CN218462644U - Integrated system for batching and feeding rubber resin granules - Google Patents

Abstract

The utility model belongs to the technical field of the conveyer belt batching is carried and specifically relates to rubber resin granule material batching pay-off integration system, including the compounding subassembly that two side by side and interval set up, two the both ends of compounding subassembly are connected the cooperation with the biax actuating mechanism that corresponds position department respectively two still be provided with a combination between the compounding subassembly and shake the material subassembly, the combination shakes the material subassembly and is used for realizing its both sides the inside granule material of compounding subassembly vibrates the compounding, at each the bottom discharge gate department of compounding subassembly all installs a meticulous auger delivery ware. The system is provided with the two mixing components simultaneously, so that the high efficiency of mixing materials such as rubber resin particles and the like can be effectively ensured, and the mixing amount and the mixing effect of the whole equipment are improved; can throw the material to two compounding subassemblies simultaneously when carrying out the compounding, throw two compounding subassemblies after the material and realize the biax drive by the biax actuating mechanism at both ends, guarantee the sufficiency of drive power effectively.

Description

Integrated system for batching and feeding rubber resin granules

Technical Field

The utility model relates to a conveyer belt batching carries technical field, in particular to novel system to used rubber, resin granule material hybrid transportation in the conveyer belt production, especially rubber resin granule material batching pay-off integration system in the conveyer belt workshop.

Background

The rubber conveyer belt is mainly used for conveying solid materials of enterprises such as mines, metallurgy, steel, coal, hydropower, building materials, chemical engineering, grains and the like, and the conveyer belt generally adopts various main materials such as rubber, resin, carbon black and the like and auxiliary material particles to realize the preparation of product covering rubber and core rubber when being processed in a conveyer belt production workshop.

Traditional batching material loading time mainly adopts artifical propelling movement batching car to throw in the material to the vibration bin inside, but because this kind of mode efficiency is lower and throw the material volume uncontrollable, also replaced by mechanical equipment gradually. There are also a number of feeding systems in the prior art that are used in conveyor belt production plants.

For example, in patent document CN202122196590.8, a feeding device for preparing an anti-aging compound rubber material is disclosed, which mainly comprises a bin (1) for refining rubber particles, a feeding cover (2) fixedly mounted on the upper surface of the bin (1), a feeding channel (3) and a blanking channel (4) arranged in the inner cavity of the feeding cover (2); the feeding device also comprises a feeding mechanism (5) which is arranged on the feeding cover (2); the feeding mechanism (5) comprises at least three feeding rollers (51) rotatably connected to the inner wall of the feeding channel (3), a plurality of material stirring sheets (52) fixedly arranged on the outer ring surface of the feeding rollers (51), and a speed reducing motor (53) fixedly arranged on the front surface of the feeding cover (2); the impurity collecting structure (6) is arranged in the inner cavity of the feeding cover (2); the impurity collecting structure (6) comprises a water storage bin (61), a rubber plug plate (62) fixedly mounted on the periphery of the upper end of the water storage bin (61), and a drain valve (63) fixedly connected to the lower surface of the feeding cover (2) in a penetrating mode.

Above-mentioned this kind of structure is often used for reinforced feeding of granule material in conveyer belt workshop, and it is mainly through carrying out multistage formula material transmission to rubber granule, and the purpose of detaching the debris on the rubber granule that need to refine, although this kind of reinforced mode can accomplish rubber granule reinforced when reinforced in the conveyer belt workshop, can not reach the operation requirement when realizing high-efficient reinforced in mixed particles such as rubber, resin.

Therefore, the utility model provides a can be in conveyer belt workshop to used rubber, resin granule material hybrid transport's novel system in the conveyer belt production here for solve the problem that exists in the conveyer belt workshop among the prior art better.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a solve one of above-mentioned technical problem, the technical scheme who adopts is: rubber resin granule material batching pay-off integration system, including two compounding subassemblies that are parallel and the interval sets up, two the both ends of compounding subassembly are connected the cooperation with the biax actuating mechanism that corresponds position department respectively, two biax actuating mechanism sets up at relative interval, two biax actuating mechanism cooperation is realized two the synchronous syntropy drive is realized to the compounding subassembly, two still be provided with a combination between the compounding subassembly and shake the material subassembly, the combination shakes the material subassembly and is used for realizing to its both sides the inside granule material of compounding subassembly vibrates the compounding, at each the bottom discharge gate department of compounding subassembly all installs a meticulous auger delivery ware, each the bottom export of meticulous auger delivery ware is used for outwards quantitative transport the granule material after mixing.

