CN117962159A - Rubber tube production compounding device - Google Patents

Abstract

The invention discloses a rubber tube production mixing device which comprises a box body, a driving assembly, a stirring assembly, a linkage assembly, a discharging assembly and a feeding assembly, wherein the stirring assembly in the box body is driven to stir rubber raw materials in the box body in a bidirectional manner, the linkage assembly is driven to move in the box body when the stirring assembly is reversed every time, after stirring for a certain number of times, the linkage assembly is connected with the feeding assembly positioned at the top of the box body, along with forward rotation of the stirring assembly, the feeding in the storage box at the top of the box body is sent into the box body, along with the reverse rotation of the stirring assembly, the linkage assembly is separated from the feeding assembly and connected with the storage box, the storage box is driven to rotate for a certain angle, so that a cavity in which the next feeding is stored is moved to the upper part of the feeding assembly, and the reciprocating manner is realized, and when the rubber raw materials are mixed, the feeding in the raw materials are automatically carried out in sequence.

Description

Rubber tube production compounding device

Technical Field

The invention relates to the technical field of rubber tube production, in particular to a mixing device for rubber tube production.

Background

The rubber is a high-elasticity polymer material with reversible deformation, is elastic at room temperature, can generate larger deformation under the action of small external force, and can recover after the external force is removed. The rubber is a completely amorphous polymer with a low glass transition temperature and often a large molecular weight, greater than several hundred thousand. Rubber is divided into natural rubber and synthetic rubber, wherein the natural rubber is prepared by extracting colloid from plants such as rubber trees, rubber grass and the like; the synthetic rubber is obtained by polymerizing various monomers. Rubber products are widely used in industry or life.

In the production process of rubber tubes, rubber raw materials need to be mixed, raw rubber needs to be added firstly for stirring during mixing, and solid softening agents, activating agents, antioxidants, fillers, plasticizers and the like are sequentially added, but in order to ensure the correct feeding sequence, the existing mixing device needs to manually stand nearby a mixer to sequentially feed materials in the mixer, and labor cost is wasted.

Disclosure of Invention

This section is intended to outline some aspects of embodiments of the application and to briefly introduce some preferred embodiments. Some simplifications or omissions may be made in this section as well as in the description of the application and in the title of the application, which may not be used to limit the scope of the application.

The present invention has been made in view of the above and/or problems occurring in the prior art mixing devices for rubber tube production.

Therefore, the invention aims to provide a rubber tube production mixing device, a driving assembly and a storage box are arranged at the top of a box body, the inside of the storage box is divided into a plurality of chambers through a partition plate, different feeds are sequentially filled in the chambers according to sequence, a stirring assembly in the box body is driven to stir rubber raw materials in the box body in a bidirectional manner, a linkage assembly is driven to move in the box body when the stirring device is reversed each time, after stirring for a certain number of times, the linkage assembly is connected with a feeding assembly positioned at the top of the box body, the feeds in the storage box at the top of the box body are sent into the box body along with forward rotation of the stirring device, the linkage assembly is separated from the feeding assembly along with the reverse rotation of the stirring device again and is connected with the storage box body, the storage box is driven to rotate for a certain angle, so that a cavity storing the next feeds in the storage box is moved to the upper part of the feeding assembly, and the reciprocating motion is realized, and when the rubber raw materials are mixed, the feeds in the sequence are automatically.

In order to solve the technical problems, according to one aspect of the present invention, the following technical solutions are provided:

a rubber tube production compounding device, which includes:

The box body is provided with a cover plate at the top, a feed inlet is formed in the top of the cover plate, a discharge hole is formed in the bottom of the box body, a baffle is hinged in the discharge hole, an observation window is formed in the side wall of the box body, and transparent glass is arranged in the observation window;

The driving assembly is arranged at the top of the cover plate;

the stirring assembly is positioned in the box body and connected with the driving assembly, and the driving assembly drives the stirring assembly to bidirectionally rotate so as to stir and mix rubber raw materials in the box body;

The linkage assembly is positioned in the box body and connected with the stirring assembly, and moves horizontally in the box body along with each inversion of the stirring assembly;

The discharging assembly comprises a mounting plate arranged at the top of the cover plate, a fixed sealing sleeve arranged at the top of the mounting plate and a storage box rotatably connected in the fixed sealing sleeve, a first feeding hole is formed in the bottom of the fixed sealing sleeve, a plurality of partition plates are arranged in the storage box, the inside of the storage box is divided into a plurality of chambers by the partition plates, a second feeding hole is formed in each chamber, and one of the second feeding holes is communicated with the first feeding hole in an initial state;

The feeding assembly is positioned at the top of the box body;

When the stirring assembly rotates reversely for 6 times, the linkage assembly is connected with the feeding assembly, the feeding assembly is driven to feed materials falling from the first feeding port, the corresponding second feeding port and the cavity of the second feeding port into the feeding port along with forward rotation of the stirring assembly, the linkage assembly is driven to be separated from the feeding assembly and connected with the discharging assembly along with continuous reverse rotation of the stirring assembly, the material storage box is driven to rotate, the next second feeding port of the cavity is connected with the first feeding port, and the materials in the cavity fall into the feeding assembly through the first feeding port.

As a preferable scheme of the rubber tube production mixing device, the driving assembly comprises a motor arranged at the top of the box body, a rotary table arranged at the output end of the motor and a fixed frame coaxially fixed with the rotary table and positioned outside the rotary table, wherein a first semicircular rack is arranged at one half of the outer wall of the rotary table, and a second semicircular rack is arranged at the half of the inner wall of the fixed frame opposite to the first semicircular rack.

