CN217773970U - Full-automatic heating planetary gravity disperser - Google Patents

Abstract

The utility model discloses a planetary gravity dispersion ware of full-automatic heating, aim at solve and adopt current deaeration mixer to mix when stirring the processing to the material, can't carry out the thermal treatment, and the material is under the effect of centrifugal force, shearing force and sliding friction power in the material cup, and the temperature rise is higher very fast, nevertheless behind the thermal balance, still can not reach the problem of requirement temperature. The device comprises a standing unit, a rack, a driving unit, a temperature adjusting unit and a control system; the standing unit comprises a sealed cavity lower plate, a sealed cavity side wall, a sealed cavity upper plate and a sealed cavity upper cover, wherein the sealed cavity lower plate, the sealed cavity side wall and the sealed cavity upper plate sequentially form a sealed cavity from bottom to top, and a cavity upper opening matched with the sealed cavity upper cover is formed in the sealed cavity upper plate. The full-automatic heating planetary gravity disperser can effectively heat the processed materials, can uniformly stir and defoam, and has the advantages of high production efficiency, simple structure, stability, reliability and the like.

Description

Full-automatic heating planetary gravity disperser

Technical Field

The utility model relates to a gravity mixing stirring field specifically is planetary gravity dispersion ware of full-automatic heating. More specifically, the application provides a planetary gravity compounding agitating unit heats automatically, and it provides a solution that heats automatically, and is significant to expanding planetary gravity disperser.

Background

In the physical field of condensed state, and industries such as novel nano materials, semiconductors, chemical industry, medicines, coatings, adhesives and the like, the raw materials are often required to be quickly mixed and stirred. In certain specific cases, it is necessary to heat the material to a certain value during mixing and deaeration.

Chinese patent CN200820062126.1 discloses a "deaeration mixer", which can conveniently mix and deaerate several raw materials, and the problem that it exists lies in: the material to be treated can not be heated, the temperature rise of the material in the material cup is higher and faster under the action of centrifugal force, shearing force and sliding friction force, but the material still can not reach the required value after thermal balance.

Therefore, a new device is urgently needed to solve the above problems.

SUMMERY OF THE UTILITY MODEL

The invention of the utility model aims to: the full-automatic heating planetary gravity disperser aims at solving the problems that when the existing defoaming stirrer is used for mixing and stirring materials, heating treatment cannot be carried out, the temperature of the materials in a material cup is high and quick under the action of centrifugal force, shearing force and sliding friction force, but the materials still cannot reach required values after heat balance. By adopting the device, the materials can be heated in the process of stirring and defoaming the materials so as to reach the preset reaction temperature, thereby meeting the requirements of specific material preparation conditions and effectively solving the problems. The full-automatic heating planetary gravity disperser can effectively heat materials to be treated, can uniformly stir and defoam, has the advantages of high production efficiency, simple structure, stability, reliability and the like, and has important significance for expanding the application range of equipment and promoting the research and development and preparation of new materials.

In order to achieve the purpose, the following technical scheme is adopted in the application:

the full-automatic heating planetary gravity disperser comprises a standing unit, a frame, a driving unit, a temperature adjusting unit and a control system;

the standing unit comprises a sealing cavity lower plate, a sealing cavity side wall, a sealing cavity upper plate and a sealing cavity upper cover, wherein the sealing cavity lower plate, the sealing cavity side wall and the sealing cavity upper plate sequentially form a sealing cavity from bottom to top;

the standing unit is arranged on the rack, and the rack can provide support for the standing unit;

the driving unit comprises a central spindle seat, a hollow spindle, a V-shaped belt wheel, a motor, a V-shaped belt, a fixed gear, a rotating arm arranged in the sealed cavity, a coupling gear set, a material cup seat used for placing a material cup, and a cup seat gear matched with the coupling gear set;

the central spindle seat is arranged on the lower plate of the sealing cavity, the hollow spindle is arranged on the central spindle seat and can rotate relative to the central spindle seat, the upper end of the hollow spindle is positioned in the sealing cavity, and the lower end of the hollow spindle is positioned outside the sealing cavity;

the V-shaped belt wheel is arranged at the lower end of the hollow main shaft, the V-shaped belt wheel and the hollow main shaft are kept relatively static, the motor is arranged outside the standing unit, the motor is connected with the rack and can provide support for the motor, the V-shaped belt is arranged on the V-shaped belt wheel and an output shaft of the motor, and the output shaft of the motor can drive the hollow main shaft to rotate through the V-shaped belt and the V-shaped belt wheel;

the fixed gear is connected with the lower plate of the sealed cavity and keeps relatively static with the lower plate of the sealed cavity, and the rotating arm is connected with the hollow main shaft and the hollow main shaft can drive the rotating arm to synchronously rotate;

the coupling gear set is connected with the rotating arm and can rotate relative to the rotating arm, the coupling gear set is meshed with the fixed gear, and the rotating arm can drive the coupling gear set to rotate relative to the fixed gear;

the material cup seat is connected with the rotating arm and can rotate relative to the rotating arm, the cup seat gear is arranged on the outer wall of the material cup seat, the cup seat gear of the material cup seat is meshed with the coupling gear set, and the material cup seat can be driven to rotate relative to the rotating arm sequentially through the coupling gear set and the cup seat gear when the rotating arm revolves;

the temperature adjusting unit comprises an infrared temperature sensor, a heating ring, a conductive cable, a slip ring support and a rotary conductive slip ring for providing electric energy for the heating ring, the infrared temperature sensor is arranged on the standing unit and can measure the temperature of the material to be processed in the material cup seat;

the heating ring is connected with the rotating arm, the heating ring is positioned on the outer side of the material cup seat and can heat materials in the material cup seat, the conductive cable penetrates through a cavity in the hollow main shaft, a sealing element for fixing the conductive cable is arranged in the hollow main shaft, and a sealing state can be formed in the sealing cavity through the sealing element;

the slip ring support is connected with the rack, the rack can provide support for the slip ring support, the rotary conductive slip ring is arranged on the slip ring support, and the slip ring support can provide support for the rotary conductive slip ring; one end of the conductive cable is electrically connected with the heating ring, and the other end of the conductive cable is electrically connected with the rotary conductive slip ring and can realize the work of the heating ring through the rotary conductive slip ring and the conductive cable in sequence so as to realize the regulation and control of the temperature of the material in the material cup seat;

the standing unit is provided with a vacuum interface, and the motor, the infrared temperature sensor and the heating ring are respectively connected with the control system.

The side wall of the sealing cavity is in a circular tube shape with two open ends or in a polygonal tube shape with two open ends;

the lower sealing cavity plate is arranged on the lower end opening of the side wall of the sealing cavity, and the upper sealing cavity plate is arranged on the upper end opening of the side wall of the sealing cavity;

the lower plate of the sealing cavity is connected with the frame, and the frame can provide support for the standing unit through the lower plate of the sealing cavity.

The shock absorption device is characterized by further comprising a plurality of shock absorption pads, wherein the shock absorption pads are arranged between the lower plate of the sealed cavity and the rack and can reduce the shock of the standing unit.

The machine also comprises a machine leg arranged below the machine frame.

The hollow main shaft is connected with the lower plate of the sealing cavity in a dynamic sealing manner.

The number of the material cup seats is N, N is a natural number and is more than or equal to 2.

The feed cup seat is two, the feed cup seat symmetry sets up on the swinging boom.

The temperature sensor is arranged on the upper cover of the sealed cavity.

The temperature sensor and the material cup seat are installed coaxially.

The heating ring and the material cup seat are coaxially arranged.

The heating ring wraps the whole material cup seat.

And the rotary conductive slip ring is fixed right below the hollow main shaft.

The axial direction of the motor output shaft is parallel to the axial direction of the hollow main shaft.

The sealing element arranged on the hollow main shaft and used for fixing the conductive cable is formed by solidifying sealing colloid.

The vacuum-pumping device is connected with the vacuum interface and can carry out vacuum-pumping treatment on the sealed cavity through the vacuum interface.

The vacuumizing device is connected with the control system.

In this application, adopt infrared temperature sensor real-time supervision material temperature, need not wait for the swinging boom to stop, very big improvement the work efficiency of equipment. Meanwhile, the sealing cavity is also a vacuum cavity and is connected with a vacuum system, so that the complexity of the system is reduced, and the reliability of the structure is ensured.

In summary, the present application provides a full-automatic heating planetary gravity disperser, which monitors the temperature of the material rotating at high speed in real time by an infrared temperature sensor, rapidly heats the material by a heating ring, and automates the whole stirring, defoaming and heating processes by the control of a control system; thereby greatly improving the working efficiency, reducing the overall batch processing cost and expanding the application field of the equipment.

Drawings

Fig. 1 is a sectional view of a fully automatic heating planetary gravity dispenser in embodiment 1.

Fig. 2 is a side view of the fully automatic heating planetary gravity dispenser of embodiment 1.

Fig. 3 is a top view of the fully automatic heating planetary gravity disperser in example 1.

The labels in the figure are: 1. heating ring, 2, material cup seat, 3, cup seat gear, 4, material cup, 5, rotating arm, 6, coupling gear set, 7, fixed gear, 8, hollow spindle, 9, central spindle seat, 10, V-shaped belt, 11, V belt wheel, 12, rotating conductive slip ring, 13, slip ring support, 14, machine foot, 15, frame, 16, motor, 17, sealing cavity side wall, 18, sealing cavity upper cover, 19, infrared temperature sensor, 20, conductive cable, 21, sealing cavity upper plate, 22, sealing cavity lower plate, 23, shock pad, 24 and vacuum interface.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings.

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

Example 1

The embodiment provides a full-automatic heating planetary gravity disperser which comprises a standing unit, a frame, a driving unit, a temperature adjusting unit and a control system. The standing unit comprises a sealed cavity lower plate, a sealed cavity side wall, a sealed cavity upper plate and a sealed cavity upper cover, and the sealed cavity lower plate, the sealed cavity side wall and the sealed cavity upper plate sequentially form a sealed cavity from bottom to top. As shown in the figure, the embodiment further comprises a plurality of shock-absorbing pads, and the shock-absorbing pads are arranged between the lower plate of the sealed cavity and the frame; the side wall of the sealed cavity is in a circular tube shape with openings at two ends, the lower plate of the sealed cavity is arranged on the lower end opening of the side wall of the sealed cavity, and the upper plate of the sealed cavity is arranged on the upper end opening of the side wall of the sealed cavity; the lower plate of the sealing cavity is connected with the frame, and the frame can provide support for the standing unit through the lower plate of the sealing cavity. Further, still include the undercarriage of setting in the frame below.

Meanwhile, a cavity upper opening matched with the sealing cavity upper cover is formed in the sealing cavity upper plate, the sealing cavity upper cover is hinged to the sealing cavity upper plate, and the sealing cavity upper cover can rotate relative to the sealing cavity upper plate to open and close the sealing cavity. In the structure, a complete sealed cavity is formed among the sealed cavity lower plate, the sealed cavity side wall, the sealed cavity upper plate and the sealed cavity upper cover.

In this embodiment, the driving unit includes a central spindle seat, a hollow spindle, a V-belt pulley, a motor, a V-belt, a fixed gear, a rotating arm disposed in the sealed cavity, a coupling gear set, a material cup seat for placing a material cup, and a cup seat gear matched with the coupling gear set. The central spindle seat is arranged on the lower plate of the sealing cavity, the hollow spindle is arranged on the central spindle seat, and the hollow spindle can rotate relative to the central spindle seat. In this embodiment, the hollow main shaft passes through the lower plate of the sealed cavity, the upper end of the hollow main shaft is located in the sealed cavity, and the lower end of the hollow main shaft is located outside the sealed cavity.

Meanwhile, the V belt wheel is arranged at the lower end of the hollow main shaft, and the V belt wheel and the hollow main shaft are kept relatively static. The motor sets up and is stewing the unit outside, and the motor links to each other with the frame, and the frame can provide the support for the motor. The V-shaped belt is arranged on the V-shaped belt wheel and the output shaft of the motor, and the output shaft of the motor can drive the hollow main shaft to rotate through the V-shaped belt and the V-shaped belt wheel.

The fixed gear is connected with the lower plate of the sealing cavity, and the fixed gear and the lower plate of the sealing cavity are kept relatively static. The rotating arm is connected with the hollow main shaft, and the hollow main shaft can drive the rotating arm to synchronously rotate. The coupling gear set is connected with the rotating arm and can rotate relative to the rotating arm; the coupling gear set is meshed with the fixed gear; and the rotating arm can drive the coupling gear set to rotate relative to the fixed gear.

The material cup seat is connected with the rotating arm and can rotate relative to the rotating arm. The cup seat gear is arranged on the outer wall of the material cup seat, the cup seat gear of the material cup seat is meshed with the coupling gear set, and the rotating arm can drive the material cup seat to rotate relative to the rotating arm sequentially through the coupling gear set and the cup seat gear during revolution.

In the structure, when the hollow main shaft drives the rotating arm to rotate, the rotating arm drives the coupling gear set to synchronously rotate; because the coupling gear set is meshed with the fixed gear, and the fixed gear and the sealing cavity lower plate keep relatively static, the coupling gear set rotates relative to the sealing cavity lower plate, and the cup seat gear is driven to be automatic based on the meshing relation between the cup seat gear of the cup seat and the coupling gear set. Further, as shown in the figure, the material cup base of this embodiment is two, and fretwork cup base symmetry sets up on the swinging boom.

In this embodiment, the temperature adjustment unit includes an infrared temperature sensor, a heating ring, a conductive cable, a slip ring support, and a rotating conductive slip ring for providing electrical energy to the heating ring. Wherein, infrared temperature sensor sets up on the unit that stews, and infrared temperature sensor can survey the temperature of the material of being handled in the cup. The infrared temperature sensor is connected with the control system and can transmit the measured temperature information of the processed material in the cup holder to the control system. Preferably, the temperature sensor and the material cup seat are coaxially installed. Further, the temperature sensor is arranged on the upper cover of the sealed cavity.

In this embodiment, the heating ring is connected to the rotating arm, and the heating ring and the rotating arm remain relatively stationary. The heating ring is positioned on the outer side of the material cup seat and can heat materials in the material cup seat. Preferably, the heating ring and the material cup seat are installed coaxially, and the heating ring wraps the whole material cup seat.

Meanwhile, the conductive cable penetrates through a cavity in the hollow main shaft, a sealing element used for fixing the conductive cable is arranged in the hollow main shaft, and a sealing state can be formed in the sealing cavity through the sealing element. In this embodiment, the sealing element is formed by solidifying the sealing colloid.

The slip ring support is connected with the frame, and the frame can provide the support for the slip ring support. The rotary conductive slip ring is arranged on the slip ring support, and the slip ring support can provide support for the rotary conductive slip ring. One end of the conductive cable is electrically connected with the heating ring, the other end of the conductive cable is electrically connected with the rotary conductive slip ring, and the work of the heating ring can be realized sequentially through the rotary conductive slip ring and the conductive cable, so that the regulation and control of the temperature of materials in the material cup seat are realized. Preferably, the rotary conductive slip ring is fixed right below the hollow spindle, and the axial direction of the output shaft of the motor is parallel to the axial direction of the hollow spindle (i.e. the motor and the hollow spindle are horizontally arranged and connected through a belt).

In this embodiment, the vacuum interface is disposed on the standing unit, and the motor, the infrared temperature sensor, and the heating ring are respectively connected to the control system.

The vacuum-pumping device is connected with the vacuum interface and can carry out vacuum-pumping treatment on the sealed cavity through the vacuum interface. Further, the vacuum-pumping device is connected with the control system.

In this embodiment, the infrared temperature sensor, the heating ring, and the control system together form a heating closed-loop system. The control system monitors the temperature of the material in the material cup rotating at a high speed in real time through the infrared temperature sensor and controls the heating ring to control the temperature of the material in the material cup in the sealing cavity.

In this embodiment, the sealed cavity lower plate is fixed on the frame through the shock pad, the motor is fixed on the right side of the sealed cavity lower plate, the rotating arm is connected on the hollow spindle, the material cup seat is movably connected on the rotating arm, a coupling gear set is fixed under the rotating arm, and the coupling gear set is respectively meshed with the cup seat gear and the fixed gear 7. The heating ring is fixed on the rotating arm, the conductive cable is connected with the rotary conductive slip ring through the hollow main shaft, the rotary conductive slip ring is fixed on the slip ring support, and the slip ring support is fixed on the rack. And the upper plate of the sealing cavity, the side wall of the sealing cavity and the lower plate of the sealing cavity are welded and fixed. The upper cover of the sealed cavity is fixed on the upper plate of the sealed cavity through a hinge, and the infrared temperature sensor is fixed on the upper cover of the sealed cavity and is coaxial with the axis of a material cup seat. The lower plate of the sealing cavity is provided with a vacuum interface.

The working process of the full-automatic heating planetary gravity disperser is as follows:

1) Putting the material into a material cup, and then putting the material cup into a material cup seat;

2) Starting a motor, wherein an output shaft of the motor drives a rotating arm to revolve through a V-shaped belt; under the drive of the motor, the rotating arm provided with the material cup rotates in the sealed cavity;

the rotating arm movably connected to the lower plate of the sealed cavity revolves, and in the process of rotating the output shaft of the motor, the revolution simultaneously triggers the rotation of the coupling gear set, and at the moment, the rotation also starts the operation, and the revolution speed and the rotation speed at the moment are determined by the transmission ratio of the gear set;

3) When the material revolves in the material cup, the material is acted by centrifugal force, and the gravity separation motion generated along the vector direction and the upward pushing action generated by the self weight of the material separate the bubbles to play a role in defoaming; meanwhile, when the material rotates in the material cup, under the action of centrifugal vector resultant force formed by the rotation of the material cup, the shearing force of the material and the wall surface of the material cup and the friction among molecules in the material generate a mixing and dispersing effect, and a vacuumizing device is started through a control system to finally realize the functions of defoaming and stirring;

4) When the infrared temperature sensor monitors that the temperature of the material does not reach a set value in real time, the control system controls the heating ring to heat so as to rapidly heat the material; when the material temperature reaches a set value, the control system controls the heating ring to stop heating, the heating of the material is stopped, and finally the functions of defoaming, stirring and heating are realized.

The utility model discloses a heating system that infrared temperature sensor, heating ring, control system constitute reaches the further separation bubble of stirring material through sealed chamber to the effect of heating material has been realized. The whole machine can accurately heat materials in real time while finishing the functions of defoaming and stirring the mixed materials, thereby greatly improving the application range of the equipment. Further, this application can improve the mixed purity of material through supplementary vacuum, improves the product quality. The full-automatic heating control system improves the overall industrial batch processing efficiency and the application field of equipment.

The above description is only exemplary of the present invention and should not be taken as limiting the scope of the present invention, as any modifications, equivalents, improvements and the like made within the spirit and principles of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. The full-automatic heating planetary gravity disperser is characterized by comprising a standing unit, a rack, a driving unit, a temperature adjusting unit and a control system;

the standing unit comprises a sealing cavity lower plate, a sealing cavity side wall, a sealing cavity upper plate and a sealing cavity upper cover, wherein the sealing cavity lower plate, the sealing cavity side wall and the sealing cavity upper plate sequentially form a sealing cavity from bottom to top;

the standing unit is arranged on the rack, and the rack can provide support for the standing unit;

the driving unit comprises a central spindle seat, a hollow spindle, a V-shaped belt wheel, a motor, a V-shaped belt, a fixed gear, a rotating arm arranged in the sealed cavity, a coupling gear set, a material cup seat used for placing a material cup, and a cup seat gear matched with the coupling gear set;

the central spindle seat is arranged on the lower plate of the sealed cavity, the hollow spindle is arranged on the central spindle seat and can rotate relative to the central spindle seat, the upper end of the hollow spindle is positioned in the sealed cavity, and the lower end of the hollow spindle is positioned outside the sealed cavity;

the V-shaped belt wheel is arranged at the lower end of the hollow main shaft, the V-shaped belt wheel and the hollow main shaft are kept relatively static, the motor is arranged outside the standing unit, the motor is connected with the rack and can provide support for the motor, the V-shaped belt is arranged on the V-shaped belt wheel and an output shaft of the motor, and the output shaft of the motor can drive the hollow main shaft to rotate through the V-shaped belt and the V-shaped belt wheel;

the fixed gear is connected with the lower plate of the sealed cavity and keeps relatively static with the lower plate of the sealed cavity, the rotating arm is connected with the hollow main shaft, and the hollow main shaft can drive the rotating arm to synchronously rotate;

the coupling gear set is connected with the rotating arm and can rotate relative to the rotating arm, the coupling gear set is meshed with the fixed gear, and the rotating arm can drive the coupling gear set to rotate relative to the fixed gear;

the material cup seat is connected with the rotating arm and can rotate relative to the rotating arm, the cup seat gear is arranged on the outer wall of the material cup seat, the cup seat gear of the material cup seat is meshed with the coupling gear set, and the material cup seat can be driven to rotate relative to the rotating arm sequentially through the coupling gear set and the cup seat gear when the rotating arm revolves;

the temperature adjusting unit comprises an infrared temperature sensor, a heating ring, a conductive cable, a slip ring support and a rotary conductive slip ring for providing electric energy for the heating ring, the infrared temperature sensor is arranged on the standing unit and can measure the temperature of the material to be processed in the material cup seat;

the heating ring is connected with the rotating arm, the heating ring is positioned on the outer side of the material cup seat and can heat materials in the material cup seat, the conductive cable penetrates through a cavity in the hollow main shaft, a sealing element for fixing the conductive cable is arranged in the hollow main shaft, and a sealing state can be formed in the sealing cavity through the sealing element;

the slip ring support is connected with the rack, the rack can provide support for the slip ring support, the rotary conductive slip ring is arranged on the slip ring support, and the slip ring support can provide support for the rotary conductive slip ring; one end of the conductive cable is electrically connected with the heating ring, and the other end of the conductive cable is electrically connected with the rotary conductive slip ring and can realize the work of the heating ring through the rotary conductive slip ring and the conductive cable in sequence so as to realize the regulation and control of the temperature of the material in the material cup seat;

the standing unit is provided with a vacuum interface, and the motor, the infrared temperature sensor and the heating ring are respectively connected with the control system.

2. The fully automated heating planetary gravity diffuser according to claim 1, wherein the capsule sidewall is in a shape of a circular tube open at both ends, or in a shape of a polygonal tube open at both ends;

the lower sealing cavity plate is arranged on the lower end opening of the side wall of the sealing cavity, and the upper sealing cavity plate is arranged on the upper end opening of the side wall of the sealing cavity;

the lower plate of the sealing cavity is connected with the rack, and the rack can provide support for the standing unit through the lower plate of the sealing cavity.

3. The full-automatic heating planetary gravity disperser according to claim 1, wherein the cup holders are N, N is a natural number and N is 2 or more.

4. The fully automatic heating planetary gravity diffuser according to claim 1, wherein the temperature sensor is installed coaxially with the cup holder.

5. The fully automated heating planetary gravity diffuser according to claim 1, wherein the heating ring and the material cup are coaxially installed.

6. The fully automated heating planetary gravity diffuser according to claim 1, wherein the rotating conductive slip ring is fixed directly below the hollow main shaft.

7. The fully automated heating planetary gravity diffuser according to claim 1, wherein the axial direction of the motor output shaft is parallel to the axial direction of the hollow main shaft.

8. The fully automated heating planetary gravity diffuser according to claim 1, wherein the sealing means provided at the hollow main shaft for fixing the conductive cable is solidified by a sealing gel.

9. The full-automatic heating planetary gravity disperser according to any of claims 1 to 8, further comprising a vacuum extractor, wherein the vacuum extractor is connected to the vacuum port and can vacuumize the sealed cavity through the vacuum port.

10. The fully automated heating planetary gravity diffuser according to claim 9, wherein the vacuum pumping device is connected to a control system.

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