CN114992937B - Quick cooling device of wave dado raw materials - Google Patents

Abstract

The application relates to a rapid cooling device for raw materials of a wave wall panel, which comprises a plurality of support frames, cooling assemblies and feeding frames, wherein the cooling assemblies are arranged between the upper sections of the support frames, the feeding frames are arranged at the upper ends of the cooling assemblies through screws, the feeding openings are arranged at the upper ends of the feeding frames, and high-temperature raw materials to be processed enter the cooling assemblies through the feeding openings. According to the application, accurate cooling of the wallboard raw material can be realized, heat is prevented from accumulating in the middle of the raw material, the spiral through grooves are formed in the outer side of the fixed cylinder, the partition plates are uniformly arranged on the inner sides of the spiral through grooves, inclined ventilation grooves are formed between adjacent partition plates, the ventilation net frame is arranged on the outer sides of the spiral through grooves, heat dissipation holes are uniformly formed in the ventilation net frame, and high-temperature gas can be effectively discharged through the inside of the ventilation grooves.

Description

Quick cooling device of wave dado raw materials

Technical Field

The application relates to the field of panel processing, in particular to a wave panel raw material rapid cooling device.

Background

The wall panels are very common in daily life, have the advantages of light weight, high strength, good shock resistance, good water resistance, good durability and the like, save raw materials, have simple forming process, can be used for manufacturing various external wall panels, internal wall decorative plates, household partition wall plate roof boards, movable house components, permanent templates, ceilings, balcony fence boards and other products with complex shapes, and the life of people is increasingly dependent on the wall panels.

In the existing panel raw material cooling equipment, as disclosed in chinese patent No. CN210952041U, a chemical raw material cooling device is specifically disclosed, when in use, raw materials are sent into a cooling cavity inside the device from a feeding port and stirred by a screw, meanwhile, a refrigeration pump cools water inside a water tank, cold water is led into a fourth connecting pipe by a first water pump and is sent into a cooling pipe for cooling raw materials, cooled liquid is led out from a discharge pump into a discharge port and is sent back into the water tank for re-refrigeration, cooled raw materials are sent onto a conveyor belt from the discharge port and are driven by the conveyor belt to be discharged from the discharge port.

In the prior art, the function of rapidly cooling the raw materials is realized by a condensation mode, but in the first aspect, the prior art conveys hot raw materials by a top-down conveying mode, wood fibers are usually easy to adhere together, the raw materials cannot be effectively evacuated in the conveying process, and after the raw materials are cooled, heat is accumulated in the middle of the raw materials, so that the subsequent use effect of the raw materials is affected; in the second aspect, since the housing is sealed, hot air can be discharged only from the upper end or the lower end of the housing, and when hot raw materials are accumulated inside the housing for a long time, a large amount of hot air is easily accumulated inside the housing, which is disadvantageous in that the hot air is emitted, and there is room for improvement in the existing cooling apparatus based on this.

Disclosure of Invention

In order to realize accurate cooling of the panel raw materials and prevent heat accumulation in the middle of the raw materials, the application provides a rapid wave panel raw material cooling device.

The application provides a rapid cooling device for a wave wall panel raw material, which adopts the following technical scheme:

the utility model provides a wave dado raw materials quick cooling device, includes support frame, cooling module and feed frame, support frame quantity be a plurality of, install cooling module between the support frame upper segment, cooling module upper end is installed the feed frame through the screw, the feed frame upper end is provided with the feed inlet, the high temperature raw materials that wait to process gets into inside the cooling module through the feed inlet.

The cooling assembly comprises a fixed cylinder, a connecting cylinder, a rotating mechanism, a dispersing mechanism, a cooling frame and a feeding mechanism, wherein the fixed cylinder is of a cylindrical hollow structure, a cavity is formed in the middle of the fixed cylinder, the connecting cylinder is internally installed, the section of the connecting cylinder is of a U-shaped structure, the rotating mechanism is internally installed in the connecting cylinder, the dispersing mechanism is arranged above the connecting cylinder, the middle of the dispersing mechanism is connected with the rotating mechanism, the cooling frame is installed between the middle of the fixed cylinder and the connecting cylinder, the cooling frame is of a spiral structure, a spiral groove is formed in the middle of the cooling frame, the spiral groove can increase the travel of raw materials falling, the feeding mechanism is uniformly installed in the spiral groove, and the inner side of the feeding mechanism is connected with the rotating mechanism.

