KR200307266Y1 - Rotary heat exchanger - Google Patents

Abstract

The present invention relates to a rotary heat exchanger having a simple structure, which significantly increases the heat transfer rate and at the same time facilitates the supply of steam and the discharge of condensate.

The structure is provided with a hollow disc-shaped disc body, a ring-shaped mounting portion having a through hole is attached to the center of the disc body, at least one or more dividers are provided with a partition space in the disc body and the inside of the disc body and the A heat exchanger attached between the outside of the mounting part and having a steam supply pipe and a condensed water discharge pipe respectively provided in the mounting part corresponding to the divided space so that steam enters into each of the divided spaces; A supply and discharge unit configured to supply steam to the heat exchanger and discharge condensate; A rotation driving unit configured to rotate the heat exchanger; It is configured to include a heat exchanger and a support configured to support the supply and discharge and the rotary drive.

By providing the rotary heat exchanger as described above, it is easy to manufacture, the manufacturing cost is significantly reduced, heat exchange efficiency is increased, more stable operation, and the heat transfer body has an effect of preventing the damage by the pressure in advance.

Description

Rotary heat exchanger

The present invention relates to a rotary heat exchanger having a simple structure, which significantly increases the heat transfer rate and at the same time facilitates the supply of steam and the discharge of condensate.

In general, a rotary heat exchanger rotates a disc heat exchanger to allow heat transfer to occur.

As one embodiment of the heat exchanger used in such a heat exchanger, the present applicant has been filed and registered "disk type heat exchanger for rotary heat exchanger" (Utility Model Registration No. 0145704) shown in Figs. This is as follows.

The hollow disk-shaped disk 100 is provided, the mounting tube 101 having a through hole 102 in the center of the disk 100 is mounted, the steam inlet 104 into the disk 100 ) And a plurality of tubes 103 having a steam outlet 105 are bent in a predetermined range, and a heat transfer medium is filled into the disc 100 except for the tube 103. The steam is introduced into the steam inlet 104 is to be configured to heat transfer to the outside of the disk body 100 while exiting through the steam outlet 105.

The heat exchanger having the heat exchanger configured as described above has a problem in that the heat exchanger passes through the heat transfer medium to perform heat exchange, thereby significantly reducing heat cutting and heat exchange efficiency.

In addition, by bending the tube as described above, the production of the heat exchanger is very difficult, there is a problem that the manufacturing cost increases accordingly.

In addition, by forming a plurality of tubes by bending as described above, there is a problem in that the failure rate is high at the time of manufacturing and at the same time the tube is broken by the pressure of steam or condensate during operation and easily broken.

The present invention is to improve the "disk type heat exchanger for rotary heat exchanger" that the applicant has already filed and registered in order to solve the conventional problems as described above,

Its purpose is to provide a rotary heat exchanger with a simple structure that significantly increases the heat transfer rate and at the same time facilitates the supply of steam and the discharge of condensate.

In addition, another object of the present invention is to provide a rotary heat exchanger that is easier to supply steam to the heat exchanger and discharge of condensate.

In order to achieve the above object, the present invention is provided with a hollow disc-shaped disc body, a ring-shaped mounting portion having a through hole to the center of the disc body is attached, at least one or more to have a partition space inside the disc body A heat exchanger, wherein a partition plate is attached between an inner portion of the disc body and an outer side of the mounting portion, and a steam supply pipe and a condensate discharge pipe are respectively provided in the mounting portion corresponding to the partition space so that steam enters into each of the partition spaces. ; A supply and discharge unit configured to supply steam to the heat exchanger and discharge condensate; A rotation driving unit configured to rotate the heat exchanger; It characterized in that it comprises a support configured to support the heat exchanger and the supply and discharge portion and the rotary drive.

In addition, the supply and discharge portion, the flange is mounted to one side of the heat exchanger, the connection pipe is mounted to the flange, the rotary joint mounted to the connection pipe, the supply pipe mounted to the rotary joint, the inside of the flange It is characterized in that consisting of a drain pipe is bent in and provided through the connecting pipe and the rotary joint.

1 is a schematic cross-sectional view of a rotary heat exchanger according to the present invention,

Figure 2 is a plan sectional view showing a heat exchanger of the rotary heat exchanger according to the present invention,

3 is a cross-sectional view showing an operating state of a rotary heat exchanger according to the present invention;

3a is a cross-sectional view showing an operating state of a heat exchanger,

3b is a plan sectional view showing an operating state of the heat exchanger;

4 is a plan sectional view showing another embodiment of a heat exchanger according to the present invention;

5 is a plan sectional view showing a conventional example;

6 is a longitudinal cross-sectional view of FIG.

