CN215952295U - Cooling bin of high-strength resin binder - Google Patents

Abstract

The utility model discloses a cooling bin for a high-strength resin binder, which comprises: the primary cooling structure is arranged on the outer side of the shell, the upper side of the shell is fixedly arranged with the carrying platform, a feeding opening is formed in the carrying platform, and a speed reducing motor is arranged on the surface of the carrying platform through the base; the second grade cooling structure, the fixed setting of second grade cooling structure is in the inside of feed bin body, and the fixed setting of cooling coil one end and inlet tube of second grade cooling structure, and the cooling coil other end sets up with the outlet pipe is fixed simultaneously. This cooling feed bin of high-strength resin binder, the inside material of feed bin body carries out while heat dissipation work through one-level cooling structure, second grade cooling structure and tertiary cooling structure, and three cooling structure simultaneous workings of group can improve the cooling effect to the inside material of feed bin body, and refrigerated is efficient, reduces the time that the inside material of feed bin body cools off to target temperature.

Description

Cooling bin of high-strength resin binder

Technical Field

The utility model relates to the field of chemical industry, in particular to a cooling bin for a high-strength resin binder.

Background

(RESIN) binder or mastic refers to RESIN (RESIN) obtained from a tree (pistacia chinensis bunge) growing in a country of mediterranean border; it is sold on the market as light amber-colored granules, just like small peas.

In the production of elastic resin, after the reaction end point is reached, it needs to be cooled, and the patent with the publication number of CN213102185U, through search, discloses a rosin resin reaction kettle with a cooling device, wherein "water cooling pipes matched with the reaction kettle body are uniformly wound on the outer side of the reaction kettle body," only the shell wall on the outer side of the reaction kettle can be cooled only through the water cooling pipes, but the materials in the reaction kettle cannot be cooled sufficiently, and the device has the defects of low working efficiency and long cooling time.

In view of the above, the present invention has been made in view of the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a cooling bin for high-strength resin binder, which solves the defects mentioned in the background technology.

In order to achieve the above object, there is provided a cooling bunker for a high-strength resin binder, comprising:

the primary cooling structure is arranged on the outer side of the shell, the upper side of the shell is fixedly arranged with the carrying platform, a feeding opening is formed in the carrying platform, and a speed reducing motor is arranged on the surface of the carrying platform through the base;

the secondary cooling structure is fixedly arranged inside the bin body, one end of a cooling coil of the secondary cooling structure is fixedly arranged with the water inlet pipe, and the other end of the cooling coil is fixedly arranged with the water outlet pipe;

a vertical pipe of the three-stage cooling structure is arranged inside the shell, and an extension pipe is fixedly arranged on the left side surface of the vertical pipe;

the feed bin body, the shell bottom of feed bin body supports through the supporting seat, and shell internally mounted has the puddler, and the tip of puddler passes through the fixed setting of shaft coupling and gear motor's output shaft simultaneously.

Preferably, the second-stage cooling structure comprises a water inlet pipe, a cooling coil and a water outlet pipe, the end part of the water inlet pipe is communicated with the water outlet end of the cooling water booster pump, and the end part of the water outlet pipe is communicated with the cooling water tower.

Preferably, the cooling coil is the helical structure who is made by metal copper material, and the cooling coil is close to the shell inner wall setting, and the cooling coil passes through the support mounting inside the shell.

Preferably, tertiary cooling structure includes communicating pipe, standpipe, connecting pipe and extension pipe, and the standpipe evenly sets up to four groups in feed bin body inside, communicates through the connecting pipe between four groups of standpipes simultaneously.

Preferably, two groups of extension pipes are arranged on the surface of the vertical pipe, and the extension pipes and the stirring blades are arranged alternately.

Preferably, the bottom of standpipe sets up for the slope, and the upper end of standpipe passes through communicating pipe and outlet pipe intercommunication setting, and communicating pipe is "L" shape structure that copper metal material made.

Preferably, the feed bin body includes gear motor, microscope carrier, shell, supporting seat, puddler, charge door and stirring leaf, and the stirring leaf evenly sets up to the multiunit in the outside of puddler, is provided with the extension pipe between adjacent two sets of stirring leaves.

