CN215325138U

CN215325138U - Layered conveying device capable of rapidly cooling for production and processing of glass beads

Info

Publication number: CN215325138U
Application number: CN202121782734.1U
Authority: CN
Inventors: 刘冰
Original assignee: Langfang Dilan Technology Co ltd
Current assignee: Langfang Dilan Technology Co ltd
Priority date: 2021-08-02
Filing date: 2021-08-02
Publication date: 2021-12-28
Anticipated expiration: 2031-08-02

Abstract

The utility model discloses a layered conveying device capable of quickly cooling for producing and processing glass microspheres, which comprises a support, a cooling cylinder, a motor, a material collecting box, a layered die carrier, a grid, a material placing plate, an elongated tube, a feed inlet, a water outlet, a discharge outlet and a valve. Set up layering conveying mechanism in a cooling section of thick bamboo, layering conveying mechanism's the case that gathers materials rotates under the drive of motor, messenger's glass microballon cooling that can be quick improves glass microballon's production efficiency greatly.

Description

Layered conveying device capable of rapidly cooling for production and processing of glass beads

Technical Field

The utility model relates to the technical field of glass bead production equipment, in particular to a layered conveying device capable of quickly cooling for producing and processing glass beads.

Background

The glass beads mean solid or hollow glass beads having a diameter of several micrometers to several millimeters, and are colorless and colored. Beads having a diameter of 0.8mm or more are called fine beads, and beads having a diameter of 0.8mm or less are called microbeads. Glass beads are one of the important raw materials for producing the reflective material. The repacking of microballon need be cooled down the back at production completion after the microballon otherwise can damage the wrapping bag, but the cooling speed is very slow if the microballon piles up the cooling by a large scale, and the cooling of current glass microballon layering transport heat sink still needs a period, influences glass microballon's production efficiency.

Disclosure of Invention

In view of the above-mentioned deficiencies or inadequacies of the prior art, it would be desirable to provide a layered delivery apparatus for glass bead production processes that provides rapid temperature reduction.

According to the technical scheme that this application embodiment provided, but the layering conveyor of glass microballon production and processing of rapid cooling, including support, a cooling section of thick bamboo, motor, the case that gathers materials, layering die carrier, graticule mesh, put thing board, extension pipe, feed inlet, water inlet, outlet, discharge gate, valve, the bottom rigid coupling of a cooling section of thick bamboo is in on the support, the motor passes through the screw rigid coupling in the bottom of a cooling section of thick bamboo, the output of motor passes the bottom of a cooling section of thick bamboo and stretches into inside the cooling section of thick bamboo, the case that gathers materials sets up in the cooling section of thick bamboo, the bottom of the case that gathers materials and the output rigid coupling of motor, the layering die carrier with the lateral wall rigid coupling of the case that gathers materials, the layering die carrier by the die carrier constitutes basic frame, the die carrier coats and is covered with the graticule mesh, the rigid coupling has put the thing board in the die carrier, this end of case that gathers materials is kept away from is connected with the extension pipe, the utility model discloses a valve, including a feed box, a material collection box, a water inlet, a water outlet, a drain pipe, a valve, a discharge gate, a discharge pipe, a valve cover, a valve.

In the utility model, the motor, the cooling cylinder, the material collecting box, the feeding hole and the water inlet are coaxial.

According to the utility model, the material collecting box is of a regular nine-edge structure, material through holes are formed in nine side walls of the material collecting box, the distance between the top of the material collecting box and the top of the cooling cylinder is 10cm-15cm, and the distance between the bottom of the material collecting box and the bottom of the cooling cylinder is 10cm-15 cm.

In the utility model, the number of the layered die carriers is equal to the number of the edges of the material collecting box.

In the utility model, the diameter of the grid is smaller than that of the glass beads.

In the utility model, the grid net is not covered on the die carrier close to the end of the material collecting box, and the die carrier close to the end of the lengthening pipe is provided with a material through hole.