* Explanation of symbols for the main parts of the drawings

10: heat exchanger

11: disc 12: mounting portion 13: through hole

14: partition space 15: partition plate 16: steam supply pipe

17: condensate discharge pipe

20: supply and discharge

21: flange 22: connection piping 23: rotary joint

24 supply pipe 25 drain pipe

30: rotating drive part

31: rotating shaft 32: drive gear 33: motor

34: Chain 35: Sprocket

40: support part

41: bearing 42: bearing housing 43: support

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

Referring to the configuration of the present invention as a schematic cross-sectional view of a rotary heat exchanger according to the present invention as shown in FIG.

The heat exchanger is provided with a supply and discharge part 20 to one side of the disk-shaped heat exchanger 10, the rotary drive unit 30 is provided to the other side of the heat exchanger 10, the lower portion of the heat exchanger 10 The furnace support part 40 is provided and is comprised.

In a more detailed configuration, the heat exchanger 10 is provided with a hollow disc-shaped disc body 11, the mounting portion 12 having a through hole 13 in the center of the disc body 11 is attached, the disc A plurality of partition plates 15 are attached to the interior of the sieve 11 so as to have a partition space 14, and the mounting part corresponding to the partition space 14 so that steam is introduced into each of the partition spaces 14 ( 12 is provided with a steam supply pipe 16 and the condensate discharge pipe 17, respectively.

In addition, the supply and discharge portion 20 is a flange 21 is mounted to one side of the disc body 11, the connection pipe 22 of the flange 21 is mounted, the end of the connection pipe 22 The rotary joint 23 is mounted, the supply pipe 24 is mounted to the rotary joint 23, the drain pipe 25 is bent through the flange 21, the connecting pipe 22 and the rotary joint 23 ) Is provided.

In addition, the rotary drive unit 30 is mounted on the other side of the disc 11, the rotary shaft 31, the drive gear 32 is mounted to the end of the rotary shaft 31, the drive gear 32 and the chain The sprocket 35 connected by 34 is configured to be driven by the motor 33.

In addition, the support portion 40 is equipped with a plurality of bearings 41 are mounted on the outer periphery of the rotary shaft 31 and the connection pipe 22, the bearing housing 42 is mounted to surround the bearing 41, the bearing The support 43 is provided at the lower portion of the housing 42.

Here, the heat exchanger (10) is rotated by the rotary drive unit 30 while the steam is supplied to the steam supply pipe (16) inherent in the partition space (14) and condensed when the condensed water through the condensed water discharge pipe (17) It is configured to be discharged to the outside so that heat exchange occurs to the outside.

In addition, the supply and discharge unit 20 serves to supply steam to the heat exchanger 10 and discharge the condensate, the steam supplied through the supply pipe 24 is a rotary joint 23 and the connection pipe 22 Into the flange 21 through, and enters the through hole 13 through the flange 21 is to enter the partition 14 through the steam supply pipe 16 protruding to the through hole (13).

In addition, the heat exchange of the heat exchanger 10 occurs, and the condensate generated is discharged to the through hole 13 through the condensate discharge pipe 17 inside the division space 14, and passes through the through hole 13 to the flange 21. Condensate is collected in the interior of the condensate is discharged to the outside again through the drain pipe (25).

In addition, the rotary drive unit 30 is rotated by the drive shaft 32 is connected to the chain 34, the sprocket 35 driven by the motor 33, the rotary shaft 31 is rotated, accordingly the rotary shaft 31 The heat exchanger 10 mounted to the rotating, the flange 21 and the connection pipe 22 is rotated integrally as the heat exchanger 10 rotates.

Therefore, the rotation driving unit 30 serves to rotate the heat exchanger 10 so that heat exchange of the heat exchanger 10 occurs properly and at the same time smooth discharge of condensate occurs.

In addition, the support 40 serves to support the heat exchanger 10 so that the heat exchanger 10 is properly rotated and operated stably by the rotation driving unit 30.

On the other hand, as shown in Figure 2 when explaining a cross-sectional view showing a heat exchanger of the rotary heat exchanger according to the present invention.

The heat exchanger (10) is provided with a hollow disc-shaped disc body (11), and a ring-shaped mounting portion (12) having a through hole (13) is attached to the center of the disc body (11), and the disc body (11) A plurality of partition plates 15 are radially attached between the inside of the disc body 11 and the outside of the mounting portion 12 so as to have a partition space 14 in the interior of each of the partition spaces 14. The steam supply pipe 16 and the condensed water discharge pipe 17 are respectively provided in the mounting part 12 corresponding to the divided space 14 so that the steam enters and exits.

Here, the heat exchanger 10 is slowly rotated and steam is supplied through the respective steam supply pipe 16 and the condensate discharge pipe 17 into the interior of the partition space 14 partitioned by the partition plate 15. When 11 is heated, the disc body 11 will heat-exchange with the outside.

As the heat exchange occurs as described above, the steam is converted into condensate, and the condensate is discharged to the outside through the condensate discharge pipe 17 through which the heat exchanger 10 rotates and is brought into contact with the through hole 13.

Then, while the heat exchanger 10 is rotated, the condensed water is continuously discharged while contacting each condensed water discharge pipe 17 continuously.

