CN214792659U

CN214792659U - Novel energy-saving cooling equipment

Info

Publication number: CN214792659U
Application number: CN202121069481.3U
Authority: CN
Inventors: 董晓敏; 李峰; 李晓岳
Original assignee: Shandong Kaidesheng Energy Saving Technology Co ltd
Current assignee: Shandong Kaidesheng Energy Saving Technology Co ltd
Priority date: 2021-05-19
Filing date: 2021-05-19
Publication date: 2021-11-19
Anticipated expiration: 2031-05-19

Abstract

The utility model discloses a novel energy-saving cooling device, which comprises a vertical beam frame, a fastening frame, a cooling box, a feeding port, a scattering component, a cooling component, a discharging barrel and a storage component, wherein the fastening frame is fixedly installed on one side of the top end surface of the vertical beam frame, the cooling box is fixedly installed in the center of the end surface of the fastening frame, the feeding port is fixedly installed in the center of the top end surface of the cooling box, the scattering component is fixedly installed on the top inside of the cooling box, the cooling component is fixedly installed in the center inside of the cooling box, the discharging barrel is connected and installed on the bottom end surface of the cooling box, and the storage component is fixedly installed on one side of the bottom end surface of the vertical beam frame; the novel energy-saving cooling equipment is simple in structure and stable in support; when the device is used, high-temperature powder can be subjected to heat exchange and cooling, and the materials are scattered and crushed, so that the materials are effectively prevented from being blocked; meanwhile, the material after thinning is cooled, so that the cooling contact area can be increased, the cooling effect is good, and the cooling efficiency is higher.

Description

Novel energy-saving cooling equipment

Technical Field

The utility model relates to a novel energy-conserving refrigeration plant field specifically is a novel energy-conserving refrigeration plant.

Background

When the powder is processed, the high-temperature powder needs to be cooled by novel energy-saving cooling equipment; in the cooling process, novel energy-saving cooling equipment is required to be used; the novel energy-saving cooling equipment in the prior art is complex in structure, blocks of materials are easy to block during cooling, so that the cooling speed of the materials is influenced, and meanwhile, the contact area of the materials is low, and the cooling efficiency is low; therefore, it is necessary to design a new energy-saving cooling device.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a novel energy-saving cooling device which has simple structure and stable support; when the device is used, high-temperature powder can be subjected to heat exchange and cooling, and the materials are scattered and crushed, so that the materials are effectively prevented from being blocked; meanwhile, the material after thinning is cooled, so that the cooling contact area can be increased, the cooling effect is good, and the cooling efficiency is higher.

The purpose of the utility model can be realized by the following technical scheme:

a novel energy-saving cooling device comprises a vertical beam frame, a fastening frame, a cooling box, a feeding port, a scattering assembly, a cooling assembly, a feeding barrel and a storage assembly, wherein the fastening frame is fixedly installed on one side of the top end face of the vertical beam frame, the cooling box is fixedly installed in the center of the end face of the fastening frame, the feeding port is fixedly installed in the center of the top end face of the cooling box, the scattering assembly is fixedly installed on the top inside of the cooling box, the cooling assembly is fixedly installed in the center inside of the cooling box, the feeding barrel is connected and installed on the bottom end face of the cooling box, the storage assembly is fixedly installed on one side of the bottom end face of the vertical beam frame, and the storage assembly is located right below the bottom end face of the feeding barrel;

the cooling component comprises a cooling clapboard, a heat conducting plate, a cooling tank, a first pipe seat, a second pipe seat, a cooling pipe, a liquid inlet pipe and a liquid outlet pipe, a plurality of cooling clapboards are respectively and fixedly arranged at the center of the inner part of the cooling box, the inner end surface of the cooling clapboard is provided with a cooling groove, the top of one side of the cooling clapboard is fixedly provided with a first pipe seat, a second pipe seat is fixedly arranged at the bottom of one side of the cooling partition plate, cooling pipes are inserted and arranged in the centers of the end surfaces of the first pipe seat and the second pipe seat, the interior of the cooling pipe passes through the first pipe seat and the second pipe seat to be communicated with the cooling tank, one side of the bottom of the end surface of the cooling tank is inserted with a liquid inlet pipe, and one end of the liquid inlet pipe penetrates through the cooling box and is communicated with the plurality of cooling pipes on one side of the first pipe seat, a liquid outlet pipe is installed on one side of the top of the end face of the cooling box in an inserting mode, and one end of the liquid outlet pipe penetrates through the cooling box and is communicated with the plurality of cooling pipes on one side of the second pipe seat.

