CN214554128U - Magnetic force driven tissue mashing equipment - Google Patents

Abstract

The utility model discloses a magnetic force driven tissue mashing equipment, which comprises a cylinder body, a cylinder cover and a base, wherein the cylinder body is fixed on the base, the cylinder cover can be detachably connected with the top of the cylinder body, a blade is rotatably connected in the cylinder body, a motor is arranged on the base, the motor drives the blade to rotate through a magnetic transmission mechanism, a quick-release interface is connected on the cylinder cover, the quick-release interface is connected with a respirator, and the top of the respirator is connected with a T-shaped clean air pipeline; the cylinder body overcoat is equipped with cooling jacket, be equipped with the first temperature sensor who is used for monitoring its inside temperature on the lateral wall of cylinder body. Structure more than adopting, the utility model discloses when smashing the tissue to pieces, can keep smashing the tissue thick liquid temperature stability after smashing to pieces, can not appear leaking moreover and by the air pollution who takes the fungus.

Description

Magnetic force driven tissue mashing equipment

Technical Field

The utility model relates to a smash the equipment field to pieces, especially relate to a magnetic drive's tissue smashes equipment to pieces.

Background

The mashing equipment used at present consists of a mashing cylinder body with a blade, a mashing cylinder cover and a mashing motor base. When in use, the tissue to be mashed is put into the mashing cylinder, and the switch of the mashing machine is turned on to be mashed. The existing mashing equipment has the following defects:

1. after the mashing machine is sterilized for multiple times, the bottom sealing ring is easy to age, and after the mashing machine is used for multiple times, the sealing ring is easy to leak, and the ball bearing is easy to block and the like;

2. the mashing cylinder cover is provided with a small hole for balancing the internal pressure and the external pressure during mashing, and the mashing cylinder cover is directly communicated with the atmosphere, so that pollution is easily caused;

3. the mashing cylinder body is not provided with a cooling system and a temperature detection device in the using process, and the mashed object can be sheared at a high speed during high-speed mashing, so that the temperature of the content is increased, and the temperature of the mashed tissue slurry cannot be kept stable;

4. the mashed tissue slurry needs to be poured out by opening a cover, the amount of the mashed sample is limited each time, and a large amount of tissue cannot be mashed at one time.

Disclosure of Invention

An object of the utility model is to provide a magnetic drive's tissue triturates equipment to pieces.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a magnetic force driven tissue mashing device comprises a cylinder body, a cylinder cover and a base, wherein the cylinder body is fixed on the base, the cylinder cover is detachably connected to the top of the cylinder body, a blade is rotatably connected in the cylinder body, a motor is arranged on the base and drives the blade to rotate through a magnetic transmission mechanism, a quick-release interface is connected to the cylinder cover and is connected with a respirator, a T-shaped clean air pipeline is connected to the top of the respirator, and a first electromagnetic valve, a second electromagnetic valve and a third electromagnetic valve are respectively connected to three branch pipes of the T-shaped clean air pipeline; the cooling jacket is sleeved outside the cylinder body and connected with a cooling water inlet pipe and a cooling water outlet pipe, the cooling water inlet pipe is sequentially connected to the seventh electromagnetic valve, the cooling water pump and the refrigerating unit, and the cooling water outlet pipe is connected with the eighth electromagnetic valve; be equipped with the first temperature sensor who is used for monitoring its inside temperature on the lateral wall of cylinder body.

Further, the bottom of the cylinder body is connected with a discharge valve.

Furthermore, a second temperature sensor for monitoring the temperature of cooling water in the cooling jacket is arranged in the cooling jacket.

Further, the utility model discloses a when small-size equipment of smashing to pieces, magnetic drive mechanism includes outer magnet rotor, interior magnet rotor and dead lever, the dead lever is fixed on the inside diapire of cylinder body along vertical direction, interior magnet rotor passes through the bearing and rotates the lower extreme of connecting in the dead lever, the blade passes through the fixed column and connects fixedly on interior magnet rotor, outer magnet rotor fixes on the output shaft of motor and is located interior magnet rotor under.

Furthermore, the bottom of the cylinder body is connected and fixed on the base through a quick-release bolt, and the cylinder cover is fixed on the top of the cylinder body through a clamp spring.

Furthermore, the bottom of the respirator is sequentially connected to the quick-release interface through a fifth electromagnetic valve and a sixth electromagnetic valve, an injection water inlet pipe is connected between the fifth electromagnetic valve and the sixth electromagnetic valve, and a fourth electromagnetic valve is connected to the injection water inlet pipe.

