KR101367610B1 - Spiral condenser - Google Patents

Abstract

The present invention relates to a spiral condenser which is to improve the performance of a cooling and heating apparatus by increasing heat exchange efficiency through the arrangement of a refrigerant pipe for a condenser and heat radiation fins corresponding to the refrigerant pipe, wherein the refrigerant pipe for a condenser is shaped into a continuous spiral of Archimedes. A spiral condenser according to the present invention for an effect above comprises: a refrigerant pipe of which the part connected from one side thereof to the other side thereof is shaped into the spiral of Archimedes from a top view and is shaped into a cone from a side view; heat radiation fins of which each is shaped into a band plate, is cut to have at least two insertion grooves arranged at one side in the width direction thereof at a distance in the refrigerant pipe, is installed to be fit to the upper or the lower side of the refrigerant pipe, and has at least two slit grooves longitudinally formed along the other side in the width direction thereof at a distance; and fixing plates shaped into band plates, woven to be inserted into the respective slit grooves in accordance with an arrangement in which the heat radiation fins are arranged into the ribs of a fan from the center of the refrigerant pipe along the circumferential direction of the refrigerant pipe, and formed into rings by meshing both ends thereof with each other, wherein the insertion grooves have half shapes of the peripheries of the refrigerant pipe.

Description

Spiral Condenser {SPIRAL CONDENSER}

The present invention relates to a spiral condenser, and more particularly, a spiral condenser for increasing the heat exchange efficiency through the arrangement of a continuous condenser refrigerant tube forming an helical spiral of Archimedes and a heat dissipation fin corresponding thereto. It is about.

Generally, an air conditioner changes an ambient temperature by using a phase change and a temperature change of a refrigerant, and includes an air conditioner, a refrigerator, and a heat pump.

The general construction of the cooling and heating device includes a compressor for compressing the refrigerant to a high pressure, a condenser for liquefying the compressed gas refrigerant, an expansion valve for adiabatically expanding the liquefied refrigerant, and an evaporator for absorbing external heat by vaporizing the refrigerant do.

These compressors, condensers, expansion valves and evaporators are connected to the piping so that the refrigerant can circulate through the closed loop cycle.

In the evaporator and the condenser, heat exchange is performed between the refrigerant and the ambient air, and a phase change occurs when the refrigerant passes through the evaporator and the condenser.

In addition, an air blowing device is installed around the evaporator and the condenser where heat exchange is performed, and air is guided by using a blowing device to increase the frequency of contact for heat exchange with the refrigerant pipe surrounding the refrigerant.

Here, a condenser for dissipating the temperature of the gaseous refrigerant and inducing liquefaction of the refrigerant will be described.

The conventional condenser has a structure in which a linear coolant pipe is repeatedly bent in a zigzag shape in a parallel state and bent in a vertical direction at each bending portion so that zigzag shapes are arranged in multiple stages, As shown in Fig.

That is, in the conventional condenser configuration, the refrigerant which has been phase-transformed from the gas state to the liquid state is made to be high in its lower portion by its own weight, and the area occupied by the planar phase is narrowly formed, The air layer passes through the continuously connected expansion valve in a state where the air layer is continuously connected, thereby causing a problem of lowering the efficiency of the evaporator.

The condenser is for converting the gaseous refrigerant into a liquid state by losing its temperature in the process of contacting the inner wall of the refrigerant tube cooled by the blowing device. To increase the condensing efficiency, the refrigerant tube temperature in the condenser is further lowered Or the gaseous refrigerant should increase the frequency of contact with the inner wall of the refrigerant pipe.

However, since the refrigerant tube of the conventional condenser is formed as a straight line except the bent portion, there is a problem that the frequency of the gaseous refrigerant contacting the inner wall of the refrigerant tube is low.

Conventionally, Korean Patent No. 10-0236337 (hereinafter referred to as "prior art") has been disclosed as a spiral condenser manufacturing apparatus for manufacturing a spiral coolant pipe.

This prior art has a structure in which a bipinn tube, in which a refrigerant tube and a heat sink are integrally formed, is wound around a conical jig and then pressed in a planar shape.

However, in the prior art, since the refrigerant tube and the heat sink are integrally formed in a spiral shape, the arrangement of the heat sinks is arranged in a spiral arrangement like the refrigerant tube, so that the space between the refrigerant tube and the refrigerant tube Its utilization is weak.

