CN213040826U - Epoxy resin processing water cooling plant - Google Patents

Abstract

The utility model provides an epoxy resin processing procedure water cooling device, which relates to the technical field of epoxy resin production and solves the problem that the linkage work of a plurality of cooling structures can not be realized through the structural improvement so as to improve the cooling effect; the cooling tube is shorter in length in unit area, the outer wall of the cooling tube is mostly smooth, and the heat dissipation area is smaller. A water cooling device for epoxy resin process comprises a barrel body; the barrel body is provided with a first heat dissipation structure, a second heat dissipation structure and a third heat dissipation structure. Through the setting of first heat radiation structure, because of the heat dissipation water pipe is the wavy structure, and be rectangular array form set up flutedly on the heat dissipation water pipe to the heat dissipation water pipe of wavy structure and the recess on the heat dissipation water pipe have constituteed reinforcing formula heat radiation structure jointly, thereby have improved the radiating effect of heat dissipation water pipe.

Description

Epoxy resin processing water cooling plant

Technical Field

The utility model belongs to the technical field of epoxy produces, more specifically says, in particular to epoxy process water cooling plant.

Background

In the existing epoxy resin production process, a cooling system is required to cool the product.

As in application No.: CN201020212142.1, the utility model discloses an epoxy process air cooling device, including fan blade and pivot, still include with the pivot transmission is connected and is used water pressure as drive power's water wheels drive arrangement, and the beneficial effect that adopts this technical scheme is: the utility model provides an epoxy process air cooling device, uses water wheels drive arrangement and adopts the surplus energy of tail water in the production to provide the energy, has saved the acquisition cost and the consumed electric energy of fan motor, and the surplus energy of make full use of production link has again practiced thrift manufacturing cost greatly.

The cooling device for epoxy resin process similar to the above application has the following disadvantages:

one is that the existing device can not realize the linkage work of a plurality of cooling structures through the structural improvement in the cooling process so as to improve the cooling effect; moreover, the cooling pipe of the existing device is short in unit area, the outer wall of the cooling pipe is mostly smooth, the heat dissipation area is small, and the overall cooling effect is affected.

Therefore, in view of the above, research and improvement are made on the existing structure and defects, and an epoxy resin process water cooling device is provided to achieve the purpose of higher practical value.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides an epoxy resin processing procedure water cooling device, which solves the problem that the existing device can not realize linkage work of a plurality of cooling structures through structural improvement during the cooling process so as to improve the cooling effect; moreover, the cooling pipe of the existing device has shorter length in unit area, and the outer wall of the cooling pipe is mostly smooth, so that the heat dissipation area is smaller, and the whole cooling effect is influenced.

The utility model relates to an epoxy resin processing procedure water cooling plant's purpose and efficiency are reached by following concrete technological means:

a water cooling device for epoxy resin process comprises a barrel body; the first heat dissipation structure is mounted on the barrel body, the second heat dissipation structure is further mounted on the barrel body, and the third heat dissipation structure is further mounted on the barrel body; a fourth heat dissipation structure is mounted on the barrel body; the third heat dissipation structure comprises a gear B, the gear B is arranged on the rotating shaft B, the gear B is meshed with the gear A, and the rotating shaft B is in a rotating state when the rotating shaft A rotates; the second heat radiation structure comprises a poking block, the poking block is installed on the rotating shaft A, and the telescopic bottle is in a continuous extrusion state when the poking block rotates along with the rotating shaft A.

Further, the first heat dissipation structure comprises a water pump, a heat dissipation water pipe and a groove, the water pump is fixed in the barrel, and the heat dissipation water pipe is fixedly connected to the water pump; the heat dissipation water pipe is of a wavy structure, the heat dissipation water pipe is provided with grooves in a rectangular array shape, and the heat dissipation water pipe of the wavy structure and the grooves in the heat dissipation water pipe jointly form an enhanced heat dissipation structure.

Further, the second heat dissipation structure comprises a rotating shaft A, blades A, a driving motor and a gear A, wherein the rotating shaft A is rotatably connected to the barrel body, the gear A is mounted on the rotating shaft A, and the rotating shaft A is also connected with a rotating shaft of the driving motor; the blade A is installed to be the rectangle array form on the pivot A, and is the stirring state when pivot A rotates the liquid in the barrel.

Furthermore, the third heat dissipation structure comprises a rotating connecting seat, a rotating shaft B and a blade B, wherein the rotating connecting seat is welded on the rotating connecting seat, and the rotating connecting seat is rotatably connected with the rotating shaft B; the rotating shaft B is provided with the blades B in a rectangular array shape, the third heat dissipation structure is located above the heat dissipation water pipe, and the heat dissipation water pipe is in a heat dissipation state when the rotating shaft B rotates.