Further, the utility model discloses a when large-scale equipment of pounding to pieces, magnetic drive mechanism includes outer magnet rotor, interior magnet rotor, transmission shaft and spacer sleeve, the spacer sleeve links into an integrated entity bottom the cylinder body, outer magnet rotor fixes on the output shaft of motor and encircles and cup joint the outside at the spacer sleeve, bearing rotation sealing connection in the bottom of cylinder body is passed through at the middle part of transmission shaft, the blade is fixed in the upper end of transmission shaft, the lower extreme of transmission shaft extend into in the spacer sleeve and with interior magnet rotor fixed connection.

Furthermore, the bottom of the respirator is sequentially connected to the quick-release interface through a fifth electromagnetic valve and a sixth electromagnetic valve, a cleaning ball is arranged on the inner side of the cylinder cover, an inlet of the cleaning ball is connected with an injection water inlet pipe, and a fourth electromagnetic valve is connected to the injection water inlet pipe.

Further, the cylinder cap passes through bolt locking to be fixed on the cylinder body, and is equipped with the sealing washer between cylinder cap and the cylinder body, be connected with the manometer that is used for monitoring cylinder body internal pressure size on the cylinder cap, still be connected with the feed inlet that can open and close on the cylinder cap.

Furthermore, a high liquid level sensor, a medium liquid level sensor and a low liquid level sensor are sequentially arranged on the inner side wall of the cylinder body from top to bottom; the device is characterized in that a liquid inlet pipe is connected onto the cylinder cover, a ninth electromagnetic valve is connected onto the liquid inlet pipe, the rear end of the ninth electromagnetic valve is respectively connected with a protective agent liquid inlet pipe and a pure steam inlet pipe, a tenth electromagnetic valve is connected onto the protective agent liquid inlet pipe, and an eleventh electromagnetic valve is connected onto the pure steam inlet pipe.

The utility model adopts the above technical scheme, following beneficial technological effect has:

1. the small mashing equipment designed by the utility model does not need to open a hole on the cylinder body and install a stirring shaft, thus thoroughly eliminating the problems of leakage or bearing blockage caused by aging of the sealing ring due to use or repeated sterilization;

2. the cylinder body bottom driving device of the improved large mashing equipment is a static sealing magnetic transmission mechanism, so that the leakage is avoided in the using and sterilizing processes;

3. the utility model can control the tissue slurry in the mashing process within the required temperature range through the linkage of the first temperature sensor in the cylinder body and the cooling system;

4. the utility model is provided with the aseptic respirator on the cylinder cover to ensure the sterility of the outside air after the air is introduced, and is provided with the T-shaped clean air pipeline to connect the clean air as the power for conveying the tissue slurry after pounding;

5. the utility model adds a liquid level sensor on the inner wall of the cylinder body of the improved large-scale mashing equipment, ensures that the input materials and the injected protective agent are proper, and the automatically injected protective agent can not overflow the cylinder body excessively;

6. the steam sterilization device is additionally arranged on the improved large mashing equipment, so that the cylinder body is ensured to be in an aseptic state;

7. the utility model discloses install second temperature sensor in the cooling jacket for the cooling water temperature when smashing to pieces is answered in the response, and the refrigeration effect of assurance cooling water is qualified.

Drawings

The present invention will be described in further detail with reference to the accompanying drawings and specific embodiments;

fig. 1 is a schematic view of embodiment 1 of the present invention;

fig. 2 is a schematic view of embodiment 2 of the present invention.

Detailed Description

As shown in fig. 1-2, the utility model relates to a magnetic force driven tissue mashing equipment, including cylinder body 1, cylinder cap 2 and base 3, cylinder body 1 is fixed on base 3, cylinder cap 2 can be dismantled and connect at the top of cylinder body 1, the internal rotation of cylinder body 1 is connected with blade 4, be equipped with motor 5 on the base 3, motor 5 drives blade 4 through magnetic transmission mechanism 6 and rotates, be connected with quick detach interface 7 on the cylinder cap 2, quick detach interface 7 is connected with respirator 8, the top of respirator 8 is connected with T shape clean air pipeline 9, be connected with first solenoid valve 10.1, second solenoid valve 10.2 and third solenoid valve 10.3 on the three branch pipes of T shape clean air pipeline 9 respectively; a cooling jacket 11 is sleeved outside the cylinder body 1, the cooling jacket 11 is connected with a cooling water inlet pipe 11.1 and a cooling water outlet pipe 11.2, the cooling water inlet pipe 11.1 is sequentially connected to a seventh electromagnetic valve 10.7, a cooling water pump 12 and a refrigerating unit 13, and the cooling water outlet pipe 11.2 is connected with an eighth electromagnetic valve 10.8; the side wall of the cylinder body 1 is provided with a first temperature sensor 14 for monitoring the internal temperature thereof.

