CN216856411U - Medicine homogenizer with heat preservation mechanism - Google Patents

Abstract

The application relates to the technical field of production equipment, in particular to a medicine homogenizer with heat preservation mechanism. The utility model provides a medicine isotropic symmetry with heat preservation mechanism is fixed with a jar body on including supporting seat, and the cover is installed in supporting on jar body, has seted up the feed inlet on the cover, has seted up the discharge gate on the jar body, still includes rabbling mechanism and temperature control mechanism on the isotropic symmetry, and temperature control mechanism includes monitoring subassembly and temperature adjustment subassembly, the monitoring subassembly with be the electricity between the temperature adjustment subassembly. This application can carry out real-time supervision through monitoring subassembly to the internal temperature of jar, then when the internal temperature of jar is less than or is higher than the setting value, and temperature adjustment subassembly is given to monitoring subassembly transfer signal, and the temperature adjustment subassembly carries out constant temperature regulation and control to the internal temperature of jar.

Description

Medicine homogenizer with heat preservation mechanism

Technical Field

The application relates to the technical field of production equipment, in particular to a medicine homogenizer with heat preservation mechanism.

Background

Homogenizers are mainly used for tissue dispersion in the biotechnology field, sample preparation in the pharmaceutical field, enzyme treatment in the food industry, detection of pesticide residues and veterinary drug residues in food, and in the pharmaceutical industry, the cosmetic industry, the paint industry, the petrochemical industry and the like.

The main materials and the auxiliary materials are required to be placed in a homogenizer for mixing in advance before production of medicines and the like, so that the raw materials are more uniform in the later mixing process.

The inventor finds that the homogenization process can be stably carried out only when the medicine with relatively sensitive temperature is kept at a constant temperature, and the quality of the medicine is improved.

SUMMERY OF THE UTILITY MODEL

In order to improve only when keeping constant temperature to the more sensitive medicine of temperature, the homogeneity process can just stably go on to improve the problem of the quality of medicine, this application provides a medicine isotropic symmetry with heat preservation mechanism.

The application provides a medicine isotropic symmetry with heat preservation mechanism adopts following technical scheme: the utility model provides a medicine isotropic symmetry with heat preservation mechanism, includes the supporting seat, installs the jar body on the supporting seat and covers the cover that closes on the jar body, the feed inlet has been seted up on the cover, the discharge gate has been seted up on the jar body, still including rabbling mechanism and temperature control mechanism on the isotropic symmetry, temperature control mechanism is including monitoring subassembly and temperature adjustment subassembly, the monitoring subassembly with be the electricity between the temperature adjustment subassembly and be connected, the temperature adjustment subassembly can be right the internal temperature of jar carries out constant temperature regulation and control.

Through adopting above-mentioned technical scheme, close the cover lid on jar body, it is internal that raw materials and the auxiliary material that will prepare the medicine drop into jar from the feed inlet, mix the material through rabbling mechanism, monitor the internal temperature of jar through the monitoring subassembly in the temperature control mechanism. When monitoring that the temperature rises or reduces, the monitoring subassembly sends the signal of telecommunication to temperature adjustment subassembly, and the temperature adjustment subassembly makes the internal temperature of jar invariable after adjusting and control the internal temperature of jar, and then makes the homogeneity process in the body go on steadily, can effectively improve the quality of medicine.

Optionally, an air cylinder and a telescopic rod are vertically arranged on the supporting seat, one end of the air cylinder and one end of the telescopic rod are connected with the supporting seat, the other end of the air cylinder and the other end of the telescopic rod are connected with a fixed block, and an accommodating cavity is formed in the fixed block; the stirring mechanism is installed including rotating (mixing) shaft on the cover, the (mixing) shaft wears to establish vertically behind the cover wears to establish on the fixed block, install driving motor on the fixed block, driving motor's motor shaft with the (mixing) shaft is in hold intracavity transmission and connect.

Through adopting above-mentioned technical scheme, after starting driving motor, driving motor makes the (mixing) shaft rotate through the transmission, and then can stir the internal material of jar. The fixed block is moved away from or close to the tank body by the cylinder and the telescopic rod, so that the tank cover is opened or closed on the tank body.

Optionally, the stirring shaft is connected with a stirring paddle, the stirring shaft and the stirring paddle are both arranged in a hollow manner, and the spaces in the stirring shaft and the stirring paddle are communicated with each other; the temperature adjustment subassembly includes the (mixing) shaft wears to establish the locating piece of installation on the one end tip of fixed block, be provided with connecting pipe and drain pipe on the locating piece, the connecting pipe links to each other with the water system, drain pipe and drainage system link to each other, install control flap on the connecting pipe, control flap with the monitoring subassembly electricity is connected.