As a preferable scheme of the rubber tube production mixing device, a circular rack is arranged at the bottom of the cover plate;

the stirring assembly comprises a rotary table located inside the box body, a third rotary rod installed at the top of the rotary table and extending out of the top of the cover plate, a fourth gear installed at the top of the third rotary rod, and a plurality of stirring rods rotatably connected to the bottom of the rotary table, wherein the fourth gear is located between the rotary table and the fixed frame, the top end of the stirring rod extends out of the top of the rotary table and is provided with a fifth gear, and the fifth gear is located inside the circular rack and meshed with the circular rack.

As a preferable scheme of the rubber tube production mixing device, the linkage assembly comprises a connecting part positioned in the box body, a first fixing plate arranged at the bottom of the cover plate and a sliding block positioned at the bottom of the cover plate in a sliding connection mode, wherein a second reciprocating threaded rod is rotatably connected to one side wall of the first fixing plate, a second reciprocating threaded hole is formed in the side wall of the sliding block, and the second reciprocating threaded rod penetrates through the second reciprocating threaded hole in a rotating mode.

As a preferable scheme of the rubber tube production mixing device, two vertical plates are symmetrically arranged at the top of the box body, a first reciprocating threaded rod is rotatably connected between the two vertical plates, a second belt pulley is arranged at one end part of the first reciprocating threaded rod, a third gear is rotatably connected to one side wall of one vertical plate, a third belt pulley is arranged on the side wall of the third gear, and the third belt pulley is connected with the second belt pulley through a belt;

The side wall of the sliding block is rotatably connected with a second gear matched with the third gear, an opening is formed in the side wall of the second gear, and the second reciprocating threaded rod penetrates through the opening.

As a preferable scheme of the rubber tube production mixing device, the invention is characterized in that a first unidirectional gear is arranged on the third rotating rod body, a second bevel gear is also arranged on the third rotating rod body, a connecting sleeve is rotatably connected to the other side wall of the first fixing plate, the connecting sleeve is fixedly connected with the second reciprocating threaded rod coaxially, a cross jack is formed at the side end of the connecting sleeve, a first rotating rod is rotatably connected to the bottom of the cover plate, a first gear matched with the second gear is arranged at one end part of the first rotating rod, a first bevel gear is arranged at the other end part of the first rotating rod, and the first bevel gear is meshed with the second bevel gear;

The connecting portion comprises an L-shaped plate, a second one-way gear and a fourth bevel gear, wherein the L-shaped plate is slidably connected to the bottom of the cover plate, the second one-way gear is rotatably connected to the bottom of the transverse section of the L-shaped plate and meshed with the first one-way gear, the fourth bevel gear is rotatably connected to the side wall of the vertical section of the L-shaped plate, a guide groove is formed in the bottom of the cover plate, a guide plate is mounted on the top of the L-shaped plate, the guide plate stretches into the inside of the guide groove, a first spring is mounted on the side wall of the guide plate, the other end of the first spring is connected to the inner wall of the guide groove, a third bevel gear is mounted on the bottom of the second one-way gear, the third bevel gear is meshed with the fourth bevel gear, a cross insert rod is rotatably connected to the side wall of the L-shaped plate, the cross insert rod is fixedly connected with the fourth bevel gear coaxially, and the cross insert rod stretches into the inside of the cross insert hole.

As a preferable scheme of the rubber tube production mixing device, a fourth belt pulley is arranged at the bottom of the storage box, a third unidirectional gear is rotatably connected to the bottom of the cover plate, a second rotating rod is arranged at the top of the third unidirectional gear, the other end of the second rotating rod extends out of the top of the cover plate and is provided with a first belt pulley, and the first belt pulley is connected with the fourth belt pulley through a belt;

The second fixing plate is mounted on the side wall of the sliding block, the top end of the second fixing plate is slidably connected to the bottom of the cover plate, the second spring is mounted on the side wall of the second fixing plate, and the unidirectional rack matched with the third unidirectional gear is mounted on the other end of the second spring.

As a preferable scheme of the rubber tube production mixing device, the feeding assembly comprises two third fixing plates symmetrically arranged at the top of the cover plate with the feeding hole as a center, a feeding box arranged between the two third fixing plates and a moving block connected to the top of the cover plate in a sliding mode, wherein a transverse slideway is arranged on the side wall of the third fixing plate, one end of the transverse slideway, which is close to the feeding hole, is provided with a vertical bending section, a slope-shaped discharging hole is arranged on the side wall of the feeding box, a first sliding rod is arranged on the side wall of the feeding box, the first sliding rod stretches into the transverse slideway, a second sliding rod is further arranged on the side wall of the feeding box, the other end of the second sliding rod penetrates through the transverse slideway and is rotatably connected to the side wall of the moving block, a first reciprocating threaded hole is formed in the side wall of the moving block, and the first reciprocating threaded rod penetrates through the first reciprocating threaded hole in a rotating mode.