The bottom of the cylinder body 1 is connected with a discharge valve 15.

A second temperature sensor 16 for monitoring the temperature of cooling water in the cooling jacket 11 is arranged in the cooling jacket 11, and when the mashing is started, the seventh electromagnetic valve 10.7 and the eighth electromagnetic valve 10.8 are opened to cool the cylinder body 1 and ensure that the content to be mashed is mashed at a lower temperature. The temperature of the material in the mashing process is controlled by a first temperature sensor 14, and when the temperature is higher, the running rotating speed of the cooling water pump 12 is increased, so that the material cooling is accelerated. Meanwhile, a second temperature sensor 16 is arranged on the cooling jacket 11 and is used for measuring the temperature of cooling water in the cooling jacket 11, and when the temperature of the cooling water does not meet the requirement, the required temperature of the cooling water is directly set through a control panel, so that the refrigerating unit 13 is cooled, and cooling water with proper temperature is produced.

As shown in fig. 1, embodiment 1 is a small mashing device, the magnetic transmission mechanism 6 includes an outer magnetic rotor 61, an inner magnetic rotor 62 and a fixing rod 63, the fixing rod 63 is fixed on the bottom wall inside the cylinder 1 along the vertical direction, the inner magnetic rotor 62 is rotatably connected to the lower end of the fixing rod 63 through a bearing, the blade 4 is fixedly connected to the inner magnetic rotor 62 through a fixing column, and the outer magnetic rotor 61 is fixed on the output shaft of the motor 5 and is located right below the inner magnetic rotor 62.

The bottom of the cylinder body 1 is connected and fixed on the base 3 through a quick-release bolt, and the cylinder cover 2 is fixed on the top of the cylinder body 1 through a clamp spring.

The bottom of the respirator 8 is sequentially connected to the quick-release interface through a fifth electromagnetic valve 10.5 and a sixth electromagnetic valve 10.6, an injection water inlet pipe 17 is connected between the fifth electromagnetic valve 10.5 and the sixth electromagnetic valve 10.6, and a fourth electromagnetic valve 10.4 is connected to the injection water inlet pipe 17.

When the device is used, the cylinder cover 2 is opened firstly, the material to be mashed and the protective agent are placed, the motor 5 on the base 3 drives the outer magnetic rotor 61 to rotate, the outer magnetic rotor 61 drives the inner magnetic rotor 62 positioned in the cylinder body 1 through magnetic force, and then the blade 4 is driven to rotate, so that the purpose of mashing the material is achieved, in the process of mashing tissues, the first electromagnetic valve 10.1, the third electromagnetic valve 10.3, the fifth electromagnetic valve 10.5 and the sixth electromagnetic valve 10.6 are sequentially opened through the control panel, the interior of the cylinder body 1 is connected with the exterior through the respirator 8, and the air entering the interior of the cylinder body 1 after mashing is ensured to be sterile; after the tissue smashing is finished, the second electromagnetic valve 10.2, the third electromagnetic valve 10.3, the fifth electromagnetic valve 10.5 and the sixth electromagnetic valve 10.6 are opened through the control panel (the other electromagnetic valves are closed), and the discharging valve 15 is opened, so that the materials are discharged through the pressure of clean air. After the materials are discharged, the fourth electromagnetic valve 10.4, the fifth electromagnetic valve 10.5 and the sixth electromagnetic valve 10.6 are controlled to be opened through a panel, the water for injection is injected into the cylinder body 1 for cleaning, and the waste water is discharged through the discharging valve 15.

As shown in fig. 2, this embodiment 2 is a large mashing device, the open type separable internal and external magnetic transmission mechanism of embodiment 1 is transformed into an inseparable static seal magnetic transmission mechanism, thereby providing a higher rotation speed, so as to ensure effective mashing of more tissues, specifically, the magnetic transmission mechanism 6 includes an external magnetic rotor 61, an internal magnetic rotor 62, a transmission shaft 63 and an isolation sleeve 64, the isolation sleeve 64 is connected with the bottom of the cylinder body 1 into a whole, the external magnetic rotor 61 is fixed on the output shaft of the motor 5 and is sleeved around the outside of the isolation sleeve 64, the middle part of the transmission shaft 63 is connected to the bottom of the cylinder body 1 through a bearing rotating seal, so as to ensure that no leakage occurs during rotation, the blade 4 is fixed at the upper end of the transmission shaft 63, and the lower end of the transmission shaft 63 extends into the isolation sleeve 64 and is fixedly connected with the internal magnetic rotor 62.

The bottom of the respirator 8 is connected to the quick-release interface 7 through a fifth electromagnetic valve 10.5 and a sixth electromagnetic valve 10.6 in sequence, a cleaning ball 18 is arranged on the inner side of the cylinder cover 2, an inlet of the cleaning ball 18 is connected with an injection water inlet pipe 17, and a fourth electromagnetic valve 10.4 is connected to the injection water inlet pipe 17 and used for cleaning after tissue smashing is finished.

The cylinder cover 2 is locked and fixed on the cylinder body 1 through bolts, a sealing ring 27 is arranged between the cylinder cover 2 and the cylinder body 1, and a pressure gauge 19 used for monitoring the internal pressure of the cylinder body 1 is connected to the cylinder cover 2. The cylinder cover 2 is also connected with a feed inlet 20 which can be opened and closed and is used for throwing in tissues.

A high liquid level sensor 21, a middle liquid level sensor 22 and a low liquid level sensor 23 are sequentially arranged on the inner side wall of the cylinder body 1 from top to bottom; the cylinder cover 2 is connected with a liquid inlet pipe 24, the liquid inlet pipe 24 is connected with a ninth electromagnetic valve 10.9, the rear end of the ninth electromagnetic valve 10.9 is respectively connected with a protective agent inlet pipe 25 and a pure steam inlet pipe 26, the protective agent inlet pipe 25 is connected with a tenth electromagnetic valve 10.10, and the pure steam inlet pipe 26 is connected with an eleventh electromagnetic valve 10.11. And selecting the corresponding liquid level sensor to work through the control panel according to the feeding amount of each time. The three liquid level sensors can sense the liquid level heights of different protective agents added in different feeding amounts, wherein the high liquid level sensor 21 is arranged at the upper part of the cylinder body 1 and is used for sensing the highest allowable liquid level of the added protective agents, and as long as the liquid level is sensed, the tenth electromagnetic valve 10.10 on the protective agent inlet pipe 25 must be closed and is not influenced by selecting a certain liquid level sensor to work.

When in use, the tissue is firstly put into the feed inlet 20, and a proper amount of protective agent is added; when the motor 5 on the base 3 drives the outer magnetic rotor 61 to rotate, the outer magnetic rotor 61 drives the inner magnetic rotor 62 positioned in the isolation sleeve 64 to rotate through magnetic force, and further drives the blade 4 to rotate, so that the purpose of mashing materials is achieved, in the process of mashing tissues, the first electromagnetic valve 10.1, the third electromagnetic valve 10.3, the fifth electromagnetic valve 10.5 and the sixth electromagnetic valve 10.6 are sequentially opened through the control panel, the inside of the cylinder body 1 is connected with the outside through the respirator 8, and the air entering the inside of the cylinder body 1 after mashing is started is ensured to be sterile; after the tissue smashing is finished, the second electromagnetic valve 10.2, the third electromagnetic valve 10.3, the fifth electromagnetic valve 10.5 and the sixth electromagnetic valve 10.6 are opened through the control panel (the other electromagnetic valves are closed), and the discharging valve 15 is opened, so that the materials are discharged through the pressure of clean air. After the materials are discharged, the fourth electromagnetic valve 10.4 is opened through panel control, injection water is injected into the cylinder body 1 for cleaning, and waste water is discharged through the discharge valve 15; after the drainage is abandoned, pure steam is introduced into the cylinder body 1 for sterilization, the first temperature sensor 14 is used for indicating the temperature of sterilization, and the pressure gauge 19 is used for indicating the internal pressure during sterilization.

The practice of the present invention has been described with reference to the accompanying drawings, but the invention is not limited to the embodiments described above, which are illustrative rather than limiting, and it will 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.