By adopting the technical scheme, the stirring paddle and the stirring shaft are arranged in a hollow and communicated manner, the stirring paddle and the stirring shaft are blocked by the positioning block, then the positioning block is provided with the connecting pipe and the drain pipe, and when the monitoring component monitors that the temperature in the tank body is reduced to a set value, the connecting pipe is kept closed; when the monitoring subassembly monitors the internal temperature of jar when the setting value, the connecting pipe keeps the intercommunication, to stirring rake and the inside intaking of (mixing) shaft to lower the temperature to the material around stirring rake and the (mixing) shaft, and then finely tune the internal temperature of jar, thereby keep the internal temperature constancy of jar.

Optionally, the positioning block is rotatably mounted on the stirring shaft by using a mechanical seal assembly.

Through adopting above-mentioned technical scheme, the setting up of mechanical seal subassembly makes the (mixing) shaft keep stable at pivoted in-process locating piece, connecting pipe and the drain pipe of connection on the locating piece.

Optionally, an insulation board is hermetically mounted on the outer side of the side wall of the tank body, the insulation board and the outer wall of the tank body form a sealed annular transmission cavity, a water delivery port and a water delivery port are formed in the two opposite ends of the insulation board, the water delivery port supplies water to the transmission cavity, and the water delivery port guides out water in the transmission cavity.

By adopting the technical scheme, the transmission cavity keeps the temperature stable state in the tank body through heat exchange by the water body flowing of the water conveying port and the water conveying port.

Optionally, a cold water pipeline and a hot water pipeline are wound in the transmission cavity in a staggered threaded manner, a control switch electrically connected with the monitoring assembly is arranged at the water inlet end of the cold water pipeline and the water inlet end of the hot water pipeline, the cold water pipeline and the hot water pipeline are connected with corresponding cold and hot water systems, and the water outlet end of the cold water pipeline and the water outlet end of the hot water pipeline are connected with surrounding drainage systems.

By adopting the technical scheme, when the monitoring component monitors that the temperature in the tank body is lower than a set value, the water amount of the hot water pipeline is increased, the water amount of the cold water pipeline is decreased, heat exchange is carried out on the water body in the transmission cavity, and then the water in the transmission cavity exchanges heat with the materials in the tank body; when the monitoring assembly monitors that the temperature in the tank body is at a set value, the water amount of the hot water pipeline is reduced, the water amount of the cold water pipeline is increased, heat exchange is carried out on the water body in the transmission cavity, and then the water in the transmission cavity carries out heat exchange with materials in the tank body. Therefore, the temperature in the tank body can be adjusted to be kept constant, the damage of temperature shock to the material quality in the tank body can be reduced through twice heat exchange, and the stability of homogenization treatment is improved.

Optionally, the tank body is provided with a locking member, and the locking member connects the tank cover with the tank body.

Through adopting above-mentioned technical scheme, establish the tight lid of cover on the jar body through the retaining member to can guarantee the leakproofness of the jar body.

Optionally, stirring blades are arranged on the stirring paddle at intervals.

Through adopting above-mentioned technical scheme, increase the area of contact of rabbling mechanism and material through stirring fan blade to improve the efficiency of homogeneity processing.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the monitoring assembly monitors the temperature in the tank body in real time, when the monitoring assembly monitors that the temperature in the tank body is lower than or higher than a set value, the monitoring assembly transmits an electric signal to the temperature adjusting assembly, and the temperature adjusting assembly adjusts the temperature in the tank body to the set value, so that the tank body is kept in a constant temperature state.

2. The cold water pipeline or the hot water pipeline exchanges heat with the water body in the transmission cavity, and then the water body in the transmission cavity exchanges heat with the materials in the tank body, so that the temperature in the tank body is adjusted to be kept in a constant temperature state.

Drawings

Fig. 1 is a schematic overall structure diagram of a medicine homogenizer with a heat preservation mechanism according to an embodiment of the present application.

Fig. 2 is a partial cross-sectional view of a medicine homogenizer with a temperature maintenance mechanism according to an embodiment of the present application.

Fig. 3 is a partially enlarged schematic view at a in fig. 2.

Fig. 4 is a partially enlarged schematic view at B in fig. 2.