Compared with the prior art: through set up drive assembly and storage case at the box top, the storage incasement portion is divided into a plurality of cavities through the baffle, different reinforced in proper order is filled in a plurality of cavities in proper order, the inside stirring subassembly of drive box carries out two-way stirring to the inside rubber raw materials of box, drive the linkage subassembly and remove in the box at every turn when agitating unit reverses, after stirring certain number of times, the linkage subassembly is connected with the pay-off subassembly that is located the box top, along with agitating unit corotation, send the inside reinforced to the box of storage case at box top, along with agitating unit reversal once more, the linkage subassembly is separated with the pay-off subassembly, and be connected with the storage case, drive the rotatory certain angle of storage case, make the cavity that has next reinforced move to pay-off subassembly top, with this reciprocatingly, realize when carrying out the compounding to the rubber raw materials, automatic order is to the inside reinforced of raw materials.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the following detailed description of the embodiments of the present invention will be given with reference to the accompanying drawings, which are to be understood as merely some embodiments of the present invention, and from which other drawings can be obtained by those skilled in the art without inventive faculty. Wherein:

FIG. 1 is a diagram showing the whole structure of a mixing device for rubber tube production;

FIG. 2 is a diagram showing the structure of the inside of a box body of a mixing device for rubber tube production;

FIG. 3 is a top view of a box body of a mixing device for rubber tube production;

FIG. 4 is a structural diagram of a stirring device of a rubber tube production mixing device;

FIG. 5 is a schematic diagram showing the connection between a stirring assembly and a driving assembly of a mixing device for rubber tube production according to the present invention;

FIG. 6 is a partial structure diagram of a mixing device for rubber tube production according to the present invention;

FIG. 7 is a view showing a structure of the mixing device for producing rubber tubes in FIG. 6A;

FIG. 8 is a diagram showing the structure of a connecting part of a mixing device for rubber tube production;

FIG. 9 is a block diagram of a mixing device for rubber tube production according to the present invention;

FIG. 10 is a diagram showing a feeding assembly of a mixing device for rubber tube production according to the present invention;

FIG. 11 is a diagram showing a structure of a discharging assembly of a mixing device for rubber tube production.

Description of the drawings: the device comprises a box body 100, a cover plate 110, a feed inlet 110a, a circular rack 110b, a first rotary rod 110c, a first gear 110c-1, a first helical gear 110c-2, a third unidirectional gear 110d, a second rotary rod 110d-1, a first belt pulley 110d-2, a discharge outlet 120, a baffle 120a, an observation window 130, a vertical plate 140, a first reciprocating threaded rod 140a, a second belt pulley 140a-1, a third gear 140b and a third belt pulley 140b-1;

the driving assembly 200, the motor 210, the turntable 220, the first semicircular rack 220a, the fixed frame 230, and the second semicircular rack 230a;

the stirring assembly 300, the rotary table 310, the third rotary rod 320, the first unidirectional gear 320a, the second helical gear 320b, the fourth gear 330, the stirring rod 340 and the fifth gear 340a;

The linkage assembly 400, the connection part 410, the L-shaped plate 410a, the guide plate 410a-1, the first spring 410a-2, the second unidirectional gear 410b, the third helical gear 410b-1, the fourth helical gear 410c, the cross insert 410c-1, the first fixing plate 420, the second reciprocating threaded rod 420a, the connecting sleeve 420b, the cross insert hole 420b-1, the slider 430, the second gear 430a, the opening 430a-1, the second fixing plate 430b, the second spring 430b-1, the unidirectional rack 430b-2, the second reciprocating threaded hole 440;

The device comprises a discharging assembly 500, a mounting plate 510, a fixed sealing sleeve 520, a first charging port 520a, a storage box 530, a baffle 530a, a second charging port 530a-1 and a fourth belt pulley 530b;

The feeding assembly 600, the third fixing plate 610, the lateral slide 610a, the vertical bent section 610a-1, the feeding box 620, the slope-shaped discharge port 620a, the first slide bar 620b, the second slide bar 620c, the moving block 630, the first reciprocating screw hole 630a.

Detailed Description

In order that the above objects, features and advantages of the invention will be readily understood, a more particular description of the invention will be rendered by reference to the appended drawings.

Next, the present invention will be described in detail with reference to the drawings, wherein the sectional view of the device structure is not partially enlarged to general scale for the convenience of description, and the drawings are only examples, which should not limit the scope of the present invention. In addition, the three-dimensional dimensions of length, width and depth should be included in actual fabrication.

For the purpose of making the objects, technical solutions and advantages of the present invention more apparent, embodiments of the present invention will be described in further detail below with reference to the accompanying drawings.

The invention provides a rubber tube production mixing device, wherein a driving component and a storage box are arranged at the top of a box body, the inside of the storage box is divided into a plurality of chambers through a partition board, different feeds are sequentially filled in the chambers in sequence, a stirring component in the box body is driven to stir rubber raw materials in the box body in a bidirectional manner, a linkage component is driven to move in the box body when the stirring device is reversed each time, after stirring for a certain number of times, the linkage component is connected with a feeding component positioned at the top of the box body, the feeds in the storage box at the top of the box body are sent into the box body along with forward rotation of the stirring device, the linkage component is separated from the feeding component along with the forward rotation of the stirring device, and is connected with the storage box body, the storage box body is driven to rotate for a certain angle, so that a cavity storing the next feeds in the storage box is moved above the feeding component, and the stirring is realized.

Example 1

Fig. 1 to 10 are schematic structural views showing a first embodiment of a rubber tube production and mixing device according to the present invention, referring to fig. 1 to 10, the rubber tube production and mixing device according to the present embodiment includes a box 100, a driving assembly 200, a stirring assembly 300, a linkage assembly 400, a discharging assembly 500 and a feeding assembly 600.

The box 100 top has apron 110, and feed inlet 110a has been seted up at apron 110 top, and the box 100 bottom has discharge gate 120, and the inside articulated baffle 120a that has of discharge gate 120, and observation window 130 has been seted up to box 100 lateral wall, and the inside transparent glass that is provided with of observation window 130, observation window 130 position are used for observing the stirring condition and the compounding condition of rubber raw materials in the box 100 inside, and after the stirring, pulling baffle 120a is opened, takes out the rubber material that the compounding is good from discharge gate 120.

The driving assembly 200 is mounted on top of the cover plate 110.

The stirring assembly 300 is located inside the box 100 and connected with the driving assembly 200, and the driving assembly 200 drives the stirring assembly 300 to rotate bidirectionally to stir and mix rubber raw materials inside the box 100.

