KR20120001853U - High Efficiency dual pipe type heat exchanger - Google Patents

Abstract

The present invention relates to a high efficiency double tube heat exchanger, and is easy to bend by adopting a special structure such that the double tube for heat exchanger formed by inserting the inner tube and the inner tube inserted inside the outer tube and the outer tube and the inner tube is kept at regular intervals at all times. And perfect heat exchange performance is prevented and the heat exchange performance is greatly improved by the irregular flow of inlet gas passing between the spiral wrinkle formed in the inner tube and the plurality of protrusions formed on the inner surface,
Its purpose is to provide a high quality, high quality, high efficiency, double tube heat exchanger that has a special structure for the connecting connector connecting the inner tube and the exterior, so that the coupling is easy, the coupling state is solid, and the sealing force is excellent.
The high efficiency double tube heat exchanger of the present invention for achieving the above object consists of an inner tube 110 through which a first fluid flows and an outer tube 120 surrounding the inner tube 110, and a double tube 100 for heat exchange;
Combining the inner tube 110 and the outer 120 at both ends of the double tube 100 for heat exchange to form a pair of connecting connectors 200 to allow the second fluid to flow between the inner tube 110 and the outer 120. Understand,
The inner tube 110 constituting the double heat exchanger body 100 for heat exchange is formed of a spiral corrugated pipe to widen the surface area (heat transfer area) as well as to bend to improve cooling or heating performance.
The exterior 120 constituting the double heat exchanger 100 for heat exchange is composed of a tubular body in which a male screw 121 is formed on both sides of the outer surface and a plurality of protrusions 122 are formed on the inner surface thereof.
When the inner tube 110 is inserted into the exterior 120, the exterior 120 and the inner tube 110 are always maintained at a constant interval by the protrusions 122 formed on the inner surface of the exterior 120.
The second fluid flowing between the outer tube and the inner tube 110 passes through a plurality of protrusions 122 formed on the inner surface of the outer shell 120 and impinges on the outer wall of the spiral corrugation formed on the inner tube, and flows very irregularly, thereby improving heat exchange performance. High efficiency double tube heat exchanger

Description

High Efficiency dual pipe type heat exchanger

The present invention relates to a high-efficiency double tube heat exchanger, and more particularly, adopts a special structure that allows a heat exchange double tube formed by inserting an inner tube into an outer tube and an inner tube to be bent at a constant interval. By doing so, the bending operation is easy and perfect, and the heat exchange performance is prevented from deteriorating. The heat exchange performance is greatly improved by the irregular flow of inflow gas passing between the spiral wrinkles formed in the inner tube and the plurality of protrusions formed on the inner surface.

It is a high quality high quality high efficiency double tube heat exchanger, which adopts a special structure of connecting connector (connector) connecting inner tube and exterior to make it easy to join, and the bonding state is strong and the sealing force is excellent after joining.

Types of heat exchangers include double tube heat exchangers, finned heat exchangers, shell and tube heat exchangers, and the like.

The double double tube heat exchanger includes a double tube for heat exchange formed by inserting an inner tube into an outer tube and an inside of the outer tube, and a connection connector coupled to both ends of the double tube to connect the inner tube to the outer tube.

And a heat exchange between the first fluid supplied into the inner tube and the second fluid supplied between the outer tube and the inner tube.

Therefore, in such a double tube type heat exchanger, in order to improve the heat exchange performance, the inner tube and the outer shape of the double tube for heat exchange are very important, and the role of supplying a second fluid between the outer tube and the inner tube is important. 2 The role of the connecting connector (connector), which plays the role of preventing the fluid from leaking to the outside, is most important.

But looking at the conventional double tube heat exchanger,

The shape of the inner tube and the exterior is so simple that the coefficient of friction due to the flow of fluids is low, so the heat exchange performance is not high.

The structure of the connection connector (connector), which plays a role of supplying the second fluid between the exterior and the inner pipe and prevents the second fluid from leaking to the outside, is too simple, difficult to connect, difficult to connect, and double pipe for heat exchange. It was difficult to dismantle easily when repairing or replacing the sieve.

On the other hand, in order to increase the heat exchange performance satisfactory by the double tube heat exchanger, the length of the double tube should be formed long. In this case, since the handling is not easy, the double tube for heat exchange can be banded in various forms to reduce the volume. To facilitate.

By the way, the conventional double tube heat exchanger is so simple in shape of the inner tube and the outer appearance that when the double tube for heat exchange is simultaneously banded, the outer tube and the inner tube are not bent while maintaining a constant interval at all times, but are bent to one side and thus have a heat exchange performance. There was a problem that results in a greatly reduced results.