Claims (10)

1. The utility model provides a magnetic drive's tissue triturates equipment to pieces, includes cylinder body, cylinder cap and base, the cylinder body is fixed on the base, and the cylinder cap can be dismantled the top of connection at the cylinder body, and the rotation is connected with the blade in the cylinder body, be equipped with motor, its characterized in that on the base: the motor drives the blade to rotate through the magnetic transmission mechanism, the cylinder cover is connected with a quick-release interface, the quick-release interface is connected with a respirator, the top of the respirator is connected with a T-shaped clean air pipeline, and three branch pipes of the T-shaped clean air pipeline are respectively connected with a first electromagnetic valve, a second electromagnetic valve and a third electromagnetic valve; the cooling jacket is sleeved outside the cylinder body and connected with a cooling water inlet pipe and a cooling water outlet pipe, the cooling water inlet pipe is sequentially connected to the seventh electromagnetic valve, the cooling water pump and the refrigerating unit, and the cooling water outlet pipe is connected with the eighth electromagnetic valve; be equipped with the first temperature sensor who is used for monitoring its inside temperature on the lateral wall of cylinder body.

2. A magnetically driven tissue mashing apparatus according to claim 1, characterized in that: the bottom of the cylinder body is connected with a discharge valve.

3. A magnetically driven tissue mashing apparatus according to claim 1, characterized in that: and a second temperature sensor for monitoring the temperature of cooling water in the cooling jacket is arranged in the cooling jacket.

4. A magnetically driven tissue mashing apparatus according to claim 1, characterized in that: the magnetic transmission mechanism comprises an outer magnetic rotor, an inner magnetic rotor and a fixed rod, the fixed rod is fixed on the bottom wall of the interior of the cylinder body in the vertical direction, the inner magnetic rotor is rotatably connected to the lower end of the fixed rod through a bearing, the blades are fixedly connected to the inner magnetic rotor through the fixed rod, and the outer magnetic rotor is fixed on an output shaft of the motor and located right below the inner magnetic rotor.

5. A magnetically-actuated tissue mashing apparatus according to claim 4, characterized in that: the bottom of the cylinder body is connected and fixed on the base through a quick-release bolt, and the cylinder cover is fixed on the top of the cylinder body through a clamp spring.

6. A magnetically-actuated tissue mashing apparatus according to claim 4, characterized in that: the bottom of the respirator is sequentially connected to the quick-release interface through a fifth electromagnetic valve and a sixth electromagnetic valve, an injection water inlet pipe is connected between the fifth electromagnetic valve and the sixth electromagnetic valve, and a fourth electromagnetic valve is connected to the injection water inlet pipe.

7. A magnetically driven tissue mashing apparatus according to claim 1, characterized in that: the magnetic transmission mechanism comprises an outer magnetic rotor, an inner magnetic rotor, a transmission shaft and an isolation sleeve, the isolation sleeve is connected with the bottom of the cylinder body into a whole, the outer magnetic rotor is fixed on an output shaft of the motor and is sleeved on the outer side of the isolation sleeve in a surrounding mode, the middle of the transmission shaft is connected to the bottom of the cylinder body in a rotating and sealing mode through a bearing, the blade is fixed at the upper end of the transmission shaft, and the lower end of the transmission shaft extends into the isolation sleeve and is fixedly connected with the inner magnetic rotor.

8. A magnetically-actuated tissue mashing apparatus according to claim 7, characterized in that: the bottom of the respirator is connected to the quick-release interface through a fifth electromagnetic valve and a sixth electromagnetic valve in sequence, a cleaning ball is arranged on the inner side of the cylinder cover, an inlet of the cleaning ball is connected with an injection water inlet pipe, and a fourth electromagnetic valve is connected to the injection water inlet pipe.

9. A magnetically-actuated tissue mashing apparatus according to claim 7, characterized in that: the cylinder cap passes through bolt locking to be fixed on the cylinder body, and is equipped with the sealing washer between cylinder cap and the cylinder body, be connected with the manometer that is used for monitoring cylinder body internal pressure size on the cylinder cap, still be connected with the feed inlet that can open and close on the cylinder cap.

10. A magnetically-actuated tissue mashing apparatus according to claim 7, characterized in that: a high liquid level sensor, a medium liquid level sensor and a low liquid level sensor are sequentially arranged on the inner side wall of the cylinder body from top to bottom; the device is characterized in that a liquid inlet pipe is connected onto the cylinder cover, a ninth electromagnetic valve is connected onto the liquid inlet pipe, the rear end of the ninth electromagnetic valve is respectively connected with a protective agent liquid inlet pipe and a pure steam inlet pipe, a tenth electromagnetic valve is connected onto the protective agent liquid inlet pipe, and an eleventh electromagnetic valve is connected onto the pure steam inlet pipe.

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