The linkage assembly 400 is located inside the box 100 and connected with the stirring assembly 300, and along with the horizontal movement of the stirring assembly 300 in the box 100 during each inversion, the linkage assembly 400 is located at the tail of the box 100 in an initial state, and along with the inversion of the stirring assembly 300, the linkage assembly 400 is driven to move in the box 100 until after the sixth inversion, the linkage assembly 400 is connected with the feeding assembly 600, and along with the inversion of the stirring assembly 300, the linkage assembly 400 is separated from the feeding assembly 600 and connected with the discharging assembly 500.

The discharging assembly 500 comprises a mounting plate 510 mounted at the top of the cover plate 110, a fixed sealing sleeve 520 mounted at the top of the mounting plate 510, and a storage box 530 rotatably connected inside the fixed sealing sleeve 520, wherein a first feeding port 520a is formed at the bottom of the fixed sealing sleeve 520, a plurality of partition plates 530a are mounted inside the storage box 530, the partition plates 530a divide the interior of the storage box 530 into a plurality of chambers, a second feeding port 530a-1 is formed inside each chamber, one of the second feeding ports 530a-1 is communicated with the first feeding port 520a in an initial state, when the linkage assembly 400 is connected with the feeding assembly 600, the linkage assembly 400 is separated from the feeding assembly 600 along with the inversion of the stirring assembly 300, and is connected with the discharging assembly 500, and when the linkage assembly 400 is driven to move along with the inversion of the stirring assembly 300, the linkage assembly 400 is driven to rotate, the second feeding port 530a-1 of the next chamber is communicated with the first feeding port 520a, and the feeding in the chamber falls into the feeding assembly 600 through the second feeding port 530a-1 and the first feeding port 520 a.

The feeding assembly 600 is located at the top of the case 100, and when the stirring assembly 300 is reversely rotated for the sixth time, the linkage assembly 400 is connected with the feeding assembly 600, and drives the feeding assembly 600 to feed the material to the feeding port 110a along with the forward rotation of the stirring assembly 300, and the material is poured into the case 100 through the feeding port 110 a.

In conjunction with fig. 1-10, in a rubber tube production mixing device of this embodiment, firstly, to add the required additive, for example, solid softener, activator, antioxidant, filler, plasticizer, etc. into a plurality of cavities in the storage tank 530, the cavity at the top of the first feeding port 520a is left empty, the rubber raw materials to be mixed are poured into the tank 100 from the feeding port 110a, the driving component 200 is started to drive the stirring component 300 to stir the rubber raw materials in the tank 100, when the stirring component 300 is reversed for the first time, the linkage component 400 is pulled to move in the tank 100 and drive the storage tank 530 to rotate by a certain angle, for example, in the case that the storage tank 530 in fig. 11 has 6 cavities, the linkage component 400 drives the storage tank 530 to rotate by 60 ° each time, at the moment, the second feeding port 530a-1 of the next cavity is communicated with the first feeding port 520a, the cavity is filled in the feeding component 600, after the stirring component 300 is reversed for the first time, the stirring component 400 and the stirring component 300 is driven to rotate forward along with the stirring component 300, when the stirring component 300 drives the linkage component 400 to drive the stirring component 300 to stir the rubber raw materials in the tank 100, when the first time, the linkage component 300 is driven to rotate along with the first time, the feeding component 600 is driven to be connected with the feeding component 600 a, and the cavity is connected to the cavity 600 a, and the first feeding component is connected to the first feeding port, and the material is mixed with the cavity, and the material is mixed in the cavity, and the cavity is mixed with the cavity, and the cavity is filled in the second feeding port, and the cavity, and the second feeding port is filled, and the cavity is filled.

Example 2

Fig. 2 to 10 are schematic structural views showing a second embodiment of a rubber tube production mixing device according to the present invention, referring to fig. 2 to 10, unlike the above embodiment, the rubber tube production mixing device according to the present embodiment further includes:

the circular rack 110b is installed at the bottom of the cover plate 110, two vertical plates 140 are symmetrically installed at the top of the box body 100, a first reciprocating threaded rod 140a is rotatably connected between the two vertical plates 140, a second belt pulley 140a-1 is installed at one end of the first reciprocating threaded rod 140a, a third gear 140b is rotatably connected to the side wall of one vertical plate 140, a third belt pulley 140b-1 is installed on the side wall of the third gear 140b, and the third belt pulley 140b-1 is connected with the second belt pulley 140a-1 through a belt.

The driving assembly 200 includes a motor 210 installed at the top of the case 100, a rotary table 220 installed at an output end of the motor 210, and a fixing frame 230 coaxially fixed with the rotary table 220 and positioned outside the rotary table 220, a first semicircular rack 220a is installed at a half of an outer wall of the rotary table 220, a second semicircular rack 230a is installed at a half of an inner wall of the fixing frame 230 opposite to the first semicircular rack 220a, and the rotary table 220 and the fixing frame 230 can be simultaneously driven to rotate by starting the motor 210.

The stirring assembly 300 includes a rotation table 310 positioned inside the case 100, a third rotating rod 320 installed at the top of the rotation table 310 and extending out of the top of the cover plate 110, a fourth gear 330 installed at the top of the third rotating rod 320, and a plurality of stirring rods 340 rotatably connected to the bottom of the rotation table 310, the fourth gear 330 being positioned between the rotation table 220 and the fixed frame 230, the top of the stirring rods 340 extending out of the top of the rotation table 310 and being installed with a fifth gear 340a, the fifth gear 340a being positioned inside the circular rack 110b and being engaged with the circular rack 110b, when the rotation table 220 and the fixed frame 230 are rotated, the second semicircular rack 230a being engaged with the fourth gear 330 to drive the fourth gear 330 to rotate forward, the rotation table 310 to drive the stirring rods 340 to rotate forward, and when the first semicircular rack 220a being engaged with the fourth gear 330 to drive the fourth gear 330 to rotate backward, the stirring rods 340 being driven by 310 to rotate backward, the circular rack 110b to drive the fifth gear 340a and the stirring rods 340 to rotate backward, so that the rotation efficiency of the rotation table 310 can be increased while rotating.

