CN217403217U - Integrated shell and tube heat exchanger - Google Patents

Abstract

The utility model relates to the technical field of integrated tube type heat exchangers, in particular to an integrated tube type heat exchanger, which comprises nine heat exchange tubes, wherein a heat dissipation assembly mechanism for assembling and dissipating heat of the nine heat exchange tubes is arranged on each heat exchange tube, the heat dissipation assembly mechanism comprises an installation component, two splicing rods, a rotary sleeve and a heat dissipation tube, the installation component is arranged outside each heat exchange tube, the splicing rods are arranged inside the installation component, one ends of the splicing rods, which are far away from the installation component, are in threaded connection with the rotary sleeve, the heat dissipation tube is fixedly connected inside the installation component, heat is transferred through the installation component by the arranged heat dissipation assembly mechanism, accelerated heat transfer is also required between the heat exchange tubes because of the integrated tube type, the installation component is subjected to accelerated heat transfer by circulating cooling liquid through the heat dissipation tube, and the convenience of device assembly is improved, the operation is simple, the heat exchange effect of the device is improved, and the heat exchange efficiency between the tube bundles is improved.

Description

Integrated shell and tube heat exchanger

Technical Field

The utility model relates to an integrated shell and tube heat exchanger technical field relates to an integrated shell and tube heat exchanger particularly.

Background

Traditional integrated shell and tube heat exchanger inconvenient assembly when using, and the design of integrated shell and tube for heat between the pipeline increases greatly, is difficult to the heat dissipation, and traditional integrated shell and tube heat exchanger when using, the inconvenient assembly of fin, and inconvenient dismantlement clearance maintenance, provides an integrated shell and tube heat exchanger to above-mentioned problem.

An effective solution to the problems in the related art has not been proposed yet.

SUMMERY OF THE UTILITY MODEL

To the problem in the correlation technique, the utility model provides an integrated shell and tube heat exchanger to overcome the above-mentioned technical problem that current correlation technique exists.

The technical scheme of the utility model is realized like this:

an integrated tube array heat exchanger comprises nine heat exchange tubes, wherein a heat dissipation assembly mechanism for assembling and dissipating heat of the nine heat exchange tubes is mounted on each heat exchange tube;

the heat dissipation assembly devices comprise an installation assembly, two splicing rods, a rotary sleeve and a heat dissipation pipe, wherein the installation assembly is installed on the outer side of the heat exchange pipe, the splicing rods are installed on the inner side of the installation assembly, one end of each splicing rod is far away from the corresponding end of the installation assembly, the corresponding rotary sleeve is connected with one end of the installation assembly through threads, and the inner side of the installation assembly is fixedly connected with the heat dissipation pipe.

Further, the mounting assembly mainly comprises a connecting plate, a splicing plate A, a splicing plate B, a splicing plate C, a splicing plate D and a splicing plate E, the right end of the connecting plate is fixedly connected with the splicing rods, the two splicing rods are vertically arranged on the left side of the connecting plate, the outer sides of the splicing rods are sequentially and slidably connected with the splicing plate A, the splicing plate B, the splicing plate C, the splicing plate D and the splicing plate E from left to right, the splicing rods penetrate through the surfaces of the splicing plate A, the splicing plate B, the splicing plate C, the splicing plate D and the splicing plate E, the splicing plates are rotatably sleeved on the right side of the splicing plate E, a group of heat exchange holes are respectively formed between the splicing plate A and the splicing plate B and between the splicing plate C and the splicing plate D, the number of each group of the heat exchange holes is two, and the inner sides of the heat exchange holes are in friction connection with the radiating pipes, a group of mounting holes are formed between the connecting plate and the splicing plate A, between the splicing plate B and the splicing plate C and between the splicing plate D and the splicing plate E, the number of the mounting holes in each group is three, and the outer side of the mounting assembly is in friction connection with the inner side wall of each mounting hole.

Furthermore, the connecting plate, the splice plate A, the splice plate B, the splice plate C, the splice plate D and the splice plate E are combined to form a square arrangement.

Further, two sets of heat dissipation mechanisms that carry out the forced air cooling heat transfer are installed in the heat dissipation assembly devices outside, heat dissipation mechanism includes equipment board, fin, heat dissipation fan, threaded rod and swivel nut, installation component outside sliding connection has the equipment board, equipment board outside fixedly connected with the fin, the fin outside is through bolt fixedly connected with the heat dissipation fan, the equal fixedly connected with in equipment board both ends the threaded rod, the threaded rod is half spiral shell column setting, one of them the threaded rod outside cover is equipped with the swivel nut.

Furthermore, the two groups of heat dissipation mechanisms are arranged in a central symmetry manner.

