CN221437015U - Quick cooling water tank structure of extrusion material - Google Patents

Abstract

The utility model provides a rapid cooling water tank structure for extruded materials, which comprises: the novel electric motor comprises a motor case, a shaft housing and a squeezing pipe, wherein the shaft housing is arranged on the right side of the motor case, a supporting seat is arranged at the lower end of the shaft housing, a connecting flange is arranged on the right side of the shaft housing, a shell is arranged on the right side of the connecting flange, an embedded seat is arranged at the upper end of the shell, a connecting seat is arranged at the upper end of the embedded seat, a top housing is arranged at the upper end of the connecting seat, a feeding cavity is formed in the inner side of the top housing, and a water inlet pipe is arranged at the upper end of the right side of the shell. Through using the guide auger, can extrude fast to foaming extrusion material, through using flange, can promote sealing connection effect between axle housing and the shell, convenient to detach simultaneously, through using two sets of connecting gear, drive two sets of stirring leaves and rotate simultaneously, through using the cooling inner tube, can carry out rapid cooling to the extrusion pipe.

Description

Quick cooling water tank structure of extrusion material

Technical Field

The utility model belongs to the technical field of foaming molds, and relates to a rapid cooling water tank structure for extruded materials.

Background

Directly filling foaming resin into a mould, heating and melting the foaming resin to form a gas-liquid saturated solution, forming a large number of micro-foam cores through nucleation, and growing the foam cores to prepare a foam plastic part;

The foaming mold needs to be cooled to solidify and solidify the foaming material during the process of injecting the foaming material and foaming. However, if the heat dissipation effect of the mold is not good, heat cannot be rapidly and effectively dissipated, which results in a high internal temperature and a rapid cooling failure.

Cooling water tanks are typically used to lower the temperature of the foam material, allowing it to quickly solidify and maintain a stable shape. Without the cooling water trough mechanism, the foam material may not cool sufficiently, resulting in an incomplete foaming process.

The cooling water tank helps to accelerate cooling and solidification of the foaming material, thereby forming a stable cell structure. Without the cooling water trough mechanism, instability of the cell structure may occur, resulting in a decrease in product quality.

The cooling water tank can help to accelerate the cooling speed of the foaming material, thereby improving the production efficiency. Without the cooling water tank mechanism, the cooling process of the foaming material may be slowed down, resulting in low production efficiency.

During the foaming material extrusion process, the material temperature is typically high, and if the cooling water trough mechanism is not present, the equipment may overheat, thereby damaging the components of the equipment.

Therefore, the cooling water tank mechanism is critical to the normal operation and product quality of the foaming material extrusion mechanism, and the lack of the cooling water tank mechanism may cause the problems, so that a rapid cooling water tank structure for the extruded material is needed to solve the problems.

Disclosure of utility model

Aiming at the defects existing in the prior art, the utility model aims to provide a rapid cooling water tank structure for extruded materials, and solves the problems in the prior art.

The utility model is realized by the following technical scheme: an extrudate rapid cooling trough structure comprising: the device comprises a motor box, a shaft housing and a squeezing pipe, wherein the shaft housing is arranged on the right side of the motor box;

The lower end of the shaft housing is provided with a supporting seat, the right side of the shaft housing is provided with a connecting flange, the right side of the connecting flange is provided with a housing, the upper end of the housing is provided with an embedding seat, the upper end of the embedding seat is provided with a connecting seat, the upper end of the connecting seat is provided with a top housing, the inner side of the top housing is provided with a feeding cavity, and the upper end of the right side of the housing is provided with a water inlet pipe;

The inner side of the shell is provided with an inner groove, the inner side of the inner groove is provided with a cooling inner pipe, the inner side of the cooling inner pipe is provided with a squeezing pipe, the inner side of the top shell is provided with a feeding cavity, the lower end of the feeding cavity is provided with a squeezing cavity, the inner side of the squeezing cavity is provided with a stirring blade, and the left side of the stirring blade is provided with a connecting gear.

As a preferred implementation mode, the motor box is internally provided with a motor, the motor box is fixedly connected with the shaft housing through bolts, a transmission shaft is arranged in the shaft housing, the right side of the transmission shaft is provided with a guide auger, and the foaming extrusion material can be rapidly extruded through the guide auger.

As a preferred implementation mode, the motor is connected with a transmission shaft, the transmission shaft is connected with a guide auger, the cross section of the guide auger is of a spiral structure, and a group of flange plates are arranged on the right side of the shaft housing and the left side of the housing.

As a preferred implementation mode, two groups of flange pieces are respectively integrated with the axle housing and the outer housing, the two groups of flange pieces form a connecting flange, the upper end of the outer housing and the inner part of the lower end of the embedded seat are mutually embedded, the sealing connection effect between the axle housing and the outer housing can be improved through the connecting flange, and meanwhile, the connecting flange is convenient to detach.

As a preferred implementation mode, the embedded seat and the connecting seat are fixedly connected through a plurality of groups of bolts, the inside of the feeding cavity is communicated with the inside of the extruding cavity, and the inside of the extruding cavity is communicated with the inside of the extruding pipe.