Furthermore, the fourth heat dissipation structure comprises a telescopic bottle, a water inlet pipe, a connecting pipe and a spray pipe, wherein the telescopic bottle is fixed on the barrel body, the water inlet pipe is connected to the telescopic bottle, and the water inlet pipe is connected to the barrel body; the telescopic bottle is further connected with a connecting pipe, the connecting pipe is connected with a spray pipe, and the spray pipe is provided with spray holes.

Furthermore, all install a check valve in inlet tube and the connecting tube, and the check valve in the inlet tube is the check valve in the closed condition connecting tube and is the open mode when flexible bottle is extruded to when flexible bottle elasticity resets, the check valve in the inlet tube is the check valve in the open condition connecting tube and is the closed mode.

Compared with the prior art, the utility model discloses following beneficial effect has:

through the matching arrangement of the second heat dissipation structure, the third heat dissipation structure and the fourth heat dissipation structure, firstly, the rotating shaft A is rotatably connected to the barrel body, the gear A is arranged on the rotating shaft A, and the rotating shaft A is also connected with a rotating shaft of the driving motor; the blades A are arranged on the rotating shaft A in a rectangular array shape, and when the rotating shaft A rotates, liquid in the barrel is in a stirring state, so that accelerated heat dissipation is realized; secondly, a rotating connecting seat is welded on the rotating connecting seat, and a rotating shaft B is rotatably connected on the rotating connecting seat; the rotating shaft B is provided with blades B in a rectangular array shape, the third heat dissipation structure is positioned above the heat dissipation water pipe, and the heat dissipation water pipe is in a heat dissipation state when the rotating shaft B rotates; thirdly, because the gear B is arranged on the rotating shaft B, the gear B is meshed with the gear A, and the rotating shaft B is in a rotating state when the rotating shaft A rotates, the liquid can be stirred and the heat can be dissipated, and simultaneously, the wind power heat dissipation can be realized; fourthly, because the water inlet pipe and the connecting pipe are both provided with a one-way valve, when the telescopic bottle is extruded, the one-way valve in the water inlet pipe is in a closed state, the one-way valve in the connecting pipe is in an open state, and when the telescopic bottle is elastically reset, the one-way valve in the water inlet pipe is in an open state, and the one-way valve in the connecting pipe is in a closed state; fifthly, because of setting aside the piece and installing on pivot A, and the flexible bottle is continuous extrusion state when setting aside the piece and rotate along with pivot A to the continuous water spray heat dissipation of fourth heat radiation structure has been realized.

Through the setting of first heat radiation structure, because of the heat dissipation water pipe is the wavy structure, and be rectangular array form set up flutedly on the heat dissipation water pipe to the heat dissipation water pipe of wavy structure and the recess on the heat dissipation water pipe have constituteed reinforcing formula heat radiation structure jointly, thereby have improved the radiating effect of heat dissipation water pipe.

Drawings

Fig. 1 is the axial view structure diagram of the barrel body of the present invention after being cut open.

Fig. 2 is an enlarged schematic view of the structure of fig. 1 a according to the present invention.

Fig. 3 is a rear view of the present invention shown in fig. 1.

Fig. 4 is the schematic view of the axial view structure after the barrel body is removed.

Fig. 5 is an enlarged schematic axial view of a fourth heat dissipation structure of the present invention.

In the drawings, the corresponding relationship between the component names and the reference numbers is as follows:

1. a barrel body; 2. a first heat dissipation structure; 201. a water pump; 202. a heat dissipation water pipe; 20201. a groove; 3. a second heat dissipation structure; 301. a rotating shaft A; 302. a blade A; 303. a drive motor; 304. a gear A; 305. a shifting block; 4. a third heat dissipation structure; 401. rotating the connecting seat; 402. a rotating shaft B; 403. a blade B; 404. a gear B; 5. a fourth heat-dissipating structure; 501. a telescopic bottle; 502. a water inlet pipe; 503. a connecting pipe; 504. and (4) a spray pipe.