Description of reference numerals:

1. a supporting seat; 2. a tank body; 21. a discharge port; 22. a suction pump; 23. a locking member; 3. a can lid; 31. a feed inlet; 32. a viewing port; 33. a pressure mechanism; 34. a stirring mechanism; 341. a stirring shaft; 342. a stirring paddle; 343. a stirring fan blade; 346. a connecting pipe; 347. a drain pipe; 348. a control valve; 35. a mechanical seal assembly; 351. positioning blocks; 4. a control box; 5. a cylinder; 51. a telescopic rod; 52. a fixed block; 521. an accommodating chamber; 522. a drive motor; 523. a synchronous belt; 61. a monitoring component; 621. a thermal insulation board; 622. a transmission cavity; 623. a cold water pipe; 624. a hot water pipe; 625. and controlling the switch.

Detailed Description

The present application is described in further detail below with reference to the attached drawings.

The embodiment of the application discloses medicine isotropic symmetry with heat preservation mechanism.

As shown in fig. 1 and 2, a medicine homogenizer with a heat preservation mechanism comprises a supporting base 1, a tank body 2, a tank cover 3, a pressure mechanism 33, a stirring mechanism 34 and a temperature control mechanism, wherein the tank body 2 is arranged on the supporting base 1, main materials and auxiliary materials of medicines to be stirred are placed in the tank body 2, and then the tank cover 3 is covered on the tank body 2. Meanwhile, the supporting seat 1 is provided with a control box 4, and the control box 4 can control the movement of each part on the homogenizer. The pressure mechanism 33 controls the pressure in the tank body 2, the stirring mechanism 34 fully stirs the main material and the auxiliary material, and the temperature control mechanism is utilized to control the temperature in the tank body 2 in a constant temperature state in the stirring process, so that the temperature requirement of material uniform mixing is met, and the homogeneity degree of the material in the tank body 2 is improved.

Be provided with retaining member 23 on jar body 2, through with retaining member 23 joint on cover 3, improve the leakproofness and the stability in use of jar body 2 and cover 3. A feed port 31, an observation port 32 and a ventilation port are arranged on the tank cover 3 in a staggered manner, the main material and the auxiliary material are poured in through the feed port 31, the homogenization condition of the main material and the auxiliary material in the tank body 2 can be observed through the observation port 32, and then the main material and the auxiliary material are fully mixed; the pressure mechanism 33 is installed at the vent hole, and oxygen-enriched air is supplied into the tank 2 or gas such as carbon dioxide generated during the stirring of the main material and the auxiliary material is pumped out by the pressure mechanism 33, thereby adjusting the pressure in the tank 2.

The bottom of keeping away from cover 3 at jar body 2 is provided with discharge gate 21, is connected with on the discharge gate 21 and inhales the material pump 22, starts to inhale the material pump 22 after with the material intensive mixing in the pipe body, inhales the material pump 22 and derives the material in jar body 2 from discharge gate 21, is convenient for carry on production flow on next step.

The stirring mechanism 34 includes a tubular stirring shaft 341 rotatably connected to the tank cover 3, the stirring shaft 341 is disposed at the center of the tank cover 3, stirring paddles 342 having a rectangular frame structure are formed at both ends of the stirring shaft 341 in an extending manner, the stirring paddles 342 are also disposed in a hollow tubular shape, and spaces in the stirring shaft 341 and the stirring paddles 342 are communicated with each other. A plurality of stirring fan blades 343 are installed at the interval on stirring rake 342, and (mixing) shaft 341 rotates, drives stirring rake 342 and rotates the material to jar body 2 in and carry out the application of force stirring, and stirring fan blade 343's setting has effectively increased the area of contact of stirring rake 342 with the material, and is more abundant to the stirring of material.

The cylinder 5 is vertically installed in one side that the jar body 2 was kept away from to supporting seat 1, and the stiff end of cylinder 5 is fixed on supporting seat 1, installs fixed block 52 at the free end of cylinder 5, installs telescopic link 51 between supporting seat 1 and the fixed block 52, and telescopic link 51 can increase the stability in use of fixed block 52. One end of the fixing rod is rotatably connected with the tank cover 3, and the cylinder 5 is started to drive the tank cover 3 to be far away from the tank body 2 by the fixing block 52.

The inside chamber 521 that holds of having seted up of fixed block 52, the one end of keeping away from cover 3 at fixed block 52 is connected with driving motor 522, and in the chamber 521 that holds in fixed block 52 was all worn to establish by driving motor 522's motor shaft and (mixing) shaft 341, motor shaft and (mixing) shaft 341 passed through hold-in range 523 and carry out the transmission and connect. The motor shaft on the driving motor 522 rotates, and the stirring shaft 341 rotates through the transmission of the synchronous belt 523, so that the stirring paddle 342 is driven to rotate, and the material can be homogenized through rotation.