As a further aspect of the present invention: the assembly of breaing up includes bearing bar, dispersion motor, dispersion axle, installation axle sleeve and the frame that falls scattered, the bearing bar passes through bolt fixed mounting at the inner wall central authorities of cooler bin, the terminal surface central authorities fixed mounting of bearing bar has the dispersion motor, the top one end of dispersion motor is connected and is installed the dispersion axle, and the outside of dispersion axle has the installation axle sleeve through screw fixed mounting, the outer wall of installation axle sleeve fixed mounting all around has a plurality of frames that fall scattered.

As a further aspect of the present invention: the heat conduction grooves are formed in the two sides of the end face of the cooling partition plate, and heat conduction plates are fixedly mounted on the end faces of the heat conduction grooves.

As a further aspect of the present invention: a flow guide seat is fixedly mounted on one side of the inner wall of the cooling box, and one end of the flow guide seat is located on the top end face of the cooling partition plate.

As a further aspect of the present invention: the storage assembly comprises a storage box, a material baffle plate and a fixed base plate, the fixed base plate is fixedly installed in the center of the end face of the bottom plate of the vertical beam frame, the material baffle plate is fixedly installed on the end face of the top of the fixed base plate, the storage box is fixedly installed on the end face of the top of the material baffle plate, and the storage box is located under the end face of the bottom of the lower material cylinder.

As a further aspect of the present invention: the bottom end face of the vertical beam frame is fixedly provided with supporting pad feet all around, and the bottom end face of each supporting pad foot is provided with a rubber antiskid plate in an attaching mode.

The utility model has the advantages that: the novel energy-saving cooling equipment is simple in structure and stable in support; when the cooling box is used, the high-temperature powder can be subjected to heat exchange and cooling through the scattering assembly in the cooling box, and the material is scattered and crushed, so that the material is effectively prevented from being blocked; meanwhile, the refined material is cooled through the cooling assembly, the cooling contact area can be increased, the cooling effect is good, and the cooling efficiency is higher.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

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

FIG. 2 is a schematic view of a partial structure of the present invention;

FIG. 3 is an overall sectional view of the present invention;

FIG. 4 is a schematic structural view of the cooling module of the present invention;

in the figure: 1. a stringer frame; 2. a fastening frame; 3. a cooling tank; 4. a feeding port; 5. breaking up the assembly; 6. a cooling assembly; 7. a flow guide seat; 8. feeding the material barrel; 9. a material storage assembly; 51. a load-bearing bar; 52. a decentralized motor; 53. A dispersion shaft; 54. installing a shaft sleeve; 55. a scatter rack; 61. cooling the partition plate; 62. a heat conducting plate; 63. a cooling tank; 64. a first stem; 65. a second stem; 66. a cooling tube; 67. a liquid inlet pipe; 68. a liquid outlet pipe; 91. a storage box; 92. a striker plate; 93. and fixing the bottom plate.

Detailed Description

The technical solution of the present invention will be described clearly and completely with reference to the following embodiments, and it should be understood that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. Based on the embodiments of the present invention, all other embodiments obtained by a person of ordinary skill in the art without creative efforts belong to the protection scope of the present invention.

As shown in fig. 1-4, a novel energy-saving cooling device comprises a vertical beam frame 1, a fastening frame 2, a cooling box 3, a feeding port 4, a scattering component 5, a cooling component 6, a discharging barrel 8 and a storage component 9, wherein the fastening frame 2 is fixedly installed on one side of the top end surface of the vertical beam frame 1, the cooling box 3 is fixedly installed in the center of the end surface of the fastening frame 2, the feeding port 4 is fixedly installed in the center of the top end surface of the cooling box 3, the scattering component 5 is fixedly installed on the top inside of the cooling box 3, the cooling component 6 is fixedly installed in the center inside of the cooling box 3, the discharging barrel 8 is connected and installed on the bottom end surface of the cooling box 3, the storage component 9 is fixedly installed on one side of the bottom end surface of the vertical beam frame 1, and the storage component 9 is located under the bottom end surface of the discharging barrel 8;

the cooling assembly 6 comprises a cooling partition plate 61, a heat conducting plate 62, a cooling groove 63, a first pipe seat 64, a second pipe seat 65, a cooling pipe 66, a liquid inlet pipe 67 and a liquid outlet pipe 68, wherein a plurality of cooling partition plates 61 are respectively and fixedly arranged at the center inside the cooling box 3, the cooling groove 63 is arranged on the inner end face of each cooling partition plate 61, the first pipe seat 64 is fixedly arranged at the top of one side of each cooling partition plate 61, the second pipe seat 65 is fixedly arranged at the bottom of one side of each cooling partition plate 61, the cooling pipes 66 are respectively and fixedly arranged at the centers of the end faces of the first pipe seat 64 and the second pipe seat 65, the inner parts of the cooling pipes 66 are communicated with the cooling groove 63 through the first pipe seat 64 and the second pipe seat 65, the liquid inlet pipe 67 is inserted and arranged at one side of the bottom of the end face of the cooling box 3, one end of the liquid inlet pipe 67 is communicated with the plurality of cooling pipes 66 at one side of the first pipe seat 64, the liquid outlet pipe 68 is inserted and arranged at one side of the top of the end face of the cooling box 3, and one end of the liquid outlet pipe 68 passes through the cooling box 3 to be communicated with a plurality of cooling pipes 66 on one side of the second pipe base 65.

