CN220959780U - High-performance heat exchanger - Google Patents

Abstract

The utility model relates to the technical field of heat exchangers, in particular to a high-performance heat exchanger, which comprises a shell; the inside installation mechanism that is equipped with of shell, installation mechanism include the installation lid, and the installation lid is equipped with two, and two installation lids symmetry set up on the shell both sides, swing joint between installation lid and the shell, and the mounting groove has been seted up to the installation lid inboard, and the inside fixedly connected with of mounting groove is sealed fills up, and the inside swing joint of mounting groove has the heat transfer board, heat transfer board bottom fixedly connected with installation piece, and the installation piece is "T" style of calligraphy structure, and the mounting groove structure corresponds each other with the installation piece structure. The installation mechanism that sets up can conveniently dismantle and maintain the operation to heat exchanger's installation, and the seal structure on the installation mechanism can promote holistic sealed effect, makes the device keep good sealing performance, and the heat exchanger fin of heliciform structure that sets up can promote the flow distance of medium to promote the area of contact between medium and the heat exchanger fin, promote holistic heat transfer effect.

Description

High-performance heat exchanger

Technical Field

The utility model relates to the technical field of heat exchangers, in particular to a high-performance heat exchanger.

Background

Heat exchangers (also known as heat exchangers or heat exchange devices) are devices for transferring heat from a hot fluid to a cold fluid to meet specified process requirements, and are one type of industrial application of convective heat transfer and thermal transfer, and heat exchangers can be classified in different ways and can be classified into three general categories, i.e., divided into a divided wall type, a hybrid type, a regenerative type (or called regenerative type) according to the operation process thereof. Most of the existing heat exchangers are of fixed structures, follow-up disassembly and maintenance operations are inconvenient, and the heat exchangers of the fixed structures can influence overall sealing performance after follow-up maintenance and installation, so that overall heat exchange effect is influenced. In view of this, we propose a high performance heat exchanger.

Disclosure of utility model

The utility model aims to provide a high-performance heat exchanger, which solves the problem that a heat exchanger with a fixed structure is inconvenient to disassemble and maintain.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

A high performance heat exchanger comprising a housing;

The inside installation mechanism that is equipped with of shell, installation mechanism includes the installation lid, the installation lid is equipped with two, two the installation lid symmetry sets up on the shell two sides, swing joint between installation lid and the shell, the mounting groove has been seted up to the installation lid inboard, the inside fixedly connected with of mounting groove is sealed fills up, the inside swing joint of mounting groove has the heat exchanger plate, heat exchanger plate bottom fixedly connected with installation piece, the installation piece is "T" style of calligraphy structure, mounting groove structure corresponds each other with the installation piece structure.

Preferably, the installation mechanism further comprises an adjusting rod, the adjusting rod is rotationally connected to the bottom end of the installation groove, a limiting block is fixedly connected to the outer side of the adjusting rod and is of an arc-shaped structure, equidistant between the limiting blocks, an anti-skid block is arranged at the bottom end of the installation block and is made of rubber, and equidistant between the anti-skid blocks is arranged.

Preferably, the installation mechanism further comprises clamping blocks, the clamping blocks are slidably connected to two sides of the installation cover, the clamping blocks are of L-shaped structures, reset springs are fixedly connected to the inner sides of the clamping blocks, storage grooves are formed in the installation cover, the clamping blocks are arranged inside the storage grooves, and clamping grooves corresponding to the clamping block structures are formed in the inner walls of the shells.

Preferably, the heat exchange mechanism is arranged on the inner side of the heat exchange plate and comprises a heat exchange tube, the heat exchange tube is coiled inside the shell, two ends of the heat exchange tube respectively penetrate through two sides of the shell, heat exchange plates are arranged on the outer side of the heat exchange tube in a surrounding mode, and are spirally arranged and fixedly connected on the inner side of the heat exchange plate.

Preferably, the heat exchange mechanism further comprises a sealing plate, the sealing plate is arranged on the inner side of the heat exchange plate, the sealing plate is made of heat conducting silica gel, a diversion trench is formed in the inner side of the sealing plate, and the diversion trench and the heat exchange tube are mutually perpendicular.

