CN210877381U - Improved generation three-dimensional tectorial membrane sand apparatus for producing - Google Patents

Abstract

The utility model relates to a tectorial membrane sand apparatus for producing technical field discloses a three-dimensional tectorial membrane sand apparatus for producing of improved generation, including the agitator staving, the controller is installed at the top of the front side of agitator staving, and the four corners of the bottom of agitator staving all is connected with the supporting legs, the intermediate position of the bottom of agitator staving is provided with first motor, the bottom of agitator staving is connected with two discharging pipes, two batching feed inlets have been seted up on the top of agitator staving, the position that the top of agitator staving is close to the batching feed inlet is connected with batching and puts in the device. The utility model discloses a feeder hopper, dust fluidization room, deflector, second motor, flabellum, dust exhaust pipe and dust collection box reach and get rid of a small amount of dust in the raw materials quartz sand before mixing with the batching with the raw materials quartz sand to improve the quality of the tectorial membrane sand of producing, improved this tectorial membrane sand apparatus for producing's practicality.

Description

Improved generation three-dimensional tectorial membrane sand apparatus for producing

Technical Field

The utility model relates to a tectorial membrane sand apparatus for producing technical field specifically is a three-dimensional tectorial membrane sand apparatus for producing of improved generation.

Background

The precoated sand refers to molding sand or core sand with a layer of solid resin film coated on the surface of sand grains before molding. There are two film-coating processes of cold method and hot method: dissolving the resin with ethanol by a cold method, adding urotropine in the sand mixing process to coat the urotropine and the sand on the surface of sand grains, and volatilizing the ethanol to obtain precoated sand; the heat method is to preheat the sand to a certain temperature, add resin to melt the sand, stir the sand to coat the resin on the surface of the sand, add urotropine water solution and lubricant, mix evenly, cool, crush and screen to obtain the precoated sand. Whether the cold method or the hot method is adopted, quartz sand and urotropine and other ingredients need to be uniformly stirred and mixed. In the production process of the precoated sand, the raw material quartz sand and the ingredients are uniformly mixed, which is an important production process.

There are multiple tectorial membrane sand production mixing arrangement in the existing market, but when these tectorial membrane sand production mixing arrangement ubiquitous sent into the agitator with quartz sand raw materials again, can not be convenient get rid of a small amount of dust in the quartz sand, and can not be convenient send the batching into in the agitator. Therefore, the technical personnel in the field provide an improved three-dimensional precoated sand production device to solve the problems in the background art.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a three-dimensional tectorial membrane sand apparatus for producing of improved generation to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

an improved three-dimensional precoated sand production device comprises a stirring barrel body, wherein a controller is installed at the top of the front side of the stirring barrel body, supporting legs are connected to four corners of the bottom end of the stirring barrel body, a first motor is arranged at the middle position of the bottom end of the stirring barrel body, two discharge pipes are connected to the bottom end of the stirring barrel body, two batching feed inlets are formed in the top end of the stirring barrel body, a batching feeding device is connected to the position, close to the batching feed inlets, of the top end of the stirring barrel body, a raw material feed inlet is formed in one side of the stirring barrel body, a dust removal device is connected to the position, close to the raw material feed inlet, of one side of the stirring barrel body, a stirring rod is connected to the top end of the first motor, and stirring blades are installed;

the dust collector comprises a dust fluidization chamber, a feed hopper is arranged at the top end of the dust fluidization chamber, the bottom of the inner side of the dust fluidization chamber is connected with a guide plate, two fan blade housings are arranged on one side of the dust fluidization chamber, one sides of the two fan blade housings, which are far away from the dust fluidization chamber, are connected with a dust exhaust pipe, the bottom end of the dust exhaust pipe is connected with a dust collection box, a second motor is arranged on the inner side of each fan blade housing, and fan blades are arranged on one side, which is close to the dust fluidization chamber, of the second motor.

As a further aspect of the present invention: batching feeding device includes the batching bucket, the bottom of batching bucket is provided with batching bucket and arranges the material pipe, the bottom in the outside of batching bucket is connected with two clamps, one side that two clamps were kept away from each other all is connected with electric cylinder, electric cylinder's bottom all is connected with the electric cylinder mount pad, the outside that the material pipe was arranged to the batching bucket is provided with the solenoid valve.