The fixed section of thick bamboo outside be provided with spiral logical groove, spiral logical inslot side evenly installs the baffle, is provided with the ventilative groove of slope between the adjacent baffle, spiral logical inslot side is installed ventilative rack, evenly is provided with the louvre on the ventilative rack, when high temperature raw materials gets into the fixed section of thick bamboo inside, high temperature gas can effectually be discharged through ventilative inslot portion, ventilative rack can play filterable effect, prevents that the raw materials from spilling over, improves the cooling effect of heat dissipation of raw materials.

The feeding mechanism comprises a rotating rod, a feeding plate and a connecting gear, wherein the rotating rod is uniformly arranged in the spiral groove, one end of the rotating rod is connected with the fixed cylinder through a bearing, the other end of the rotating rod is connected with the connecting cylinder through a bearing, the feeding plate is arranged in the middle of the rotating rod, the connecting gear is arranged at the inner end of the rotating rod, and the connecting gear is connected with the rotating mechanism.

As a preferable technical scheme of the application, the rotating mechanism comprises a driving motor, a rotating shaft and a rotating gear, wherein the driving motor is arranged in the connecting cylinder through a motor seat, the rotating shaft is arranged on an output shaft of the driving motor, the upper end of the rotating shaft is connected with the connecting cylinder through a bearing, and the rotating gear is uniformly arranged on the rotating shaft.

As a preferable technical scheme of the application, the dispersing mechanism comprises a mounting seat and a dispersing plate, wherein the mounting seat is fixedly arranged at the upper end of the rotating mechanism, jacks are uniformly arranged at the outer sides of the mounting seat, the dispersing plate is fixedly arranged in the jacks, and the dispersing plate is of a rectangular structure.

As a preferable technical scheme of the application, the cooling frame is of a spiral structure, the surface of the cooling frame is a smooth surface, the cooling frame is made of a heat conducting material, and when high-temperature raw materials contact the surface of the cooling frame, heat can be rapidly transferred to the cooling frame, so that the raw materials are cooled conveniently.

As a preferable technical scheme of the application, the middle part of the cooling frame is uniformly provided with the condensing pipes, and the end parts of the condensing pipes are communicated with the external circulation water, so that cold water can effectively transfer out heat on the cooling frame, prevent heat accumulation and ensure the cooling effect of raw materials.

As a preferable technical scheme of the application, the feeding plate is of a rectangular structure, through grooves are uniformly formed in the feeding plate, and when the feeding plate rotates, the feeding plate can drive raw materials to be conveyed and play a role in flaring, so that the raw materials can be effectively cooled while moving downwards.

As a preferable technical scheme of the application, the inside of the connecting cylinder is provided with the booster fan, the booster fan is arranged on the rotating mechanism, the inner wall of the connecting cylinder is uniformly provided with the air holes, the diameters of the air holes are reduced from inside to outside, and the booster fan can drive hot air to effectively radiate outwards.

(III) beneficial effects

1. In order to prevent heat from accumulating in the fixed cylinder, the outer side of the fixed cylinder is provided with a spiral through groove, the inner side of the spiral through groove is uniformly provided with a baffle plate, an inclined ventilation groove is arranged between adjacent baffle plates, the outer side of the spiral through groove is provided with a ventilation net rack, the ventilation net rack is uniformly provided with radiating holes, high-temperature gas can be effectively discharged through the inside of the ventilation groove, meanwhile, the ventilation net rack can play a role in filtering, raw materials are prevented from overflowing outwards along with hot gas, and the phenomenon of waste of the raw materials is avoided;

2. in order to prevent raw materials entering the inside of the fixed cylinder from being adhered together, the application is provided with the dispersing mechanism, when the raw materials enter the inside of the fixed cylinder, the dispersing plate can uniformly disperse the high-temperature raw materials and prevent the raw materials from accumulating, so that the high-temperature raw materials can fully contact with the cooling rack, and the high-temperature raw materials can be cooled conveniently;

3. in order to facilitate the downward movement of the raw materials along the cooling frame of the spiral structure, the feeding mechanism is arranged in the application, the rotating mechanism drives the feeding plate to rotate through the connecting gear, the feeding plate rolls up the raw materials in a flaring mode, raw materials are prevented from being adhered together, the raw materials can be sufficiently cooled, meanwhile, the raw materials can be conveyed downwards along the cooling frame by the rotation of the feeding plate, the raw materials are prevented from being accumulated on the cooling frame of the spiral structure, and the subsequent cooling processing of the raw materials is facilitated.

Drawings

The application will be further described with reference to the drawings and examples.

FIG. 1 is a schematic perspective view of the present application;

FIG. 2 is a schematic plan view of the present application;

FIG. 3 is a schematic cross-sectional view of the structure of FIG. 2 at A-A in accordance with the present application;

FIG. 4 is a schematic cross-sectional view of the present application between a dispersing mechanism and a feed rack;

fig. 5 is a schematic cross-sectional view of a cooling module according to the present application.