Preferably, the heat exchange mechanism further comprises a fastening plate, the fastening plate is slidably connected to the inner side of the heat exchange plate, a fixing groove corresponding to the fastening plate structure is formed in the inner side of the heat exchange tube, and the fixing groove corresponds to the fastening plate structure.

Preferably, the heat exchange mechanism further comprises a magnetic block, the magnetic block is fixedly connected inside the fixing groove and at the tail end of the fastening plate, and the polarities of the corresponding surfaces of the magnetic block are opposite.

By means of the technical scheme, the utility model provides the high-performance heat exchanger. The method has at least the following beneficial effects:

(1) The utility model can facilitate the installation, the disassembly and the maintenance operation of the heat exchanger through the installation mechanism, and the sealing structure on the installation mechanism can promote the whole sealing effect, so that the device can still maintain good sealing performance after the disassembly and the maintenance.

(2) According to the utility model, the flow distance of the medium can be increased through the heat exchange plates with the spiral structures, so that the contact area between the medium and the heat exchange plates is increased, the overall heat exchange effect and the heat exchange performance are improved, and the high-performance heat exchange of the heat exchanger is realized.

(3) According to the utility model, gaps between the heat exchange plates and the heat exchange tubes can be filled through the arranged sealing plate structure, and meanwhile, the diversion trench on the side surface of the sealing plate can conveniently lift the contact surface between the medium and the sealing plate, so that the overall heat exchange effect is further improved.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model, illustrate and together with the description serve to explain a part of the utility model:

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is an enlarged schematic view of the utility model at A;

FIG. 3 is an exploded view of the present utility model;

FIG. 4 is an enlarged schematic view of the utility model at B;

FIG. 5 is a schematic view of an adjusting lever structure according to the present utility model;

In the figure: 1. a housing; 2. a mounting mechanism; 201. a mounting cover; 202. a mounting groove; 203. a sealing gasket; 204. a heat exchange plate; 205. a mounting block; 206. an adjusting rod; 207. a limiting block; 208. an anti-skid block; 209. a clamping block; 210. a return spring; 211. a storage tank; 212. a clamping groove; 3. a heat exchange mechanism; 301. a heat exchange tube; 302. a heat exchange plate; 303. a sealing plate; 304. a diversion trench; 305. a fastening plate; 306. a fixing groove; 307. and a magnetic block.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Example 1

A high performance heat exchanger, as shown in figures 1-5, includes a housing 1; the inside installation mechanism 2 that is equipped with of shell 1, installation mechanism 2 includes installation lid 201, installation lid 201 is equipped with two, two installation lids 201 symmetry set up on shell 1 both sides, swing joint between installation lid 201 and the shell 1, installation groove 202 has been seted up to the installation lid 201 inboard, installation groove 202 inside fixedly connected with sealed pad 203, installation groove 202 inside swing joint has heat transfer plate 204, heat transfer plate 204 bottom fixedly connected with installation piece 205, installation piece 205 is "T" style of calligraphy structure, installation groove 202 structure corresponds with installation piece 205 structure each other, installation mechanism 2 still includes regulation pole 206, regulation pole 206 rotates to be connected in installation groove 202 bottom, regulation pole 206 outside fixedly connected with stopper 207, stopper 207 is arc structure, the equidistance sets up between the stopper 207, installation piece 205 bottom is equipped with non-slipping spur 208, non-slipping spur 208 is the rubber material, equidistant setting between non-slipping spur 208, installation mechanism 2 still includes fixture block 209, fixture block 209 sliding connection is in installation lid 201 both sides, fixture block 209 is "L" style of calligraphy structure, fixture block 209 inboard fixedly connected with reset spring 210, be equipped with reservoir 211 on installation lid 201, fixture block 211 sets up inside the reservoir, the fixture block 211, shell inner wall has the fixture block 212 that corresponds each other with the fixture block 212.