The linkage assembly 400 includes a connection part 410 positioned in the box 100, a first fixing plate 420 installed at the bottom of the cover plate 110, and a slider 430 positioned at the bottom of the cover plate 110 in a sliding connection manner, wherein one side wall of the first fixing plate 420 is rotatably connected with a second reciprocating threaded rod 420a, a second reciprocating threaded hole 440 is formed in the side wall of the slider 430, the second reciprocating threaded rod 420a rotatably penetrates through the second reciprocating threaded hole 440, a second gear 430a matched with a third gear 140b is rotatably connected to the side wall of the slider 430, an opening 430a-1 is formed in the side wall of the second gear 430a, the second reciprocating threaded rod 420a penetrates through the opening 430a-1, a first unidirectional gear 320a is installed on the shaft of the third rotary rod 320, a second helical gear 320b is also installed on the shaft of the third rotary rod 320, a connecting sleeve 420b is rotatably connected to the other side wall of the first fixing plate 420, the connecting sleeve 420b is fixedly connected with the second reciprocating threaded rod 420a coaxially, the connecting sleeve 420b is provided with a cross insertion hole 420b-1 at the side end, a first rotating rod 110c is rotatably connected to the bottom of the cover plate 110, a first gear 110c-1 matched with the second gear 430a is mounted at one end of the first rotating rod 110c, a first bevel gear 110c-2 is mounted at the other end of the first rotating rod 110c, the first bevel gear 110c-2 is meshed with the second bevel gear 320b, the connecting part 410 comprises an L-shaped plate 410a which is slidably connected to the bottom of the cover plate 110, a second one-way gear 410b which is rotatably connected to the bottom of the transverse section of the L-shaped plate 410a and meshed with the first one-way gear 320a, a fourth bevel gear 410c which is rotatably connected to the side wall of the vertical section of the L-shaped plate 410a, a guide groove is formed in the bottom of the cover plate 110, a guide plate 410a-1 is mounted at the top of the L-shaped plate 410a, the guide plate 410a-1 extends into the guide groove, a first spring 410a-2 is mounted on the side wall of the guide plate 410a-1, the other end of the first spring 410a-2 is connected to the inner wall of the guide groove, the bottom of the second unidirectional gear 410b is provided with a third bevel gear 410b-1, the third bevel gear 410b-1 is meshed with a fourth bevel gear 410c, the side wall of the L-shaped plate 410a is rotatably connected with a cross insert rod 410c-1, the cross insert rod 410c-1 is fixedly connected with the fourth bevel gear 410c in a coaxial way, the cross insert rod 410c-1 stretches into the cross insert hole 420b-1, the side wall of the sliding block 430 is provided with a second fixing plate 430b, the top end of the second fixing plate 430b is slidably connected to the bottom of the cover plate 110, the side wall of the second fixing plate 430b is provided with a second spring 430b-1, the other end of the second spring 430b-1 is provided with a unidirectional rack 430b-2 matched with the third unidirectional gear 110d, the unidirectional rack 430b-2 is slidably connected to the bottom of the cover plate 110 to guide the unidirectional rack 430b-2, preventing the unidirectional rack 430b-2 from being deviated during engagement, when the fourth gear 330 drives the third rotating rod 320 and the rotating table 310 to rotate, the third rotating rod 320 drives the second helical gear 320b and the first unidirectional gear 320a to rotate forward, the second helical gear 320b drives the first helical gear 110c-2 to rotate, the first helical gear 110c-2 drives the first rotating rod 110c and the first gear 110c-1 to rotate, when the first unidirectional gear 320a rotates forward, the inclined surface of the first unidirectional gear 320a presses the inclined surface of the second unidirectional gear 410b, the L-shaped plate 410a and the guide plate 410a-1 are pressed far from the first unidirectional gear 320a and the first spring 410a-2 are pressed, when the fourth gear 330 drives the third rotating rod 320 to rotate reversely, the third rotating rod 320 drives the first unidirectional gear 320a to rotate reversely, and the first spring 410a-2 pushes the L-shaped plate 410a and the second unidirectional gear 410b to reset, the straight edge of the first unidirectional gear 320a is abutted with the straight edge of the second unidirectional gear 410b, the first unidirectional gear 320a is meshed with the second unidirectional gear 410b, the first unidirectional gear 320a drives the second unidirectional gear 410b to rotate, the second unidirectional gear 410b drives the third bevel gear 410b-1 to rotate, the third bevel gear 410b-1 drives the fourth bevel gear 410c and the cross insert rod 410c-1 to rotate, the cross insert rod 410c-1 drives the connecting sleeve 420b and the second reciprocating threaded rod 420a to rotate, the sliding block 430 and the second gear 430a are pushed to move a certain distance by utilizing the screw rod structure, in the initial state, the sliding block 430 is positioned at the rearmost end of the second reciprocating threaded rod 420a, the second gear 430a is meshed with the first gear 110c-1 and the third gear 140b, when the motor 210 drives the turntable 220 and the fixed frame 230 to rotate, the first semicircular rack 220a is meshed with the fourth gear 330 first, that is, the first unidirectional gear 320a is driven to rotate reversely, the second reciprocating threaded rod 420a is driven to rotate, the sliding block 430 is driven to move forward, the second gear 430a is separated from the first gear 110c-1 and the third gear 140b, when the third reverse rotation of the fourth gear 330 is finished, the sliding block 430 moves to the forefront end of the second reciprocating threaded rod 420a, and when the sixth reverse rotation of the fourth gear 330 is finished, the sliding block 430 moves to the tail end of the second reciprocating threaded rod 420a again, the second gear 430a is meshed with the first gear 110c-1 and the third gear 140b, at this time, as the second semicircular rack 230a drives the fourth gear 330 and the third rotary rod 320 to rotate forwardly, the second helical gear 320b drives the first gear 110c-1 to rotate forwardly, the first gear 110c-1 drives the second gear 430a and the third gear 140b to rotate, the third gear 140b drives the third pulley 140b-1 to rotate, the third pulley 140b-1 rotates the second pulley 140a-1 and the first reciprocating threaded rod 140 a.

