CN213147472U - Low-energy consumption heat transfer device for fine chemical engineering - Google Patents

Abstract

The utility model discloses a low energy consumption is in heat transfer device of meticulous chemical industry, including first splint, the right side of first splint is equipped with the second splint, the equal rigid coupling in inboard of first splint and second splint has the rubber pad. This low energy consumption is in heat transfer device of fine chemistry industry, can make couple and link separation, can be quick with first splint and second splint and the board quick separation that generates heat, be convenient for maintain, the heat transfer device that has solved current low energy consumption and has been used for fine chemistry industry to adopt the bolt and so on more installs on the source that generates heat, and the problem of the maintenance of being not convenient for dismantle or change, in passing through the import drainage inlet pipe with external comdenstion water, the comdenstion water is forming the heat conduction that the board produced that generates heat through the export discharge and is away, and the power consumption is low.

Description

Low-energy consumption heat transfer device for fine chemical engineering

Technical Field

The utility model relates to a fine chemistry industry technical field specifically is a low energy consumption in fine chemistry industry's heat transfer device.

Background

The fine chemistry industry is the intensive industry of technique that the comprehensiveness is stronger, at first, the technological process is long in the production process, the unit reaction is many, the raw materials is complicated, middle process control requires rigorously, and the application relates to many fields, the theoretical knowledge and the professional skill of multidisciplinary, fine chemistry industry both need conduct heat to the source that generates heat, must guarantee the characteristics that the power consumption is low that transfer heat still, but current low energy consumption is used for the heat transfer unit of fine chemistry industry to adopt the heat transfer unit of bolt class to install on the source that generates heat, and be not convenient for dismantle the problem of maintenance or change, the heat transfer unit that has the current low energy consumption to be used for fine chemistry simultaneously, mostly be integrative structure, can have a large amount of incrustations in the circulating pipe after long-time.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a low energy consumption is in heat transfer device of fine chemistry industry to solve the current low energy consumption that provides in the above-mentioned background art and be used for heat transfer device of fine chemistry industry to adopt the bolt and so on more to install on the source that generates heat, and the problem of the maintenance of being not convenient for dismantle or change.

In order to achieve the above object, the utility model provides a following technical scheme: a heat transfer device with low energy consumption in fine chemical engineering comprises a first clamping plate, wherein a second clamping plate is arranged on the right side of the first clamping plate, rubber pads are fixedly connected to the inner sides of the first clamping plate and the second clamping plate, the inner sides of the rubber pads are attached to the outer walls of two sides of a heating plate, and mounting mechanisms are mounted at four corners of the first clamping plate;

the mounting mechanism comprises a hook, a hanging ring, a shell, a first spring, a top block, a pin shaft and a bracket;

the right side arc internal surface of couple laminates with the middle outer wall of link mutually, the rear end rigid coupling of link is at the top left side front end of second splint, the left side outer wall of couple all with the right side inner chamber of casing and the middle inner wall clearance fit of first spring, the left end rigid coupling of couple has the kicking block, the right-hand member of kicking block laminates with the left end of first spring mutually, the right-hand member of first spring laminates with the right-hand member inner wall of casing mutually, the casing rotates with the support through the round pin axle and links to each other, the rear end rigid coupling of support is at the top left side front end of first splint.

Preferably, a heat transfer mechanism is arranged in the middle front end of the first clamping plate;

the heat transfer mechanism comprises a water pipe, an inlet, an outlet, a rubber block, a first groove and a support rod;

the below left end intercommunication of water pipe has the import, the top right side intercommunication of water pipe has the export, the both sides outer wall of water pipe all laminates with the interior side surface of block rubber mutually, the outside rigid coupling of block rubber is on the outside surface of first recess, inner wall in the middle of the below at the bracing piece is seted up to first recess, the top rigid coupling of bracing piece is on the top left side bottom surface of first splint.

Preferably, the rubber block, the first groove and the support rod are arranged above the water pipe at equal intervals.

Preferably, the outer walls of the inlet and the outlet are both provided with a fixing mechanism;

the fixing mechanism comprises a clamping block, a sliding groove, a sliding plate, a second spring and a second groove;

two the inboard surface of clamp splice all laminates with the outer wall of export mutually, the equal rigid coupling in outside rear end of clamp splice has the slider, the slider all with spout slip joint, the spout is all seted up at the middle front end inner wall of slide, the equal rigid coupling in the outside of slider has the second spring, the equal rigid coupling in the outside surface of spout in the outside of second spring, the equal rigid coupling in the outside surface of second recess in the outside of slide, the top right side inner wall at first splint is seted up to the second recess.