The temperature control mechanism comprises a monitoring component 61 and a temperature adjusting component, and the monitoring component 61 and the temperature adjusting component are electrically connected. The monitoring component 61 is arranged on the tank cover 3 and used for monitoring the temperature in the tank body 2, when the temperature is higher than a set value or lower than the set value, the monitoring component 61 transmits a signal to the temperature adjusting component, and the temperature adjusting component carries out cooling or heating treatment in time, so that the material in the tank body 2 is kept in a constant temperature state.

The temperature adjustment subassembly sets up on rabbling mechanism 34 and outside jar body 2, and the one end that agitator shaft 341 wore out cover 3 upwards extends to vertically wearing out fixed block 52, wears out fixed block 52 at agitator shaft 341's one end and installs locating piece 351, and fixed block 52 carries out the shutoff with the tip of agitator shaft 341. As shown in fig. 3, two through holes are vertically formed in the fixed block 52, a connection pipe 346 having a control valve 348 is inserted into one through hole, and a drain pipe 347 having a control valve 348 is inserted into the other through hole. The connecting pipe 346 is communicated with a nearby water using system, the drain pipe 347 is communicated with a surrounding drainage system, when the monitoring assembly 61 monitors that the temperature in the tank body 2 is higher than a set value, a signal is sent to the control valve 348 of the connecting pipe 346, the control valve 348 is opened, water in the water inlet system flows along the stirring shaft 341 and the stirring paddle 342, heat exchange is carried out between the water and surrounding materials, and then the water flows out of the drain pipe 347 to the surrounding drainage system, so that the materials can be effectively cooled. When the monitoring component 61 detects that the temperature in the tank 2 is lower than the set value, the monitoring component 61 transmits a signal to the control valve 348, water does not enter the connecting pipe 346 any more, the temperature of the material cannot be further reduced, and the stirring paddle 342 and the stirring fan 343 generate heat by friction in the process of stirring the material to adjust the temperature of the material.

The mechanical seal assembly 35 is installed at one end of the stirring shaft 341 far away from the tank cover 3, and the positioning block 351 is installed on the mechanical seal assembly 35, so that the influence of the stirring shaft 341 on the positioning block 351, the connecting pipe 346 and the drain pipe 347 during rotation is reduced.

2 overcoat of the jar body is equipped with an annular heated board 621, and heated board 621's both ends and jar 2 outer walls of body are connected for heated board 621 and jar 2 outer walls enclose and establish into inclosed annular transmission chamber 622, have seted up the water transmission mouth of a river and have sent the mouth of a river at heated board 621 relative both ends, give water in to transmission chamber 622 through the water transmission mouth of a river, and the rivers ability in the transmission chamber 622 flows along sending the mouth of a river, thereby can change the water in the transmission chamber 622.

Misplace the spiral winding in transmission chamber 622 and have cold water pipeline 623 and hot water pipeline 624, seted up two via holes on insulation board 621's lateral wall, every via hole all extends to the position of keeping away from insulation board 621 and forms tubular structure, and tubular structure keeps away from the tip of insulation board 621 and all is provided with the shutoff piece, improves transmission chamber 622's leakproofness. As shown in fig. 4, two abdicating holes are formed on each blocking block, the ends of the cold water pipe 623 and the hot water pipe 624, which are located at the same end, penetrate out of the abdicating holes at the corresponding positions, a control switch 625 is arranged at the position penetrating out of the abdicating holes, the water inlet ends of the cold water pipe 623 and the hot water pipe 624 are adjacent to corresponding cold and hot water systems, and the water outlet ends of the cold water pipe 623 and the hot water pipe 624 are connected to the surrounding drainage systems.

Meanwhile, the control switch 625 at the water inlet end of the cold water pipeline 623 and the hot water pipeline 624 is electrically connected with the monitoring component 61, when the monitoring component 61 finds that the temperature in the tank body 2 is lower than a set value, the monitoring component 61 gives a signal, so that the water inlet amount in the cold water pipeline 623 is reduced, the water inlet amount in the hot water pipeline 624 is increased, the hot water pipeline 624 and the water body in the transmission cavity 622 perform heat exchange, and the water body in the transmission cavity 622 performs heat exchange with the material after the temperature of the water body is increased. When the monitoring assembly 61 monitors that the temperature of the material is higher than the set value, the water inflow in the hot water pipeline 624 is reduced, the water inflow in the cold water pipeline 623 is increased, and the heat exchange enables the temperature of the liquid in the transmission cavity 622 to be reduced and then the material is cooled. The temperature of the material is increased or decreased after the two heat exchanges, the influence of the rapid temperature decrease or increase on the material is reduced, and the stability of the material homogenization process is improved, so that the quality of the medicine raw material in the subsequent production and manufacturing is ensured.