Furthermore, each group of heat dissipation mechanisms further comprises two clamping blocks, one side of the assembling plate is fixedly connected with the two clamping blocks, clamping grooves are formed in the outer sides of the connecting plate and the splicing plate E, and the clamping blocks are connected with the corresponding clamping grooves in a sliding mode.

Furthermore, two adjacent threaded rod combinations are arranged in a threaded rod mode, and the outer sides of the two threaded rods are in threaded connection with the outer sides of the corresponding threaded sleeves.

The utility model provides an integrated shell and tube heat exchanger, the beneficial effects of the utility model are as follows:

1. the utility model discloses in, through the heat dissipation assembly devices who sets up, the heat is through the installation component heat transfer, because be so integrated shell and tube type also need carry out the heat transfer with higher speed between the heat transfer pipe, circulate the coolant liquid through the cooling tube and carry out the heat transfer with higher speed to the installation component, improve the convenience of device assembly, easy operation, and improve device heat transfer effect, improve the heat exchange efficiency between the tube bank.

2. The utility model discloses in, through the heat dissipation mechanism that sets up, align two adjacent threaded rod laminating, revolve in the threaded rod outside through the swivel nut, then will assemble the fixed centre gripping of board in the outside of installation component, through equipment board heat conduction, blow the fin through the heat dissipation fan and carry out the heat transfer, carry out quick heat transfer to the heat exchange pipe, make things convenient for the device to assemble, also conveniently dismantle, and then conveniently clear up and maintain easy operation to the fin.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic diagram of an overall structure of an integrated shell and tube heat exchanger according to an embodiment of the present invention;

fig. 2 is a schematic view of an installation structure of a heat dissipation assembly mechanism of an integrated shell and tube heat exchanger according to an embodiment of the present invention;

fig. 3 is a schematic view of an installation structure of a heat dissipation mechanism of an integrated shell and tube heat exchanger according to an embodiment of the present invention;

in the figure:

1. a heat exchange pipe;

2. a heat dissipation assembly mechanism; 21. mounting the component; 211. a connecting plate; 212. a splice plate A; 213. a splice plate B; 214. a splice plate C; 215. a splice plate D; 216. a splice plate E; 22. splicing rods; 23. screwing a sleeve; 24. a radiating pipe;

3. a heat dissipation mechanism; 31. assembling a plate; 32. a fin; 33. a heat dissipation fan; 34. a clamping block; 35. a threaded rod; 36. a threaded sleeve.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The invention will be further described with reference to the accompanying drawings and specific embodiments:

the first embodiment is as follows:

referring to fig. 1 and fig. 2, an integrated tube array heat exchanger according to an embodiment of the present invention includes nine heat exchange tubes 1, and a heat dissipation assembly mechanism 2 for assembling and dissipating heat from the nine heat exchange tubes 1 is installed on the heat exchange tubes 1;

the heat dissipation assembly mechanism 2 comprises an installation component 21, two splicing rods 22, a rotary sleeve 23 and a heat dissipation pipe 24, the installation component 21 is installed on the outer side of the heat exchange pipe 1, the splicing rods 22 are installed on the inner side of the installation component 21, one end, far away from the installation component 21, of each splicing rod 22 is connected with the rotary sleeve 23 through threads, and the heat dissipation pipe 24 is fixedly connected to the inner side of the installation component 21.

The installation component 21 mainly comprises a connecting plate 211, a splicing plate A212, a splicing plate B213, a splicing plate C214, a splicing plate D215 and a splicing plate E216, the right end of the connecting plate 211 is fixedly connected with the splicing rod 22, the two splicing rods 22 are arranged on the left side of the connecting plate 211 from top to bottom, the splicing plate A212, the splicing plate B213, the splicing plate C214, the splicing plate D215 and the splicing plate E216 are sequentially and slidably connected outside the splicing rod 22 from left to right, a rotating sleeve 23 is arranged on the right side of the splicing plate E216, a group of heat exchange holes are respectively arranged between the splicing plate A212 and the splicing plate B213 and between the splicing plate C214 and the splicing plate D215, the number of the heat exchange holes is two, the inner sides of the heat exchange holes are in frictional connection with the radiating pipe 24, a group of installation holes are arranged between the connecting plate 211 and the splicing plate A212, between the splicing plate B213 and the splicing plate C214 and between the splicing plate D215 and the splicing plate E216, the number of the mounting holes in each group is three, and the outer side of the mounting component 21 is in friction connection with the inner side wall of the mounting hole.

The connection plate 211, the splice plate a212, the splice plate B213, the splice plate C214, the splice plate D215, and the splice plate E216 are combined to form a square.