Preferably, the sliding block and the sliding groove form a sliding structure.

Preferably, the clamping blocks are symmetrically distributed in the upper side and the lower side by taking the center line of the outlet as the center.

Compared with the prior art, the beneficial effects of the utility model are that: compared with the traditional technology, the heat transfer device with low energy consumption in fine chemical engineering has the following advantages:

through first splint, the second splint, the rubber pad, generate heat the board, the couple, the link, a housing, first spring, the kicking block, the cooperation between round pin axle and the support, successively drag the couple in four corners, the couple drives the kicking block and makes first spring compression to right side removal in the casing, the casing rotates on the support through the round pin axle, can make couple and link separation, can be quick with first splint and second splint with generate heat board quickly separating, be convenient for maintain, the heat transfer device who has solved current low energy consumption and is used for fine chemical industry adopts the bolt and so on more installs on the source that generates heat, and be not convenient for dismantle the problem of maintenance or change.

Through the cooperation between the first clamping plate, the second clamping plate, the heating plate, the water pipe, the inlet, the outlet, the rubber block, the first groove, the supporting rods, the clamping blocks, the sliding block, the sliding plate, the second spring and the second groove, outside condensed water is discharged into the water pipe through the inlet, the condensed water is discharged through the outlet to form water circulation to conduct away heat generated by the heating plate, the energy consumption is low, the clamping blocks on the two sides of the inlet and the outlet are dragged in sequence, the clamping blocks slide outwards in the sliding grooves on the sliding plates on the two sides through the sliding block to compress the second springs on the two sides, the two clamping blocks are separated from the inlet and the outlet respectively at the moment, the water pipe is lifted upwards, the water pipe can be quickly separated from the rubber blocks in the first grooves on the six supporting rods, the water pipe is disassembled and cleaned, the existing heat transfer device for fine chemical engineering with low energy consumption is solved, most of the integral structure, a large amount of scale, inconvenient cleaning.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the water pipe, inlet and outlet of FIG. 1;

FIG. 3 is a schematic structural view of the water pipe, the rubber block and the support rod in FIG. 1;

FIG. 4 is a schematic view of the outlet, clamp block and second groove of FIG. 1;

fig. 5 is a schematic structural view of the hook, the housing and the first spring in fig. 1.

In the figure: 1. the heat-insulation board comprises a first clamping plate, 2, a second clamping plate, 3, a rubber pad, 4, a mounting device, 401, a hook, 402, a hanging ring, 403, a shell, 404, a first spring, 405, a top block, 406, a pin shaft, 407, a support, 5, a heat transfer mechanism, 501, a water pipe, 502, an inlet, 503, an outlet, 504, a rubber block, 505, a first groove, 506, a supporting rod, 6, a fixing mechanism, 601, a clamping block, 602, a sliding block, 603, a sliding groove, 604, a sliding plate, 605, a second spring, 606, a second groove, 7 and a heating plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying 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.

Referring to fig. 1-5, the present invention provides a technical solution: a heat transfer device with low energy consumption in fine chemical engineering comprises a first clamping plate 1, a second clamping plate 2 is arranged on the right side of the first clamping plate 1, rubber pads 3 are fixedly connected to the inner sides of the first clamping plate 1 and the second clamping plate 2, the inner sides of the rubber pads 3 are attached to the outer walls of two sides of a heating plate 7, the rubber pads 3 seal gaps between the first clamping plate 1 and the heating plate 7 and between the second clamping plate 2 and the heating plate 7, the heating plate 7 is external fine chemical engineering heating equipment, the rubber pads 3 are made of fluororubber, mounting mechanisms 4 are mounted at four corners of the first clamping plate 1, each mounting mechanism 4 comprises a hook 401, a hanging ring 402, a shell 403, a first spring 404, a top block 405, a pin 406 and a support 407, the arc-shaped inner surface on the right side of the hook 401 is attached to the outer wall in the middle of the hanging ring 402, the hooks 401 at the four corners are hung on the hanging rings 402, so that the first clamping plate 1, the rear end of the hanging ring 402 is fixedly connected with the front end of the left side above the second clamping plate 2, the second clamping plate 2 supports the first hanging ring 402, the outer wall of the left side of the hook 401 is in clearance fit with the inner cavity of the right side of the shell 403 and the inner wall of the middle of the first spring 404, the hook 401 moves left and right in the shell 403 and the first spring 404, the left end of the hook 401 is fixedly connected with a top block 405, the right end of the top block 405 is attached to the left end of the first spring 404, the hook 401 drives the top block 405 to move to the right side in the shell 403 to compress the first spring 404, the hook 401 is hung on the hanging ring 402, the hook 401 is reset through the elasticity of the first spring 404 to enable the first clamping plate 1 and the second clamping plate 2 to be installed on the heating plate 7, otherwise, the hook 401 is taken down to enable the first clamping plate 1 and the second clamping plate 2 to be quickly separated from the heating plate 7 and detached, the right end of the first spring 404 is attached to the inner wall, the housing 403 is rotatably connected to the bracket 407 by a pin 406, the housing 403 is rotated on the bracket 407 by a pin 406, the rear end of the bracket 407 is fixedly connected to the front end of the left side above the first clamping plate 1, and the first clamping plate 1 supports the four brackets 407.

The heat transfer mechanism 5 is arranged in the front end of the middle of the first clamping plate 1, the heat transfer mechanism 5 comprises a water pipe 501, an inlet 502, an outlet 503, a rubber block 504, a first groove 505 and a supporting rod 506, the left end of the lower part of the water pipe 501 is communicated with the inlet 502, outside condensed water enters the water pipe 501 through the inlet 502, the right side of the upper part of the water pipe 501 is communicated with the outlet 503, the condensed water after heat transfer in the water pipe 501 is discharged from the outlet 503 to form water circulation for heat transfer, the water pipe 501 is made of copper, the outer walls of the two sides of the water pipe 501 are both attached to the inner side surface of the rubber block 504, the outer side of the rubber block 504 is fixedly connected to the outer side surface of the first groove 505, the first groove 505 is arranged on the inner wall of the middle of the lower part of the supporting rod 506, the two sides of the water pipe 501 are fixed in the rubber block 504 on the first groove 505 of the three supporting rods 506 on, the top end of the supporting rod 506 is fixedly connected to the bottom end surface of the left side above the first clamping plate 1, the first clamping plate 1 supports the three supporting rods 506 on the two sides, the water pipe 501 is also installed in the second clamping plate 2, and the rubber block 504, the first groove 505 and the supporting rod 506 are equidistantly arranged above the water pipe 501 to fix and stabilize the water pipe 501.

The outer walls of the inlet 502 and the outlet 503 are respectively provided with a fixing mechanism 6, the fixing mechanism 6 comprises clamping blocks 601, a sliding block 602, a sliding groove 603, a sliding plate 604, a second spring 605 and a second groove 606, the inner side surfaces of the two clamping blocks 601 are respectively attached to the outer wall of the outlet 503, the two clamping blocks 601 fix the outlet 503, the inlet 502 is fixed by the same method, so as to fix the water pipe 501, the sliding blocks 602 are fixedly connected to the rear ends of the outer sides of the clamping blocks 601, the sliding blocks 602 are respectively in sliding clamping connection with the sliding grooves 603, the sliding grooves 603 are respectively arranged on the inner wall of the front end of the middle of the sliding plate 604, the second spring 605 is fixedly connected to the outer sides of the sliding blocks 602, the clamping blocks 601 at the two sides slide to the inner sides in the sliding grooves 603 on the sliding plates 604 at the two sides through the sliding blocks 602 to compress the second springs 605 at the two sides, otherwise, the clamping blocks 601 are reset through the elasticity of the second springs 605, the outer sides of the second springs 605 are fixedly connected to the outer side surface of the sliding groove 603, the sliding groove 603 supports the second springs 605, the outer sides of the sliding plates 604 are fixedly connected to the outer side surface of the second groove 606, the second groove 606 is formed in the inner wall of the right side above the first clamping plate 1, the second groove 606 in the first clamping plate 1 supports the two sliding plates 604, the sliding blocks 602 and the sliding grooves 603 form a sliding structure, the sliding blocks 602 slide up and down in the sliding groove 603, and the clamping blocks 601 are symmetrically distributed up and down by taking the center line of the outlet 503 as the center, so that the outlet 503 is fixed stably.

When the heat transfer device with low energy consumption in fine chemistry industry is used, firstly, outside condensed water is manually discharged into a water inlet pipe 501 through an inlet 502, the condensed water is discharged through an outlet 503 to form water circulation to conduct away heat generated by a heating plate 7, hooks 401 at four corners are manually dragged in sequence, the hooks 401 drive a top block 405 to move towards the right side in a shell 403 to compress a first spring 404, the shell 403 rotates on a support 407 through a pin shaft 406, the hooks 401 and a hanging ring 402 can be separated, a first clamping plate 1 and a second clamping plate 2 can be rapidly separated from the heating plate 7, clamping blocks 601 at two sides of the inlet 502 and the outlet 503 are manually dragged in sequence, the clamping blocks 601 all slide towards the outer side in sliding grooves 603 on sliding plates 604 at two sides through sliding blocks 602 to compress second springs 605 at two sides, at the moment, the two clamping blocks 601 respectively leave the inlet 502 and the outlet 503, the water pipe 501 is lifted upwards, and the water pipe 501 can be rapidly separated from rubber blocks 503 in first grooves 505 on six supporting rods 506, the water pipe 501 is disassembled and cleaned, and the water pipe 501 on the second clamping plate 2 is disassembled in the same way.

In the description of the present invention, it is to be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "one side", "top", "inner", "front", "center", "both ends", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "disposed," "connected," "fixed," "screwed" and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate medium, and may be connected through the inside of two elements or in an interaction relationship between two elements, unless otherwise specifically defined, and the specific meaning of the above terms in the present invention will be understood by those skilled in the art according to specific situations.

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

Claims (6)

1. A heat transfer device for fine chemicals with low energy consumption, comprising a first clamping plate (1), characterized in that: a second clamping plate (2) is arranged on the right side of the first clamping plate (1), rubber pads (3) are fixedly connected to the inner sides of the first clamping plate (1) and the second clamping plate (2), the inner sides of the rubber pads (3) are attached to the outer walls of the two sides of the heating plate (7), and mounting mechanisms (4) are mounted at four corners of the first clamping plate (1);

the mounting mechanism (4) comprises a hook (401), a hanging ring (402), a shell (403), a first spring (404), a top block (405), a pin shaft (406) and a bracket (407);

couple (401) right side arc internal surface and the laminating of the middle outer wall of link (402), the rear end of link (402) is solid in the top left side front end of second splint (2), the left side outer wall of couple (401) all with the right side inner chamber of casing (403) and the middle inner wall clearance fit of first spring (404), the left end of couple (401) is solid has kicking block (405), the right-hand member of kicking block (405) and the left end of first spring (404) are laminated mutually, the right-hand member of first spring (404) and the right-hand member inner wall of casing (403) are laminated mutually, casing (403) rotate with support (407) through round pin axle (406) and link to each other, the rear end of support (407) is solid in the top left side front end of first splint (1).

2. A low energy consumption fine chemical heat transfer apparatus as claimed in claim 1, wherein: a heat transfer mechanism (5) is arranged in the front end of the middle of the first clamping plate (1);

the heat transfer mechanism (5) comprises a water pipe (501), an inlet (502), an outlet (503), a rubber block (504), a first groove (505) and a support rod (506);

the below left end intercommunication of water pipe (501) has import (502), the top right side intercommunication of water pipe (501) has export (503), the both sides outer wall of water pipe (501) all laminates with the interior side surface of block rubber (504), the outside rigid coupling of block rubber (504) is on the outside surface of first recess (505), inner wall in the middle of the below at bracing piece (506) is seted up in first recess (505), the top rigid coupling of bracing piece (506) is at the top left side bottom surface of first splint (1).

3. A low energy consumption fine chemical heat transfer apparatus as claimed in claim 2, wherein: the rubber block (504), the first groove (505) and the supporting rod (506) are arranged above the water pipe (501) at equal intervals.

4. A low energy consumption fine chemical heat transfer apparatus as claimed in claim 2, wherein: the outer walls of the inlet (502) and the outlet (503) are both provided with a fixing mechanism (6);

the fixing mechanism (6) comprises a clamping block (601), a sliding block (602), a sliding groove (603), a sliding plate (604), a second spring (605) and a second groove (606);

two the inboard surface of clamp splice (601) all laminates with the outer wall of export (503), the equal rigid coupling in outside rear end of clamp splice (601) has slider (602), slider (602) all with spout (603) slip joint, the middle front end inner wall at slide (604) is all seted up in spout (603), the equal rigid coupling in the outside of slider (602) has second spring (605), the equal rigid coupling in the outside surface of spout (603) in the outside of second spring (605), the equal rigid coupling in the outside surface of second recess (606) in the outside of slide (604), the top right side inner wall at first splint (1) is seted up in second recess (606).

5. The heat transfer device for low energy consumption in fine chemical engineering according to claim 4, wherein: the sliding block (602) and the sliding groove (603) form a sliding structure.

6. The heat transfer device for low energy consumption in fine chemical engineering according to claim 4, wherein: the clamping blocks (601) are symmetrically distributed up and down by taking the center line of the outlet (503) as the center.

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