As a further aspect of the present invention: the first motor, the electric cylinder, the electromagnetic valve and the second motor are electrically connected with the controller.

As a further aspect of the present invention: the fan blade dust removal device is characterized in that a vent hole is formed in the position, close to the fan blade housing, of one side of the dust exhaust pipe, one side of the dust fluidization chamber is connected with the stirring barrel body, and a discharge hole is formed in the position, close to the guide plate, of one side of the dust fluidization chamber.

As a further aspect of the present invention: the batching bucket is arranged the material pipe and is connected with the inside of batching feed inlet.

As a further aspect of the present invention: the internal diameter of clamp and the external diameter looks adaptation of batching bucket.

Compared with the prior art, the beneficial effects of the utility model are that:

1. through the batching barrel, the electric cylinder, the clamp, the material pipe is arranged to solenoid valve and batching barrel, when needing to send the batching into the batching barrel and stir with the raw materials quartz sand, at first put the batching barrel that is equipped with the batching between two clamps, and arrange the material pipe with the batching barrel and place the inboard at the batching feed inlet, then open the electric cylinder, the piston rod of electric cylinder drives the clamp and moves and the batching barrel contacts towards the direction of batching barrel, make two clamps fix the batching barrel, when needing to pour into the batching barrel, open the solenoid valve through the controller, thereby make the batching in the batching barrel pour into the batching barrel from batching barrel row material pipe and batching feed inlet into the batching barrel, thereby reach the convenient mesh of pouring into the batching barrel, and the volume of the batching that can be convenient control pours into the batching in the batching barrel, thereby make things convenient for staff's use, the practicality of this tectorial membrane sand apparatus for producing is improved.

2. Through the feeder hopper, the dust fluidization chamber, the deflector, the second motor, the flabellum, dust exhaust pipe and dust collection box, when injecting raw materials quartz sand into the agitator staving, at first be connected external raw materials quartz sand input mechanism with the feeder hopper, make raw materials quartz sand drop into the dust fluidization chamber from the feeder hopper, at the in-process that raw materials quartz sand freely descends in the dust fluidization chamber, open the second motor, the output shaft of second motor drives the flabellum and rotates, in order to discharge the dust in the dust fluidization chamber into the dust collection box through the dust exhaust pipe, raw materials quartz sand falls into the agitator staving through the deflector and has carried out the mixing operation, thereby reach and get rid of a small amount of dust in the raw materials quartz sand before mixing with the batching at raw materials quartz sand, thereby the quality of the tectorial membrane sand that has produced has been improved, the practicality of this tectorial membrane sand apparatus for producing has been.

Drawings

FIG. 1 is a schematic structural diagram of an improved three-dimensional precoated sand production device;

FIG. 2 is a partial sectional view of a stirring barrel body and a dust removing device in the improved three-dimensional precoated sand production device;

FIG. 3 is a schematic view of a part of a dispensing device in an improved three-dimensional precoated sand production device;

fig. 4 is a partial sectional view of a dust removing device in an improved three-dimensional precoated sand production device.

In the figure: 1. a stirring barrel body; 2. a dust removal device; 3. a dosing device; 4. a controller; 5. supporting legs; 6. a material feeding port; 7. a first motor; 8. a discharge pipe; 9. stirring blades; 10. a stirring rod; 11. a raw material inlet; 21. a fan blade housing; 22. a second motor; 23. a dust exhaust pipe; 24. a feed hopper; 25. a fan blade; 26. a dust fluidization chamber; 27. a guide plate; 28. a dust collection box; 31. a batching barrel; 32. clamping a hoop; 33. an electromagnetic valve; 34. a discharge pipe of the batching barrel; 35. an electric cylinder mounting seat; 36. an electric cylinder.