Also, in the prior art, when the refrigerant tube is formed in two or more stages in order to extend the length of the refrigerant tube, the first and second heat sink plates having the same curvature are welded to each other to maintain its shape, The connected relation is repeatedly arranged to be folded from the farthest end to the next outer end.

That is, when the bifin tube is formed in two stages, the first and second stages on the center side are wound with the same diameter while the adjacent heat sink plates are welded, and the bifin tube extending from the second- And then the relationship of forming two stages with the same curvature is repeated.

Accordingly, when the refrigerant is liquefied in a certain section of the refrigerant tube, it is difficult to form the refrigerant tube in a multi-stage structure. It can not be done.

In addition, in the conventional spiral coolant tube arrangement, the spigot portion and the bottom portion of the spiral cone shape are disposed in the horizontal direction so that the refrigerant may be high in the spiral section, and the coolant tube is formed close to the sharp cone shape so that the cooling fins Installation was also a difficult problem.

In order to solve the above problems of the prior art, the applicant of the Republic of Korea Patent Application No. 10-2012-0111891 (spiral condenser of the heating and cooling device) and Republic of Korea Patent Application No. 10-2012-0122322 (helical condenser of the cooling and heating device) and Korea Patent Application No. 10-2012-0126864 (Spiral condenser manufacturing apparatus and its manufacturing method) has been developed and applied.

The present invention is to propose another embodiment in connection with the installation of the heat radiation fin of the "helical condenser" configuration filed by the applicant described above.

Korean Patent No. 10-0236337

The present invention has been made to solve the above-mentioned problems of the prior art, to provide a spiral condenser to facilitate the installation of the heat radiation fins corresponding to the condenser refrigerant pipe is bent in a continuous spiral shape of Archimedes along the conical shape. .

A characteristic constitution of the helical condenser according to the present invention for achieving the above object, the portion extending from one side to the other side forms a spiral shape of Archimedes in plan view and a conical shape when viewed from the side; A strip-shaped plate body, in which a fitting groove having a half shape around the refrigerant pipe is cut to a length formed at least two at intervals formed by the refrigerant pipe on one side in a width direction thereof so that the refrigerant pipe is above or below the refrigerant pipe. A heat dissipation fin installed to be fitted into the fitting groove, and having at least two slit grooves spaced apart from each other in the longitudinal direction on the other side in the width direction; A strip-shaped plate body, in which a plurality of heat dissipation fins are installed in the shape of a buccaltar in a circumferential direction at a central portion of the coolant pipe, are fitted in each of the slit grooves, and are interwoven with each other to form a ring shape. It consists of a configuration including a fixed plate.

In addition, it is preferable that the wing portion forming the shape of the heat dissipation fins protruding vertically extending from one surface of the heat dissipation fin along the periphery thereof is preferably formed.

In addition, the coolant pipe is preferably manufactured in a shape in which both sides of the horizontal direction are pressed so as to have an elongated shape in the vertical direction.

In addition, the fitting groove and the slit groove may be formed to have an inclination of an angle (θ) equal to the angle (θ) toward the center, which is a vertex position of a conical shape with respect to the plane at the edge portion of the refrigerant pipe with respect to the width direction. In addition, the angle θ range is preferably within 1 ~ 10 °.

In addition, the heat dissipation fins and the fixing plate are fixed by spot welding at the intersections, and the fixing plates further include a clamp fixed to the refrigerant pipe at the spiral center of the Archimedes, and a plurality of radially arranged from the clamps. It is preferable to fix the radiating fins and the fixing plate with respect to the clamp through the support of the.

As described above, according to the present invention, the heat dissipation fins arranged in the radial direction at the center thereof in a radial direction corresponding to the refrigerant pipes forming the conical shape and the helical spiral shape of Archimedes, and the fixing plate, clamp and support of the shape that couple them are welded and fixed to each other. As the installation is easy, the heat radiation fins and the fixing plate are arranged in the direction of the flow of air passing between the refrigerant pipes, thereby increasing the heat conduction efficiency.

1 is a partial cutaway perspective view for explaining the configuration of the spiral condenser constitution and the coupling relationship between the configuration according to an embodiment of the present invention.
FIG. 2 is a plan view for explaining the constitution of the spiral condenser shown in FIG. 1 and the arrangement relationship between these constitutions.
3 is a side cross-sectional view for explaining the configuration of the spiral condenser shown in FIG. 1 and the arrangement relationship of these configurations.
4 is a front view illustrating the heat radiation fins illustrated in FIGS. 1 to 3.