Detailed Description

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are merely for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example (b):

as shown in figures 1 to 5:

the utility model provides an epoxy resin process water cooling device, which comprises a barrel body 1; the barrel body 1 is provided with a first heat dissipation structure 2, the barrel body 1 is also provided with a second heat dissipation structure 3, and the barrel body 1 is also provided with a third heat dissipation structure 4; a fourth heat dissipation structure 5 is arranged on the barrel body 1; referring to fig. 1, the third heat dissipation structure 4 includes a gear B404, the gear B404 is mounted on a rotating shaft B402, the gear B404 is meshed with the gear a304, and the rotating shaft B402 is in a rotating state when the rotating shaft a301 rotates, so that heat dissipation by wind power can be realized while heat dissipation by liquid stirring is realized; referring to fig. 1, the second heat dissipation structure 3 includes a dial block 305, the dial block 305 is installed on the rotating shaft a301, and the telescopic bottle 501 is in a continuous squeezing state when the dial block 305 rotates along with the rotating shaft a301, so as to achieve continuous water spraying heat dissipation of the fourth heat dissipation structure 5.

Referring to fig. 1 and 2, the first heat dissipation structure 2 includes a water pump 201, a heat dissipation water pipe 202 and a groove 20201, the water pump 201 is fixed in the tub 1, and the heat dissipation water pipe 202 is fixedly connected to the water pump 201; the heat dissipation water pipe 202 is of a wavy structure, the heat dissipation water pipe 202 is provided with grooves 20201 in a rectangular array shape, and the heat dissipation water pipe 202 of the wavy structure and the grooves 20201 on the heat dissipation water pipe 202 jointly form an enhanced heat dissipation structure, so that the heat dissipation effect of the heat dissipation water pipe 202 is improved.

Referring to fig. 1, the second heat dissipation structure 3 includes a rotation shaft a301, a blade a302, a driving motor 303 and a gear a304, the rotation shaft a301 is rotatably connected to the tub 1, the gear a304 is mounted on the rotation shaft a301, and the rotation shaft a301 is further connected to a rotation shaft of the driving motor 303; blades A302 are arranged on the rotating shaft A301 in a rectangular array shape, and when the rotating shaft A301 rotates, liquid in the barrel body 1 is in a stirring state, so that accelerated heat dissipation is realized.

Referring to fig. 1, the third heat dissipation structure 4 includes a rotation connection seat 401, a rotation shaft B402 and a blade B403, the rotation connection seat 401 is welded on the rotation connection seat 401, and the rotation shaft B402 is rotatably connected on the rotation connection seat 401; the blades B403 are mounted on the rotating shaft B402 in a rectangular array, and the third heat dissipation structure 4 is located above the heat dissipation water pipe 202, and when the rotating shaft B402 rotates, the heat dissipation water pipe 202 is in a heat dissipation state.

Referring to fig. 1, the fourth heat dissipation structure 5 includes a telescopic bottle 501, a water inlet pipe 502, a connection pipe 503, and a nozzle 504, the telescopic bottle 501 is fixed on the tub 1, the water inlet pipe 502 is connected to the telescopic bottle 501, and the water inlet pipe 502 is connected to the tub 1; the telescopic bottle 501 is further connected with a connecting pipe 503, the connecting pipe 503 is connected with a spray pipe 504, and the spray pipe 504 is provided with spray holes.

Referring to fig. 5, a check valve is installed in each of the inlet tube 502 and the connection tube 503, and the check valve in the inlet tube 502 is in a closed state when the collapsible bottle 501 is squeezed and the check valve in the connection tube 503 is in an open state, and the check valve in the inlet tube 502 is in an open state when the collapsible bottle 501 is elastically restored and the check valve in the connection tube 503 is in a closed state.

The specific use mode and function of the embodiment are as follows:

when the electric bucket is used, when the driving motor 303 rotates, firstly, the rotating shaft A301 is connected to the bucket body 1 in a rotating mode, the gear A304 is installed on the rotating shaft A301, and the rotating shaft A301 is also connected with the rotating shaft of the driving motor 303; the blades A302 are arranged on the rotating shaft A301 in a rectangular array shape, and when the rotating shaft A301 rotates, liquid in the barrel body 1 is in a stirring state, so that accelerated heat dissipation is realized; secondly, the rotating connecting seat 401 is welded on the rotating connecting seat 401, and the rotating connecting seat 401 is rotatably connected with a rotating shaft B402; the rotating shaft B402 is provided with the blades B403 in a rectangular array, the third heat dissipation structure 4 is located above the heat dissipation water pipe 202, and the heat dissipation water pipe 202 is in a heat dissipation state when the rotating shaft B402 rotates; thirdly, because the gear B404 is arranged on the rotating shaft B402, the gear B404 is meshed with the gear A304, and the rotating shaft B402 is in a rotating state when the rotating shaft A301 rotates, the liquid stirring heat dissipation can be realized, and the wind power heat dissipation can also be realized; fourthly, because the water inlet pipe 502 and the connecting pipe 503 are both provided with a one-way valve, when the telescopic bottle 501 is squeezed, the one-way valve in the water inlet pipe 502 is in a closed state, the one-way valve in the connecting pipe 503 is in an open state, and when the telescopic bottle 501 elastically resets, the one-way valve in the water inlet pipe 502 is in an open state, the one-way valve in the connecting pipe 503 is in a closed state; fifthly, because the dial block 305 is installed on the rotating shaft a301, and when the dial block 305 rotates along with the rotating shaft a301, the telescopic bottle 501 is in a continuous extrusion state, thereby realizing continuous water spraying heat dissipation of the fourth heat dissipation structure 5.