As an embodiment of the present invention, the scattering assembly 5 includes a bearing rod 51, a scattering motor 52, a scattering shaft 53, an installation shaft sleeve 54 and a scattering frame 55, the bearing rod 51 is fixedly installed in the center of the inner wall of the cooling box 3 through a bolt, the scattering motor 52 is fixedly installed in the center of the end surface of the bearing rod 51, the scattering shaft 53 is installed at one end of the top of the scattering motor 52 in a connected manner, the installation shaft sleeve 54 is fixedly installed at the outer side of the scattering shaft 53 through a bolt, and a plurality of scattering frames 55 are fixedly installed around the outer wall of the installation shaft sleeve 54; the materials are scattered and crushed through the scattering assembly 5, the scattering motor 52 at the top of the bearing rod 51 drives the mounting shaft sleeve 54 to rotate through the scattering shaft 53 when working, the scattering frame 55 at the outer side of the mounting shaft sleeve 54 can hit the materials and crush the materials, and the crushed materials fall into the space between the adjacent cooling partition plates 61 through the flow guide seat 7.

As an embodiment of the utility model, the heat conduction groove has all been seted up to the terminal surface both sides of cooling baffle 61, and the terminal surface fixed mounting of heat conduction groove has heat-conducting plate 62, is convenient for carry out the heat transfer.

As an embodiment of the utility model, inner wall one side fixed mounting of cooler bin 3 has water conservancy diversion seat 7, and the one end of water conservancy diversion seat 7 is located the top end face of cooling baffle 61, and the unloading of being convenient for avoids the material to pile up at the top of cooling baffle 61.

As an embodiment of the present invention, the storage assembly 9 includes a storage box 91, a striker plate 92 and a fixed bottom plate 93, the fixed bottom plate 93 is fixedly installed in the center of the bottom plate end face of the vertical beam frame 1, the striker plate 92 is fixedly installed on the top end face of the fixed bottom plate 93, the storage box 91 is fixedly installed on the top end face of the striker plate 92, and the storage box 91 is located under the bottom end face of the lower charging barrel 8; the material after the cooling flows into storage component 9 through feed cylinder 8 and carries out the storage, and the material can have stable supporting effect to striker plate 92 in feed cylinder 8 falls into striker plate 92 top storage box 91 down, through PMKD 93, the material pile falls in storage box 91's inside to conveniently receive the material.

As an embodiment of the utility model, the bottom terminal surface of erector beam frame 1 all around equal fixed mounting have the support to fill up the foot, and the laminating of the bottom terminal surface of supporting to fill up the foot installs rubber antiskid ribbed tile, improves the stability of supporting.

The utility model discloses a theory of operation: when the cooling device is used, the vertical beam frame 1 can be supported by the supporting foot pads at the bottom of the vertical beam frame 1, the cooling box 3 is fixed at one side of the vertical beam frame 1 by the fastening frame 2, cooling liquid is conveyed into the cooling box 3 through the cooling assembly 6, materials to be cooled are injected into the cooling box 3 through the feeding port 4, the materials are scattered and crushed through the scattering assembly 5, when the scattering motor 52 at the top of the bearing rod 51 works, the mounting shaft sleeve 54 is driven to rotate through the scattering shaft 53, the scattering frame 55 at the outer side of the mounting shaft sleeve 54 can hit and crush the materials, the crushed materials fall between the adjacent cooling partition plates 61 through the flow guide seat 7, the cooling liquid flows into the cooling pipe 66 at one side of the first pipe seat 64 through the liquid inlet pipe 67 and is conveyed into the cooling groove 63 in the cooling partition plate 61 through the cooling pipe 66, and when the cooling liquid flows through the cooling groove 63 and the heat conducting plate 62, the material carries out the heat transfer with the coolant liquid, liquid after the cooling flows into drain pipe 68 through the first tube socket 64 of second tube socket 65 one side, the inside through drain pipe 68 discharge cooler bin 3, the material after the cooling flows into storage assembly 9 through feed cylinder 8 and carries out the storage, the material falls into striker plate 92 top storage box 91 through feed cylinder 8 down in, can have stable supporting effect to striker plate 92 through PMKD 93, the material pile falls in the inside of storage box 91, thereby conveniently receive the material.

