CN218741557U - Material cup device for cooling and vacuum and homogenizer adopting same - Google Patents

Abstract

The utility model provides a material cup device for cooling and vacuum and a homogenizer adopting the device, wherein, the material cup device comprises an inner cup body, an outer cup body and a rotating cup cover; the outer cup body is sleeved outside the inner cup body, the rotary cup cover can be detachably covered at the cup opening at the top of the outer cup body and can seal the cup opening of the inner cup body, a through hole is formed in the rotary cup cover, and a rotary joint connected with an external vacuum device is rotatably arranged at the through hole; the upper part of the outer cup body is in sealed fit connection with the upper part of the inner cup body, the lower part of the outer cup body and the lower part of the inner cup body are arranged at intervals and form a cooling chamber, a rotating shaft is arranged at the bottom of the outer cup body, a cavity is arranged in the middle of the rotating shaft, and the cavity is communicated with the cooling chamber; the bottom of the rotating shaft is rotatably connected with a rotating air shaft connected with external cooling equipment. Based on above-mentioned material cup device design isotropic symmetry, can realize carrying out evacuation processing to material cup inside, also can cool off the material cup outside simultaneously, guarantee that cooling and evacuation go on in step, each other does not influence.

Description

Material cup device for cooling and vacuum and homogenizer adopting same

Technical Field

The utility model relates to a stirring deaeration equipment technical field, in particular to be used for cooling and vacuum material cup device and adopt device's isotropic symmetry.

Background

The homogenizer is widely applied to stirring and defoaming of paint, printing ink, color paste, pigment, electronic materials, chocolate paste, biological medicine cosmetics, nano materials and the like, and in the stirring and defoaming process, partial heat is transferred into the materials through the inside of the rotating body, so that the temperature of the materials is overhigh, and the stirring effect is influenced. At present, the isotropic symmetry is in order to obtain better stirring effect, corresponding cooling structure has been set up and has come auxiliary cooling, the deaeration isotropic symmetry of existing area cooling function on the existing market, mainly be the rotatory seal cavity of the direct UNICOM of cooling gas, cool off whole cavity, it is big to need refrigerated space, this just leads to needing a large amount of cooling gas, and this kind of cooling method is relatively poor to the cooling effect of material, can't directly cool down to the revolving cup is inside, and can't compatible vacuum operation simultaneously, the limitation is great.

SUMMERY OF THE UTILITY MODEL

In view of the above, there is a need to provide a material cup device for cooling and vacuum and a homogenizer using the same, so as to implement vacuum-pumping treatment on the inside of the material cup, and simultaneously cool the outside of the material cup, thereby ensuring that cooling and vacuum-pumping are performed synchronously without mutual influence.

In order to achieve the above purpose, the utility model adopts the technical proposal that:

a material cup device for cooling and vacuum comprises an inner cup body, an outer cup body, a cup rotating cover, a rotating joint, a rotating shaft and a rotating air shaft; the outer cup body is sleeved outside the inner cup body, the rotary cup cover can be detachably covered on the cup opening at the top of the outer cup body, the cup opening of the inner cup body is sealed when the rotary cup cover is covered on the outer cup body, a through hole is formed in the rotary cup cover and is communicated with the inner part of the inner cup body, a rotary joint used for being connected with an external vacuum device is rotatably installed at the through hole, and the rotary joint is located on the outer side of the inner cup body and is communicated with the inner part of the inner cup body through the through hole; the upper part of the outer cup body is in sealed fit connection with the upper part of the inner cup body, the lower part of the outer cup body and the lower part of the inner cup body are arranged at intervals to form a cooling chamber, a rotating shaft is arranged at the bottom of the outer cup body, a cavity is formed in the middle of the rotating shaft, and the cavity is communicated with the cooling chamber; the bottom of rotation axis is rotated and is connected with the rotatory air shaft that is used for being connected with external cooling equipment, rotatory air shaft and cavity intercommunication.