A fourth belt pulley 530b is installed at the bottom of the storage tank 530, a third unidirectional gear 110d is rotatably connected to the bottom of the cover plate 110, a second rotating rod 110d-1 is installed at the top of the third unidirectional gear 110d, the other end of the second rotating rod 110d-1 extends out of the top of the cover plate 110 and is provided with a first belt pulley 110d-2, the first belt pulley 110d-2 is connected with the fourth belt pulley 530b through a belt, when the sliding block 430 moves backwards until the second gear 430a is meshed with the first gear 110c-1 and the third gear 140b, the sliding block 430 drives the unidirectional rack 430b-2 to move backwards, at the moment, the inclined surface of the unidirectional rack 430b-2 is abutted with the inclined surface of the third unidirectional gear 110d, the unidirectional rack 430b-2 is extruded to move towards the second fixed plate 430b and the second spring 430b-1 is extruded, and after the second gear 430a is meshed with the first gear 110c-1 and the third gear 140b, as the fourth gear 330 is reversed again to drive the first unidirectional gear 320a to rotate reversely, and when the sliding block 430 and the second gear 430a are driven to move forwards, the second spring 430b-1 pushes the unidirectional rack 430b-2 to reset, the straight edge of the unidirectional rack 430b-2 is abutted against the straight edge of the third unidirectional gear 110d, when the sliding block 430 and the unidirectional rack 430b-2 move forwards, the unidirectional rack 430b-2 drives the third unidirectional gear 110d to rotate, the third unidirectional gear 110d drives the second rotating rod 110d-1 and the first belt pulley 110d-2 to rotate, the first belt pulley 110d-2 drives the fourth belt pulley 530b and the storage box 530 to rotate for 60 degrees by using the belt, the sliding block 430 continues to move forwards to drive the unidirectional rack 430b-2 to separate from the third unidirectional gear 110d, when the storage box 530 rotates, the second charging port 530a-1 in the next cavity is communicated with the first charging port 520a, the charge in the cavity is discharged through the second charge port 530a-1 and the first charge port 520 a.

The feeding assembly 600 includes two third fixing plates 610 symmetrically installed at the top of the cover plate 110 with the feeding hole 110a as a center, a feeding box 620 located between the two third fixing plates 610, and a moving block 630 slidably connected at the top of the cover plate 110, wherein a lateral slideway 610a is provided on a side wall of the third fixing plate 610, one end of the lateral slideway 610a near the feeding hole 110a is provided with a vertical bending section 610a-1, a slope discharging hole 620a is provided on a side wall of the feeding box 620, a first sliding rod 620b is installed on a side wall of the feeding box 620, the first sliding rod 620b extends into the lateral slideway 610a, a second sliding rod 620c is installed on a side wall of the feeding box 620, the other end of the second sliding rod 620c extends through the lateral slideway 610a and is rotatably connected to a side wall of the moving block 630, a first reciprocating threaded hole 630a is provided on a side wall of the moving block 630, the first reciprocating threaded rod 140a rotates through the first reciprocating threaded hole 630a, when the second gear 430a is engaged with the first gear 110c-1 and the third gear 140b, the second bevel gear 320b and the first gear 110c-1 are driven to rotate by the forward rotation of the fourth gear 330, the second gear 430a and the third gear 140b are driven to rotate by the first gear 110c-1, and then the first reciprocating threaded rod 140a is driven to rotate, the moving block 630 is driven to move back and forth by the first reciprocating threaded rod 140a to reciprocate by the lead screw structure, when the feeding box 620 moves forward, the first slide bar 620b and the second slide bar 620c move inside the transverse slide 610a until the first slide bar 620b moves to the front end of the transverse slide 610a, the top end of the vertical bending section 610a-1 moves downward along the vertical bending section 610a-1 as the feeding box 620 moves forward, the front end of the feeding box 620 turns downward, the inside of the feeding box 620 falls into the inside of the feeding inlet 110a through the slope-shaped discharging hole 620a, when the feeding cassette 620 moves backward, the first slide bar 620b is pulled to move upward along the vertical bending section 610a-1, and the second slide bar 620c moves backward inside the lateral slide way 610a until the first slide bar 620b moves to the top end of the vertical bending section 610a-1, and the front end of the lateral slide way 610a is reset, at this time, the feeding cassette 620 is aligned, and as the feeding cassette 620 continues to move backward, the first slide bar 620b and the second slide bar 620c move backward inside the lateral slide way 610 a.