The present invention was devised to solve the above-mentioned conventional problems, and the special heat exchanger for the heat exchanger formed by inserting an inner tube into the outer tube and the inner tube is maintained at a constant interval at all times. By adopting the structure, the bending work is easy and perfect, and the heat exchange performance is prevented from being lowered, and the heat exchange performance is greatly improved by the irregular flow of inflow gas passing between the spiral wrinkles formed in the inner tube and the plurality of protrusions formed on the inner surface. sure,

Its purpose is to provide a high quality, high quality, high efficiency, double tube heat exchanger that has a special structure for the connecting connector connecting the inner tube and the exterior, so that the coupling is easy, the coupling state is solid, and the sealing force is excellent.

The present invention presented in the problem to be solved as described above is a double tube for heat exchange consisting essentially of an inner tube flowing through the first fluid and the outer tube surrounding the inner tube,

Combination of the inner tube and the exterior at both ends of the double tube for heat exchange consists of a pair of connecting connectors to allow the second fluid to flow between the inner tube and the exterior,

The inner pipe constituting the heat exchanger double pipe body is formed as a spiral corrugated pipe to widen the surface area (heat transfer area) as well as to be bent to improve cooling or heating performance,

The appearance constituting the heat exchanger double tube is composed of a tube body formed with a plurality of projections on the inner surface,

When the inner tube is inserted into the interior of the exterior by the projections formed on the inner surface of the exterior and the inner tube is always maintained at a constant interval,

The second fluid flowing between the outer tube and the inner tube passes through a plurality of protrusions formed on the inner surface of the outer tube, while hitting the outer wall of the spiral corrugation formed on the inner tube while flowing very irregularly.

The high efficiency double tube heat exchanger of the present invention constitutes an outer tube and a double tube body for heat exchange by inserting an inner tube into the inside of the outer tube,

Adopt a spiral corrugated pipe that can increase the surface area (heat transfer area) as well as bend to improve cooling or heating performance.

By adopting the exterior as a tube with a plurality of protrusions formed on the inner surface, the long double tube is banded in various forms to simultaneously satisfy the purpose of obtaining satisfactory heat exchange performance and the purpose of reducing volume and facilitating handling. Even if it is made by the projection formed on the inner surface of the exterior and the inner tube is always maintained at a constant interval.

Therefore, there is an advantage that the bending operation is easy and perfect.

In addition, since the inner tube is not biased to one side and is heat exchanged evenly, there is an advantage that the reduction in heat exchange performance caused by the inner tube is biased to one side is completely prevented.

In addition, there is an advantage that the heat exchange performance is greatly improved by the irregular flow of inlet gas passing between the spiral wrinkle formed in the inner tube and the plurality of protrusions formed on the outer surface.

On the other hand, the present invention has a special structure including an inner tube sealing hole and the other inner tube sealing hole which is installed inside the coupler and the coupler screwed to the connecting body and the inner body is contracted by the tightening pressure of the coupler is connected to the external body connected By adopting a connection connector (connector), the inner tube and the outer tube are connected very firmly, and additionally, the outer surface of the inner tube is completely sealed by the sealed packing, so that the second fluid flowing between the outer tube and the inner tube is completely prevented by increasing the sealing force. There is an advantage of not leaking.

In addition, the present invention has the advantage of more convenient to use because it can be used to connect the hose if necessary by further forming a hose connecting portion at the rear end of the other side of the tube sealing opening constituting the connecting connector.

Therefore, it is clear that the present invention is a groundbreaking design that can be used very usefully in practical use because the above advantages are combined.

1 is an exploded perspective view showing a part of the present invention.
Figure 2 is an assembled perspective view showing the overall configuration of the present invention.
Figure 3 is a state banding the subject innovation heat exchanger double tube.
Figure 4 is an exploded perspective view of the main portion of the connector for connecting the inner tube and the exterior of the present invention heat exchanger double pipe.
Figure 5a, Figure 5b is a state diagram used in the connection connector of the present invention,
Figure 5a is a side cross-sectional view showing a state before assembly.
Figure 5b is a side cross-sectional view showing a state after assembly.

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

The high efficiency double tube heat exchanger of the present invention basically consists of an inner tube 110 through which the first fluid flows and an outer tube 120 surrounding the inner tube 110 as shown in FIGS. 1 to 5. With 100,

Combining the inner tube 110 and the outer 120 at both ends of the heat exchange double tube 100 is composed of a pair of connecting connectors 200 to allow the second fluid to flow between the inner tube 110 and the outer 120. have.