Preferably, the outer cup and the rotor cover are detachably connected through a buckle.

Preferably, the inner cup body is connected with the rotary cup cover in a sealing mode through a sealing ring.

Preferably, the rotation center lines of the rotary joint, the inner cup body, the rotary shaft and the rotary air shaft are coincident.

Further, based on the material cup device, the utility model also provides a homogenizer, which comprises a horizontal support mechanism, the material cup device, a cooling device and a vacuum device; the transverse support mechanism is provided with at least one material cup device, the transverse support mechanism is provided with a cooling channel, one end of the cooling channel is communicated with cooling equipment, and the other end of the cooling channel is communicated with a rotary air shaft of the material cup device; and a rotary joint of the material cup device is connected with a vacuum device.

Further preferably, the utility model discloses an isotropic symmetry still includes the shell, the shell has the chamber of accomodating, accomodate horizontal supporting mechanism of intracavity installation and expect the cup device.

Further preferably, a safety door and a rotary connecting joint are arranged at the top of the containing cavity; the safety door is connected to the shell and used for opening and closing the containing cavity; the rotary connecting joint is rotatably installed on the shell and is positioned in a closed space formed by the safety door and the shell when the safety door covers the containing cavity, the rotary joint of the material cup device is connected with the vacuum device through the rotary connecting joint, and the rotary connecting joint is connected with the vacuum device through air pipes.

Further preferably, the cooling channel is communicated with a cooling device through a first cooling joint, and the first cooling joint is rotatably mounted on the transverse support mechanism.

Further preferably, the cooling channel is communicated with a rotary air shaft of the material cup device through a second cooling connector, and the second cooling connector is rotatably installed on the transverse support.

Further preferably, the cooling channel comprises a main shaft air cavity and a support air cavity, the main shaft air cavity is positioned on the revolution main shaft of the cross support mechanism, and the support air cavity is positioned on the cross support of the cross support mechanism; one end of the main shaft air cavity is communicated with the cooling equipment, the other end of the main shaft air cavity is communicated with one end of the support air cavity, and the other end of the support air cavity is communicated with a rotary air shaft of the material cup device through an air pipe.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. the utility model discloses a material cup device makes the cooling gas get into inside the material cup through the cooling cavity that interior cup and outer cup formed, and the cooling gas that gets into can enough be directly to the material cooling, can keep apart the interference of outside heat to the material again, and directly cools off the inside mode of material cup, does not need a large amount of cooling gas to cool down, and this has reduced the energy resource consumption of cooling gas to a certain extent.

2. The utility model discloses a top including cup and outer cup sets up the revolving cup lid, and the revolving cup is covered and is set up rotary joint in order to be connected with vacuum apparatus to make vacuum apparatus can carry out evacuation processing to the interior cup of material cup device, the setting of cooling chamber in addition, make the utility model discloses a material cup device can also can be to the processing of cooling down of material cup inside material evacuation, and the efficiency of evacuation and cooling is higher, and the effect is better.

3. The utility model discloses an isotropic symmetry adopts foretell material cup device, can be so that isotropic symmetry can carry out evacuation and cooling's operation simultaneously stirring deaeration process, and evacuation and cooling's operation each other do not influence, and stirring effect is good.

Drawings

FIG. 1 is a schematic view of a cup holder according to the present invention;

fig. 2 is a schematic view of the homogenizer of the present invention;

FIG. 3 is a schematic view of a cup apparatus applied to a homogenizer;

FIG. 4 is a schematic view of the cup assembly mounted on the cross-support mechanism showing the piping layout of the vacuum system;

FIG. 5 is an internal schematic view of the cooling system shown in section in FIG. 2, showing the piping layout of the cooling system.

Description of the main elements

In the figure: the cup comprises an inner cup body 1, an outer cup body 2, a cooling chamber 3, a rotating shaft 4, a cavity 5, a rotating air shaft 6, a first bearing 7, a buckle 8, a rotating joint 9, a rotating cup cover 10, a sealing ring 11, a transverse support 12, a support plate 13, a spindle seat 14, a revolving spindle 15, a motor 16, a second cooling joint 17, a first cooling joint 18, cooling equipment 19, a vacuum device 20, a rotating connecting joint 21, a support frame 22, a shell 23, a safety door 24, a storage cavity 25, a rotating cavity 26, a control screen 27, a start-stop switch 28, an emergency-stop switch 29, a damping fixed block 30, a rack 31, a support foot 32, an air pipe 33, a gear 34 and a second bearing 35.

The following detailed description of the invention will be further described in conjunction with the above-identified drawings.

Detailed Description

Example 1

Referring to fig. 1, in a first embodiment of the present invention, a material cup device for cooling and vacuum includes an inner cup body 1, an outer cup body 2, a cup rotating cover 10, a rotary joint 9, a rotary shaft 4, and a rotary air shaft 6. The outer cup body 2 is sleeved outside the inner cup body 1, the rotary cup cover 10 is detachably covered at the cup opening at the top of the outer cup body 2, the rotary cup cover 10 is covered on the outer cup body 2 to seal the cup opening of the inner cup body 1, a through opening is formed in the rotary cup cover 10 and is communicated with the inner part of the inner cup body 1, a rotary joint 9 used for being connected with an external vacuum device 20 is rotatably installed at the through opening, and the rotary joint 9 is located on the outer side of the inner cup body 1 and is communicated with the inner part of the inner cup body 1 through the through opening; the upper part of the outer cup body 2 is in sealed fit connection with the upper part of the inner cup body 1, the lower part of the outer cup body 2 and the lower part of the inner cup body 1 are arranged at intervals to form a cooling chamber 3, a rotating shaft 4 is installed at the bottom of the outer cup body 2, a cavity 5 is formed in the middle of the rotating shaft 4, and the cavity 5 is communicated with the cooling chamber 3; the bottom of the rotating shaft 4 is rotatably connected with a rotating air shaft 6 used for being connected with an external cooling device 19, and the rotating air shaft 6 is communicated with the cavity 5.

The utility model discloses a material cup device places the material through interior cup 1, cup 1 in closing through revolving cup lid 10 lid for interior cup 1 and outside formation isolation cavity, outside vacuum apparatus 20 is through the isolation cavity intercommunication that rotary joint 9 on the revolving cup lid 10 and interior cup 1 formed, thereby can carry out the evacuation operation to 1 inside of internal cup, make material cup device realize vacuum state, and rotary joint 9's setting is the rotation design of batch cup device. In the embodiment, in order to make the cup lid 10 better seal the inner cup 1 and make the inner cup 1 form a better vacuum environment, the inner cup 1 and the cup lid 10 are hermetically connected through the sealing ring 11. In addition, in order to enable the rotary cup cover 10 to stably cover the inner cup body 1, the rotary cup cover 10 is connected with the outer cup body 2 in a detachable connection mode, and specifically, the outer cup body 2 and the rotary cup cover 10 are detachably connected through a buckle 8; of course, other detachable connection modes can be adopted between the outer cup body 2 and the revolving cup cover 10, as long as the revolving cup cover 10 can be detachably mounted on the outer cup body 2.

Furthermore, the utility model discloses a material cup of material cup device comprises interior cup 1 and outer cup 2, the lower part of interior cup 1 and outer cup 2 forms cooling chamber 3, cooling chamber 3 passes through cavity 5 on the rotation axis 4, rotatory gas axle 6 is connected with outside cooling arrangement 19, outside cooling arrangement 19 can be through rotatory gas axle 6, cavity 5 on the rotation axis 4 is with the leading-in cooling chamber 3 of cooling gas, thereby make cooling gas surround the outside of cup 1 including, the material of cup 1 in the influence of outside heat has been isolated, simultaneously can cool down the processing to the material of cup 1, avoid influencing the stirring effect of cup 1 material in because of the temperature rises, specifically can cool off the heat that the material stirring produced, can isolate the heat transfer that material cup lower part bearing and gear drive produced to the material again. The utility model discloses in, the setting of 6 rotations of rotatory gas shafts is the same with the setting of rotary joint 9 rotations, all is designed for the rotation of batch cup device for the material cup device can carry out evacuation and cooling operation simultaneously at the rotation process. Preferably, the rotation center lines of the rotary joint 9, the inner cup 1, the rotary shaft 4 and the rotary air shaft 6 coincide. The rotary air shaft 6 is mounted on the rotary shaft 4 through a bearing one 7, so that the rotary air shaft 6 can rotate relative to the rotary shaft 4 through the bearing.

Based on the above, the utility model discloses a material cup device can realize evacuation and cooling operation simultaneously, just, and two operations do not influence each other to better material treatment effect has.

Example 2

Further, referring to fig. 2-5, the present invention further provides a homogenizer, which comprises a housing 23, a horizontal support mechanism, the above-mentioned material cup device, a cooling device 19 and a vacuum device 20. The housing 23 is provided with a receiving cavity 25, and a transverse support mechanism and a material cup device are arranged in the receiving cavity 25. The transverse support mechanism is provided with at least one material cup device, the transverse support mechanism is provided with a cooling channel, one end of the cooling channel is communicated with a cooling device 19, and the other end of the cooling channel is communicated with a rotary air shaft 6 of the material cup device; the rotary joint 9 of the material cup device is connected with a vacuum device 20.

The utility model discloses an adopt the aforesaid to carry out evacuation and refrigerated material cup device simultaneously, can be so that the isotropic symmetry when stirring the operation to the material, avoid the heat to the influence of material, its stirring effect is better. Furthermore, the material cup device can revolve with the cross support 12 under the action of the cross support mechanism, and can rotate on the cross support 12, and the material cup device is adjacent to the cooling equipment 19 through a cooling channel arranged on the cross support mechanism, so that the supply of cooling gas and the revolution and rotation of the material cup device are not mutually influenced. Preferably, in order to facilitate the flow of cooling gas into the cup device, the cooling channel is communicated with a cooling device 19 through a first cooling joint 18, and the first cooling joint 19 is rotatably mounted on the transverse support mechanism; the cooling channel is communicated with a rotary air shaft 6 of the material cup device through a second cooling connector 17, and the second cooling connector is rotatably arranged on the transverse support 12; the first cooling joint 18 and the cooling device 19 and the second cooling joint 17 and the rotary air shaft 6 are communicated through an air pipe 33.

In the present embodiment, a safety door 24 and a rotary joint 21 are provided at the top of the housing chamber 25; the safety door 24 is connected to the housing 23 and used for opening and closing the accommodating cavity 25; the rotary connecting joint 21 is rotatably installed on the shell 23 and is positioned in a closed space formed by the safety door 24 and the shell 23 when the safety door 24 covers the containing cavity 25, the rotary joint 9 of the cup device is connected with the vacuum device 20 through the rotary connecting joint 21, and the rotary joint 9 and the rotary connecting joint 21 and the vacuum device 20 are connected through air pipes 33. The safety door 24 is convenient for opening the containing cavity 25, so that materials can be fed, taken or parts in the shell 23 can be checked and overhauled. The rotary connecting joint 21 is convenient for connecting the material cup devices on the transverse support mechanism with the vacuum devices 20, namely, one vacuum device 20 can be connected with all the material cup devices on the transverse support mechanism, so as to simultaneously carry out vacuum pumping operation on the material cup devices. Further, in order to facilitate the opening and closing of the safety door 24 and the installation of the rotary connecting joint 21, the rotary connecting joint 21 is installed on the shell 23 through the supporting frame 22, the safety door 24 is provided with an upward concave convex part right facing the rotary connecting joint 21 and the supporting frame 22, so that when the storage cavity 25 is covered by the safety door 24, the rotary connecting joint 21 and the supporting frame 22 are accommodated in the convex part, the situation that the opening and closing of the safety door 24 are influenced by the arrangement of the rotary connecting joint 21 and the supporting frame 22 is avoided, and meanwhile, the installation position of the rotary connecting joint 21 meets the requirement that the material cup device and the transverse support mechanism are installed on the storage cavity 25. The vacuum device 20 may be installed inside the housing 23 or outside the housing 23, and in the present embodiment, the vacuum device 20 is installed outside the housing 23.

Further, the cooling channel of the present embodiment includes a main shaft air cavity and a support air cavity, the main shaft air cavity is located on the revolution main shaft 15 of the cross support mechanism, and the support air cavity is located on the cross support 12 of the cross support mechanism; one end of the main shaft air cavity is communicated with a cooling device 19, the other end of the main shaft air cavity is communicated with one end of the support air cavity, and the other end of the support air cavity is communicated with a rotary air shaft 6 of the material cup device through an air pipe 33; that is, the cooling passage is located at the revolution center of the lateral support mechanism so that the air tube 33 revolves with the lateral support mechanism, and it is preferable to locate the main shaft air chamber and the support air chamber on the rotation center axis of the revolution main shaft 15.

In addition, it should be noted that the utility model discloses a cross support mechanism drive material cup device revolution and rotation of isotropic symmetry are prior art, and present the utility model discloses below embodiment 3 give one of them, nevertheless the utility model discloses a cross support mechanism is not limited to this kind of structure, in addition, in below embodiment 3, still gives other parts of isotropic symmetry except above-mentioned structure, specifically as follows:

example 3

The horizontal support mechanism is installed inside the shell 23 through a support plate 13, a spindle seat 14 is installed on the support plate 13, a revolution spindle 15 of the horizontal support mechanism is installed on the support plate 13 through the spindle seat 14 in a rotating mode, the revolution spindle 15 is driven to rotate through a motor 16, the revolution spindle 15 is installed on a horizontal support 12, the horizontal support 12 is connected with a rotating shaft 4 of a material cup device through a bearing II 35 in a rotating mode, a gear 34 is sleeved on the rotating shaft 4 of the material cup device and is connected with a main gear on the revolution spindle 15 in a meshing mode through the gear 34, specifically, the center shaft is connected with a central shaft on the revolution spindle 15, the central shaft is sleeved in the revolution spindle 15 through a bearing in a rotating mode and is connected with the horizontal support 12 in a rotating mode, and a spindle air cavity is formed in the central shaft. The motor 16 drives the revolution main shaft 15 to rotate to drive the cross support 12 to rotate, and further drives the material cup device to rotate along with the cross support 12, namely, to revolve; the rotation of the revolution main shaft 15 causes the central shaft to rotate relative to the cross support 12, and the central shaft causes the material cup device to rotate relative to the cross support 12 in a gear transmission mode, namely the material cup device rotates.

The bottom of the supporting plate 13 is fixedly arranged on a frame 31 through a shock absorption fixing block 30, and the shock absorption fixing block 30 can reduce the vibration transmitted to the frame 31 by the stirring component during operation; the shell 23 is mounted on the top of a frame 31, and a support foot 32 is arranged at the bottom of the frame 31.

The shell 23 is also internally provided with a rotary cavity 26, and the rotary cavity 26 is arranged outside the transverse support mechanism and the material cup device in a surrounding manner to play a role in protection and prevent foreign matters from flying out during centrifugal rotation.

The shell 23 is provided with a control screen 27, an electric control system, an emergency stop switch 29 and a start-stop switch 28, and the control screen 27 can be used for setting the rotating speed and the running time of the motor 16, controlling the cooling and vacuum time, controlling the running states of the cooling equipment 19 and the vacuum pump and setting parameters of two modes. During daily use, after the start-stop switch 28 is pressed, the homogenizer operates at a set rotating speed, and the cooling system and the vacuum system operate according to set parameters. When an emergency occurs, the emergency stop switch 29 is pressed, and the whole machine stops running.