The terms and words used in the present specification and claims should not be construed to be limited to ordinary or dictionary meanings, but the inventor may appropriately define the concept of the term to describe its invention in the best way Can be interpreted as meaning and concept consistent with the technical idea of the present invention.

It should be noted that the embodiments described in this specification and the configurations shown in the drawings are merely preferred embodiments of the present invention and do not represent all the technical ideas of the present invention, It should be understood that various equivalents and modifications may be present.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in FIG. 1, the spiral condenser according to the present invention includes a refrigerant pipe 10 having a portion extending from one side to the other side forming an helical shape of Archimedes in plan view and a cone shape in side view.

Here, the refrigerant pipe 10 is generally located in a higher phase as a whole is located in the center portion, and the interval between the extended and neighboring refrigerant pipe 10 is kept constant.

In addition, it is preferable to manufacture the above-mentioned refrigerant pipe 10 in the shape pressed so that the both sides of the horizontal direction may mutually approach so that cross-sectional shape may form elongate shape in the vertical direction.

In this way, the cross-sectional shape of the coolant pipe 10 is elongated in the vertical direction when the coolant flowing inside the coolant pipe 10 receives centrifugal force and contacts the inner wall in the outer direction of the inner wall of the coolant pipe 10. This is to increase the possibility of contact by shortening the length of the transverse direction in which centrifugal force acts from the flow of the coolant on the basis of the same cross-sectional area.

In addition, another reason for forming the cross-sectional shape of the refrigerant pipe 10 in the vertical direction is elongated, when the refrigerant in the gas state is liquefied by the loss of thermal energy in the process of contacting the inner wall of the refrigerant pipe 10, To flow through the bottom, and the gaseous refrigerant to flow through the top.

In addition, another reason why the cross-sectional shape of the coolant pipe 10 is elongated in the vertical direction is that the space between the coolant pipes 10 is further increased when the coolant pipes 10 extend to form a predetermined interval. As the liquefied refrigerant is prevented from blocking the inside of the refrigerant pipe 10, the height of the refrigerant pipe 10 at the center position can be reduced as much as possible from the plane position based on the edge portion of the cone shape. You can also expect.

On the other hand, the spiral condenser of the present invention is provided with a heat dissipation fin 12 of a structure that is assembled in the upper or lower portion of the refrigerant pipe 10 corresponding to the shape of the refrigerant pipe 10 described above.

As shown in FIGS. 1 to 4, the heat dissipation fins 12 are formed in a band-shaped plate body in which a concave fitting groove 14 is formed in a half shape around the refrigerant pipe 10 from one side in the width direction to the inward direction. At the periphery of the fitting groove 14, wings 16 are formed along the periphery thereof to extend vertically from one surface of the heat dissipation fin 12 to enclose a portion around the side wall of the refrigerant pipe 10. .

In addition, the length of the heat dissipation fin 12 is cut to the length that the at least two fitting grooves 14 are formed at a pitch interval formed by the refrigerant pipe 10 described above with respect to the longitudinal direction of the heat dissipation fin 12. The maximum length of the fitting grooves 14 corresponds to the number of the refrigerant pipes 10 located near the center and the outermost refrigerant pipes 10 and the refrigerant pipes 10 between them according to the helical shape of Archimedes. To the length that is fully formed and arranged.

Here, when the length of the heat radiation fin 12 is formed over the above limited length because it interferes with other heat radiation fins 12 or the other side is difficult to install.

Of course, both end portions of the heat dissipation fin 12 may be folded or bent in an uninterrupted direction to prevent interference with other neighboring heat dissipation fins 12 when extending beyond the fitting groove 14 described above. Can be.

In addition, at least two or more slit grooves 18 are formed along the longitudinal direction at the other portions of the heat radiation fin 12 in the width direction.

The slit groove 18 formed as described above is formed for coupling with the fixing plate 20 for fixing the heat dissipation fins 12, which will be described later, and will be described again in the description of the fixing plate 20.

In the above-mentioned heat dissipation fin 12 configuration, the fitting groove 14 and the slit groove 18 including the wing portion 16 described above have the outermost edge of the refrigerant pipe 10 with respect to the width direction of the heat dissipation fin 12. It is formed to be inclined at an angle θ equal to the inclination angle θ from the planar position relative to the portion to the height of the refrigerant pipe 10 of the central portion.

As shown in FIG. 1, the heat dissipation fins 12 formed as described above may be disposed at an outer direction from the center along the Archimedes spiral in the upper or lower portion of the refrigerant pipe 10 in which the longitudinal direction of the heat dissipation fins 12 is already formed. Arranged so as to face each other, and then the alignment grooves 14 described above are aligned to correspond to the interval between the refrigerant tubes 10, and the refrigerant pipes 10 located at mutually opposite positions are fitted into the insertion grooves 14.

