A vacuum centrifugal defoaming machine for encapsulation adhesive
The mechanical linkage design, which combines a braking device and a limit switch, solves the safety and efficiency issues of the centrifugal degassing machine when the lid is opened, and achieves the functions of stable stopping and rapid material replacement.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- LONGYAN DEYU LIGHTING
- Filing Date
- 2025-07-03
- Publication Date
- 2026-06-05
AI Technical Summary
Existing centrifugal degassing machines lack sufficient safety measures when the lid is opened, which can easily cause danger due to inertial rotation. Furthermore, photoelectric detection is prone to errors, affecting the operating efficiency and safety of the equipment.
The system employs a braking device and a limit switch linkage to mechanically disconnect the centrifugal structure circuit when the lid is opened. Combined with a pre-opening device, this ensures the centrifugal structure stops stably and avoids inertial rotation.
It improves the safety and efficiency of equipment opening, reduces safety hazards caused by photoelectric detection errors, and ensures the ability to quickly change materials.
Smart Images

Figure CN224321064U_ABST
Abstract
Description
Technical Field
[0001] This utility model belongs to the field of centrifugal degassing machines, and specifically relates to a vacuum centrifugal degassing machine for encapsulating adhesives. Background Technology
[0002] Various industrial colloids inevitably generate air bubbles during their preparation. To avoid affecting the use of the colloid, these bubbles need to be removed. The common practice is to use a centrifuge for degassing. A centrifugal degassing machine uses centrifugal force to separate air bubbles from the material. The material rotates at high speed inside the centrifugal degassing machine, generating centrifugal force that separates the material from the air bubbles, ultimately achieving degassing. However, current technology often uses photoelectric detection methods such as infrared to detect the open state, and the system stops the degassing machine's rotation based on the detection signal. This method has poor safety measures when the cover is open, failing to guarantee a slowdown or complete stop. Even after the cover is open, the centrifugal structure continues to rotate due to inertia, posing a potential hazard. Furthermore, after the cover is open, it's necessary to wait for the centrifugal structure to stop before replacing the material for the next use, wasting time and reducing efficiency. Additionally, photoelectric sensors are prone to errors due to obstruction or system malfunctions, affecting normal operation and creating further hazards, making the process inconvenient. Utility Model Content
[0003] (a) Technical problems to be solved
[0004] To overcome the shortcomings of existing technologies, a vacuum centrifugal degassing machine for encapsulating adhesives is proposed. This addresses the problem that existing technologies often rely on photoelectric detection methods such as infrared sensors to detect the open state, and the system stops the degassing machine's rotation based on the detection signal. However, these methods lack safety measures when the cap is open, failing to guarantee a reduction in speed or a complete stop. Furthermore, the centrifugal structure continues to rotate due to inertia after the cap is opened, posing a safety hazard. This also results in waiting for the centrifugal structure to stop before material can be replaced for the next use, wasting time and reducing efficiency. Additionally, the photoelectric sensors are prone to errors due to obstruction or system malfunctions, affecting normal operation and creating further safety risks, making the process quite inconvenient.
[0005] (II) Technical Solution
[0006] This utility model is achieved through the following technical solution: This utility model proposes a vacuum centrifugal degassing machine for encapsulating adhesive, the structure of which includes a machine body, a chamber cover and a controller, the chamber cover is hinged to the machine body, and the controller is assembled on the machine body;
[0007] The machine body is provided with a self-rotating seat, a degassing chamber and a revolution seat, the revolution seat is rotatably assembled in the degassing chamber and the self-rotating seat is rotatably assembled on the revolution seat;
[0008] It also includes a braking device, which is assembled inside the degassing chamber. The braking device includes a lever, a first push rod, a limiting sleeve, a first sliding groove, a limit switch, an assembly plate, a braking plate, a second push rod, and a first elastic element. The lever is assembled to the side wall of the degassing chamber via a shaft. Both ends of the lever are provided with first sliding grooves. The first push rod and the second push rod are respectively assembled to both ends of the lever via the first sliding grooves and the shaft. The limiting sleeve and the assembly plate are both fixed to the side wall of the degassing chamber. The limiting sleeve is used to limit the movement of the first push rod and the second push rod. The end of the first push rod away from the lever is connected to the chamber cover. The end of the second push rod away from the lever passes through the assembly plate and is fixedly connected to the braking plate. The braking plate is located on the side of the assembly plate adjacent to the rotating seat and the revolving seat. A first elastic element is assembled between the assembly plate and the braking plate. The first elastic element is used to press the braking plate to stop the rotating seat and the revolving seat. The limit switch is used to automatically cut off the power to the power structure of the rotating seat and the revolving seat during the operation of the braking plate.
[0009] Furthermore, it also includes a vacuum pump, sensors, and a power supply. The vacuum pump is used to evacuate the degassing chamber, the sensors are used to detect environmental parameters inside the degassing chamber, and the power supply is used to connect and supply power to the equipment.
[0010] Furthermore, the sensors are vacuum sensors, temperature and humidity sensors, weight sensors, and speed sensors, etc., and the power source is a rechargeable battery that can be externally powered.
[0011] Furthermore, it also includes a pre-opening cover device, which includes a second elastic element, a limiting rod, a connecting strip, a second sliding groove, and an adsorption block. The limiting rod is embedded in the machine body, and one end of the limiting rod is fixedly connected to the machine body through the second elastic element, which is used to pull the limiting rod toward the machine body. One end of the adsorption block is in contact with the cover, and the other end of the adsorption block is fixed with a connecting strip. The connecting strip is provided with a second sliding groove, and the other end of the limiting rod is slidably connected to the second sliding groove through a shaft. The adsorption block is used to adsorb the cover.
[0012] Furthermore, the adsorption block is a magnet or a suction cup. When the adsorption block is a magnet, the compartment cover is made of metal or has a corresponding metal structure. When the adsorption block is a suction cup, the connection between the compartment cover and the adsorption block is a smooth plane or has a corresponding smooth surface structure.
[0013] Furthermore, the first elastic element is a compression spring, the second elastic element is a tension spring, and the elastic force of the first elastic element is between the minimum elastic force and the maximum elastic force of the second elastic element.
[0014] Furthermore, the maximum displacement distance of the adsorption block is less than the distance between the braking plate's self-rotating seat and the revolution seat, and the maximum displacement distance of the adsorption block is greater than the distance at which the braking plate triggers the limit switch.
[0015] Furthermore, the machine body also includes a partition, a gear ring, a bevel gear, a self-rotating assembly seat, a cover lock, a motor, gears, and a drive shaft. The partition is fixed inside the machine body, and its top forms a degassing chamber within the machine body. A gear ring is fixed to the top of the partition. One end of the drive shaft is fixedly connected to a planetary seat, and the other end of the drive shaft passes through the partition and is fixedly connected to a gear. The motor drives the drive shaft to rotate through the gear. The planetary seat is located above the gear ring. The self-rotating assembly seat is fixedly mounted on the planetary seat, and a self-rotating seat is rotatably mounted on the self-rotating assembly seat. The self-rotating seat is fixedly connected to the bevel gear, and the bevel gear meshes with the gear ring. The cover lock is used to lock the chamber cover to the machine body. The brake plate is located above the side of the planetary seat adjacent to the chamber cover.
[0016] Furthermore, the machine body is also equipped with a gearbox, and the motor is connected to the gears through the gearbox. The gearbox is used for the speed change connection between the motor and the gears.
[0017] Furthermore, the toothed ring is a ring with toothed grooves adjacent to the side of the self-rotating assembly seat.
[0018] Furthermore, the braking device also includes a wear-resistant ring and a wear-resistant plate. The wear-resistant ring is fixedly mounted on the side of the orbital seat near the compartment cover, and the wear-resistant plate is fixedly mounted on the side of the braking plate near the orbital seat.
[0019] (III) Beneficial Effects
[0020] One of the above technical solutions has the following advantages or beneficial effects:
[0021] Equipped with a braking device and limit switch, the device is linked to the silo cover via a push rod and lever. When the silo cover is closed, the push rod causes the braking plate to disengage from the centrifugal structure, allowing the equipment to perform centrifugal degassing normally. When the silo cover is open, the braking device first presses against the limit switch before contacting the centrifugal structure, disconnecting the circuit of the centrifugal structure and stopping its operation. Then, the braking plate presses against the centrifugal structure through the first elastic element, reducing the inertial rotation time of the centrifugal structure after it is disconnected from power. At the same time, the device uses mechanical linkage for braking, which can better ensure the stability of power stopping and braking, and prevent situations such as sensing errors. Even if the limit switch fails to trigger, the equipment can still decelerate until it stops, ensuring the safety of the equipment after the cover is opened. It also allows the equipment to quickly change materials for the next degassing after a single degassing cycle, improving efficiency. Attached Figure Description
[0022] Other features, objects, and advantages of this invention will become more apparent from the following detailed description of non-limiting embodiments with reference to the accompanying drawings:
[0023] Figure 1This is a three-dimensional structural diagram of the present invention;
[0024] Figure 2 This is a cross-sectional structural diagram of the present invention;
[0025] Figure 3 This utility model Figure 2 A magnified structural diagram of A in the middle;
[0026] Figure 4 This is a top view schematic diagram of the structure of the present invention with the thickness of the compartment cover removed;
[0027] Figure 5 This utility model Figure 4 A magnified structural diagram of B in the diagram;
[0028] Figure 6 This is a cross-sectional view of the present invention with the rotation structure removed.
[0029] Figure 7 This utility model Figure 6 A magnified structural diagram of C;
[0030] Figure 8 This is a cross-sectional structural diagram of the pre-opened state after removing the self-rotating structure in Embodiment 2 of this utility model;
[0031] Figure 9 This is a cross-sectional structural diagram of the fully opened state after removing the self-rotating structure in Embodiment 2 of this utility model;
[0032] In the diagram: Body - 1, Compartment Cover - 2, Controller - 3, Vacuum Pump - 4, Braking Device - 5, Sensor - 6, Power Supply - 7, Pre-opening Cover Device - 8, Partition - 101, Gear Ring - 102, Bevel Gear - 103, Rotating Assembly Base - 104, Rotating Base - 105, Cover Lock - 106, Degassing Chamber - 107, Revolution Base - 108, Motor - 109, Gearbox - 110, Gear - 111, Drive Shaft - 112, Lever - 501, First Push Rod - 502, Limit Sleeve - 503, First Slide Groove - 504, Limit Switch - 505, Assembly Plate - 506, Brake Plate - 507, Second Push Rod - 508, Wear Ring - 509, First Elastic Component - 510, Wear Plate - 511, Second Elastic Component - 801, Limit Rod - 802, Connecting Strip - 803, Second Slide Groove - 804, Adsorption Block - 805. Detailed Implementation
[0033] The present invention will be further described in detail below with reference to the embodiments, but the implementation of the present invention is not limited thereto.
[0034] Example 1:
[0035] This utility model provides a vacuum centrifugal degassing machine for encapsulating adhesive: its structure includes a machine body 1, a chamber cover 2 and a controller 3, wherein the chamber cover 2 is hinged to the machine body 1 and the controller 3 is assembled on the machine body 1;
[0036] The machine body 1 is provided with a self-rotating seat 105, a degassing chamber 107 and a revolution seat 108. The revolution seat 108 is rotatably mounted in the degassing chamber 107, and the self-rotating seat 105 is rotatably mounted on the revolution seat 108.
[0037] It also includes a braking device 5, which is assembled inside the degassing chamber 107. The braking device 5 includes a lever 501, a first push rod 502, a limiting sleeve 503, a first slide groove 504, a limit switch 505, an assembly plate 506, a braking plate 507, a second push rod 508, and a first elastic element 510. The lever 501 is assembled to the side wall of the degassing chamber 107 via a shaft. Both ends of the lever 501 are provided with the first slide groove 504. The first push rod 502 and the second push rod 508 are respectively assembled to both ends of the lever 501 via the first slide groove 504 and the shaft. The limiting sleeve 503 and the assembly plate 506 are both fixed to the side wall of the degassing chamber 107. The limiting sleeve 503... The first push rod 502 and the second push rod 508 are used for movement limit. The end of the first push rod 502 away from the lever 501 is connected to the cover 2. The end of the second push rod 508 away from the lever 501 passes through the assembly plate 506 and is fixedly connected to the brake plate 507. The brake plate 507 is located on the side of the assembly plate 506 adjacent to the rotating seat 105 and the revolving seat 108. A first elastic element 510 is assembled between the assembly plate 506 and the brake plate 507. The first elastic element 510 is used to press the brake plate 507 to brake the rotating seat 105 and the revolving seat 108. The limit switch 505 is used to automatically cut off the power structure of the rotating seat 105 and the revolving seat 108 during the operation of the brake plate 507.
[0038] The device also includes a vacuum pump 4, a sensor 6, and a power supply 7. The vacuum pump 4 is used to evacuate the degassing chamber 107, the sensor 6 is used to detect the environmental parameters inside the degassing chamber 107, and the power supply 7 is used to connect and supply power to the device.
[0039] Among them, the sensor 6 is a vacuum sensor, temperature and humidity sensor, weight sensor and speed sensor, etc., and the power supply 7 is a rechargeable battery that can be connected to external power.
[0040] In operation, with the lid 2 closed, the lid 2 will press down the first push rod 502, causing the first push rod 502 to drive the second push rod 508 upward via the lever 501. This causes the brake plate 507 to press up the first elastic element 510, disengaging it from braking the self-rotating seat 105 and the revolution seat 108, thus stopping the braking of the centrifugal structure and allowing it to operate normally. During the opening of the lid 2, as the first push rod 502 rises, the brake plate 507 is pressed down by the first elastic element 510. At this time, the brake plate 507 will first trigger the limit switch 505, causing it to disconnect power to the power structure of the self-rotating seat 105 and the revolution seat 108, ensuring... When the centrifugal structure of the equipment is in a stopped state, the brake plate 507 will contact the centrifugal structure, causing it to stop due to friction. This reduces the inertial rotation time of the centrifugal structure after it is disconnected from the power source. The design of cutting off the power before braking prevents premature braking of the centrifugal structure from damaging the power structure of the self-rotating seat 105 and the revolution seat 108, ensuring the safety of opening the cover and the safety of use. At the same time, the device uses mechanical linkage for braking, which can better ensure the stability of power stopping and braking, and reduce the occurrence of sensing errors. Even if the limit switch fails to trigger, the equipment can be slowed down until it stops through the brake plate 507, which facilitates emergency stopping and better ensures the safety of the equipment after opening the cover.
[0041] Example 2:
[0042] Compared to the aforementioned embodiments, this embodiment further includes a pre-opening cover device 8. The pre-opening cover device 8 includes a second elastic element 801, a limiting rod 802, a connecting strip 803, a second sliding groove 804, and an adsorption block 805. The limiting rod 802 is embedded in the body 1. One end of the limiting rod 802 is fixedly connected to the body 1 through the second elastic element 801. The second elastic element 801 is used to pull the limiting rod 802 toward the body 1. One end of the adsorption block 805 is attached to the cover 2. The other end of the adsorption block 805 is fixed with the connecting strip 803. The second sliding groove 804 is provided through the connecting strip 803. The other end of the limiting rod 802 is slidably connected to the second sliding groove 804 through a shaft. The adsorption block 805 is used for adsorption of the cover 2.
[0043] Wherein, the adsorption block 805 is a magnet or a suction cup. When the adsorption block 805 is a magnet, the compartment cover 2 is made of metal or has a corresponding metal structure. When the adsorption block 805 is a suction cup, the connection between the compartment cover 2 and the adsorption block 805 is a smooth plane or has a corresponding smooth surface structure.
[0044] Wherein, the first elastic element 510 is a compression spring, the second elastic element 801 is a tension spring, and the elastic force of the first elastic element 510 is located between the minimum elastic force and the maximum elastic force of the second elastic element 801.
[0045] The maximum displacement distance of the adsorption block 805 is less than the distance between the brake plate 507 and the rotating seat 105 and the orbital seat 108, and the maximum displacement distance of the adsorption block 805 is greater than the distance between the brake plate 507 and the limit switch 505.
[0046] When the compartment cover 2 is unlocked, the first elastic element 510 presses down the brake plate 507, causing the first brake plate 507 to drive the first push rod 502 upward via the second push rod 508 and lever 501. This causes the first push rod 502 to automatically press down on the compartment cover 2. At this time, the suction block 805, due to its attraction to the compartment cover 2, combined with the suction block 805 being held by the second elastic element 801, and the elastic relationship between the second elastic element 801 and the first elastic element 510, ensures that the compartment cover 2 will only automatically rise a certain distance after unlocking before being limited by the pre-opening device 8. This also restricts the first elastic element 510 from pressing down on the brake plate 507. At this time, the brake plate 507 will trigger the limit switch 505 to first cut off the power to the centrifugal structure, but will not immediately contact the centrifugal structure to stop. Only after the bin cover 2 is manually lifted to disengage from the adsorption block 805 will the brake plate 507 continue to lower and stop the centrifugal structure. This better ensures the phased stop of the centrifugal structure and avoids the situation where the motor is still running due to residual power and causes excessive impact when the power is cut off and the stop is stopped immediately. This further ensures the safety of the equipment. After the adsorption block 805 is disengaged from the bin cover 2, it will also be reset by the pull of the second elastic element 801. The rest of the structure and effect are the same as those in the previous embodiment.
[0047] Example 3:
[0048] Compared to the previous embodiments, the machine body 1 in this embodiment is further provided with a partition 101, a gear ring 102, a bevel gear 103, a self-rotating assembly seat 104, a cover lock 106, a motor 109, a gear 111, and a drive shaft 112. The partition 101 is fixed inside the machine body 1, and its top forms a degassing chamber 107 inside the machine body 1. The gear ring 102 is fixed to the top of the partition 101. One end of the drive shaft 112 is fixedly connected to the revolving seat 108, and the other end of the drive shaft 112 passes through the partition 101 and is fixedly connected to the gear 111. The motor 109 drives the drive shaft 112 to rotate via the gear 111. The orbital seat 108 is located above the gear ring 102. The self-rotating assembly seat 104 is fixedly mounted on the orbital seat 108. A self-rotating seat 105 is rotatably mounted on the self-rotating assembly seat 104. The self-rotating seat 105 is fixedly connected to the bevel gear 103. The bevel gear 103 meshes with the gear ring 102. The cover lock 106 is used to lock the compartment cover 2 and the machine body 1. The brake plate 507 is located above the side of the orbital seat 108 adjacent to the compartment cover 2.
[0049] The machine body 1 is also equipped with a gearbox 110. The motor 109 is connected to the gear 111 through the gearbox 110. The gearbox 110 is used for the speed change connection between the motor 109 and the gear 111.
[0050] The toothed ring 102 is a ring with toothed grooves on the side adjacent to the self-rotating assembly 104.
[0051] In use, the motor 109 drives the drive shaft 112 to rotate, causing the orbital seat 108 to rotate. When the orbital seat 108 rotates, it drives the rotating seat 105 mounted on the self-rotating mounting base 104 to move accordingly. The bevel gear 103, which is fixedly connected to the rotating seat 105, meshes with the gear ring 102, which is fixed on the partition plate 101 and does not move with the orbital seat 108. This allows the rotating seat 105 to rotate when it moves with the orbital seat 108, thus realizing the single motor 109 driving both rotation and revolution, saving on power components and other structures. At the same time, the brake plate 507 of the braking device 5 only needs to lower to contact the orbital seat 108 to brake the orbital seat 108, which can stop both the orbital seat 108 and the rotating seat 105. This is convenient and quick. The remaining structure and effects are unchanged compared to the previous embodiment.
[0052] Example 4:
[0053] Compared to the previous embodiments, the braking device 5 in this embodiment further includes a wear-resistant ring 509 and a wear-resistant plate 511. The wear-resistant ring 509 is fixedly mounted on the side of the orbital seat 108 adjacent to the side of the compartment cover 2, and the wear-resistant plate 511 is fixedly mounted on the side of the braking plate 507 adjacent to the orbital seat 108. This allows the wear-resistant ring 509 and the wear-resistant plate 511 to be replaced after braking wear as the device is used more, facilitating long-term use. The remaining structure and effects are unchanged compared to the previous embodiments.
[0054] In the description of this utility model, it should be noted that the terms "upper", "lower", "left", "right", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this utility model and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this utility model.
[0055] The control method of this utility model is to control the device by manually starting and stopping the switch. The wiring diagram of the power element and the supply of power are common knowledge in the field. Since this utility model is mainly used to protect mechanical devices, the control method and wiring layout will not be explained in detail.
[0056] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. It will be apparent to those skilled in the art that this utility model is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or basic characteristics of this utility model. Therefore, the embodiments should be considered exemplary and non-limiting in all respects. The scope of this utility model is defined by the appended claims rather than the foregoing description, and thus all variations falling within the meaning and scope of equivalents of the claims are intended to be included within this utility model. No reference numerals in the claims should be construed as limiting the scope of the claims.
[0057] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.
Claims
1. A vacuum centrifugal degassing machine for encapsulating adhesive, the structure of which includes a machine body (1), a bin cover (2) and a controller (3), wherein the bin cover (2) is hinged to the machine body (1) and the controller (3) is mounted on the machine body (1); Its features are: The machine body (1) is provided with a self-rotating seat (105), a degassing chamber (107) and a revolution seat (108). The revolution seat (108) is rotatably mounted in the degassing chamber (107), and the self-rotating seat (105) is rotatably mounted on the revolution seat (108). It also includes a braking device (5), which is assembled inside the degassing chamber (107). The braking device (5) includes a lever (501), a first push rod (502), a limiting sleeve (503), a first slide groove (504), a limit switch (505), an assembly plate (506), a braking plate (507), a second push rod (508), and a first elastic element (510). The lever (501) is assembled to the side wall of the degassing chamber (107) via a shaft. Both ends of the lever (501) are provided with a first slide groove (504). The first push rod (502) and the second push rod (508) are respectively assembled to both ends of the lever (501) via the first slide groove (504) and the shaft. The limiting sleeve (503) and the assembly plate (506) are both fixed to the side wall of the degassing chamber (107). The first push rod (502) and the second push rod (508) are used to limit the movement of the first push rod (502) and the second push rod (508). The end of the first push rod (502) away from the lever (501) is connected to the cover (2). The end of the second push rod (508) away from the lever (501) passes through the assembly plate (506) and is fixedly connected to the brake plate (507). The brake plate (507) is located on the side of the assembly plate (506) near the rotating seat (105) and the revolving seat (108). A first elastic element (510) is assembled between the assembly plate (506) and the brake plate (507). The first elastic element (510) is used to press the brake plate (507) to brake the rotating seat (105) and the revolving seat (108). The limit switch (505) is used to automatically cut off the power structure of the rotating seat (105) and the revolving seat (108) during the operation of the brake plate (507).
2. The vacuum centrifugal degassing machine for encapsulating adhesive according to claim 1, characterized in that: It also includes a vacuum pump (4), a sensor (6) and a power supply (7). The vacuum pump (4) is used to evacuate the degassing chamber (107), the sensor (6) is used to detect the environmental parameters inside the degassing chamber (107), and the power supply (7) is used to connect and supply power to the equipment.
3. The vacuum centrifugal degassing machine for encapsulating adhesive according to claim 1, characterized in that: It also includes a pre-opening cover device (8), which includes a second elastic element (801), a limiting rod (802), a connecting strip (803), a second sliding groove (804), and an adsorption block (805). The limiting rod (802) is embedded in the machine body (1). One end of the limiting rod (802) is fixedly connected to the machine body (1) through the second elastic element (801). The second elastic element (801) is used to pull the limiting rod (802) toward the machine body (1). One end of the adsorption block (805) is attached to the cover (2). The other end of the adsorption block (805) is fixed with a connecting strip (803). The second sliding groove (804) is provided through the connecting strip (803). The other end of the limiting rod (802) is slidably connected to the second sliding groove (804) through a shaft. The adsorption block (805) is used for adsorption of the cover (2).
4. The vacuum centrifugal degassing machine for encapsulating adhesive according to claim 3, characterized in that: The adsorption block (805) is a magnet or a suction cup. When the adsorption block (805) is a magnet, the compartment cover (2) is made of metal or has a corresponding metal structure. When the adsorption block (805) is a suction cup, the connection between the compartment cover (2) and the adsorption block (805) is a smooth plane or has a corresponding smooth surface structure.
5. The vacuum centrifugal degassing machine for encapsulating adhesive according to claim 3, characterized in that: The first elastic element (510) is a compression spring, and the second elastic element (801) is a tension spring. The elastic force of the first elastic element (510) is between the minimum elastic force and the maximum elastic force of the second elastic element (801).
6. The vacuum centrifugal degassing machine for encapsulating adhesive according to claim 5, characterized in that: The maximum displacement distance of the adsorption block (805) is less than the distance between the brake plate (507) and the rotating seat (105) and the orbital seat (108), and the maximum displacement distance of the adsorption block (805) is greater than the distance between the brake plate (507) and the limit switch (505).
7. A vacuum centrifugal degassing machine for encapsulating adhesive according to claim 1 or 3, characterized in that: The machine body (1) is also equipped with a partition (101), a gear ring (102), a bevel gear (103), a self-rotating assembly seat (104), a cover lock (106), a motor (109), a gear (111), and a drive shaft (112). The partition (101) is fixed inside the machine body (1) and its top forms a degassing chamber (107) inside the machine body (1). The gear ring (102) is fixed to the top of the partition (101). One end of the drive shaft (112) is fixedly connected to the revolving seat (108), and the other end of the drive shaft (112) passes through the partition (101) and is fixedly connected to the gear (111). The motor... (109) The drive shaft (112) is driven to rotate by the gear (111). The revolution seat (108) is located above the gear ring (102). The self-rotating assembly seat (104) is fixedly mounted on the revolution seat (108). A self-rotating seat (105) is rotatably mounted on the self-rotating assembly seat (104). The self-rotating seat (105) is fixedly connected to the bevel gear (103). The bevel gear (103) meshes with the gear ring (102). The cover lock (106) is used to lock the compartment cover (2) and the machine body (1). The brake plate (507) is located above the side of the revolution seat (108) adjacent to the compartment cover (2).
8. A vacuum centrifugal degassing machine for encapsulating adhesive according to claim 7, characterized in that: The machine body (1) is also equipped with a gearbox (110), and the motor (109) is connected to the gear (111) through the gearbox (110). The gearbox (110) is used for the speed change connection between the motor (109) and the gear (111).
9. A vacuum centrifugal degassing machine for encapsulating adhesive according to claim 7, characterized in that: The toothed ring (102) is a ring with toothed grooves on the side adjacent to the self-rotating assembly seat (104).
10. A vacuum centrifugal degassing machine for encapsulating adhesive according to claim 7, characterized in that: The braking device (5) further includes a wear-resistant ring (509) and a wear-resistant plate (511). The wear-resistant ring (509) is fixedly mounted on the side of the orbital seat (108) near the compartment cover (2), and the wear-resistant plate (511) is fixedly mounted on the side of the braking plate (507) near the orbital seat (108).