In the in-process of using, connect jar lid 3 and jar body 2 with retaining member 23, then leading-in main material and auxiliary material from feed inlet 31, then utilize the pressure in the pressure mechanism 33 control jar body 2, monitoring subassembly 61 monitors the temperature in jar body 2, utilize the temperature adjustment subassembly to adjust the temperature in jar body 2 for the temperature in jar body 2 keeps invariable, guarantees that the relatively poor medicine of thermal stability can remain stable in the homogeneity in-process, the quality of body height medicine.

The present embodiment is only for explaining the present application, and it is not limited to the present application, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present application.

Claims (7)

1. The utility model provides a medicine isotropic symmetry with heat preservation mechanism, includes supporting seat (1), installs jar body (2) on supporting seat (1) and lid and closes cover (3) on jar body (2), its characterized in that: the tank cover (3) is provided with a feeding hole (31), the tank body (2) is provided with a discharging hole (21), the homogenizer also comprises a stirring mechanism (34) and a temperature control mechanism, the temperature control mechanism comprises a monitoring component (61) and a temperature adjusting component, the monitoring component (61) is electrically connected with the temperature adjusting component, and the temperature adjusting component can regulate and control the temperature in the tank body (2) at a constant temperature; an air cylinder (5) and an expansion rod (51) are vertically arranged on the supporting seat (1), one end of the air cylinder (5) and one end of the expansion rod (51) are connected with the supporting seat (1), the other end of the air cylinder (5) and the other end of the expansion rod (51) are connected with a fixing block (52), and an accommodating cavity (521) is formed in the fixing block (52); the stirring mechanism (34) comprises a stirring shaft (341) rotatably mounted on the tank cover (3), the stirring shaft (341) penetrates through the tank cover (3) and then vertically penetrates through a fixing block (52), a driving motor (522) is mounted on the fixing block (52), and a motor shaft of the driving motor (522) is in transmission connection with the stirring shaft (341) in the accommodating cavity (521).

2. The medicine homogenizer with a heat preservation mechanism of claim 1, wherein: the stirring shaft (341) is connected with a stirring paddle (342), the stirring shaft (341) and the stirring paddle (342) are both arranged in a hollow manner, and the spaces in the stirring shaft (341) and the stirring paddle (342) are communicated with each other; the temperature adjusting assembly comprises a positioning block (351) arranged at one end part of the stirring shaft (341) penetrating through the fixing block (52), a connecting pipe (346) and a drain pipe (347) are arranged on the positioning block (351), the connecting pipe (346) is connected with a water using system, the drain pipe (347) is connected with a drainage system, a control valve (348) is arranged on the connecting pipe (346), and the control valve (348) is electrically connected with the monitoring assembly (61).

3. The medicine homogenizer with a heat preservation mechanism of claim 2, wherein: the positioning block (351) is rotatably arranged on the stirring shaft (341) by adopting a mechanical seal assembly (35).

4. The medicine homogenizer with a heat preservation mechanism of claim 1, wherein: the outside seal of jar body (2) lateral wall installs heated board (621), heated board (621) with jar body (2) outer wall forms sealed cyclic annular transmission chamber (622), heated board (621) relative both ends seted up with the water delivery mouth and send the mouth of a river, the water delivery mouth is right transmission chamber (622) feed water, send the mouth of a river will water in transmission chamber (622) is derived.

5. The medicine homogenizer with a heat preservation mechanism of claim 4, wherein: the transmission chamber (622) is internally wound with a cold water pipeline (623) and a hot water pipeline (624) in a staggered threaded manner, the water inlet ends of the cold water pipeline (623) and the hot water pipeline (624) are provided with a control switch (625) electrically connected with the monitoring component (61), the cold water pipeline (623) and the hot water pipeline (624) are connected with a corresponding cold and hot water system, and the water outlet ends of the cold water pipeline (623) and the hot water pipeline (624) are connected with a surrounding drainage system.

6. The medicine homogenizer with a heat preservation mechanism of claim 1, wherein: install retaining member (23) on the jar body (2), retaining member (23) will cover (3) with the jar body (2) are connected.

7. The medicine homogenizer with a heat preservation mechanism of claim 2, wherein: stirring blades (343) are arranged on the stirring paddle (342) at intervals.

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