Preferably in any one of the above schemes, the mixing component includes two vertical positioning seats which are spaced relatively and are fixedly arranged, two horizontal mixing silo is fixedly arranged at the top of the vertical positioning seat, a feeding pipe orifice is arranged at the top of the horizontal mixing silo, a blocking cover is arranged at the top of the feeding pipe orifice, a mixing main shaft is arranged in a cylindrical mixing cavity of the horizontal mixing silo, the left end and the right end of the mixing main shaft respectively movably and hermetically penetrate through a mounting hole in a side end cover of the horizontal mixing silo and respectively connected and matched with a double-shaft driving mechanism at a corresponding position, a flexible sealing member is arranged between the mounting holes of the side end covers at the two ends of the mixing main shaft in a clearance fit manner and in the middle of the mounting holes so as to realize small vibration of the horizontal mixing silo, a plurality of mixing teeth which are used for stirring and mixing rubber-resin mixed granules in the cylindrical mixing cavity are fixedly arranged on the outer side wall of the mixing main shaft along the length direction at intervals in the cylindrical mixing cavity, and a fine spiral conveyor is arranged at the bottom of an inverted cone-shaped discharge hole at the middle section of the horizontal mixing silo.

In any of the above schemes, preferably, the combined material vibrating assembly includes a connecting seat disposed between the two horizontal mixing silos, and two side walls of the connecting seat are respectively and fixedly provided with a vibrator for connecting with an outer side wall of the horizontal mixing silo at a corresponding position;

the horizontal mixing bin is connected with the tops of the positioning vertical seats through elastic buffer seats.

In any of the above schemes, preferably, a four-outlet type pulse air pump is installed at the top of the connecting seat, and each outlet of the pulse air pump is connected to the inside of the corresponding cylindrical mixing cavity of the horizontal mixing bin through a pulse air pipe; and each plugging cover is provided with an air pressure balancing hole.

In any of the above schemes, preferably, the double-shaft driving mechanism includes an outer mounting seat fixedly arranged, a platform seat is fixedly mounted on the top of the outer mounting seat, a double-shaft output motor is fixedly mounted on the top of the middle section of the platform seat, motor shafts on two sides of the double-shaft output motor are respectively connected with a speed reducer through a coupling, an output end of each speed reducer is respectively connected with an input end of the bevel gear reversing unit at a corresponding position, an output end of each bevel gear reversing unit is respectively connected with an end of the mixing main shaft at a corresponding position, the two double-shaft output motors are matched to simultaneously drive two end portions of each mixing main shaft at two sides of the mixing main shafts in a combined and synchronous manner, and the two mixing main shafts simultaneously mix and mix the mixed particles in the respective corresponding cylindrical mixing cavities.

In any of the above schemes, preferably, the bevel gear reversing unit includes a bevel gear box fixedly installed at the top of the platform base, an input bevel gear and an output bevel gear which are engaged with each other are installed in the bevel gear box, and the input bevel gear and the output bevel gear both movably penetrate through a through hole at a corresponding position of the bevel gear box and are connected with an output end of the speed reducer at the corresponding position and a corresponding end of the mixing spindle respectively.

In any of the above solutions, it is preferable that the transmission ratio of the input bevel gear to the output bevel gear is 1:1.

In any of the above aspects, preferably, the dual-shaft output motor is a dual-shaft stepping motor.

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

1. the system is provided with the two mixing components simultaneously, so that the high efficiency of mixing materials such as rubber resin particles and the like can be effectively ensured, and the mixing amount and the mixing effect of the whole equipment are improved; can throw the material to two compounding subassemblies simultaneously when carrying out the compounding, throw two compounding subassemblies after the material and realize the biax drive by the biax actuating mechanism at both ends, guarantee the sufficiency of drive power effectively.

2. The combination that sets up here shakes and expects subassembly adopts vibration, the mode of pulse air current can cooperate the inside stirring compounding of horizontal blending bunker better to reach the further homogeneous mixing to the material under the compounding state, improves the effect and the efficiency of mixing, compounding.

3. The mode that the both ends that the compounding main shaft of each compounding subassembly all adopted when carrying out rotary drive carried out the drive simultaneously can guarantee the sufficiency of power supply better, and the synchronous syntropy drive in both ends can guarantee the stability when realizing the rotation simultaneously, guarantees the abundant nature of power when mixing a large amount of granule materials.

4. The bottom of each horizontal mixing bunker is provided with a fine screw conveyor, so that the mixed materials can be conveyed outwards quickly, and the materials can be discharged outwards smoothly when the mixed materials are conveyed outwards due to the arrangement of the vibrating piece.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the technical solutions in the prior art will be briefly described below. Throughout the drawings, like elements or components are generally identified by like reference numerals. In the drawings, elements or components are not necessarily drawn to scale.

Fig. 1 is a schematic top view of the present invention.

Fig. 2 is a schematic side view of the present invention.

Fig. 3 is a schematic view of the partial cross-sectional structure of the present invention.

Fig. 4 is a schematic diagram of the internal structure of the present invention.

In the figure, 1, a fine screw conveyor; 2. positioning a vertical seat; 3. a horizontal mixing bin; 4. a feed tube orifice; 5. a blocking cover; 6. a cylindrical mixing chamber; 7. a mixing main shaft; 8. stirring teeth; 9. a connecting seat; 10. a vibrator; 11. an elastic buffer seat; 12. a pulse air pump; 13. a pulse trachea; 14. an air pressure balancing hole; 15. installing an outer seat; 16. a platform base; 17. a dual-shaft output motor; 18. a speed reducer; 19. an output bevel gear; 20. a bevel gear box; 21. an input bevel gear.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and therefore are only examples, and the protection scope of the present invention is not limited thereby. The specific structure of the utility model is shown in figures 1-4.

Example 1:

rubber resin granule material batching pay-off integration system, including two compounding subassemblies that are parallel and the interval sets up, two the both ends of compounding subassembly are connected the cooperation with the biax actuating mechanism that corresponds position department respectively, two biax actuating mechanism sets up at relative interval, two biax actuating mechanism cooperation is realized two the synchronous syntropy drive is realized to the compounding subassembly, two still be provided with a combination between the compounding subassembly and shake the material subassembly, the combination shakes the material subassembly and is used for realizing to its both sides the inside granule material of compounding subassembly vibrates the compounding, at each the bottom discharge gate department of compounding subassembly all installs a meticulous auger delivery ware 1, each the bottom export of meticulous auger delivery ware 1 is used for outwards quantitative transport the granule material after mixing. The rubber resin particle material batching and feeding integrated system integrally adopts the two material mixing components, so that the material mixing efficiency can be improved when the particles are mixed, the mixing of large batches of mixed materials can be realized, and meanwhile, because the two ends of each material mixing component are provided with power by adopting a double-shaft driving mechanism during the mixing, the sufficiency of the power during the material mixing and stirring can be better ensured; simultaneously the in-process cooperation of mixing starts the combination and shakes the material subassembly in order to reach further assurance compounding effect, promote compounding efficiency.

In any of the above schemes, preferably, the mixing component includes two vertical positioning seats 2 which are spaced relatively and fixedly arranged, two vertical positioning seats 2 are fixedly mounted at the top of the vertical positioning seat 2, a horizontal mixing silo 3 is mounted at the top of the horizontal mixing silo 3, a feeding pipe orifice 4 is mounted at the top of the feeding pipe orifice 4, a blocking cover 5 is mounted at the top of the feeding pipe orifice 4, a mixing main shaft 7 is mounted in a cylindrical mixing cavity 6 of the horizontal mixing silo 3, the left end and the right end of the mixing main shaft 7 respectively movably and hermetically penetrate through mounting holes in side end covers of the horizontal mixing silo 3 and respectively connected and matched with the double-shaft driving mechanism at corresponding positions, a flexible sealing member is arranged between the mounting holes of the side end covers at the left end and the right end of the mixing main shaft 7 in a clearance fit manner and in the middle to facilitate matching to realize small-amplitude vibration of the horizontal mixing silo 3, a plurality of mixing teeth 8 for stirring and mixing rubber resin mixed particles in the cylindrical mixing cavity 6 are fixedly mounted on the outer side wall of the middle section of the mixing main shaft 7 along the length direction at intervals, and a plurality of spiral conveyor 1 is mounted at the bottom of the spiral discharge port of the middle section of the horizontal mixing silo 3. When the mixing component works, two ends of the mixing main shaft 7 are respectively connected with the corresponding double-shaft driving mechanisms, so that the simultaneous driving of the two ends can be ensured when the mixing driving is carried out, the sufficiency of the driving force is ensured, the mixing and stirring effect is improved, and the stirring driving can be rapidly realized when a large amount of mixed granular materials are in the mixing component; meanwhile, the whole horizontal mixing silo 3 is also provided with a combined vibration component, so that the auxiliary vibration in the mixing and stirring process can be effectively ensured to achieve better efficiency.

In any of the above schemes, preferably, the combined material vibrating assembly includes a connecting seat 9 disposed between the two horizontal mixing silos 3, and two side walls of the connecting seat 9 are respectively and fixedly mounted with a vibrator 10 for connecting with an outer side wall of the horizontal mixing silo 3 at a corresponding position; the horizontal mixing bin 3 is connected with the top of each positioning vertical seat 2 through an elastic buffer seat. The combined vibration component is powered on through the vibrator 10 to achieve a state of mechanical vibration during operation, so that the particle materials can be better vibrated in a matching manner during mixing and stirring, and rapid and sufficient mixing is realized.

In any of the above schemes, preferably, a four-outlet type pulse air pump 12 is installed at the top of the connecting seat 9, and each outlet of the pulse air pump 12 is connected to the inside of the corresponding cylindrical mixing cavity 6 of the horizontal mixing bin 3 through a pulse air pipe 13; each of the plugging caps 5 is provided with an air pressure balance hole 14. The pulse air pump 12 mainly uses high-pressure and intermittent pulse of high-pressure pulse to realize rapid high-pressure airflow impact in the cylindrical mixing cavity 6, so as to be matched with the stirred granular materials to disperse.

In any of the above schemes, preferably, the double-shaft driving mechanism includes a fixed installation outer seat 15, a platform seat 16 is fixedly installed at the top of the installation outer seat 15, a double-shaft output motor 17 is fixedly installed at the top of the middle section of the platform seat 16, motor shafts at two sides of the double-shaft output motor 17 are respectively connected with a speed reducer 18 through a coupling, an output end of each speed reducer 18 is respectively connected with an input end of the bevel gear reversing unit at a corresponding position, an output end of each bevel gear reversing unit is respectively connected with an end of the mixing main shaft 7 at a corresponding position, the two double-shaft output motors 17 are matched to simultaneously realize synchronous resultant force driving on two end portions of each mixing main shaft 7 at two sides thereof, and the two mixing main shafts 7 simultaneously realize mixing and mixing of the mixed particles in the respective corresponding cylindrical mixing cavities 6 thereof. When the double-shaft driving mechanism works, double-shaft output power is realized by using a double-shaft output motor 17, the power is respectively decelerated by a speed reducer 18, and finally is output to the end part of the mixing main shaft 7 in a transmission reversing way through a bevel gear reversing unit so as to achieve the purpose of inputting rotary power. When the two double-shaft output motors 17 move, the two double-shaft output motors need to be matched at the same speed according to needs and apply force to two ends of each mixing main shaft 7 simultaneously, and resultant force is formed to better ensure the driving effect.

Example 2:

rubber resin granule material batching pay-off integrated system, including two compounding subassemblies that are parallel and the interval sets up, two the both ends of compounding subassembly are connected the cooperation with the biax actuating mechanism that corresponds position department respectively, two biax actuating mechanism sets up at relative interval, two biax actuating mechanism cooperation is realized two the synchronous syntropy drive of compounding subassembly realization, two still be provided with a combination between the compounding subassembly and shake the material subassembly, the combination is shaken the material subassembly and is used for realizing its both sides the inside granule material of compounding subassembly vibrates the compounding, at each the bottom discharge gate department of compounding subassembly all installs a meticulous auger delivery ware 1, each the bottom export of meticulous auger delivery ware 1 is used for outside quantitative transport granule material after the mixture.

In any of the above schemes, preferably, the mixing component includes two vertical positioning seats 2 which are spaced relatively and fixedly arranged, two vertical positioning seats 2 are fixedly mounted at the top of the vertical positioning seat 2, a horizontal mixing silo 3 is mounted at the top of the horizontal mixing silo 3, a feeding pipe orifice 4 is mounted at the top of the feeding pipe orifice 4, a blocking cover 5 is mounted at the top of the feeding pipe orifice 4, a mixing main shaft 7 is mounted in a cylindrical mixing cavity 6 of the horizontal mixing silo 3, the left end and the right end of the mixing main shaft 7 respectively movably and hermetically penetrate through mounting holes in side end covers of the horizontal mixing silo 3 and respectively connected and matched with the double-shaft driving mechanism at corresponding positions, a flexible sealing member is arranged between the mounting holes of the side end covers at the left end and the right end of the mixing main shaft 7 in a clearance fit manner and in the middle to facilitate matching to realize small-amplitude vibration of the horizontal mixing silo 3, a plurality of mixing teeth 8 for stirring and mixing rubber resin mixed particles in the cylindrical mixing cavity 6 are fixedly mounted on the outer side wall of the middle section of the mixing main shaft 7 along the length direction at intervals, and a plurality of spiral conveyor 1 is mounted at the bottom of the spiral discharge port of the middle section of the horizontal mixing silo 3.

When the mixing component works, two ends of the mixing main shaft 7 are respectively connected with the corresponding double-shaft driving mechanisms, so that the simultaneous driving of the two ends can be ensured when the mixing driving is carried out, the sufficiency of the driving force is ensured, the mixing and stirring effect is improved, and the stirring driving can be rapidly realized when a large amount of mixed granular materials are in the mixing component; meanwhile, the horizontal mixing bin 3 is integrally provided with a combined vibration component, so that the auxiliary vibration in the mixing and stirring process can be effectively ensured to achieve better efficiency.

In any of the above schemes, preferably, the combined material vibrating assembly includes a connecting seat 9 disposed between the two horizontal mixing silos 3, and two side walls of the connecting seat 9 are respectively and fixedly mounted with a vibrator 10 for connecting with an outer side wall of the horizontal mixing silo 3 at a corresponding position;

the horizontal mixing bin 3 is connected with the top of each positioning vertical seat 2 through an elastic buffer seat 11.

The combined vibration component is in a state of mechanical vibration by switching on a power supply through the vibrator 10 during working, so that the mixing and stirring can be better guaranteed to be matched with vibration particles, and the rapid mixing is fully realized.

In any of the above schemes, preferably, a four-outlet type pulse air pump 12 is installed at the top of the connecting seat 9, and each outlet of the pulse air pump 12 is connected to the inside of the corresponding cylindrical mixing cavity 6 of the horizontal mixing bin 3 through a pulse air pipe 13; each of the plugging caps 5 is provided with an air pressure balance hole 14.

The pulse air pump 12 mainly uses high-pressure and intermittent pulse of high-pressure pulse to realize rapid high-pressure airflow impact in the cylindrical mixing cavity 6, so as to be matched with the stirred granular materials to disperse.

In any of the above schemes, preferably, the double-shaft driving mechanism includes a fixed mounting outer seat 15, a platform seat 16 is fixedly mounted on the top of the mounting outer seat 15, a double-shaft output motor 17 is fixedly mounted on the top of the middle section of the platform seat 16, motor shafts on two sides of the double-shaft output motor 17 are respectively connected with a speed reducer 18 through a coupling, an output end of each speed reducer 18 is respectively connected with an input end of the bevel gear reversing unit at a corresponding position, an output end of each bevel gear reversing unit is respectively connected with an end of the mixing main shaft 7 at a corresponding position, the two double-shaft output motors 17 are matched to simultaneously drive two end portions of each mixing main shaft 7 on two sides thereof in a combined manner, and the two mixing main shafts 7 simultaneously stir and mix the mixed particles in the cylindrical mixing cavities 6 corresponding to the mixing main shafts.

When the double-shaft driving mechanism works, double-shaft output power is realized by using a double-shaft output motor 17, the power is respectively decelerated by a speed reducer 18, and finally is output to the end part of the mixing main shaft 7 in a transmission reversing way through a bevel gear reversing unit so as to achieve the purpose of inputting rotary power.

When the two double-shaft output motors 17 move, the two double-shaft output motors need to be matched at the same speed according to needs, and force is simultaneously applied to the two ends of each mixing main shaft 7, so that resultant force is formed, and the driving effect is better ensured.

In any of the above schemes, preferably, the bevel gear reversing unit includes a bevel gear box 20 fixedly installed on the top of the platform base 16, an input bevel gear 21 and an output bevel gear 19 which are engaged with each other are installed in the bevel gear box 20, and the input bevel gear 21 and the output bevel gear 19 both movably penetrate through a through hole at a corresponding position of the bevel gear box 20 and are connected with an output end of the speed reducer 18 and a corresponding end of the mixing spindle 7 at the corresponding position respectively.

The input bevel gear 21 and the output bevel gear 19 can realize the reversing of the input power by 90 degrees after being meshed and matched with each other, thereby ensuring the compactness of the structure and better realizing that the four end parts of the two mixing main shafts 7 can finish the power transmission and driving only by two double-shaft output motors 17.

In any of the above solutions, it is preferable that the transmission ratio of the input bevel gear 21 to the output bevel gear 19 is 1:1.

In any of the above schemes, preferably, the dual-shaft output motor 17 is a dual-shaft stepping motor, and can perform commutation and speed regulation better according to needs.

The specific working principle is as follows:

the rubber resin particle material batching and feeding integrated system is integrated

Before work, a proper amount of rubber resin granules are put into each horizontal mixing bin 3 through each feeding pipe opening 4, and each plugging cover 5 is installed after the feeding is finished. The adoption of the two material mixing components can ensure that the material mixing efficiency is improved when the particles are mixed, the mixing of large batches of mixed materials can be realized, and simultaneously, because the two ends of each material mixing component are provided with power by adopting a double-shaft driving mechanism during the mixing, the sufficiency of the power during the material mixing and stirring can be better ensured; simultaneously the in-process cooperation of mixing starts the combination and shakes the material subassembly in order to reach further assurance compounding effect, promote compounding efficiency.

After feeding, the two double-shaft driving mechanisms can be started to be synchronously matched to reasonably drive the corresponding mixing main shaft 7 to rotate, when the double-shaft driving mechanisms work, double-shaft output power is realized by using a double-shaft output motor 17, the power is respectively decelerated through a speed reducer 18, and finally is output to the end part of the mixing main shaft 7 through the transmission and the reversing of a bevel gear reversing unit to achieve the purpose of inputting rotary power.

Meanwhile, in order to ensure the mixing efficiency and effect, the combined vibration component achieves a mechanical vibration state by switching on a power supply through the vibrator 10 during working, so that the mixing and stirring can be better ensured to be matched with vibration particles, and the rapid and sufficient mixing can be realized; the pulse air pump 12 is started, and the high-pressure air impact to the interior of the cylindrical mixing cavity 6 is realized in a high-pressure and intermittent pulse mode of high-pressure pulse, so that the stirred particles are dispersed in a matched manner.

After the material mixing is finished, the combined vibrating assembly can be kept opened, and meanwhile, each fine screw conveyor 1 is started to output the mixed granular materials outwards in a fixed quantity.

The system is provided with the two mixing components simultaneously, so that the high efficiency of mixing materials such as rubber resin particles and the like can be effectively ensured, and the mixing amount and the mixing effect of the whole equipment are improved; when the materials are mixed, the materials can be fed into the two material mixing components at the same time, and after the materials are fed, the two material mixing components are driven by double shafts at two ends through double-shaft driving mechanisms, so that the sufficiency of driving power is effectively ensured; the combined material vibrating component arranged in the mixing device can better match with stirring and mixing materials in the horizontal mixing bin 3 in a vibrating and pulse airflow mode to further uniformly mix the materials in a mixing state, so that the mixing and mixing effects and efficiency are improved; the mixing main shafts 7 of the mixing components are driven at two ends simultaneously when being driven to rotate, so that the sufficiency of power supply can be better ensured, and the stability of rotation can be ensured by synchronously driving the two ends in the same direction, so that the sufficiency of power when a large amount of particle materials are mixed is ensured; the bottom of each horizontal mixing bunker 3 is provided with a fine screw conveyor 1, so that the mixed materials can be conveyed outwards quickly, and the materials can be discharged outwards smoothly when the mixed materials are conveyed outwards due to the arrangement of the vibrating piece.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit the same; although the present invention has been described in detail with reference to the foregoing embodiments, it should be understood by those skilled in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the scope of the embodiments of the present invention, and are intended to be covered by the claims and the specification; to those skilled in the art, any alternative improvements or changes made to the embodiments of the present invention are all within the scope of the present invention.

The parts of the present invention not described in detail are the known techniques of those skilled in the art.

Claims (8)

1. Rubber resin granule material batching pay-off integration system, its characterized in that: the two-shaft vibration mixing device comprises two mixing components which are arranged in parallel at intervals, wherein two end parts of each mixing component are respectively connected and matched with a double-shaft driving mechanism at a corresponding position, the double-shaft driving mechanisms are arranged at intervals relatively, the double-shaft driving mechanisms are matched to realize synchronous equidirectional driving of the two mixing components, a combined vibration component is further arranged between the two mixing components and used for realizing vibration mixing of particle materials inside the mixing components at two sides of the combined vibration component, a fine spiral conveyor is arranged at a bottom discharge port of each mixing component, and a bottom outlet of each fine spiral conveyor is used for quantitatively conveying the particle materials after mixing outwards.

2. The rubber resin granule batching and feeding integrated system as claimed in claim 1, wherein: the mixing component comprises two vertical positioning seats which are arranged at two opposite intervals and fixedly, a horizontal mixing silo is fixedly arranged at the top of each vertical positioning seat, a feeding pipe opening is arranged at the top of the horizontal mixing silo, a blocking cover is arranged at the top of the feeding pipe opening, a mixing main shaft is arranged in a cylindrical mixing cavity of the horizontal mixing silo, the left end and the right end of the mixing main shaft respectively movably and hermetically penetrate out of a mounting hole in a side end cover of the horizontal mixing silo and respectively connected and matched with a double-shaft driving mechanism at a corresponding position, a flexible sealing piece is arranged between the mounting holes of the side end covers at the two ends of the mixing main shaft in a clearance fit mode and in the middle of the mounting hole so as to be matched to realize small-amplitude vibration of the horizontal mixing silo, a plurality of mixing teeth which are used for stirring and mixing rubber-resin mixing particles in the cylindrical mixing cavity are fixedly arranged on the outer side wall of the mixing main shaft along the length direction of the mixing main shaft at the intervals, and mixing teeth of the inverted cone-shaped discharge port at the middle section of the bottom of the horizontal mixing silo are arranged, and the fine spiral conveyor is arranged at the bottom of the horizontal mixing silo.

3. The rubber resin granule batching and feeding integrated system as claimed in claim 2, wherein: the combined material vibrating component comprises a connecting seat arranged between the two horizontal mixing bins, and vibrators used for being connected with the outer side walls of the horizontal mixing bins at corresponding positions are fixedly arranged on the two side walls of the connecting seat respectively;

the horizontal mixing bin is connected with the top of each positioning vertical seat through an elastic buffer seat.

4. The rubber resin granule batching and feeding integrated system as claimed in claim 3, wherein: a four-outlet type pulse air pump is installed at the top of the connecting seat, and each outlet of the pulse air pump is connected into the corresponding cylindrical mixing cavity of the horizontal mixing bin through a pulse air pipe; and each plugging cover is provided with an air pressure balancing hole.

5. The rubber resin granule batching and feeding integrated system as claimed in claim 4, wherein: the double-shaft driving mechanism comprises a fixedly arranged outer mounting seat, a platform seat is fixedly mounted at the top of the outer mounting seat, a double-shaft output motor is fixedly mounted at the top of the middle section of the platform seat, motor shafts on two sides of the double-shaft output motor are respectively connected with a speed reducer through a coupler, the output end of each speed reducer is respectively connected with the input end of a bevel gear reversing unit at the corresponding position, the output end of each bevel gear reversing unit is respectively connected with the end part of a mixing main shaft at the corresponding position, the two double-shaft output motors are matched to realize synchronous resultant force driving on the two end parts of each mixing main shaft on two sides of the double-shaft output motors, and the two mixing main shafts simultaneously stir and mix the mixed particles in respective corresponding cylindrical mixing cavities of the mixing main shafts.

6. The rubber resin granule batching and feeding integrated system as claimed in claim 5, wherein: the bevel gear reversing unit comprises a bevel gear box fixedly installed at the top of the platform base, an input bevel gear and an output bevel gear which are meshed with each other are installed in the bevel gear box, and the input bevel gear and the output bevel gear movably penetrate through a through hole in the corresponding position of the bevel gear box and are connected with the output end of the speed reducer and the corresponding end of the mixing main shaft in the corresponding position respectively.

7. The rubber resin granule batching and feeding integrated system as claimed in claim 6, wherein: the transmission ratio of the input bevel gear to the output bevel gear is 1:1.

8. The rubber resin granule batching and feeding integrated system as claimed in claim 7, wherein: the double-shaft output motor is a double-shaft stepping motor.

Images