In this embodiment, installation mechanism 2 can carry out convenient installation operation to heat transfer mechanism 3, joint formula structure can conveniently make up each other between heat transfer plate 204 and the installation lid 201 simultaneously, thereby promote the convenience of installation dismantlement, the mounting groove 202 structure is the T style of calligraphy structure that the structure corresponds each other with the installation piece 205 structure simultaneously, can promote the stability between installation piece 205 and the mounting groove 202 in the installation, the inside sealed pad 203 of mounting groove 202 can be filled the space between mounting groove 202 and the heat transfer plate 204 simultaneously, thereby promote the sealing performance of heat transfer in-process, fixture block 209 draw-in groove 212 structure can conveniently install the installation lid 201 to shell 1, fixture block 209 of L type structure can conveniently stir fixture block 209.

Example 2

As shown in fig. 3 and 4, the heat exchange mechanism 3 is disposed inside the heat exchange plate 204, the heat exchange mechanism 3 includes a heat exchange tube 301, the heat exchange tube 301 is coiled inside the casing 1, two ends of the heat exchange tube 301 respectively pass through two sides of the casing 1, the heat exchange tube 301 is disposed outside the heat exchange tube 301 in a surrounding manner, the heat exchange tube 302 is disposed in a spiral manner, the heat exchange tube 302 is fixedly connected inside the heat exchange plate 204, the heat exchange mechanism 3 further includes a sealing plate 303, the sealing plate 303 is disposed inside the heat exchange tube 302, the sealing plate 303 is made of heat-conducting silica gel, the sealing plate 303 is provided with a diversion groove 304, the diversion groove 304 and the heat exchange tube 301 are mutually perpendicular, the heat exchange mechanism 3 further includes a fastening plate 305, the fastening plate 305 is slidingly connected inside the heat exchange plate 204, a fixing groove 306 mutually corresponding to the fastening plate 305 is disposed inside the heat exchange tube 301, the heat exchange mechanism 3 further includes a magnetic block 307, the magnetic block 307 is fixedly connected inside the fixing groove 306 and at the tail end of the fastening plate 305, and the polarity of the corresponding surface of the magnetic block 307 is opposite.

In this embodiment, heat exchange mechanism 3 can realize the heat transfer operation, heat transfer board 204 and closing plate 303 encircle and set up in the heat exchange tube 301 outside, the heliciform structure can make things convenient for heat transfer medium to flow, the heliciform structure can promote the distance that heat transfer medium flows simultaneously, thereby promote heat transfer area and heat transfer effect, in order to reach the effect of high-efficient heat transfer, the assembly type structure also can conveniently dismantle heat transfer board 204 from the heat exchange tube 301 outside simultaneously, the inboard fastening plate 305 of heat transfer board 204 cooperates magnetic force piece 307 can carry out assistance-localization real time to heat transfer board 204 when two heat transfer boards 204 assemble, simultaneously fastening plate 305 can promote the sealed effect between the heat transfer board 204.

When the high-performance heat exchanger is used, a heat exchange source is led into the heat exchange tube 301 from one end of the heat exchange tube 301, flows along the coiled heat exchange tube 301 and is discharged from the other end, a medium to be subjected to heat exchange enters the shell 1 from one end of the shell 1, flows along the heat exchange plates 204 which are arranged in a staggered manner and exchanges heat with the heat exchange source in the heat exchange tube 301, is discharged from the other end of the shell 1, firstly contacts the heat exchange plates 204 when flowing between the heat exchange plates 204, flows along the spiral heat exchange plates 204, gaps between the heat exchange plates 204 and the heat exchange tube 301 are filled through the sealing plates 303, the sealing plates 303 are made of heat conducting silica gel, heat in the heat exchange tube 301 can be transferred to the medium among the heat exchange plates 302, the heat exchange tube 301 and the medium among the heat exchange plates 302, the guide grooves 304 formed in the side surfaces of the sealing plates 303 can promote the contact surfaces between the medium and fluid, thereby improving the heat exchange effect, when the maintenance operation is carried out subsequently, the clamping block 209 is stirred inwards, the tail end of the clamping block 209 is moved out of the clamping groove 212, then the mounting cover 201 can be detached from two sides, the heat exchange plate 204 is mounted and fixed in the mounting groove 202 through the mounting block 205, the mounting block 205 with the T-shaped structure can enable the heat exchange plate 204 to be mounted on the mounting cover 201 on one side, the sealing gasket 203 on the inner side of the mounting groove 202 can fill the gap between the heat exchange plate 204 and the mounting groove 202 after the other side of the heat exchange plate 204 is mounted in the mounting groove 202, the fastening plate 305 moves into the fixing groove 306 of the adjacent heat exchange plate 302 when the heat exchange plate 302 is assembled, the gap between the heat exchange plates 302 is filled, the tightness between the heat exchange plates 302 is improved, the two heat exchange plates 302 can be positioned through the structure of the fastening plate 305, the two heat exchange plates 302 are prevented from being deviated, the magnetic block 307 can fix the heat exchange plate 302, so that the heat exchange plate 302 is prevented from loosening.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. A high performance heat exchanger comprising a housing (1), characterized in that: the utility model discloses a heat exchange device, including shell (1), inside installation mechanism (2) that is equipped with of shell (1), installation mechanism (2) are including installation lid (201), installation lid (201) are equipped with two, two installation lid (201) symmetry sets up on shell (1) two sides, swing joint between installation lid (201) and shell (1), mounting groove (202) have been seted up to installation lid (201) inboard, inside fixedly connected with sealed pad (203) of mounting groove (202), inside swing joint of mounting groove (202) has heat exchange plate (204), heat exchange plate (204) bottom fixedly connected with installation piece (205), installation piece (205) are "T" style of calligraphy structure, mounting groove (202) structure and installation piece (205) structure correspond each other.