Three heat exchange tubes 1 are placed between a connecting plate 211 and a splicing plate A212, three heat exchange tubes 1 are placed between a splicing plate B213 and a splicing plate C214, three heat exchange tubes 1 are placed between a splicing plate D215 and a splicing plate E216, then the splicing plate A212, the splicing plate B213, the splicing plate C214, the splicing plate D215 and the splicing plate E216 are sequentially sleeved on a splicing rod 22, then a turnbuckle 23 is spirally sleeved on the splicing rod 22, then the connecting plate 211, the splicing plate A212, the splicing plate B213, the splicing plate C214, the splicing plate D215 and the splicing plate E216 are clamped and fixed, the heat exchange tubes 1 are used for heat exchange pipelines, heat exchanges heat through an installation component 21, accelerated heat exchange is needed between the heat exchange tubes 1 because of an integrated tube array type, accelerated heat exchange is needed to be carried out on the installation component 21 through cooling liquid flowing through the heat dissipation tubes 24, convenience in assembly is improved, operation is simple, and heat exchange effect of the device is improved, the heat exchange efficiency between the tube bundles is improved.

Example two:

referring to fig. 1 and 3, an integrated tube array heat exchanger according to an embodiment of the present invention includes nine heat exchange tubes 1, and a heat dissipation assembly mechanism 2 for assembling and dissipating heat from the nine heat exchange tubes 1 is installed on the heat exchange tubes 1;

the heat dissipation assembly mechanism 2 comprises an installation component 21, two splicing rods 22, a rotary sleeve 23 and a heat dissipation pipe 24, the installation component 21 is installed on the outer side of the heat exchange pipe 1, the splicing rods 22 are installed on the inner side of the installation component 21, one end, far away from the installation component 21, of each splicing rod 22 is connected with the rotary sleeve 23 through threads, and the heat dissipation pipe 24 is fixedly connected to the inner side of the installation component 21.

Two sets of heat dissipation mechanism 3 that carry out the forced air cooling heat transfer are installed to heat dissipation assembly devices 2 outside, heat dissipation mechanism 3 includes assembly plate 31, fin 32, heat dissipation fan 33, threaded rod 35 and swivel nut 36, 21 outside sliding connection of installation component has assembly plate 31, 31 outside fixedly connected with fins 32 of assembly plate, the heat dissipation fan 33 is passed through bolt fixedly connected with in the fin 32 outside, the equal fixedly connected with threaded rod 35 in assembly plate 31 both ends, threaded rod 35 is the setting of half double-screw bolt form, one of them threaded rod 35 outside cover is equipped with swivel nut 36.

The two groups of heat dissipation mechanisms 3 are arranged in central symmetry.

Each group of heat dissipation mechanisms 3 further comprises two clamping blocks 34, one side of the assembly plate 31 is fixedly connected with the two clamping blocks 34, clamping grooves are formed in the outer sides of the connecting plate 211 and the splicing plate E216, and the clamping blocks 34 are connected with the corresponding clamping grooves in a sliding mode.

Two adjacent threaded rods 35 are combined to be arranged in a threaded rod mode, and the outer sides of the two threaded rods 35 are in threaded connection with the outer sides of the corresponding threaded sleeves 36.

Aim at the draw-in groove of connecting plate 211 and splice plate E216 respectively with two sets of fixture blocks 34 when using, then align two adjacent threaded rod 35 laminating, revolve in the threaded rod 35 outside through swivel nut 36, then with the fixed centre gripping of assembly plate 31 in the outside of installation component 21, heat conduction through assembly plate 31, blow fin 32 through radiator fan 33 and carry out the heat transfer, carry out quick heat transfer to heat exchange pipe 1, the convenience is installed, also conveniently dismantle, and then conveniently clear up and maintain fin 32, and is easy operation.

For the convenience of understanding the technical solution of the present invention, the following detailed description is made on the working principle or the operation mode of the present invention in the practical process.

In practical application, when in use, three heat exchange tubes 1 are placed between a connecting plate 211 and a splicing plate A212, three heat exchange tubes 1 are placed between a splicing plate B213 and a splicing plate C214, three heat exchange tubes 1 are placed between a splicing plate D215 and a splicing plate E216, then the splicing plate A212, the splicing plate B213, the splicing plate C214, the splicing plate D215 and the splicing plate E216 are sequentially sleeved on a splicing rod 22, then a rotary sleeve 23 is spirally sleeved on the splicing rod 22, then the connecting plate 211, the splicing plate A212, the splicing plate B213, the splicing plate C214, the splicing plate D215 and the splicing plate E216 are clamped and fixed, the heat exchange tubes 1 are used for heat exchange of pipelines, heat is exchanged through an installation component 21, accelerated heat exchange needs to be carried out between the heat exchange tubes 1 because of an integrated tube array type, accelerated heat exchange is carried out on the installation component 21 by circulating cooling liquid through the cooling tube 24, convenience in assembly of the device is improved, and operation is simple, and improve the heat transfer effect of the device, improve the heat exchange efficiency between the tube bank, the device aims at the draw-in groove of connecting plate 211 and splice plate E216 respectively with two sets of fixture blocks 34 when using, then align two adjacent threaded rod 35 laminating, through 36 the swivel nut outside of threaded rod 35, then with the fixed centre gripping of equipment board 31 in the outside of installation component 21, heat conduction through equipment board 31, blow fin 32 through cooling fan 33 and carry out the heat transfer, carry out quick heat transfer to heat transfer pipe 1, convenience of assembly, also conveniently dismantle, and then conveniently clear up and maintain fin 32, and is easy to operate.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (7)