Detailed Description

Referring to fig. 1-4, in the embodiment of the present invention, an improved three-dimensional precoated sand production device comprises a stirring barrel body 1, a controller 4 is installed on the top of the front side of the stirring barrel body 1, supporting legs 5 are connected to four corners of the bottom end of a stirring barrel body 1, a first motor 7 is arranged in the middle of the bottom end of the stirring barrel body 1, two discharging pipes 8 are connected to the bottom end of the stirring barrel body 1, two batching feed inlets 6 are formed in the top end of the stirring barrel body 1, a batching feeding device 3 is connected to the position, close to the batching feed inlets 6, of the top end of the stirring barrel body 1, a raw material feed inlet 11 is formed in one side of the stirring barrel body 1, a dust removing device 2 is connected to the position, close to the raw material feed inlet 11, of one side of the stirring barrel body 1, a stirring rod 10 is connected to the top end of the first motor 7, and stirring blades 9;

the dust removing device 2 comprises a dust fluidizing chamber 26, a feed hopper 24 is arranged at the top end of the dust fluidizing chamber 26, a guide plate 27 is connected to the bottom of the inner side of the dust fluidizing chamber 26, two fan blade cover shells 21 are arranged on one side of the dust fluidizing chamber 26, a dust exhaust pipe 23 is connected to one side, far away from the dust fluidizing chamber 26, of the two fan blade cover shells 21, a dust collection box 28 is connected to the bottom end of the dust exhaust pipe 23, a second motor 22 is installed on the inner side of the fan blade cover shell 21, and fan blades 25 are installed on one side, close to the dust fluidizing chamber 26.

In fig. 3: the batching feeding device 3 comprises a batching barrel 31, a batching barrel discharging pipe 34 is arranged at the bottom end of the batching barrel 31, two hoops 32 are connected to the bottom of the outer side of the batching barrel 31, an electric cylinder 36 is connected to one side, away from each other, of the two hoops 32, an electric cylinder mounting seat 35 is connected to the bottom end of the electric cylinder 36, an electromagnetic valve 33 is arranged at the outer side of the batching barrel discharging pipe 34, so that when batching is required to be fed into the batching barrel body 1 to be stirred with raw material quartz sand, firstly, the batching barrel 31 with the batching is placed between the two hoops 32, the batching barrel discharging pipe 34 is placed at the inner side of a batching feeding port 6, then, the electric cylinder 36 is opened, a piston rod of the electric cylinder 36 drives the hoops 32 to move towards the batching barrel 31 and the batching barrel 31 to be contacted, so that the batching barrel 31 is fixed by the two hoops 32, open solenoid valve 33 through controller 4 to make the batching in the batching bucket 31 arrange the material pipe 34 and batching feed inlet 6 from the batching bucket and pour into in the agitator staving 1, thereby reach the purpose of conveniently pouring into the batching in the agitator staving 1.

In fig. 1, 2, 3 and 4: the first motor 7, the electric cylinder 36, the electromagnetic valve 33 and the second motor 22 are all electrically connected with the controller 4, so that the controller 4 can control the first motor 7, the electric cylinder 36, the electromagnetic valve 33 and the second motor 22 to work.

In fig. 4: a vent hole is arranged at the position of one side of the dust exhaust pipe 23 close to the fan blade cover 21, one side of the dust fluidization chamber 26 is connected with the stirring barrel body 1, and a discharge hole is arranged at the position of one side of the dust fluidization chamber 26 close to the guide plate 27, so that dust in the dust fluidization chamber 26 can enter the dust collection box 28 through the dust exhaust pipe 23.

In fig. 1: the batching bucket is arranged material pipe 34 and is connected with the inside of batching feed inlet 6 to batching in the batching bucket 31 can be followed batching bucket and arranged material pipe 34 and batching feed inlet 6 and pour into in the agitator staving 1.

In fig. 3: the inner diameter of the clips 32 is adapted to the outer diameter of the dispensing container 31, so that the two clips 32 can firmly fix the dispensing container 31.