In the utility model, a plurality of object placing plates are arranged, and the length of the object placing plates is less than that of the layered die carrier.

In the utility model, the side wall of the end of the lengthening pipe, which is far away from the layered die carrier, is of an arc structure and is movably contacted with the inner side wall of the cooling cylinder, and a sealing ring is arranged at the contact part of the lengthening pipe and the inner side wall of the cooling cylinder.

In the utility model, the size of the discharge hole is smaller than that of the lengthening pipe.

To sum up, the beneficial effect of this application: the utility model arranges a layered conveying mechanism in a cooling cylinder, a material collecting box of the layered conveying mechanism rotates under the drive of a motor, the material collecting box drives a layered die carrier fixedly connected with the side wall of the material collecting box to rotate, a grid is covered on the layered die carrier, a plurality of object placing plates are arranged in the layered die carrier, glass microspheres are fed into the material collecting box from a feed inlet, the motor is started, the motor rotates at high speed to throw the glass microspheres into the layered die carrier, then the rotating speed of the motor is adjusted to slow down the rotating speed of the motor, the glass microspheres are on the object placing plates, water can pass through the grid because the diameter of the grid is smaller than that of the glass microspheres, the glass microspheres can not be flushed out of the layered die carrier, the rotation of the layered die carrier can accelerate the cooling, the glass microspheres can be cooled rapidly, a valve on a discharge outlet is opened after the cooling is finished, when the outlet of an extension pipe is aligned with the discharge outlet, the glass microspheres are thrown out of the cooling cylinder, the utility model can quickly cool the glass beads and greatly improve the production efficiency of the glass beads.

Drawings

Other features, objects and advantages of the present application will become more apparent upon reading of the following detailed description of non-limiting embodiments thereof, made with reference to the accompanying drawings in which:

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a left side view of the present invention;

FIG. 3 is a right side half-sectional view of the present invention;

FIG. 4 is a diagrammatic view of the layered conveyor of the present invention;

FIG. 5 is a first drawing of a layered scaffold of the present invention;

FIG. 6 is a second drawing of the layered scaffold of the present invention;

fig. 7 is a front view of the layered scaffold of the present invention.

Reference numbers in the figures: the device comprises a support-1, a cooling cylinder-2, a motor-3, a material collecting box-4, a layered die carrier-5, a die carrier-501, a grid-502, a storage plate-503, an extension pipe-6, a feed inlet-7, a water inlet-8, a water outlet-9, a discharge outlet-10 and a valve-11;

Detailed Description

The present application will be described in further detail with reference to the following drawings and examples. It is to be understood that the specific embodiments described herein are merely illustrative of the relevant invention and not restrictive of the utility model. It should be noted that, for convenience of description, only the portions related to the present invention are shown in the drawings.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict. The present application will be described in detail below with reference to the embodiments with reference to the attached drawings.