1. An integrated shell and tube heat exchanger, characterized in that: the heat exchanger comprises nine heat exchange tubes (1), wherein a heat dissipation assembly mechanism (2) for assembling and dissipating heat of the nine heat exchange tubes (1) is arranged on each heat exchange tube (1);

heat dissipation assembly devices (2) are including installation component (21), two concatenation poles (22), spiral cover (23) and cooling tube (24), install heat exchange tube (1) outside installation component (21), install installation component (21) inboard concatenation pole (22), it keeps away from to splice pole (22) the one end threaded connection of installation component (21) has spiral cover (23), the inboard fixedly connected with of installation component (21) cooling tube (24).

2. An integrated shell and tube heat exchanger according to claim 1, wherein: the mounting assembly (21) mainly comprises a connecting plate (211), a splicing plate A (212), a splicing plate B (213), a splicing plate C (214), a splicing plate D (215) and a splicing plate E (216), the right end of the connecting plate (211) is fixedly connected with the splicing rods (22), the two splicing rods (22) are arranged on the left side of the connecting plate (211) from top to bottom, the outer sides of the splicing rods (22) are sequentially and slidably connected with the surfaces of the splicing plate A (212), the splicing plate B (213), the splicing plate C (214), the splicing plate D (215) and the splicing plate E (216) from left to right, the splicing rods (22) penetrate through the surfaces of the splicing plate A (212), the splicing plate B (213), the splicing plate C (214), the splicing plate D (215) and the splicing plate E (216), and the rotary sleeve (23) is arranged on the right side of the splicing plate E (216), the heat exchange structure is characterized in that a group of heat exchange holes are formed between the splicing plate A (212) and the splicing plate B (213) and between the splicing plate C (214) and the splicing plate D (215), the number of each group of heat exchange holes is two, the inner side of each heat exchange hole is in friction connection with the radiating pipe (24), a group of mounting holes are formed between the connecting plate (211) and the splicing plate A (212), between the splicing plate B (213) and the splicing plate C (214) and between the splicing plate D (215) and the splicing plate E (216), the number of each group of mounting holes is three, and the outer side of the mounting assembly (21) is in friction connection with the inner side wall of each mounting hole.

3. An integrated shell and tube heat exchanger according to claim 2, wherein: the connecting plate (211), the splicing plate A (212), the splicing plate B (213), the splicing plate C (214), the splicing plate D (215) and the splicing plate E (216) are combined to form a square arrangement.

4. An integrated shell and tube heat exchanger according to claim 3, wherein: two sets of heat dissipation mechanisms (3) that carry out the forced air cooling heat transfer are installed in heat dissipation assembly devices (2) outside, heat dissipation mechanism (3) are including equipment board (31), fin (32), heat dissipation fan (33), threaded rod (35) and swivel nut (36), installation component (21) outside sliding connection has equipment board (31), equipment board (31) outside fixedly connected with fin (32), bolt fixedly connected with is passed through in the fin (32) outside heat dissipation fan (33), the equal fixedly connected with in equipment board (31) both ends threaded rod (35), threaded rod (35) are half screw column and set up, one of them threaded rod (35) outside cover is equipped with swivel nut (36).

5. An integrated shell and tube heat exchanger according to claim 4, wherein: the two groups of heat dissipation mechanisms (3) are arranged in a centrosymmetric manner.

6. An integrated shell and tube heat exchanger according to claim 4, wherein: each group of heat dissipation mechanisms (3) further comprises two clamping blocks (34), one side of the assembling plate (31) is fixedly connected with the two clamping blocks (34), clamping grooves are formed in the outer sides of the connecting plate (211) and the splicing plate E (216), and the clamping blocks (34) are connected with the corresponding clamping grooves in a sliding mode.

7. An integrated shell and tube heat exchanger according to claim 4, wherein: two adjacent threaded rods (35) are combined to form a threaded rod assembly, and the outer sides of the two threaded rods (35) are in threaded connection with the outer sides of the corresponding threaded sleeves (36).

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