The utility model discloses a theory of operation is: when raw material quartz sand needs to be injected into the stirring barrel body 1, firstly, an external raw material quartz sand feeding mechanism is connected with the feed hopper 24, so that the raw material quartz sand is fed into the dust fluidization chamber 26 from the feed hopper 24, in the process that the raw material quartz sand freely descends in the dust fluidization chamber 26, the second motor 22 is opened, an output shaft of the second motor 22 drives the fan blades 25 to rotate, so that dust in the dust fluidization chamber 26 is discharged into the dust collection box 28 through the dust discharge pipe 23, the raw material quartz sand falls into the stirring barrel body 1 through the guide plate 27 to be mixed, when the ingredients need to be fed into the stirring barrel body 1 to be stirred with the raw material quartz sand, firstly, the ingredient mixing barrel 31 filled with the ingredients is placed between the two hoops 32, the ingredient discharge pipe 34 is placed on the inner side of the ingredient feed inlet 6, then the electric cylinder 36 is opened, the piston rod of the electric cylinder 36 drives the hoops 32 to move towards the direction of the ingredient mixing barrel 31 and contact the, make two clamps 32 fix batching bucket 31, when need inject the batching into in the agitator tank body 1, open solenoid valve 33 through controller 4 to make the batching in the batching bucket 31 arrange the material pipe 34 and batching feed inlet 6 from the batching bucket and pour into in the agitator tank body 1.

The above-mentioned, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (6)

1. An improved three-dimensional precoated sand production device comprises a stirring barrel body (1), and is characterized in that a controller (4) is installed at the top of the front side of the stirring barrel body (1), supporting legs (5) are connected to four corners of the bottom of the stirring barrel body (1), a first motor (7) is arranged at the middle position of the bottom of the stirring barrel body (1), two discharging pipes (8) are connected to the bottom of the stirring barrel body (1), two batching feeding ports (6) are arranged at the top of the stirring barrel body (1), a batching feeding device (3) is connected to the position, close to the batching feeding ports (6), of the top of the stirring barrel body (1), a raw material feeding port (11) is arranged on one side of the stirring barrel body (1), and a dust removal device (2) is connected to the position, close to the raw material feeding port (11), of one side of the stirring barrel body (1), the top end of the first motor (7) is connected with a stirring rod (10), and stirring blades (9) are arranged on two sides of the stirring rod (10);

dust collector (2) include dust fluidization chamber (26), the top of dust fluidization chamber (26) is provided with feeder hopper (24), the bottom of the inboard of dust fluidization chamber (26) is connected with deflector (27), one side of dust fluidization chamber (26) is provided with two fan blade housings (21), one side that dust fluidization chamber (26) was kept away from in two fan blade housings (21) is connected with dust exhaust pipe (23) jointly, the bottom of dust exhaust pipe (23) is connected with dust collection box (28), second motor (22) are installed to the inboard of fan blade housing (21), second motor (22) are close to one side of dust fluidization chamber (26) and install flabellum (25).

2. The improved stereoscopic precoated sand production device according to claim 1, wherein the batching feeding device (3) comprises a batching barrel (31), the bottom end of the batching barrel (31) is provided with a batching barrel discharging pipe (34), the bottom of the outer side of the batching barrel (31) is connected with two clamps (32), one side of the two clamps (32) which are far away from each other is connected with an electric cylinder (36), the bottom end of the electric cylinder (36) is connected with an electric cylinder mounting seat (35), and the outer side of the batching barrel discharging pipe (34) is provided with a solenoid valve (33).

3. The improved stereoscopic precoated sand production device according to claim 2, wherein the first motor (7), the electric cylinder (36), the electromagnetic valve (33) and the second motor (22) are electrically connected with the controller (4).

4. The improved three-dimensional precoated sand production device according to claim 1, wherein a vent hole is formed in a position, close to the fan blade cover (21), of one side of the dust exhaust pipe (23), one side of the dust fluidization chamber (26) is connected with the stirring barrel body (1), and a discharge hole is formed in a position, close to the guide plate (27), of one side of the dust fluidization chamber (26).

5. The improved stereoscopic precoated sand production device according to claim 2, wherein the discharge pipe (34) of the batching barrel is connected with the inside of the batching feed inlet (6).

6. The improved stereoscopic precoated sand production device according to claim 2, wherein the inner diameter of the clamp (32) is adapted to the outer diameter of the dosing barrel (31).

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