In combination with fig. 2 to 10, in the rubber tube production mixing device of this embodiment, when in use, firstly, the cavity at the top of the first feeding port 520a is left empty, and the feeding is sequentially poured into the cavities, the rubber raw material is poured into the box body 100 from the feeding port 110a, the starting motor 210 drives the turntable 220 and the fixed frame 230 to rotate, the first semicircular rack 220a drives the fourth gear 330 to reversely rotate, the fourth gear 330 drives the turntable 310 and the stirring rod 340 to stir the rubber, the fourth gear 330 drives the first unidirectional gear 320a and the second reciprocating threaded rod 420a to rotate, the sliding block 430 and the second fixed plate 430b are driven to rotate by utilizing the lead screw structure, the third unidirectional gear 110d and the fourth belt pulley 530b are driven to rotate, then the storage box 530b is driven to rotate, the next cavity is driven to rotate to the top of the first feeding port 520a, the second feeding port 530a-1 and the first feeding port 520a are communicated with the first feeding port 520a, the fourth gear 330 a enters the feeding box 620 to rotate along with the fourth gear 310 and the stirring rod 340, the fourth gear 330 drives the first unidirectional gear 320a and the fourth reciprocating threaded rod 420a to rotate, the fourth gear 430b drives the sliding block 140a to rotate along with the fourth gear 140 c and the fourth rotating forward and the fourth rotating rod 620 b, and the fourth rotating forward and the fourth rotating rod 430b drives the fourth feed box 140b to rotate, and the fourth rotating forward and the fourth feed box 620 c rotates along with the fourth rotating gear 620 b, and the fourth rotating forward and the fourth rotating gear 620 b rotates, the second gear 430a is separated from the first gear 110c-1 and the third gear 140b, the sliding block 430 drives the unidirectional rack 430b-2 to move backwards, the unidirectional rack 430b-2 drives the third unidirectional gear 110d and the fourth belt pulley 530b to rotate, the fourth belt pulley 530b drives the storage box 530 to rotate, the second charging port 530a-1 of the next cavity is communicated with the first charging port 520a, and charging of the cavity falls into the feeding box 620 through the second charging port 530a-1 and the first charging port 520a and reciprocates in sequence, so that automatic charging according to sequence in the material mixing process is realized.

Although the invention has been described hereinabove with reference to embodiments, various modifications thereof may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In particular, the features of the disclosed embodiments may be combined with each other in any manner as long as there is no structural conflict, and the exhaustive description of these combinations is not given in this specification merely for the sake of omitting the descriptions and saving resources. Therefore, it is intended that the invention not be limited to the particular embodiment disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.

Claims (8)

1. The utility model provides a rubber tube production compounding device which characterized in that includes:

the novel glass box comprises a box body (100), wherein a cover plate (110) is arranged at the top of the box body (100), a feed inlet (110 a) is formed in the top of the cover plate (110), a discharge outlet (120) is formed in the bottom of the box body (100), a baffle (120 a) is hinged to the inside of the discharge outlet (120), an observation window (130) is formed in the side wall of the box body (100), and transparent glass is arranged in the observation window (130);

A driving assembly (200) mounted on top of the cover plate (110);

the stirring assembly (300) is positioned in the box body (100) and connected with the driving assembly (200), and the driving assembly (200) drives the stirring assembly (300) to bidirectionally rotate so as to stir and mix rubber raw materials in the box body (100);

The linkage assembly (400) is positioned in the box body (100) and connected with the stirring assembly (300), and moves horizontally in the box body (100) along with each inversion of the stirring assembly (300);

The discharging assembly (500) comprises a mounting plate (510) arranged at the top of the cover plate (110), a fixed sealing sleeve (520) arranged at the top of the mounting plate (510) and a storage box (530) rotatably connected inside the fixed sealing sleeve (520), wherein a first feeding hole (520 a) is formed in the bottom of the fixed sealing sleeve (520), a plurality of partition plates (530 a) are arranged inside the storage box (530), the partition plates (530 a) divide the inside of the storage box (530) into a plurality of chambers, a second feeding hole (530 a-1) is formed in each chamber, and one of the second feeding holes (530 a-1) is communicated with the first feeding hole (520 a) in an initial state;

The feeding assembly (600) is positioned at the top of the box body (100);

When the stirring assembly (300) rotates reversely for 6 times, the linkage assembly (400) is connected with the feeding assembly (600), along with the forward rotation of the stirring assembly (300), the feeding assembly (600) is driven to feed materials falling from the first feeding port (520 a) and the corresponding second feeding port (530 a-1) and the cavity thereof into the feeding port (110 a), along with the continuous reverse rotation of the stirring assembly (300), the linkage assembly (400) is driven to separate from the feeding assembly (600), and is connected with the discharging assembly (500), the storage box (530) is driven to rotate, the second feeding port (530 a-1) of the next cavity is connected with the first feeding port (520 a), and the materials in the cavity fall into the feeding assembly (600) through the first feeding port (520 a).

2. A rubber tube production mixing device according to claim 1, wherein the driving assembly (200) comprises a motor (210) installed at the top of the box body (100), a rotary table (220) installed at the output end of the motor (210) and a fixed frame (230) coaxially fixed with the rotary table (220) and located outside the rotary table (220), a first semicircular rack (220 a) is installed on one half of the outer wall of the rotary table (220), and a second semicircular rack (230 a) is installed on the half of the inner wall of the fixed frame (230) opposite to the first semicircular rack (220 a).

3. A rubber tube production mixing device according to claim 2, characterized in that the bottom of the cover plate (110) is provided with a circular rack (110 b);

The stirring assembly (300) comprises a rotating table (310) positioned in the box body (100), a third rotating rod (320) arranged at the top of the rotating table (310) and extending out of the top of the cover plate (110), a fourth gear (330) arranged at the top of the third rotating rod (320) and a plurality of stirring rods (340) rotatably connected to the bottom of the rotating table (310), wherein the fourth gear (330) is positioned between the rotating table (220) and the fixed frame (230), the top end of the stirring rod (340) extends out of the top of the rotating table (310) and is provided with a fifth gear (340 a), and the fifth gear (340 a) is positioned in the circular rack (110 b) and meshed with the circular rack (110 b).

4. A rubber tube production compounding device according to claim 3, wherein the linkage assembly (400) comprises a connecting portion (410) located inside the box body (100), a first fixing plate (420) installed at the bottom of the cover plate (110) and a sliding block (430) located at the bottom of the cover plate (110) in sliding connection, a side wall of the first fixing plate (420) is rotatably connected with a second reciprocating threaded rod (420 a), a second reciprocating threaded hole (440) is formed in the side wall of the sliding block (430), and the second reciprocating threaded rod (420 a) penetrates through the second reciprocating threaded hole (440) in a rotating mode.

5. A rubber tube production mixing device according to claim 4, wherein two risers (140) are symmetrically arranged at the top of the box body (100), a first reciprocating threaded rod (140 a) is rotatably connected between the two risers (140), a second belt pulley (140 a-1) is arranged at one end part of the first reciprocating threaded rod (140 a), a third gear (140 b) is rotatably connected to the side wall of one riser (140), a third belt pulley (140 b-1) is arranged on the side wall of the third gear (140 b), and the third belt pulley (140 b-1) is connected with the second belt pulley (140 a-1) through a belt;

the side wall of the sliding block (430) is rotatably connected with a second gear (430 a) matched with the third gear (140 b), an opening (430 a-1) is formed in the side wall of the second gear (430 a), and the second reciprocating threaded rod (420 a) penetrates through the opening (430 a-1).

6. The rubber tube production mixing device according to claim 5, wherein a first unidirectional gear (320 a) is mounted on the third rotating rod (320) shaft, a second bevel gear (320 b) is mounted on the third rotating rod (320) shaft, a connecting sleeve (420 b) is rotatably connected to the other side wall of the first fixing plate (420), the connecting sleeve (420 b) is fixedly connected with the second reciprocating threaded rod (420 a) coaxially, a cross jack (420 b-1) is formed in the side end of the connecting sleeve (420 b), a first rotating rod (110 c) is rotatably connected to the bottom of the cover plate (110), a first gear (110 c-1) matched with the second gear (430 a) is mounted at one end of the first rotating rod (110 c), a first bevel gear (110 c-2) is mounted at the other end of the first rotating rod (110 c-2), and the first bevel gear (110 c-2) is meshed with the second bevel gear (320 b);

The connecting portion (410) comprises an L-shaped plate (410 a) which is slidably connected to the bottom of the cover plate (110), a second unidirectional gear (410 b) which is rotatably connected to the bottom of the transverse section of the L-shaped plate (410 a) and meshed with the first unidirectional gear (320 a), and a fourth bevel gear (410 c) which is rotatably connected to the side wall of the vertical section of the L-shaped plate (410 a), a guide groove is formed in the bottom of the cover plate (110), a guide plate (410 a-1) is mounted on the top of the L-shaped plate (410 a), the guide plate (410 a-1) stretches into the interior of the guide groove, a first spring (410 a-2) is mounted on the side wall of the guide plate (410 a-1), a third bevel gear (410 b-1) is mounted on the bottom of the second unidirectional gear (410 b), a cross-1) is meshed with the fourth bevel gear (410 c), a cross-1) is rotatably connected to the side wall of the L-shaped plate (410 a), and a cross-1) is fixedly connected to the inner side of the cross-shaped plate (410 c) and the cross-1) is fixedly connected to the inner side of the cross-shaped rod (410 c).

7. The rubber tube production mixing device according to claim 4, wherein a fourth belt pulley (530 b) is installed at the bottom of the storage box (530), a third unidirectional gear (110 d) is rotatably connected to the bottom of the cover plate (110), a second rotating rod (110 d-1) is installed at the top of the third unidirectional gear (110 d), the other end of the second rotating rod (110 d-1) extends out of the top of the cover plate (110) and is provided with a first belt pulley (110 d-2), and the first belt pulley (110 d-2) is connected with the fourth belt pulley (530 b) through a belt;

The sliding block (430) is characterized in that a second fixing plate (430 b) is arranged on the side wall of the sliding block (430), the top end of the second fixing plate (430 b) is slidably connected to the bottom of the cover plate (110), a second spring (430 b-1) is arranged on the side wall of the second fixing plate (430 b), and a unidirectional rack (430 b-2) matched with the third unidirectional gear (110 d) is arranged at the other end of the second spring (430 b-1).

8. The rubber tube production compounding device of claim 5, wherein the feeding assembly (600) comprises two third fixing plates (610) symmetrically installed at the top of the cover plate (110) with the feeding hole (110 a) as a center, a feeding box (620) located between the two third fixing plates (610) and a moving block (630) slidably connected to the top of the cover plate (110), a transverse slide (610 a) is formed in the side wall of the third fixing plates (610), a vertical bending section (610 a-1) is formed at one end of the transverse slide (610 a) close to the feeding hole (110 a), a slope-shaped discharging hole (620 a) is formed in the side wall of the feeding box (620), a first sliding rod (620 b) is installed on the side wall of the feeding box (620), a second sliding rod (620 c) is installed on the side wall of the feeding box (620), the other end of the second sliding rod (620 c) penetrates through the transverse slide (610 a) and is rotatably connected to the first sliding rod (630 a), and a threaded reciprocating rod (630 a) is rotatably connected to the first sliding rod (630 a) penetrates through the first sliding rod (630 a).