fluid of the second flow is rotated and guided outward, thereby causing the vortex formed when the first fluid of the first flow and the first fluid of the second flow collide as described above to become more active, thereby causing the vortex body The vortex induced in the first fluid passing through (42) and the vortex rotating member 44 is formed very effectively.

Accordingly, the first fluid flowing through the pipe 10 is very effectively induced as a vortex while passing through the vortex inducing means 40, leading to efficient heat exchange between the first fluid and the pipe 10.

Here, as shown in FIG. 4D, when the flow rate of the first fluid flowing through the pipe 10 increases, the vortex is generated by the hydraulic pressure of the first fluid passing through the central through hole 42aa of the vortex body 42. The rotating member 44 is pushed rearward, thereby widening the passage between the inclined body 42a of the vortex body 42 and the vortex body 44a of the vortex rotating member 44, thereby ensuring stable distribution of the first fluid. Conversely, when the flow rate of the first fluid is reduced, the vortex rotation member 44, which was transported rearward by the elastic restoring force of the control spring 45, is transported forward and returns to the inclined body 42a of the vortex body 42. And the passage between the vortex body (44a) of the vortex rotation member 44 is narrowed, and an appropriate flow speed of the second flow flowing between the inclined body (42a) and the vortex body (44a) is secured, so that the first flow of the first flow is secured. Of course, effective collision with the fluid is induced.

In addition, as shown in FIG. 4, the front part penetrates the guide rod 43 and is connected to the vortex rotation member 44, and the rear part is exposed to the rear of the vortex body 42 and is connected to the vortex rotation member 44. ) and a long rotating rod 51 that rotates together, the front of which is connected to the rear of the rotating rod 51 and rotates together with the rotating rod 51, and is formed in a spiral shape with a plurality of distribution holes 52a formed therein. It is configured to include a band-shaped vortex guide piece 52.

That is, as shown in FIG. 4C, the first fluid that has passed through the vortex inducing means 40 is once again induced to vortex through the vortex inducing piece 52 rotating together with the rotating rod 51. As the first fluid passes through the plurality of injection holes 52a formed in the vortex guide piece 52, the flow of the first fluid is sprayed into multiple flows, so that the first fluid passing through the vortex guide piece 52 It is dispersed into multiple flows and rotates like a whirlpool, mixing them evenly with each other, leading to very effective heat exchange with the pipe 10.

The high-efficiency heat exchanger pipe 100 for a heat exchanger of the present invention, which has the above configuration, has heat exchange fins 20 formed on the outer peripheral surface of the pipe 10, and a streamlined groove 31 and a vortex-shaped groove on the inner peripheral surface of the pipe 10. By forming (32), the refrigerant flowing inside the pipe (10) efficiently exchanges heat with the pipe (10) due to the streamlined and vortex-shaped grooves (31, 32), and the pipe (10) has heat exchange fins (20). This has the effect of efficiently exchanging heat with the external fluid.

In addition, by inducing a vortex of the first fluid flowing inside the pipe 10 through the vortex inducing means 40 and the vortex induction piece 52, the entire first fluid is evenly contacted with the inner peripheral surface of the pipe 10. This has the effect of enabling very efficient heat exchange between the first fluid and the second fluid using the pipe 10 as a medium.

The present invention has been described with reference to the embodiments shown in the accompanying drawings, but these are illustrative and are not limited to the above-described embodiments, and various modifications and equivalent embodiments can be made by those skilled in the art. You will understand the point. In addition, it goes without saying that modifications can be made by those skilled in the art without impairing the spirit of the present invention. Accordingly, the scope claimed in the present invention will not be limited by the scope of the detailed description, but will be limited by the claims and technical ideas described later.

10. Pipe 20. Heat exchange fin
30. Groove 31. Streamlined groove
32. Vortex-type groove 40. Vortex induction means
41. Installation groove 42. Vortex body
43. Guide rod 44. Vortex rotating member
45. Adjustment spring 51. Rotating rod
52. Vortex induction
100. High-efficiency heat transfer tube for heat exchanger

Claims (4)

In the heat exchanger installed in the heat exchanger to induce heat exchange between the first fluid circulating inside and the second fluid outside,
A long rod-shaped pipe 10 penetrated inside to allow the first fluid to circulate therein;
Heat exchange fins (20) formed in a spiral shape on the outer peripheral surface of the pipe (10) and protruding outward; and
A groove 30 formed in a spiral shape on the inner peripheral surface of the pipe 10 to induce rotation and eddy currents of the first fluid flowing inside the pipe 10 to induce efficient heat exchange between the pipe 10 and the first fluid; Includes,
It further includes a vortex inducing means 40 formed inside the pipe 10 to induce a vortex of the first fluid flowing inside the pipe 10,
The vortex inducing means 40 has an installation groove 41 formed in an annular shape on the inner peripheral surface of the pipe 10, and is internally fixed to the installation groove 41, and is formed in the shape of a hat at the front of the pipe 10. An inclined body (42a) is formed to guide the first fluid flowing through to the outside, and a central through hole (42aa) is formed at the center of the inclined body (42a), and an edge of the inclined body (42a) is formed. An outer through-hole (42ab) is formed through which the first fluid flowing outward along the inclined body (42a) passes, and at the rear, it passes through the center and outer through-holes (42aa, 42ab) of the inclined body (42a). A vortex body 42 in which a distribution hole 42b is formed that guides and transports the first fluid rearward, and a vortex rotation member 44 that extends and protrudes from the rear center of the vortex body 42 toward the inclined body 42a. A guide rod 43 is rotatably bound to the guide rod 43, and has a stopper 43a formed at the end to prevent the vortex rotation member 44 from deviating from the guide rod 43, which guides the forward and backward transfer of the vortex rotation member 44. A hatch-shaped vortex body 44a positioned spaced apart from the inclined body 42a is formed to guide the first fluid flowing in through the central through hole 42aa of the inclined body 42a outward to the inclined body 42a. At the same time as colliding with the first fluid passing through the outer through hole (42ab) of (42a), the vortex body (44a) is composed of a plurality of vortex wings (44a') and the first fluid passing through the central through hole (42aa) A vortex rotation member 44 that is rotated by the fluid and induces a vortex of the first fluid, and elastically supports the vortex rotation member 44 forward by relying on the guide rod 43 to form a vortex rotation member 44. A high-efficiency heat transfer pipe for a heat exchanger, characterized in that it includes an adjustment spring (45) that guides the first fluid to be transported rearward or elastically returned to the front depending on the flow rate of the first fluid.
delete delete According to claim 1,
The front is connected to the vortex rotation member 44 through the guide rod 43, and the rear is exposed to the rear of the vortex body 42 and rotates with the vortex rotation member 44. class,
The front is connected to the rear of the rotating rod 51 and rotates together with the rotating rod 51, and includes a long strip-shaped vortex inducing piece 52 that is formed in a spiral shape and has a plurality of dispersion holes 52a therein. A high-efficiency heat transfer tube for a heat exchanger, characterized in that it is composed of: