CN115610755A - Special lithium manganese button cell heat-seal production line of external tire pressure monitoring system - Google Patents

Abstract

The invention belongs to the technical field of conveying, and particularly relates to a special lithium-manganese button cell heat-sealing production line for an external tire pressure monitoring system, wherein a feeding device is suitable for conveying raw materials; the bearing device is arranged on one side of the feeding device and is suitable for bearing the raw materials conveyed by the feeding device and conveying the bearing raw materials to the conveying device; conveyer, the adapting device sets up conveyer is last, conveyer is suitable for the raw materials transportation that carries adapting device, has realized carrying out the plastic envelope in the button cell transportation to piece or impurity that produce when to the plastic envelope are clear away, avoid piece or impurity to cause the influence to plastic envelope and transportation.

Description

Special lithium manganese button cell heat-seal production line of external tire pressure monitoring system

Technical Field

The invention belongs to the technical field of conveying, and particularly relates to a heat-sealing production line of a lithium-manganese button cell special for an external tire pressure monitoring system.

Background

The button cell needs to pass through a plurality of processes in the production process, and the button cell is transported by various conveying devices among the processes so as to be processed according to the sequence of the processes. When the button cell is processed, the plastic package plastic film outside the button cell is required to protect the button cell, but the plastic package film is different in quality during plastic package, so that the plastic package film is broken during plastic package, fragments are left on a feeding track, and the plastic package film is possibly broken during plastic package, so that large broken plastic package film objects are adhered to the feeding track, when the next button cell is subjected to plastic package, plastic package film impurities remained on the feeding track can influence the effect of plastic package, and the plastic package film fragments and the like on the feeding track can fall on subsequent annular belts or conveying belts during the transportation of the button cell, influence is caused on the transportation of the button cell after subsequent plastic package, and the plastic package film of the button cell can be damaged.

Therefore, a new external heat sealing production line for the lithium-manganese button cell dedicated for the tire pressure monitoring system needs to be designed based on the technical problems.

Disclosure of Invention

The invention aims to provide a heat sealing production line of a lithium-manganese button cell special for an external tire pressure monitoring system.

In order to solve the technical problem, the invention provides a heat sealing production line of a lithium-manganese button cell special for an external tire pressure monitoring system, which comprises:

a feeding device adapted to convey a feedstock;

the receiving device is arranged on one side of the feeding device and is suitable for receiving the raw materials conveyed by the feeding device and conveying the received raw materials to the conveying device;

the conveying device is arranged on the bearing device and is suitable for conveying the raw materials conveyed by the bearing device.

Further, the feeding device includes: a plurality of layers of feeding tracks;

the feeding track is arranged on the frame body, the tail end of the feeding track is arranged above the conveying device, and the tail end of the feeding track is arranged on one side of the annular belt in the bearing device;

a pushing block is arranged on the feeding track;

the feeding track is covered with a thermoplastic machine;

when the raw materials conveyed by the feeding device are received, the pushing block is suitable for pushing the raw materials on the feeding track into a thermoplastic molding machine for plastic packaging, and pushing the plastic-packaged raw materials onto the annular belt from the tail end of the feeding track.

Further, the transportation device includes: a conveyor belt and a pair of baffles;

the baffles are oppositely arranged, and the conveying belt is arranged between the baffles;

the bearing device is arranged on the baffle and is positioned above the conveying belt;

the conveyor belt is adapted to transport the feedstock transported on the endless belt.

Further, the receiving device includes: the adjusting mechanism and the bearing mechanism;

the adjusting mechanism is arranged on the baffle;

the bearing mechanism is arranged on the adjusting mechanism so as to arrange the bearing mechanism above the conveying belt;

the adjusting mechanism is suitable for adjusting the height of the bearing mechanism from the conveying belt and the angle between the bearing mechanism and the baffle.

Further, the adjustment mechanism includes: a pair of support frames;

the supporting frames are oppositely arranged, and a rotating shaft is arranged between the supporting frames;

the rotating shaft is connected with a driving motor, and the driving motor is suitable for driving the rotating shaft to rotate;

the supporting mechanism is arranged on the rotating shaft, and the rotating shaft drives the supporting mechanism to rotate when rotating;

the support frame comprises a first arm brace and a second arm brace;

one end of each first supporting leg is hinged with the corresponding baffle, and the other end of each first supporting leg is hinged with one end of each second supporting leg;

the other end of the second supporting leg is connected with the baffle in a sliding manner;

the other end of the second supporting foot is connected with the cylinder, the cylinder is arranged on the baffle, and the cylinder is suitable for pushing the second supporting foot to slide on the conveying device.

Further, the reception mechanism includes: the device comprises an annular belt, a pair of connecting frames and a bearing hopper;

the connecting frames are sleeved on the rotating shaft and are oppositely arranged;

the annular belt is arranged between the two connecting frames;

the bearing hopper is arranged between the two connecting frames, and the bearing hopper is hinged with the connecting frames;

one surface of the bearing hopper is provided with an opening, and one surface adjacent to one surface of the opening is provided with a notch;

the driving motor is suitable for driving the rotating shaft to rotate and drive the connecting frame to rotate so as to adjust the distance between the bearing hopper and the feeding device.

Further, when accepting the raw materials that the pay-off track carried, bear the weight of the fill and be close to the orbital tail end of pay-off, the slope of endless belt sets up this moment, and endless belt's one end is located the below of pay-off track tail end, and the other end is close to the conveyer belt, and the raw materials that the pay-off track carried passes through endless belt landing to the conveyer belt, bears the piece that drops on the pay-off track through bearing the weight of the fill.

Furthermore, when the conveying belt is cleaned, the opening edge of the bearing hopper is driven to be in contact with the conveying belt through the rotating shaft, and impurities on the conveying belt are shoveled into the bearing hopper through the edge of the bearing hopper.

Further, when cleaning the endless belt, drive through the pivot and bear fill breach border and endless belt contact, endless belt contacts with the conveyer belt this moment, drives endless belt through the conveyer belt and rotates, and endless belt is by bearing fill breach top downwardly rotating, shovels the impurity of endless belt into bearing the weight of the fill through bearing fill breach border and in the fill.

On the other hand, the invention also provides a working method of the heat sealing production line of the lithium manganese button cell special for the external tire pressure monitoring system, which comprises the following steps:

conveying the raw materials through a feeding device;

the material conveyed by the feeding device is received by the receiving device, and the received material is conveyed to the conveying device.

The invention has the beneficial effects that through the feeding device, the feeding device is suitable for conveying raw materials; the receiving device is arranged on one side of the feeding device and is suitable for receiving the raw materials conveyed by the feeding device and conveying the received raw materials to the conveying device; conveyer, the adapting device sets up conveyer is last, conveyer is suitable for the raw materials transportation that carries adapting device, has realized carrying out the plastic envelope in the button cell transportation to piece or impurity that produce when to the plastic envelope are clear away, avoid piece or impurity to cause the influence to plastic envelope and transportation.

Additional features and advantages of the invention will be set forth in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and drawings.

In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly described below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

Fig. 1 is a schematic structural view of a heat-sealing production line of a lithium manganese button cell dedicated for an external tire pressure monitoring system according to the present invention;

FIG. 2 is a schematic view of the receiving device of the present invention;

FIG. 3 is a schematic view of the structure of the bucket of the present invention;

FIG. 4 is a schematic illustration of conveyor belt cleaning according to the present invention;

FIG. 5 is a schematic illustration of the invention for cleaning an endless belt.

In the figure:

1, a feeding device, 12 feeding rails, 13 frame bodies, 14 push blocks and 15 thermoplastic machines;

2 bearing device, 21 first supporting leg, 22 second supporting leg, 23 air cylinder, 24 rotating shaft, 25 driving motor, 26 annular belt, 27 connecting frame, 28 bearing bucket and 281 gap;

3 conveying device, 31 conveying belt and 32 baffle.

Detailed Description

To make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings, and it is apparent that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

Example 1

As shown in fig. 1 to fig. 5, this embodiment 1 provides a heat sealing production line for a lithium-manganese button cell dedicated for an external tire pressure monitoring system, including: a feeding device 1, the feeding device 1 being adapted to convey a raw material; the raw material can be button cell, the exterior of the button cell is sleeved with a plastic packaging film, the button cell is conveyed to the bearing device 2 through the feeding device 1 after being plastic packaged on the feeding device 1, and the button cell is transferred to the conveying device 3 through the bearing device 2; the receiving device 2 is arranged on one side of the feeding device 1, and the receiving device 2 is suitable for receiving the raw materials conveyed by the feeding device 1 and conveying the received raw materials to the conveying device 3; conveyer 3, receiving device 2 sets up on conveyer 3, conveyer 3 is suitable for the raw materials transportation with receiving device 2 transport, has realized carrying out the plastic envelope in button cell transportation to piece or impurity that produce when to the plastic envelope are clear away, avoid piece or impurity to cause the influence to plastic envelope and transportation.

In this embodiment, the feeding device 1 includes: a plurality of layers of feeding tracks 12; the feeding track is covered with a thermoplastic machine 15; the number of layers of the feeding track 12 can directly correspond to the number of layers of the thermoplastic machine 15, and after the thermoplastic machine 15 carries out plastic packaging on the raw materials (button cells); the feeding track 12 is arranged on the frame body 13, the tail end of the feeding track 12 is arranged above the conveying belt 31 of the conveying device 3, and the tail end of the feeding track 12 is arranged on one side of the endless belt 26; a pushing block 14 is arranged on the feeding track 12; when receiving the raw materials conveyed by the feeding device 1, the pushing block 14 is suitable for pushing the raw materials on the feeding track 12 into the thermoplastic machine 15 for plastic packaging, and pushing the plastic packaged raw materials from the tail end of the feeding track 12 onto the annular belt 26; after all the raw materials on the feeding rail 12 of one layer are pushed into the endless belt 26, the driving motor 25 drives the rotating shaft 24 to rotate, so that the endless belt 26 is aligned with the feeding rail 12 of the next layer to receive the raw materials of the next layer.

In the present embodiment, the transport device 3 includes: a conveyor belt 31 and a pair of baffles 32; the baffles 32 are oppositely arranged, and the conveying belt 31 is arranged between the baffles 32; one end of the first supporting leg 21 is hinged with a corresponding baffle 32, and the cylinder 23 is arranged on the baffle 32; the cylinder 23 is suitable for driving the other end of the second supporting leg 22 to slide on the baffle 32; the conveyor belt 31 is adapted to transport the material transported on the endless belt 26.

In this embodiment, the receiving device 2 includes: the adjusting mechanism and the bearing mechanism; the adjusting mechanism is arranged on the conveying device 3; the bearing mechanism is arranged on the adjusting mechanism so as to arrange the bearing mechanism above the conveying device 3; the adjusting mechanism is suitable for adjusting the height of the bearing mechanism from the conveying belt 31 and the angle between the bearing mechanism and the baffle 32 so as to adjust the distance and the angle between the bearing mechanism and the feeding device 1 and between the conveying belt 31 and the baffle 32.

In this embodiment, the adjustment mechanism includes: a pair of support frames; the support frames are oppositely arranged, and a rotating shaft 24 is arranged between the support frames; the rotating shaft 24 is connected with a driving motor 25, and the driving motor 25 is suitable for driving the rotating shaft 24 to rotate; the bearing mechanism is arranged on the rotating shaft 24, and the rotating shaft 24 drives the bearing mechanism to rotate when rotating; the supporting frame comprises a first supporting leg 21 and a second supporting leg 22; one end of the first supporting leg 21 is hinged with the corresponding baffle 32, and the other end is hinged with one end of the second supporting leg 22; the other end of the second supporting leg 22 is slidably connected with the baffle 32; the other end of the second arm brace 22 is connected with a cylinder 23, and the cylinder 23 is suitable for pushing the second arm brace 22 to slide on the transportation device 3; the two cylinders 23 can work synchronously to drive the two second supporting feet 22 to move synchronously, so as to stably adjust the distance between the first supporting foot 21 and the second supporting foot 22, when the second supporting foot 22 moves towards the first supporting foot 21, the distance between the first supporting foot 21 and the second supporting foot 22 is reduced, the included angle between the first supporting foot 21 and the second supporting foot 22 is reduced, the rotating shaft 24 can be driven to arch upwards, the distance between the bearing mechanism and the conveying belt 31 is increased, when the first supporting foot 21 is far away from the second supporting foot 22, the distance between the first supporting foot 21 and the second supporting foot 22 is increased, the included angle between the first supporting foot 21 and the second supporting foot 22 is increased, and the bearing mechanism is close to the conveying belt 31 downwards.

In this embodiment, the receiving mechanism includes: an endless belt 26, a pair of link frames 27, and a load-bearing bucket 28; the connecting frame 27 is sleeved on the rotating shaft 24, and the connecting frame 27 is arranged oppositely; the endless belt 26 is disposed between two connecting frames 27; the carrying bucket 28 is arranged between the two connecting frames 27, and the carrying bucket 28 is hinged with the connecting frames 27; one surface of the carrying bucket 28 is provided with an opening, and one surface adjacent to the opening surface is provided with a notch 281; the driving motor 25 is suitable for driving the rotating shaft 24 to rotate, so as to drive the connecting frame 27 to rotate, so as to adjust the distance between the bearing hopper 28 and the feeding device 1;