The embodiments of the present invention have been presented for purposes of illustration and description, and are not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiments with various modifications as are suited to the particular use contemplated.

Claims (6)

1. An epoxy resin processing water cooling device is characterized in that: comprises a barrel body (1); the barrel body (1) is provided with a first heat dissipation structure (2), the barrel body (1) is also provided with a second heat dissipation structure (3), and the barrel body (1) is also provided with a third heat dissipation structure (4); a fourth heat dissipation structure (5) is mounted on the barrel body (1); the third heat dissipation structure (4) comprises a gear B (404), the gear B (404) is installed on a rotating shaft B (402), the gear B (404) is meshed with the gear A (304), and the rotating shaft B (402) is in a rotating state when the rotating shaft A (301) rotates; second heat radiation structure (3) are including dialling movable block (305), dial movable block (305) and install on pivot A (301), and when dialling movable block (305) and follow pivot A (301) and rotate flexible bottle (501) and be continuous extrusion state.

2. The epoxy resin process water cooling device as claimed in claim 1, wherein: the first heat dissipation structure (2) comprises a water pump (201), a heat dissipation water pipe (202) and a groove (20201), the water pump (201) is fixed in the barrel body (1), and the heat dissipation water pipe (202) is fixedly connected to the water pump (201); the heat dissipation water pipe (202) is of a wavy structure, the grooves (20201) are formed in the heat dissipation water pipe (202) in a rectangular array mode, and the heat dissipation water pipe (202) of the wavy structure and the grooves (20201) in the heat dissipation water pipe (202) jointly form an enhanced heat dissipation structure.

3. The epoxy resin process water cooling device as claimed in claim 1, wherein: the second heat dissipation structure (3) comprises a rotating shaft A (301), blades A (302), a driving motor (303) and a gear A (304), the rotating shaft A (301) is rotatably connected to the barrel body (1), the gear A (304) is mounted on the rotating shaft A (301), and the rotating shaft A (301) is further connected with a rotating shaft of the driving motor (303); blades A (302) are installed on the rotating shaft A (301) in a rectangular array shape, and when the rotating shaft A (301) rotates, liquid in the barrel body (1) is in a stirring state.

4. The epoxy resin process water cooling device as claimed in claim 1, wherein: the third heat dissipation structure (4) comprises a rotary connecting seat (401), a rotating shaft B (402) and a blade B (403), the rotary connecting seat (401) is welded on the rotary connecting seat (401), and the rotating shaft B (402) is rotatably connected on the rotary connecting seat (401); blades B (403) are installed on the rotating shaft B (402) in a rectangular array mode, the third heat dissipation structure (4) is located above the heat dissipation water pipe (202), and the heat dissipation water pipe (202) is in a heat dissipation state when the rotating shaft B (402) rotates.

5. The epoxy resin process water cooling device as claimed in claim 1, wherein: the fourth heat dissipation structure (5) comprises a telescopic bottle (501), a water inlet pipe (502), a connecting pipe (503) and a spray pipe (504), the telescopic bottle (501) is fixed on the barrel body (1), the water inlet pipe (502) is connected to the telescopic bottle (501), and the water inlet pipe (502) is connected to the barrel body (1); the telescopic bottle (501) is further connected with a connecting pipe (503), the connecting pipe (503) is connected with a spray pipe (504), and the spray pipe (504) is provided with spray holes.

6. The epoxy resin process water cooling device as claimed in claim 5, wherein: all install a check valve in inlet tube (502) and connecting pipe (503), and the check valve in inlet tube (502) is the check valve in closed condition connecting pipe (503) and is the open mode when telescopic bottle (501) is extruded to when telescopic bottle (501) elasticity resets, and the check valve in inlet tube (502) is the check valve in the open condition connecting pipe (503) and is the closed mode when telescopic bottle (501) elasticity resets.

Images