In addition, the heat exchanger 10 is rotated so that the supply and discharge of steam occurs smoothly in sequence, thereby eliminating the phenomenon that the inside is pressurized and broken or damaged.

Therefore, the heat exchanger 10 is configured to be easy to manufacture with a simple structure, the heat exchange easily occurs and to prevent damage due to pressure.

On the other hand, Figure 3 is a cross-sectional view showing the operating state of the rotary heat exchanger according to the present invention,

3A is a cross-sectional view showing an operating state of a heat exchanger,

3B is a plan sectional view showing an operating state of the heat exchanger.

Referring to Figure 3 the operation relationship of the heat exchanger as follows.

As shown in FIG. 3A, when the heat exchanger 10 is driven by the motor 33 and steam is supplied through the supply pipe 24, the heat exchanger 10, the connection pipe 22, and the flange ( The steam is supplied into the disc body 11 through the steam supply pipe 16 through 21.

As such, when the steam enters into the disc body 11, the heat exchanger 10 rotates to exchange heat with the outside.

In addition, after the heat exchanger 10 undergoes heat exchange with the outside, steam inside the disc 11 is converted into condensate, which is discharged from the heat exchanger 10 through the condensate discharge pipe 17. It will be gathered to the inner lower side of the flange 21.

The condensed water collected in this way is discharged to the outside through the drain pipe 25 bent by the pressure of the steam.

Therefore, while the heat exchanger is being rotated, the supply of steam, heat exchange, and discharge of condensate are sequentially generated to achieve stable and precise heat exchange.

3B, the steam entering the inside of the division space 14 through the steam supply pipe 16 and the condensate discharge pipe 17 is formed into the disc body 11. Heat exchange to the outside of the condensate generated in the process of the heat exchange is collected in the interior of the divided space 14, the condensate thus collected is in contact with the condensate discharge pipe 17 continuously through the through-hole 13 Will be discharged to the outside.

Therefore, the condensate discharge pipe 17 is provided on the edge portion of the divided space 14 while being provided so as not to protrude from the outer surface of the mounting portion 12 so that the condensed water is smoothly discharged from the inside of the divided space 14 to the through hole 13. It is preferable to be provided.

Therefore, the heat exchanger is configured so that the heat exchange is properly performed in a simple structure and at the same time the supply of steam and the discharge of condensate are smoothly prevented from being damaged by pressurization.

On the other hand, as shown in Figure 4 when explaining a cross-sectional view showing another embodiment of the heat exchanger 10 according to the present invention.

The heat exchanger (10) is provided with a hollow disc-shaped disc body (11), and a mounting portion (12) having a through hole (13) is attached to the center of the disc body (11), and the inside of the disc body (11) A plurality of dividing plates 15 are attached to the dividing spaces 14, respectively, and steam supply pipes are respectively provided to the mounting portions 12 corresponding to the dividing spaces 14 so that steam is introduced into each of the dividing spaces 14. 16 and the condensate discharge pipe 17 is provided.

Here, since the partition plate 14 is provided with three partitions 14, it is well known that various modifications of the heat exchanger 10 are possible.

By various modifications as described above, the heat exchanger 10 may be selectively used by manufacturing a suitable one for the performance and heat exchange efficiency of the heat exchanger.

As described above, the present invention has a simple structure, and the heat transfer rate is significantly increased, and at the same time, the supply of steam and the discharge of condensate are easy, so that the production is easy, the manufacturing cost is significantly reduced, the heat exchange efficiency is increased, more stable operation, and the heat carrier is applied to pressure. It is effective to be prevented from being damaged by it.

In addition, the present invention has the effect that the supply of steam to the heat exchanger and the discharge of condensate more easily, making the production easier, more stable and precise operation.

Claims (2)

A hollow disc-shaped disc body 11 is provided, and a ring-shaped mounting portion 12 having a through hole 13 is attached to the center of the disc body 11, and a partition space (11) is provided inside the disc body 11. At least one partition plate 15 is attached between the inside of the disc body 11 and the outside of the mounting portion 12 so as to have a 14, and the partition space so that steam enters into each of the partition spaces 14. A heat exchanger (10) configured to be provided with a steam supply pipe (16) and a condensate discharge pipe (17) in the mounting portion (12) corresponding to (14), respectively; A supply and discharge unit 20 configured to supply steam to the heat exchanger 10 and discharge condensate; A rotation driving unit 30 configured to rotate the heat exchanger 10; Rotary heat exchanger characterized in that it comprises a support (40) configured to support the heat exchanger (10) and the supply and discharge unit (20) and the rotary drive unit (30). The method of claim 1; The supply and discharge unit 20, the flange 21 is mounted to one side of the heat exchanger (10), the connection pipe 22 is mounted to the flange 21, and the connection pipe 22 is mounted A rotary joint 23, a supply pipe 24 mounted to the rotary joint 23, and a drain pipe bent in the flange 21 and penetrated through the connection pipe 22 and the rotary joint 23. Rotary heat exchanger, characterized in that consisting of (25).