At this time, the wing portion 16 formed at the periphery of the fitting groove 140 is in close contact with the shape surrounding the portion of the side circumference of the corresponding refrigerant pipe (10).

In addition, the plurality of heat dissipation fins 12 installed in this way are arranged in a buccal shape along the circumferential direction at the center portion of the plurality of the heat dissipation lines of the Archimedes formed by the refrigerant pipe 12.

Each of the slit grooves 18 described above with respect to the heat dissipation fins 12 disposed as described above is provided as a strip-shaped plate body, which is fitted into the slit grooves 18 and woven together, and both ends thereof interlock with each other to form a ring shape. The fixed plate 20 is installed.

The fixing plate 20 forms one ring shape as both ends thereof are fixed in a form in which both ends are bent and engaged with each other between the heat dissipation fins 12.

And the site | part into which the fixed plate 20 was fitted corresponding to each slit groove 18 is mutually fixed by welding (spot welding).

In addition to this configuration, the helical condenser according to the present invention includes a clamp 24 fixed by pressing, welding, or fastening to the side of the refrigerant pipe 10 having a shape erected in a direction perpendicular to the center portion according to the swirling shape of Archimedes. Further, the side of the clamp 24 is further provided with a plurality of supports 22 arranged in the radial direction around the clamp 24.

Then, by welding again at a portion corresponding to the above-mentioned fixing plate 20 in the vertical direction of the support 22, it is possible to stably fix the heat radiation fins 12 to the refrigerant pipe 10.

Thus, the fixing of the heat dissipation fins 12 to the refrigerant pipe 10 is arranged and welded to the dimensions of the clamp 24, the support 22, the fixing plate 20 and the heat dissipation fins 12 are designed in the reverse order. After arranging and arranging corresponding to the refrigerant pipe 10 forming the vortex of Archimedes in a state of being installed, it may be configured to be fixed to the refrigerant pipe 10 by using the clamp 24 described above.

In this case, it can be easily manufactured by separately manufacturing a fixed structure including a heat dissipation fin 12 made from a coolant tube 10 and a jig having the same shape as the helical coolant tube 10 of Archimedes. Will be.

Description of the Related Art [0002]
10: refrigerant pipe 12: heat dissipation fin
14: fitting groove 16: wings
18: slit groove 20: fixed plate
22: support 24: clamp

Claims (5)

A refrigerant pipe forming a spiral shape of the Archimedes when viewed from one side to the other side and a conical shape when viewed from the side;
A strip-shaped plate body, in which a fitting groove having a half shape around the refrigerant pipe is cut to a length formed at least two at intervals formed by the refrigerant pipe on one side in a width direction thereof so that the refrigerant pipe is above or below the refrigerant pipe. A heat dissipation fin installed to be fitted into the fitting groove, and having at least two slit grooves spaced apart from each other in the width direction along the length direction; And
A strip-shaped plate body, in which a plurality of heat dissipation fins are installed in the shape of a buccaltar in a circumferential direction at a central portion of the coolant pipe, are fitted in each of the slit grooves, and are interwoven with each other to form a ring shape. Fixed plate;
Spiral condenser characterized in that consisting of a configuration including.
The method of claim 1,
Spiral condenser characterized in that the wing portion of the heat dissipation fin is formed on the peripheral edge of the heat dissipation fin is formed to extend vertically protruding from one surface of the heat dissipation fin along the periphery.
The method of claim 1,
The refrigerant pipe is a spiral condenser, characterized in that the cross-sectional shape is produced in a shape in which both sides in the horizontal direction is pressed to form an elongated shape in the vertical direction.
The method of claim 3, wherein
The fitting groove and the slit groove have an inclination of the angle (θ) equal to the angle (θ) toward the center of the cone-shaped vertex position at the edge of the refrigerant pipe with respect to the width direction, the angle ( θ) range is formed within 1 ~ 10 ° spiral condenser.
The method of claim 1,
The heat dissipation fins and the fixing plate are fixed by spot welding at intersections with each other, and the fixing plates further include a clamp fixed to the refrigerant pipe at the spiral center of the Archimedes, and a plurality of supports arranged in a radial direction from the clamp. Spiral condenser characterized in that the fixing of the radiating fins and the fixing plate is made with respect to the clamp through.

Images