The above description is for the detailed description of the preferred possible embodiments of the present invention, but the embodiments are not intended to limit the scope of the present invention, and all equivalent changes or modifications accomplished under the technical spirit suggested by the present invention should fall within the scope of the present invention.

Claims (10)

1. A material cup device for cooling and vacuum comprises an inner cup body, an outer cup body, a cup rotating cover, a rotating joint, a rotating shaft and a rotating air shaft; the method is characterized in that: the outer cup body is sleeved outside the inner cup body, the rotary cup cover is detachably covered at the cup opening at the top of the outer cup body, the cup opening of the inner cup body is sealed when the rotary cup cover is covered on the outer cup body, a through opening is formed in the rotary cup cover and is communicated with the inside of the inner cup body, a rotary joint used for being connected with an external vacuum device is rotatably installed at the through opening, and the rotary joint is located on the outer side of the inner cup body and is communicated with the inside of the inner cup body through the through opening; the upper part of the outer cup body is in sealed fit connection with the upper part of the inner cup body, the lower part of the outer cup body and the lower part of the inner cup body are arranged at intervals to form a cooling chamber, a rotating shaft is arranged at the bottom of the outer cup body, a cavity is formed in the middle of the rotating shaft, and the cavity is communicated with the cooling chamber; the bottom of rotation axis rotates and is connected with the rotatory gas axle that is used for being connected with external cooling equipment, rotatory gas axle and cavity intercommunication.

2. A cup apparatus for cooling and vacuum as defined in claim 1, wherein: the outer cup body is detachably connected with the rotary cup cover through a buckle.

3. A cup apparatus for cooling and vacuum as defined in claim 1, wherein: the inner cup body is connected with the rotary cup cover in a sealing way through a sealing ring.

4. A cup apparatus for cooling and vacuum as defined in claim 1, wherein: the rotation center lines of the rotary joint, the inner cup body, the rotary shaft and the rotary air shaft are overlapped.

5. A homogenizer, characterized in that: comprises a transverse support mechanism, a material cup device according to any one of claims 1-4, a cooling device and a vacuum device; the transverse support mechanism is provided with at least one material cup device, the transverse support mechanism is provided with a cooling channel, one end of the cooling channel is communicated with cooling equipment, and the other end of the cooling channel is communicated with a rotary air shaft of the material cup device; and a rotary joint of the material cup device is connected with a vacuum device.

6. The homogenizer of claim 5, wherein: still include the shell, the shell has accomodates the chamber, accomodate intracavity installation horizontal support mechanism and material cup device.

7. The homogenizer of claim 6, wherein: the top of the containing cavity is provided with a safety door and a rotary connecting joint; the safety door is connected to the shell and used for opening and closing the containing cavity; the rotary connecting joint is rotatably installed on the shell and is located in a closed space formed by the safety door and the shell when the safety door cover closes the containing cavity, the rotary joint of the material cup device is connected with the vacuum device through the rotary connecting joint, and the rotary connecting joint and the vacuum device are connected through air pipes.

8. The homogenizer of claim 5, wherein: the cooling channel is communicated with cooling equipment through a first cooling connector, and the first cooling connector is rotatably installed on the transverse support mechanism.

9. The homogenizer of claim 5, wherein: the cooling channel is communicated with a rotary air shaft of the material cup device through a second cooling joint, and the second cooling joint is rotatably arranged on the transverse support.

10. The homogenizer of claim 5, wherein: the cooling channel comprises a main shaft air cavity and a support air cavity, the main shaft air cavity is positioned on a revolution main shaft of the transverse support mechanism, and the support air cavity is positioned on a transverse support of the transverse support mechanism; one end of the main shaft air cavity is communicated with the cooling equipment, the other end of the main shaft air cavity is communicated with one end of the support air cavity, and the other end of the support air cavity is communicated with a rotary air shaft of the material cup device through an air pipe.

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