As shown in fig. 1-7, the layered conveying device for producing and processing glass beads capable of rapidly cooling comprises a support 1, a cooling cylinder 2, a motor 3, a material collecting box 4, a layered mold base 5, a mold base 501, a grid 502, a material placing plate 503, an elongated tube 6, a material inlet 7, a water inlet 8, a water outlet 9, a material outlet 10 and a valve 11, wherein the bottom of the cooling cylinder 2 is fixedly connected to the support 1, the motor 3 is fixedly connected to the bottom of the cooling cylinder 2 through screws, the output end of the motor 3 penetrates through the bottom of the cooling cylinder 2 and extends into the cooling cylinder 2, the material collecting box 4 is arranged in the cooling cylinder 2, the bottom of the material collecting box 4 and the output end of the motor 3 are fixedly connected, the layered mold base 5 is fixedly connected to the side wall of the material collecting box 4, the layered mold base 5 is composed of a basic frame by the mold base 501, the mold base 501 is covered with the grid 502, the rigid coupling has in the die carrier 501 put thing board 503, die carrier 501 keeps away from this end rigid coupling of case 4 that gathers materials has elongated tube 6, the top of case 4 that gathers materials has been seted up feed inlet 7, the rigid coupling has the inlet pipe on the feed inlet 7, the inlet pipe stretches out 2 outsides of cooling section of thick bamboo, the top of cooling section of thick bamboo 2 has been seted up water inlet 8, the rigid coupling has the inlet tube on the water inlet 8, the bottom of cooling section of thick bamboo 2 has been seted up outlet 9, the rigid coupling has the drain pipe on the outlet 9, is provided with on the drain pipe valve 11, seted up on the lateral wall of case 4 that gathers materials discharge gate 10, the rigid coupling has the discharging pipe on the discharge gate 10, be provided with on the discharging pipe valve 11. The motor 3, the cooling cylinder 2, the material collecting box 4, the feed inlet 7 and the water inlet 8 are coaxial. The material collecting box 4 is of a regular nine-edge body structure, material through openings are formed in nine side walls of the material collecting box 4, the distance between the top of the material collecting box 4 and the top of the cooling cylinder 2 is 10cm-15cm, and the distance between the bottom of the material collecting box 4 and the bottom of the cooling cylinder 2 is 10cm-15 cm. The number of the layered die carriers 5 is equal to the number of the edges of the material collecting box 4. The mesh 502 has a diameter less than the diameter of the glass microspheres. The die carrier 501 close to the end of the material collecting box 4 is not covered with the grid 502, and the die carrier 501 close to the end of the lengthening pipe 6 is provided with a material passing port. The plurality of object placing plates 503 are provided, and the length of the object placing plates 503 is smaller than that of the layered die carrier 5. The extension pipe 6 is far away from the side wall of the end of the layered die carrier 5 is of an arc-shaped structure and is in movable contact with the inner side wall of the cooling cylinder 2, and a sealing ring is arranged at the contact position of the extension pipe 6 and the inner side wall of the cooling cylinder 2. The size of the discharge hole 10 is smaller than that of the elongated tube 6.

The utility model arranges a layered conveying mechanism in a cooling cylinder, a material collecting box of the layered conveying mechanism rotates under the drive of a motor, the material collecting box drives a layered die carrier fixedly connected with the side wall of the material collecting box to rotate, a grid is covered on the layered die carrier, a plurality of object placing plates are arranged in the layered die carrier, glass microspheres are fed into the material collecting box from a feed inlet, the motor is started, the motor rotates at high speed to throw the glass microspheres into the layered die carrier, then the rotating speed of the motor is adjusted to slow down the rotating speed of the motor, the glass microspheres are on the object placing plates, water can pass through the grid because the diameter of the grid is smaller than that of the glass microspheres, the glass microspheres can not be flushed out of the layered die carrier, the rotation of the layered die carrier can accelerate the cooling, the glass microspheres can be cooled rapidly, a valve on a discharge outlet is opened after the cooling is finished, when the outlet of an extension pipe is aligned with the discharge outlet, the glass microspheres are thrown out of the cooling cylinder, the utility model can quickly cool the glass beads and greatly improve the production efficiency of the glass beads.

The foregoing description is only exemplary of the preferred embodiments of the application and is provided for the purpose of illustrating the general principles of the technology and the like. Meanwhile, the scope of the utility model according to the present application is not limited to the technical solutions in which the above-described technical features are combined in a specific manner, and also covers other technical solutions in which the above-described technical features or their equivalent are combined arbitrarily without departing from the inventive concept described above. For example, the above features may be replaced with (but not limited to) features having similar functions disclosed in the present application.