Here, the inner tube 110 constituting the double heat exchanger body 100 is formed in various structures to increase the surface area (heat transfer area) as well as to bend to improve cooling or heating performance. In the design, a spiral corrugated pipe was adopted.

The pleats of the helical corrugated pipe are composed of one or two or more rows.

On the other hand, the exterior 120, the male screw 121 is formed on the outer surface of both side ends, a plurality of protrusions 122 are formed on the inner surface.

Accordingly, when the inner tube 110 is inserted into the outer tube 120, the ends of the protrusions 122 formed on the inner surface of the outer tube 120 come into contact with the outer surface of the inner tube 110.

Therefore, by the protrusions 122 formed on the inner surface of the exterior 120, the exterior 120 and the inner tube 110 is configured to maintain a constant interval at all times.

On the other hand, the pair of connecting connectors 200 for coupling the inner tube 110 and the outer tube 120 at both ends of the heat exchange double pipe 100, the rear end of the connector 211 that can introduce or discharge the second fluid. And an exterior connection portion 231 which is screwed or welded to the exterior 120 and is formed, and both ends of the inner tube 110 are not inserted into the front end of the inner tube 110 and are inclined inward to the front surface. A connection body 230 having a coupling hole 232a and having a coupler coupling portion 232 provided with an external thread 232b on an outer edge thereof;

A coupler 240 screwed to a male screw 232b formed at an outer edge of the coupler coupling portion 232 of the connection body and having an inclined surface pressing portion 241 formed at a rear inner surface thereof;

An inner tube sealing hole 250 made of a synthetic resin material inserted into an inner tube sealing hole coupling hole 232a formed in the connection body 230 and having an outer surface formed of an inclined surface 251;

The coupler 240 is inserted into the inside and the outer surface is formed of the inclined surface 261, the inner surface is made of a synthetic resin material of the other side of the tube sealing hole 260 is inserted.

At this time, the coupling coupling groove 232c of the coupler coupling portion 231 of the connection body 230 may be further formed, and the sealing force may be increased by coupling the sealing packing 234 thereto.

In addition, it may be made by further forming a hose connecting portion 262 which is connected to the hose 11 on the outer surface of the rear end of the other tube sealing opening (260).

It will be described in detail the operating state of the high-efficiency double tube heat exchanger of the present invention having the configuration as described above.

First, in order to satisfy the purpose of obtaining heat exchange performance satisfactory by the special configuration of the double pipe 100 as described above and reducing the volume and facilitating the handling at the same time, the long double pipe 100 is formed in various forms. Even if the bending process, the outer surface 120 and the inner tube 110 are always maintained at a constant interval by the protrusions 122 formed on the inner surface of the outer surface 120.

Therefore, the banding operation is easily and completely made, as well as the inner tube 110 is not biased to one side, so the heat exchange is evenly performed, thereby completely preventing the reduction of heat exchange performance caused by the inner tube 110 biased to one side. do.

In addition, when the first fluid flows to the inner pipe 110 constituting the double pipe 100 of the present invention and the second fluid is supplied and flows between the inner pipe 110 and the exterior 120,

In the case of the inner tube 110 is formed as a spiral corrugated tube, so that the first fluid moves while hitting the inner wall of the spiral wave tube, so that the thermal conductivity is excellent due to an increase in the friction coefficient.

In addition, the second fluid flowing between the outer tube and the inner tube 110 passes through a plurality of protrusions 122 formed on the inner surface of the outer shell 120 and simultaneously hits the outer wall of the spiral wrinkle formed in the inner tube, so that the flow flows very irregularly. As a result, heat exchange performance is greatly improved.

Hereinafter, the state of use of the connection connector 200 shown as an embodiment of the present invention.

First, the exterior 120 constituting the double pipe 100 is screwed or welded to the exterior connecting portion 231, each side of which constitutes the connection connector 200.

In addition, the inner tube 110 constituting the double tube 100 is on the outer surface in the state in which both ends of the inner tube 110 is not formed wrinkles inserted into the coupler coupling portion 232 of the connection body 230 Inner tube 250 is made of synthetic resin.

Then, the coupler 240 is connected to the coupler 240 at the rear end of the coupler 240 in the state in which the other end pipe 10 coupled with the other end pipe closure 260 made of synthetic resin is coupled to the inner pipe closure 250. Screw on (232) and tighten tightly.