As a preferred implementation mode, the connecting gears are provided with two groups, the connecting gears on the left side are a driving mechanism, the connecting gears on the right side are driven mechanisms, the two groups of connecting gears are meshed with each other, and the two groups of stirring blades can be driven to rotate simultaneously by using the two groups of connecting gears.

As a preferred implementation mode, every group connecting gear corresponds a set of stirring leaf and connects, and two sets of stirring leaf are crisscross and contactless each other, go into inside intercommunication each other of water pipe and the inside cooling inner tube, just the cooling inner tube is a helicitic texture and twines at the crowded material outside surface, the cooling inner tube is located inside the inside groove, cooling inner tube left side lower extreme is equipped with the outlet pipe, can carry out quick cooling to crowded material pipe through the cooling inner tube.

After the technical scheme is adopted, the utility model has the beneficial effects that: through using the guide auger, can extrude fast to foaming extrusion material, through using flange, can promote sealing connection effect between axle housing and the shell, convenient to detach simultaneously, through using two sets of connecting gear, drive two sets of stirring leaves and rotate simultaneously, through using the cooling inner tube, can carry out rapid cooling to the extrusion pipe.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the utility model, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic top view of a front view of an extruded material rapid cooling trough structure of the present utility model;

FIG. 2 is a top view of the structure of the present utility model showing the rapid cooling trough for extrudate;

FIG. 3 is a right side view of the structure of the present utility model when two sets of stirring blades are staggered;

FIG. 4 is a front view of the inside of an inner tank in the structure of the rapid cooling trough for extrudate according to the present utility model;

In the figure: 100-motor box, 110-axle housing, 120-supporting seat, 130-connecting flange, 140-embedding seat, 150-tube head, 160-inner groove, 170-water inlet pipe, 180-connecting seat, 190-top housing, 200-feeding cavity, 210-extrusion cavity, 220-stirring blade, 230-connecting gear, 240-cooling inner pipe and 250-extrusion pipe.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, a rapid cooling trough structure for extruded materials includes: the motor box 100, the shaft housing 110 and the extrusion pipe 250 are arranged on the right side of the motor box 100;

The lower end of the shaft housing 110 is provided with a supporting seat 120, the right side of the shaft housing 110 is provided with a connecting flange 130, the right side of the connecting flange 130 is provided with a shell, the upper end of the shell is provided with an embedded seat 140, the upper end of the embedded seat 140 is provided with a connecting seat 180, the upper end of the connecting seat 180 is provided with a top housing 190, the inner side of the top housing 190 is provided with a feeding cavity 200, and the upper end of the right side of the shell is provided with a water inlet pipe 170;

The shell inboard is equipped with inside groove 160, and inside groove 160 is inside to be equipped with cooling inner tube 240, and cooling inner tube 240 inboard is equipped with crowded material pipe 250, and top shell 190 inboard is equipped with pan feeding chamber 200, and pan feeding chamber 200 lower extreme is equipped with crowded material chamber 210, and crowded material chamber 210 is inside to be equipped with and stirs material leaf 220, stirs material leaf 220 left side and is equipped with connecting gear 230.

The motor is arranged in the motor case 100, the motor case 100 is fixedly connected with the shaft housing 110 through bolts, a transmission shaft is arranged in the shaft housing 110, a guide auger is arranged on the right side of the transmission shaft, and foaming extrusion materials can be rapidly extruded through the guide auger.

The motor is connected with the transmission shaft, and the transmission shaft is connected with the guide auger, and guide auger cross section is a helical structure, and axle housing 110 right side and shell left side all are equipped with a set of flange piece.

The two groups of flange pieces are respectively integrated with the axle housing 110 and the outer housing, the two groups of flange pieces form the connecting flange 130, the upper end of the outer housing is embedded with the lower end of the embedded seat 140, the sealing connection effect between the axle housing 110 and the outer housing can be improved through the connecting flange 130, and meanwhile, the disassembly is convenient.

The insert seat 140 and the connecting seat 180 are fixedly connected through a plurality of groups of bolts, the inside of the feeding cavity 200 is communicated with the inside of the extruding cavity 210, and the inside of the extruding cavity 210 is communicated with the inside of the extruding pipe 250.

The connecting gears 230 are provided with two groups, the left connecting gear 230 is a driving mechanism, the right connecting gear 230 is a driven mechanism, the two groups of connecting gears 230 are meshed with each other, and the two groups of stirring blades 220 can be driven to rotate simultaneously by using the two groups of connecting gears 230.

Each group of connecting gears 230 corresponds to a group of stirring blades 220 and is connected, the two groups of stirring blades 220 are staggered and do not contact with each other, the inside of the water inlet pipe 170 is communicated with the inside of the cooling inner pipe 240, the cooling inner pipe 240 is of a spiral structure and is wound on the outer side surface of the extrusion pipe 250, the cooling inner pipe 240 is positioned inside the inner groove 160, the left lower end of the cooling inner pipe 240 is provided with a water outlet pipe, and the extrusion pipe 250 can be rapidly cooled through the cooling inner pipe 240.