Compared with the prior art, the utility model has the beneficial effects that: the inside material of feed bin body carries out while heat dissipation work through one-level cooling structure, second grade cooling structure and tertiary cooling structure, and three cooling structure simultaneous workings of group can improve the cooling effect to the inside material of feed bin body, and refrigerated is efficient, reduces the time that the inside material of feed bin body cools off to target temperature.

Drawings

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

FIG. 2 is a schematic sectional view taken along line A-A in FIG. 1;

FIG. 3 is a schematic cross-sectional view taken along line B-B in FIG. 1;

fig. 4 is a top view of the structure stage of the present invention.

Reference numbers in the figures: 1. a primary cooling structure; 2. a secondary cooling structure; 21. a water inlet pipe; 22. a cooling coil; 23. a water outlet pipe; 3. a tertiary cooling structure; 31. a communicating pipe; 32. a vertical tube; 33. a connecting pipe; 34. an extension pipe; 4. a bin body; 41. a reduction motor; 42. a stage; 43. a housing; 44. a supporting seat; 45. a stirring rod; 46. a feed inlet; 47. stirring the leaves.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a cooling bin for high-strength resin binder, comprising: the device comprises a primary cooling structure 1, a secondary cooling structure 2, a tertiary cooling structure 3 and a stock bin body 4;

primary cooling structure 1 is arranged outside housing 43, the upper side of housing 43 is fixed with stage 42, simultaneously, stage 42 is provided with feed inlet 46, and the surface of stage 42 is provided with speed reducing motor 41 through the base;

the secondary cooling structure 2 is fixedly arranged inside the bin body 4, one end of a cooling coil 22 of the secondary cooling structure 2 is fixedly arranged with the water inlet pipe 21, and the other end of the cooling coil 22 is fixedly arranged with the water outlet pipe 23;

the vertical pipe 32 of the tertiary cooling structure 3 is arranged inside the shell 43, and the left surface of the vertical pipe 32 is fixedly provided with the extension pipe 34;

the bottom of the outer shell 43 of the silo body 4 is supported by the supporting seat 44, the stirring rod 45 is arranged inside the outer shell 43, and the end of the stirring rod 45 is fixedly arranged with the output shaft of the speed reducing motor 41 through the coupler.

The inside material of feed bin body 4 carries out while heat dissipation work through one-level cooling structure 1, second grade cooling structure 2 and tertiary cooling structure 3, and three cooling structure simultaneous workings of group can improve the cooling effect to the inside material of feed bin body 4, and refrigerated is efficient, reduces the time of the inside material cooling of feed bin body 4 to target temperature.

As a preferred embodiment, the secondary cooling structure 2 includes a water inlet pipe 21, a cooling coil 22 and a water outlet pipe 23, and the end of the water inlet pipe 21 is communicated with the water outlet end of the cooling water booster pump, and the end of the water outlet pipe 23 is communicated with the cooling water tower.

As shown in fig. 1: the cooling water enters the cooling coil 22 through the water inlet pipe 21 by the booster pump, the other water outlet end of the cooling coil 22 is bent upward and communicated with the water outlet pipe 23, and the water inside the cooling coil 22 enters the external cooling tower through the water outlet pipe 23 for cooling.

In a preferred embodiment, the cooling coil 22 is a spiral structure made of copper material, and the cooling coil 22 is disposed near the inner wall of the housing 43, and the cooling coil 22 is mounted inside the housing 43 by a bracket.

Copper has good heat conductivity, and can improve the cooling effect of cooling water in the cooling coil 22 on high-temperature materials in the shell 43.

As a preferred embodiment, the tertiary cooling structure 3 includes a communicating pipe 31, stand pipes 32, connecting pipes 33 and extension pipes 34, and the stand pipes 32 are uniformly arranged in four groups inside the silo body 4, and the four groups of stand pipes 32 are communicated with each other through the connecting pipes 33.

As shown in fig. 1: the stirring blades 47 rotate under the action of the stirring rod 45 and the speed reduction motor 41, the stirring blades 47 rotate to stir the materials inside the shell 43, and the extension pipe 34 is used for performing sufficient heat exchange work cooling work on the materials inside the shell 43.

In a preferred embodiment, two sets of extension pipes 34 are disposed on the surface of the standpipe 32, and the extension pipes 34 are spaced apart from the stirring blades 47.

As a preferred embodiment, the bottom of the vertical tube 32 is disposed obliquely, the upper end of the vertical tube 32 is disposed in communication with the water outlet pipe 23 through the communication tube 31, and the communication tube 31 is an "L" shaped structure made of copper metal.

Inside the inside cooling water of inlet tube 21 enters into standpipe 32 through inlet tube 21 and communicating pipe 31, communicates the work through connecting pipe 33 between four group's standpipes 32 to guarantee the cooling effect of four group's standpipes 32 to the inside material of shell 43, inside 23 inside outlet pipes, the external world of discharging were injected into to the inside liquid accessible communicating pipe 31 to after the material cooling of standpipe 32.

As a preferred embodiment, the storage bin body 4 includes a speed reduction motor 41, a carrying platform 42, a housing 43, a supporting seat 44, a stirring rod 45, a feeding port 46 and stirring blades 47, wherein the stirring blades 47 are uniformly arranged in multiple groups outside the stirring rod 45, and an extension pipe 34 is arranged between two adjacent groups of stirring blades 47.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. A cooling feed bin of high-strength resin bonding agent, characterized by comprising:

the cooling structure comprises a primary cooling structure (1), wherein the primary cooling structure (1) is arranged on the outer side of a shell (43), the upper side of the shell (43) is fixedly arranged with a carrier (42), a feed inlet (46) is arranged on the carrier (42), and a speed reducing motor (41) is arranged on the surface of the carrier (42) through a base;

the secondary cooling structure (2) is fixedly arranged inside the bin body (4), one end of a cooling coil (22) of the secondary cooling structure (2) is fixedly arranged with the water inlet pipe (21), and the other end of the cooling coil (22) is fixedly arranged with the water outlet pipe (23);

the three-stage cooling structure (3), wherein a vertical pipe (32) of the three-stage cooling structure (3) is arranged inside the shell (43), and an extension pipe (34) is fixedly arranged on the left side surface of the vertical pipe (32);

feed bin body (4), shell (43) bottom of feed bin body (4) is supported through supporting seat (44), and shell (43) internally mounted has puddler (45), and the tip of puddler (45) passes through the fixed setting of output shaft of shaft coupling and gear motor (41) simultaneously.

2. The cooling silo of a high-strength resin binder of claim 1, characterized in that: and the secondary cooling structure (2) comprises a water inlet pipe (21), a cooling coil (22) and a water outlet pipe (23), the end part of the water inlet pipe (21) is communicated with the water outlet end of the cooling water booster pump, and the end part of the water outlet pipe (23) is communicated with the cooling water tower.

3. The cooling silo of a high-strength resin binder of claim 2, characterized in that: the cooling coil (22) is of a spiral structure made of metal copper materials, the cooling coil (22) is arranged close to the inner wall of the shell (43), and the cooling coil (22) is installed inside the shell (43) through a support.

4. The cooling silo of a high-strength resin binder of claim 1, characterized in that: tertiary cooling structure (3) are including communicating pipe (31), standpipe (32), connecting pipe (33) and extension pipe (34), and standpipe (32) evenly set up to four groups in feed bin body (4) inside, communicate through connecting pipe (33) between four groups standpipe (32) simultaneously.

5. The cooling silo of a high-strength resin binder of claim 4, characterized in that: two groups of extension pipes (34) are arranged on the surface of the vertical pipe (32), and the extension pipes (34) and the stirring blades (47) are arranged alternately.

6. The cooling silo of a high-strength resin binder of claim 4, characterized in that: the bottom of standpipe (32) sets up for the slope, and the upper end of standpipe (32) passes through communicating pipe (31) and outlet pipe (23) intercommunication setting, and communicating pipe (31) are the "L" shape structure that copper metal material made.

7. The cooling silo of a high-strength resin binder of claim 1, characterized in that: feed bin body (4) include gear motor (41), microscope carrier (42), shell (43), supporting seat (44), puddler (45), charge door (46) and stirring leaf (47), and stirring leaf (47) evenly set up to the multiunit in the outside of puddler (45), are provided with between adjacent two sets of stirring leaf (47) extension pipe (34).

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