The preferred embodiments of the present invention disclosed above are intended only to help illustrate the present invention. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise embodiments disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and its practical applications, to thereby enable others skilled in the art to best understand the invention for and utilize the invention. The present invention is limited only by the claims and their full scope and equivalents.

Claims

1. The novel energy-saving cooling equipment is characterized by comprising a vertical beam frame (1), a fastening frame (2), a cooling box (3), a feeding port (4), a scattering component (5), a cooling component (6), a discharging barrel (8) and a storage component (9), wherein the fastening frame (2) is fixedly installed on one side of the top end surface of the vertical beam frame (1), the cooling box (3) is fixedly installed in the center of the end surface of the fastening frame (2), the feeding port (4) is fixedly installed in the center of the top end surface of the cooling box (3), the scattering component (5) is fixedly installed on the top inside of the cooling box (3), the cooling component (6) is fixedly installed in the center of the inside of the cooling box (3), the discharging barrel (8) is connected and installed on the bottom end surface of the cooling box (3), the storage component (9) is fixedly installed on one side of the bottom end surface of the vertical beam frame (1), the storage component (9) is positioned right below the end surface of the bottom of the lower charging barrel (8);

the cooling assembly (6) comprises a cooling partition plate (61), a heat conducting plate (62), a cooling groove (63), a first pipe seat (64), a second pipe seat (65), a cooling pipe (66), a liquid inlet pipe (67) and a liquid outlet pipe (68), wherein the cooling partition plate (61) is fixedly arranged at the center of the inside of the cooling box (3) respectively, the cooling groove (63) is formed in the end face of the inside of the cooling partition plate (61), the first pipe seat (64) is fixedly arranged at the top of one side of the cooling partition plate (61), the second pipe seat (65) is fixedly arranged at the bottom of one side of the cooling partition plate (61), the cooling pipe (66) is installed in the center of the end faces of the first pipe seat (64) and the second pipe seat (65) in an inserting mode, the liquid inlet pipe (67) is installed on one side of the bottom of the end face of the cooling box (3) in an inserting mode, the first pipe seat (64) and the second pipe seat (65) are communicated with the cooling groove (63) in an inserting mode, and one end of the liquid inlet pipe (67) penetrates through the cooling box (3) and a plurality of cooling pipes (66) on one side of the first pipe seat (64), a liquid outlet pipe (68) is installed on one side of the top of the end face of the cooling box (3) in an inserting mode, and one end of the liquid outlet pipe (68) penetrates through the cooling box (3) and the plurality of cooling pipes (66) on one side of the second pipe seat (65) to be communicated.

2. The novel energy-saving cooling device according to claim 1, wherein the scattering component (5) comprises a bearing rod (51), a scattering motor (52), a scattering shaft (53), a mounting shaft sleeve (54) and a scattering frame (55), the bearing rod (51) is fixedly mounted in the center of the inner wall of the cooling box (3) through bolts, the scattering motor (52) is fixedly mounted in the center of the end surface of the bearing rod (51), the scattering shaft (53) is connected and mounted at one end of the top of the scattering motor (52), the mounting shaft sleeve (54) is fixedly mounted on the outer side of the scattering shaft (53) through a bolt, and the scattering frames (55) are fixedly mounted on the periphery of the outer wall of the mounting shaft sleeve (54).

3. The novel energy-saving cooling device as claimed in claim 1, wherein heat conducting grooves are formed in both sides of the end surface of the cooling partition plate (61), and a heat conducting plate (62) is fixedly mounted on the end surface of each heat conducting groove.

4. The novel energy-saving cooling device according to claim 1, wherein a flow guide seat (7) is fixedly installed on one side of the inner wall of the cooling box (3), and one end of the flow guide seat (7) is located on the top end face of the cooling partition plate (61).

5. The novel energy-saving cooling device of claim 1, wherein the storage assembly (9) comprises a storage box (91), a baffle plate (92) and a fixed bottom plate (93), the fixed bottom plate (93) is fixedly installed in the center of the end surface of the bottom plate of the vertical beam frame (1), the baffle plate (92) is fixedly installed on the end surface of the top of the fixed bottom plate (93), the storage box (91) is fixedly installed on the end surface of the top of the baffle plate (92), and the storage box (91) is located under the end surface of the bottom of the lower charging barrel (8).

6. The novel energy-saving cooling device as claimed in claim 1, wherein supporting foot pads are fixedly mounted on the periphery of the bottom end face of the vertical beam frame (1), and rubber antiskid plates are mounted on the bottom end faces of the supporting foot pads in an attaching mode.