In this way, as the coupler 240 is tightened, the inner tube sealing hole 250 is inserted into the inner tube sealing hole 232a and the inclined surface 251 formed on the outer surface of the inner tube sealing hole 250 is the inner tube sealing hole coupling hole. Pressing by the inclined inner surface of the (232a) is pressed (constricted) is strongly held at both ends of the inner tube 110, which is not wrinkled to form a zoom and sealed at the same time.

Therefore, since the outer surface of the inner tube 110 is completely sealed, the second fluid flowing between the outer tube 120 and the inner tube 110 does not leak out to the outside at all.

At this time, if the sealing packing 234 is coupled to the packing coupling groove 232c formed inside the coupler coupling portion 231 of the connection body 230, a stronger sealing force can be obtained.

Meanwhile, when the coupler 240 is tightened, the inclined surface pressing part 241 formed on the inner surface of the coupler 240 presses the inclined surface 261 formed on the outer surface in the case of the other side tube sealing opening 260. It is retracted (contracted) and strongly holds both ends of the other pipe 10 to seal at the same time as the zoom.

Therefore, the first fluid flowing into or out of the inner tube 110 through the other side tube 10 is completely moved through the inner tube 110 without leaking to the outside.

On the other hand, since the hose connection portion 262 is further formed on the outer surface of the rear end of the other tube sealing opening 261, the hose 11 can be connected to the hose connection portion 262 as needed, which is very convenient. Do.

10: other body 11: hose
100: double pipe 110: inner pipe
120: Appearance 122: Projection
200: connection connector 230: connection body
211: connector 231: external connection
232: coupler coupling portion 232a: inner tube sealing hole coupling hole
232b: external thread 232c: packing mating groove
234: Hermetic packing 240: Coupler
241: inclined surface pressing portion 250: inner tube sealing
251,261: Slope 260: The other side sealed enclosure
262: hose connection

Claims (4)

The double pipe 100 for heat exchange consisting of the inner tube 110, the first fluid flows and the outer shell 120 surrounding the inner tube 110,
Combining the inner tube 110 and the outer 120 at both ends of the double tube 100 for heat exchange to form a pair of connecting connectors 200 to allow the second fluid to flow between the inner tube 110 and the outer 120. Understand,
The inner tube 110 constituting the double heat exchanger body 100 for heat exchange is formed of a spiral corrugated pipe to widen the surface area (heat transfer area) as well as to bend to improve cooling or heating performance.
The exterior 120 constituting the double heat exchanger body 100 for heat exchange consists of a tube body having a plurality of protrusions 122 formed therein,
When the inner tube 110 is inserted into the exterior 120, the exterior 120 and the inner tube 110 are always maintained at a constant interval by the protrusions 122 formed on the inner surface of the exterior 120.
The second fluid flowing between the outer tube and the inner tube 110 passes through a plurality of protrusions 122 formed on the inner surface of the outer shell 120 and impinges on the outer wall of the spiral corrugation formed on the inner tube, and flows very irregularly, thereby improving heat exchange performance. High efficiency double tube heat exchanger The method of claim 1,
The pair of connection connectors 200 for coupling the inner tube 110 and the outer shell 120 at both ends of the heat exchanger double tube body 100,
The rear end is formed with a connector 211 capable of introducing or discharging the second fluid and an exterior connector 231 which is screwed or welded to the exterior 120, and has a spiral pleat formed at the front end of the inner tube 110. A connection body 230 having both ends inserted and provided with a coupler coupling part 232 having an inner tube sealing hole coupling hole 232a inclined inwardly on a front surface thereof and having an external thread 232b on an outer edge thereof;
A coupler 240 screwed to a male screw 232b formed at an outer edge of the coupler coupling portion 230 of the connecting body and having an inclined surface pressing portion 241 formed at a rear inner surface thereof;
An inner tube sealing hole 250 inserted into an inner tube sealing hole coupling hole 232a formed in the connection body 230 and having an outer surface formed of an inclined surface 251;
The high efficiency double tube heat exchanger is inserted into the coupler (240), the outer surface is formed with an inclined surface (261) and the inner surface is formed with the other side of the tube sealing hole (260) is inserted into the other side. The method of claim 2,
Further forming a packing coupling groove 232c in the coupler coupling portion 231 of the connecting body 230,
High efficiency double tube heat exchanger characterized in that the sealing force is increased by combining the sealing packing 234. The method of claim 2,
High efficiency double pipe heat exchanger, characterized in that the hose connection portion 262 is further formed on the rear end outer surface of the other side of the tube sealing opening (261).

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