Detailed Description

The application is described in further detail below with reference to fig. 1-5.

The embodiment of the application discloses a rapid cooling device for a wave wall panel raw material, which can effectively realize the function of accurately cooling the wall panel raw material and preventing heat from accumulating in the middle of the raw material.

Embodiment one:

as shown in fig. 1 to 5, a wave panel raw material rapid cooling device comprises a plurality of support frames 1, cooling assemblies 2 and feeding frames 3, wherein the number of the support frames 1 is multiple, the cooling assemblies 2 are arranged between the upper sections of the support frames 1, the feeding frames 3 are arranged at the upper ends of the cooling assemblies 2 through screws, and feeding inlets are formed in the upper ends of the feeding frames 3.

As shown in fig. 3, the cooling assembly 2 includes a fixed cylinder 21, a connecting cylinder 22, a rotating mechanism 23, a dispersing mechanism 24, a cooling rack 25 and a feeding mechanism 26, the fixed cylinder 21 is of a cylindrical hollow structure, a cavity is formed in the middle of the fixed cylinder 21, the connecting cylinder 22 is installed in the fixed cylinder 21, the cross section of the connecting cylinder 22 is of a U-shaped structure, the rotating mechanism 23 is installed in the connecting cylinder 22, the dispersing mechanism 24 is arranged above the connecting cylinder 22, the middle of the dispersing mechanism 24 is connected with the rotating mechanism 23, the cooling rack 25 is installed between the middle of the fixed cylinder 21 and the connecting cylinder 22, the cooling rack 25 is of a spiral structure, a spiral groove is formed in the middle of the cooling rack 25, the feeding mechanism 26 is evenly installed in the spiral groove, and the inner side of the feeding mechanism 26 is connected with the rotating mechanism 23.

In the in-service use process, high-temperature raw materials gets into inside the fixed cylinder 21 through feeding frame 3, and rotary mechanism 23 drives the raw materials dispersion through dispersion mechanism 24 at first for the raw materials can evenly spread, and the raw materials carries out and can even drop inside cooling frame 25, and cooling frame 25 can effectually go out the heat transfer on the raw materials, afterwards, feeding mechanism 26 can drive the raw materials and follow cooling frame 25 inside downward movement, and the raw materials after the cooling is collected through the fixed cylinder 21 lower extreme.

In order to prevent heat from accumulating inside the fixed cylinder 21, a spiral through groove is formed in the outer side of the fixed cylinder 21 in the embodiment, partition plates 211 are uniformly arranged on the inner side of the spiral through groove, inclined ventilation grooves are formed between adjacent partition plates 211, a ventilation net rack 212 is arranged on the outer side of the spiral through groove, and heat dissipation holes are uniformly formed in the ventilation net rack 212.

In the in-service use, when high temperature raw materials gets into inside the fixed section of thick bamboo 21, high temperature gas can effectually be discharged through ventilative inslot, and ventilative rack 212 can play filterable effect simultaneously, prevents that the raw materials from outwards spilling over along with the steam, avoids the raw materials to take place extravagant phenomenon.

In order to further improve the heat dissipation efficiency inside the fixed cylinder 21, in this embodiment, a booster fan is disposed inside the connecting cylinder 22, the booster fan is mounted on the rotating mechanism 23, ventilation holes are uniformly formed in the inner wall of the connecting cylinder 22, the diameter of the ventilation holes is reduced from inside to outside, the booster fan rotates synchronously with the rotating mechanism 23, and the hot air is effectively discharged outwards under the driving of the gas generated by the booster fan.

As shown in fig. 5, the rotating mechanism 23 includes a driving motor 231, a rotating shaft 232 and a rotating gear 233, the driving motor 231 is mounted in the connecting cylinder 22 through a motor base, the rotating shaft 232 is mounted on an output shaft of the driving motor 231, the upper end of the rotating shaft 232 is connected with the connecting cylinder 22 through a bearing, and the rotating gear 233 is uniformly mounted on the rotating shaft 232.

In the actual use process, the driving motor 231 can drive the dispersing mechanism 24 to rotate through the rotating shaft 232, and meanwhile, the rotating gear 233 on the rotating shaft 232 can drive the feeding mechanism 26 to synchronously rotate, so that the heat dissipation effect of raw materials is improved.