Claims

1. But layering conveyor of glass microballon production and processing of rapid cooling, including support (1), a cooling section of thick bamboo (2), motor (3), case (4) that gathers materials, layering die carrier (5), die carrier (501), graticule mesh (502), put thing board (503), extension pipe (6), feed inlet (7), water inlet (8), outlet (9), discharge gate (10), valve (11), characterized by: the bottom rigid coupling of a cooling section of thick bamboo (2) is in on support (1), motor (3) are in through the screw rigid coupling the bottom of a cooling section of thick bamboo (2), the output of motor (3) passes the bottom of a cooling section of thick bamboo (2) and stretches into inside a cooling section of thick bamboo (2), material collection case (4) set up in a cooling section of thick bamboo (2), the bottom of material collection case (4) and the output rigid coupling of motor (3), layering die carrier (5) with the lateral wall rigid coupling of material collection case (4), layering die carrier (5) by die carrier (501) constitute basic frame, die carrier (501) coats outward and is stamped graticule mesh (502), the rigid coupling has in die carrier (501) puts thing board (503), die carrier (501) are kept away from this end rigid coupling of material collection case (4) have elongated tube (6), feed inlet (7) have been seted up at the top of material collection case (4), the rigid coupling has the inlet pipe on feed inlet (7), and the inlet pipe stretches out a cooling section of thick bamboo (2) are outside, seted up at the top of a cooling section of thick bamboo (2) water inlet (8), the rigid coupling has the inlet tube on water inlet (8), seted up the bottom of a cooling section of thick bamboo (2) outlet (9), the rigid coupling has the drain pipe on outlet (9), is provided with on the drain pipe valve (11), seted up on the lateral wall of case (4) that gathers materials discharge gate (10), the rigid coupling has the discharging pipe on discharge gate (10), is provided with on the discharging pipe valve (11).

2. The layered delivery apparatus for the production and processing of glass microspheres capable of rapid cooling as claimed in claim 1, wherein: the motor (3), the cooling cylinder (2), the material collecting box (4), the feed inlet (7) and the water inlet (8) are coaxial.

3. The layered delivery apparatus for the production and processing of glass microspheres capable of rapid cooling as claimed in claim 1, wherein: the material collecting box (4) is of a regular nine-edge body structure, a material through opening is formed in nine side walls of the material collecting box (4), the top of the material collecting box (4) and the top interval of the cooling cylinder (2) are 10cm-15cm, and the bottom of the material collecting box (4) and the bottom interval of the cooling cylinder (2) are 10cm-15 cm.

4. The layered delivery apparatus for the production and processing of glass microspheres capable of rapid cooling as claimed in claim 1, wherein: the number of the layered die carriers (5) is equal to the number of the edges of the material collecting box (4).

5. The layered delivery apparatus for the production and processing of glass microspheres capable of rapid cooling as claimed in claim 1, wherein: the diameter of the mesh (502) is smaller than the diameter of the glass microspheres.

6. The layered delivery apparatus for the production and processing of glass microspheres capable of rapid cooling as claimed in claim 1, wherein: the grid (502) is not covered on the die carrier (501) close to the end of the material collecting box (4), and a material passing opening is formed in the die carrier (501) close to the end of the lengthening pipe (6).

7. The layered delivery apparatus for the production and processing of glass microspheres capable of rapid cooling as claimed in claim 1, wherein: the plurality of object placing plates (503) are provided, and the length of the object placing plates (503) is smaller than that of the layered die carrier (5).

8. The layered delivery apparatus for the production and processing of glass microspheres capable of rapid cooling as claimed in claim 1, wherein: keep away from extension pipe (6) this end lateral wall of layering die carrier (5) be the arc structure and with cooling section of thick bamboo (2) inside wall movable contact, extension pipe (6) and cooling section of thick bamboo (2) inside wall contact department are provided with the sealing washer.

9. The layered delivery apparatus for the production and processing of glass microspheres capable of rapid cooling as claimed in claim 1, wherein: the size of the discharge hole (10) is smaller than that of the lengthening pipe (6).