2. A high performance heat exchanger according to claim 1, wherein: the mounting mechanism (2) further comprises an adjusting rod (206), the adjusting rod (206) is rotationally connected to the bottom end of the mounting groove (202), limiting blocks (207) are fixedly connected to the outer side of the adjusting rod (206), the limiting blocks (207) are of arc-shaped structures, equidistant between the limiting blocks (207), anti-slipping blocks (208) are arranged at the bottom end of each mounting block (205), the anti-slipping blocks (208) are made of rubber, and equidistant between the anti-slipping blocks (208) are arranged.

3. A high performance heat exchanger according to claim 1, wherein: the mounting mechanism (2) further comprises clamping blocks (209), the clamping blocks (209) are slidably connected to two sides of the mounting cover (201), the clamping blocks (209) are of an L-shaped structure, reset springs (210) are fixedly connected to the inner sides of the clamping blocks (209), storage grooves (211) are formed in the mounting cover (201), the clamping blocks (209) are arranged inside the storage grooves (211), and clamping grooves (212) corresponding to the clamping block (209) in structure are formed in the inner wall of the shell (1).

4. A high performance heat exchanger according to claim 1, wherein: the heat exchange mechanism is characterized in that a heat exchange mechanism (3) is arranged on the inner side of the heat exchange plate (204), the heat exchange mechanism (3) comprises a heat exchange tube (301), the heat exchange tube (301) is coiled inside the shell (1), two ends of the heat exchange tube (301) are respectively arranged on two sides of the shell (1), heat exchange plates (302) are arranged on the outer side of the heat exchange tube (301) in a surrounding mode, the heat exchange plates (302) are arranged in a spiral mode, and the heat exchange plates (302) are fixedly connected on the inner side of the heat exchange plate (204).

5. A high performance heat exchanger as defined in claim 4 wherein: the heat exchange mechanism (3) further comprises a sealing plate (303), the sealing plate (303) is arranged on the inner side of the heat exchange plate (302), the sealing plate (303) is made of heat-conducting silica gel, a diversion trench (304) is formed in the inner side of the sealing plate (303), and the diversion trench (304) and the heat exchange tube (301) are mutually perpendicular.

6. A high performance heat exchanger as defined in claim 4 wherein: the heat exchange mechanism (3) further comprises a fastening plate (305), the fastening plate (305) is slidably connected inside the heat exchange plate (204), a fixing groove (306) corresponding to the structure of the fastening plate (305) is formed inside the heat exchange tube (301), and the fixing groove (306) corresponds to the structure of the fastening plate (305).

7. A high performance heat exchanger as defined in claim 4 wherein: the heat exchange mechanism (3) further comprises a magnetic block (307), the magnetic block (307) is fixedly connected inside the fixing groove (306) and at the tail end of the fastening plate (305), and the polarities of the corresponding surfaces of the magnetic block (307) are opposite.