As shown in fig. 4, in order to prevent raw materials entering the fixing barrel 21 from adhering together, in this embodiment, a dispersing mechanism 24 is provided, the dispersing mechanism 24 includes a mounting seat 241 and a dispersing plate 242, the upper end of the rotating mechanism 23 is fixedly provided with the mounting seat 241, the outer side of the mounting seat 241 is uniformly provided with an inserting hole, the dispersing plate 242 is fixedly installed in the inserting hole, and the dispersing plate 242 is in a rectangular structure.

In the actual use process, the dispersing plate 242 can uniformly disperse the high-temperature raw materials, so that the raw materials are prevented from accumulating, and the high-temperature raw materials can fully contact with the cooling rack 25, thereby being beneficial to cooling the high-temperature raw materials.

In order to increase the cooling stroke of the raw material, the cooling rack 25 is configured in a spiral structure in this embodiment, and the surface of the cooling rack 25 is a smooth surface.

It should be noted that, compared with the direct falling of the raw materials, the spiral cooling rack 25 can effectively increase the falling stroke of the raw materials, so that the high-temperature raw materials can be sufficiently cooled, and the subsequent use of the raw materials is facilitated.

In order to ensure the heat transfer effect, in this embodiment, the cooling rack 25 is made of a heat conducting material, and when the high-temperature raw material contacts the surface of the cooling rack 25, the heat can be quickly transferred to the cooling rack 25, so that the heat transfer effect is improved.

In order to further ensure the cooling effect of the raw materials, the middle part of the cooling frame 25 in the embodiment is uniformly provided with a condensing pipe, the condensing pipe is also spirally distributed, the condensing pipe is positioned on the upper surface of the cooling frame 25, and the end part of the condensing pipe is communicated with the external circulation water, so that cold water can effectively transfer out heat on the cooling frame 25, and heat accumulation is prevented.

The condenser pipes on the surface of the cooling rack 25 are smooth after being arranged, so that friction can be reduced, and the phenomenon of stacking of wood raw materials can be prevented.

Embodiment two:

referring to fig. 2 to 5, in order to facilitate the downward movement of the raw materials along the cooling rack 25 of the spiral structure on the basis of the first embodiment, and simultaneously, in order to accurately disperse the raw materials moving downward, a corresponding feeding mechanism 26 is provided in the second embodiment.

As shown in fig. 5, in order to facilitate the downward movement of the raw materials along the cooling rack 25 with the spiral structure, in this embodiment, a feeding mechanism 26 is provided, the feeding mechanism 26 includes a rotating rod 261, a feeding plate 262 and a connecting gear 263, the rotating rod 261 is uniformly provided in the spiral groove, one end of the rotating rod 261 is connected with the fixed cylinder 21 through a bearing, the other end of the rotating rod 261 is connected with the connecting cylinder 22 through a bearing, the feeding plate 262 is mounted in the middle of the rotating rod 261, the connecting gear 263 is mounted at the inner end of the rotating rod 261, and the connecting gear 263 is connected with the rotating mechanism 23.

In the in-service use process, the rotating mechanism 23 drives the feeding plate 262 to rotate through the connecting gear 263, the feeding plate 262 rolls up raw materials through the flaring mode, raw materials are prevented from being adhered together, the raw materials can be sufficiently cooled, meanwhile, the feeding plate 262 rotates to enable the raw materials to be downwards conveyed along the cooling frame 25, the raw materials are prevented from being accumulated on the cooling frame of the spiral structure, and the subsequent cooling processing of the raw materials is facilitated.

It should be noted that, the feeding plate 262 is rectangular, through grooves are uniformly formed in the feeding plate 262, when the feeding plate 262 rotates, the feeding plate 262 can drive raw materials to be conveyed, meanwhile, the feeding plate 262 can play a role of fan blades, and the feeding plate 262 can be used for flaring the raw materials, so that the raw materials can be cooled effectively while moving downwards.

The working process of the embodiment of the application is as follows:

the first step: connecting the high-temperature raw material with the feeding frame 3, and allowing the high-temperature raw material to enter the fixed cylinder 21 through the feeding frame 3;

and a second step of: the dispersion plate 242 can uniformly disperse the high-temperature raw materials and prevent the raw materials from piling up, so that the high-temperature raw materials can fully contact with the cooling rack 25, and the high-temperature raw materials can be cooled;

and a third step of: the cooling frame 25 is made of heat conducting materials, when the high-temperature raw materials contact the surface of the cooling frame 25, heat can be rapidly transferred to the cooling frame 25, the falling stroke of the raw materials can be effectively increased by the cooling frame 25 with the spiral structure, the high-temperature raw materials can be sufficiently cooled, and the subsequent use of the raw materials is facilitated;

fourth step: the rotating mechanism 23 drives the feeding plate 262 to rotate through the connecting gear 263, and the feeding plate 262 rolls up raw materials in a flaring mode, so that the raw materials can be sufficiently cooled, and meanwhile, the raw materials can be downwards conveyed along the cooling frame 25 by rotating the feeding plate 262, so that the raw materials are cooled.