Referring to fig. 1-4, as a first embodiment of the present utility model: firstly, a worker puts materials to be foamed and formed into the material extruding cavity 210 through the material extruding cavity 200, and the materials enter the material extruding cavity 210 through the material extruding cavity 200, as the connecting gears 230 are provided with two groups, the left connecting gear 230 is a driving mechanism, the right connecting gear 230 is a driven mechanism, the two groups of connecting gears 230 are meshed with each other, the two groups of connecting gears 230 rotate to drive the two groups of stirring blades 220 to rotate, the two groups of stirring blades 220 guide foaming materials into the material extruding pipe 250, then a motor is started, the motor drives a transmission shaft to rotate, and the transmission shaft rotates to drive the guide auger to rotate, and as the cross section of the guide auger is of a spiral structure, the high-temperature foaming materials can be extruded from the left side to the right side of the material extruding pipe 250 through the guide auger.

Referring to fig. 1-4, as a second embodiment of the present utility model: based on the description of the above embodiments, further, in order to solve the problem that the foaming mold needs to be cooled to solidify and solidify during the process of injecting the foaming material and foaming. However, if the heat dissipation effect of the mold is not good, heat cannot be rapidly and effectively dissipated, which may result in a problem that the internal temperature is high, resulting in damage to the foaming mold, firstly, a worker hermetically connects the external cooling water pipe with the water inlet pipe 170 and makes the external cooling water enter the cooling inner pipe 240 through the water inlet pipe 170, and since the cooling inner pipe 240 has a spiral structure and is wound around the outer side surface of the extruding pipe 250, the cooling inner pipe 240 is positioned inside the inner groove 160, and the cooling inner pipe 240 and the outer side of the extruding pipe 250 maintain the cooling water circulation, thereby rapidly reducing the internal temperature of the extruding pipe 250.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the utility model.

Claims (7)

1. An extrudate rapid cooling trough structure comprising: motor case (100), axle housing (110) and squeeze tube (250), its characterized in that: a shaft housing (110) is arranged on the right side of the motor box (100);

The novel high-pressure oil-well drilling machine is characterized in that a supporting seat (120) is arranged at the lower end of the shaft housing (110), a connecting flange (130) is arranged on the right side of the shaft housing (110), a housing is arranged on the right side of the connecting flange (130), an embedded seat (140) is arranged at the upper end of the housing, a connecting seat (180) is arranged at the upper end of the embedded seat (140), a top housing (190) is arranged at the upper end of the connecting seat (180), a feeding cavity (200) is arranged on the inner side of the top housing (190), and a water inlet pipe (170) is arranged at the upper end of the right side of the housing;

The inner tank (160) is arranged on the inner side of the shell, the cooling inner pipe (240) is arranged inside the inner tank (160), the extruding pipe (250) is arranged on the inner side of the cooling inner pipe (240), the feeding cavity (200) is arranged on the inner side of the top shell (190), the extruding cavity (210) is arranged at the lower end of the feeding cavity (200), the stirring blade (220) is arranged inside the extruding cavity (210), and the connecting gear (230) is arranged on the left side of the stirring blade (220).

2. The extrudate rapid cooling trough structure according to claim 1, characterized in that: the novel electric motor is characterized in that a motor is arranged inside the motor box (100), the motor box (100) is fixedly connected with the shaft housing (110) through bolts, a transmission shaft is arranged inside the shaft housing (110), and a guide auger is arranged on the right side of the transmission shaft.

3. The extrudate rapid cooling trough structure according to claim 2, characterized in that: the motor is connected with the transmission shaft, the transmission shaft is connected with the guide auger, the cross section of the guide auger is of a spiral structure, and a group of flange plates are arranged on the right side of the shaft housing (110) and the left side of the housing.

4. A rapid extrusion cooling water tank structure according to claim 3, wherein: the two groups of flange plates are respectively integrated with the shaft housing (110) and the shell, the two groups of flange plates form a connecting flange (130), and the upper end of the shell is mutually embedded with the inner part of the lower end of the embedded seat (140).

5. The extrudate rapid cooling trough structure according to claim 4, wherein: the embedded seat (140) is fixedly connected with the connecting seat (180) through a plurality of groups of bolts, the inside of the feeding cavity (200) is communicated with the inside of the extruding cavity (210), and the inside of the extruding cavity (210) is communicated with the inside of the extruding pipe (250).

6. The extrudate rapid cooling trough structure according to claim 1, characterized in that: the connecting gears (230) are provided with two groups, the left connecting gear (230) is a driving mechanism, the right connecting gear (230) is a driven mechanism, and the two groups of connecting gears (230) are meshed with each other.

7. The extrudate rapid cooling trough structure according to claim 6, wherein: every group connecting gear (230) corresponds a set of stirring leaf (220) and connects, and two sets of stirring leaf (220) are crisscross and contactless each other, go into inside intercommunication each other of water pipe (170) and cooling inner tube (240), just cooling inner tube (240) are a helicitic texture and twine at extrusion pipe (250) outside surface, cooling inner tube (240) are located inside groove (160), cooling inner tube (240) left side lower extreme is equipped with the outlet pipe.