The above description is only of the preferred embodiments of the present application and is not intended to limit the present application, but various modifications and variations can be made to the present application by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (7)

1. The utility model provides a wave dado raw materials rapid cooling device, includes support frame (1), cooling module (2) and feed frame (3), its characterized in that: the support frame (1) quantity be a plurality of, install cooling module (2) between support frame (1) upper segment, feeding frame (3) are installed through the screw to cooling module (2) upper end, feeding frame (3) upper end is provided with the feed inlet, wherein:

the cooling assembly (2) comprises a fixed cylinder (21), a connecting cylinder (22), a rotating mechanism (23), a dispersing mechanism (24), a cooling frame (25) and a feeding mechanism (26), wherein the fixed cylinder (21) is of a cylindrical hollow structure, a cavity is formed in the middle of the fixed cylinder (21), the connecting cylinder (22) is internally installed in the fixed cylinder (21), the cross section of the connecting cylinder (22) is of a U-shaped structure, the rotating mechanism (23) is internally installed in the connecting cylinder (22), the dispersing mechanism (24) is arranged above the connecting cylinder (22), the middle of the dispersing mechanism (24) is connected with the rotating mechanism (23), the cooling frame (25) is installed between the middle of the fixed cylinder (21) and the connecting cylinder (22), the middle of the cooling frame (25) is of a spiral structure, a spiral groove is formed in the middle of the cooling frame, the spiral groove is internally and the feeding mechanism (26) is uniformly installed, and the inner side of the feeding mechanism (26) is connected with the rotating mechanism (23).

The outer side of the fixed cylinder (21) is provided with a spiral through groove, the inner side of the spiral through groove is uniformly provided with a baffle plate (211), an inclined ventilation groove is arranged between the adjacent baffle plates (211), the outer side of the spiral through groove is provided with a ventilation net rack (212), and the ventilation net rack (212) is uniformly provided with heat dissipation holes;

feeding mechanism (26) include dwang (261), delivery sheet (262) and connecting gear (263), the inside dwang (261) that evenly is provided with of helicla flute, dwang (261) one end is connected with fixed cylinder (21) through the bearing, dwang (261) other end is connected with connecting cylinder (22) through the bearing, dwang (261) mid-mounting has delivery sheet (262), connecting gear (263) are installed to dwang (261) inner, connecting gear (263) are connected with rotary mechanism (23).

2. A wave panel stock rapid cooling apparatus as defined in claim 1, wherein: the rotating mechanism (23) comprises a driving motor (231), a rotating shaft (232) and a rotating gear (233), the driving motor (231) is arranged in the connecting cylinder (22) through a motor base, the rotating shaft (232) is arranged on an output shaft of the driving motor (231), the upper end of the rotating shaft (232) is connected with the connecting cylinder (22) through a bearing, and the rotating gear (233) is uniformly arranged on the rotating shaft (232).

3. A wave panel stock rapid cooling apparatus as defined in claim 1, wherein: the dispersing mechanism (24) comprises a mounting seat (241) and a dispersing plate (242), the mounting seat (241) is fixedly arranged at the upper end of the rotating mechanism (23), jacks are uniformly formed in the outer side of the mounting seat (241), the dispersing plate (242) is fixedly arranged in the jacks, and the dispersing plate (242) is of a rectangular structure.

4. A wave panel stock rapid cooling apparatus as defined in claim 1, wherein: the cooling frame (25) is of a spiral structure, the surface of the cooling frame (25) is a smooth surface, and the cooling frame (25) is made of a heat-conducting material.

5. A wave panel stock rapid cooling apparatus as defined in claim 1, wherein: the middle part of the cooling frame (25) is uniformly provided with a condensing pipe, and the end part of the condensing pipe is communicated with external circulating water.

6. A wave panel stock rapid cooling apparatus as defined in claim 1, wherein: the feeding plate (262) is of a rectangular structure, and through grooves are uniformly formed in the feeding plate (262).

7. A wave panel stock rapid cooling apparatus as defined in claim 1, wherein: the connecting cylinder (22) is internally provided with a booster fan, the booster fan is arranged on the rotating mechanism (23), ventilation holes are uniformly formed in the inner wall of the connecting cylinder (22), and the diameter of each ventilation hole is reduced from inside to outside.