when receiving the raw materials conveyed by the feeding device 1, the air cylinder 23 stops working, so that the distance between the first supporting leg 21 and the second supporting leg 22 is kept fixed, at this time, the driving motor 25 drives the rotating shaft 24 to rotate, the bearing hopper 28 is close to the tail end of the feeding device 1, at this time, the annular belt 26 is obliquely arranged, one end of the annular belt 26 is located below the tail end of the feeding track 12, (a gap is reserved between the annular belt 26 and the feeding track 12, so that the scraps on the feeding track 12 are pushed into the bearing hopper 28, and when plastic films or button batteries with broken plastic films are attached to the feeding track 12 due to plastic encapsulation, the adhered plastic films or button batteries with broken plastic films partially contact the annular belt 26, so that the original adhered state becomes a falling state, the fallen plastic films or button batteries with broken plastic films partially fall into the bearing hopper 28, the other end of the adhered plastic films or button batteries with broken plastic films partially fall into the conveying belt 31, and the raw materials conveyed by the feeding device 1 (the raw materials on the same layer of the feeding track 12 fall from the tail end of the annular belt 26 through the corresponding pushing block 14 onto the conveying device 3 (the conveying device 3), and the conveying device 3, and the scraps fall on the conveying device 12 through the bearing track 12 and the conveying device 12 and the bearing belt 31); when the conveyer belt 31 is cleaned, the cylinder 23 drives the second arm brace 22 to be away from the first arm brace 21, so that the distance between the first arm brace 21 and the second arm brace 22 is increased, the bearing bucket 28 is made to be close to the conveyer belt 31 downwards, the opening edge of the bearing bucket 28 is driven by the rotating shaft 24 to be in contact with the conveyer (the opening of the bearing bucket 28 cannot be downward in the rotating process, and collected impurity fragments are prevented from falling on the conveyer belt 31), and the impurities on the conveyer are shoveled into the bearing bucket 28 through the edge of the bearing bucket 28 along with the rotation of the conveyer belt 31 (when the plastic-sealed button cell falls into the bearing bucket 28, part of the fragments fall on the conveyer belt 31); when the ring belt 26 is cleaned (when the button cell falls on the ring belt 26, a part of broken plastic film may have chips or impurities to fall on the ring belt 26), the cylinder 23 drives the second arm brace 22 to be away from the first arm brace 21, so that the distance between the first arm brace 21 and the second arm brace 22 is increased, the bearing bucket 28 is made to be downward close to the conveyer belt 31, the gap 281 edge of the bearing bucket 28 is driven to be in contact with the ring belt 26 through the rotating shaft 24, at this time, the ring belt 26 is in contact with the transportation device 3, the ring belt 26 is driven to rotate in the rotation process through the conveyer belt 31, the ring belt 26 is rotated downward from above the gap 281 of the bearing bucket 28, and the impurities of the ring belt 26 are shoveled into the bearing bucket 28 through the gap 281 edge of the bearing bucket 28.

Example 2

On the basis of embodiment 1, this embodiment 2 further provides a working method of the heat sealing production line for the lithium-manganese button cell dedicated for the external tire pressure monitoring system in embodiment 1, including: conveying the raw materials through a feeding device 1; the raw material conveyed by the feeding device 1 is received by the receiving device 2 and conveyed to the conveying device 3.

In summary, according to the invention, the feeding device 1 is adapted to convey the raw material; the raw material can be button cell, the exterior of the button cell is sleeved with a plastic packaging film, the button cell is conveyed to the bearing device 2 through the feeding device 1 after being plastic packaged on the feeding device 1, and the button cell is transferred to the conveying device 3 through the bearing device 2; the receiving device 2 is arranged on one side of the feeding device 1, and the receiving device 2 is suitable for receiving the raw materials conveyed by the feeding device 1 and conveying the received raw materials to the conveying device 3; conveyer 3, receiving device 2 sets up on conveyer 3, conveyer 3 is suitable for the raw materials transportation with receiving device 2 transport, has realized carrying out the plastic envelope in button cell transportation to piece or impurity that produce when to the plastic envelope are clear away, avoid piece or impurity to cause the influence to plastic envelope and transportation.

The components selected for use in the present application (components not illustrated for specific structures) are all common standard components or components known to those skilled in the art, and the structure and principle thereof can be known to those skilled in the art through technical manuals or through routine experimentation.

In the description of the embodiments of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the several embodiments provided in the present application, it should be understood that the disclosed system, apparatus and method may be implemented in other ways. The above-described embodiments of the apparatus are merely illustrative, and for example, the division of the units is only one logical division, and there may be other divisions when actually implemented, and for example, a plurality of units or components may be combined or integrated into another system, or some features may be omitted, or not executed. In addition, the shown or discussed mutual coupling or direct coupling or communication connection may be an indirect coupling or communication connection of devices or units through some communication interfaces, and may be in an electrical, mechanical or other form.

The units described as separate parts may or may not be physically separate, and parts displayed as units may or may not be physical units, may be located in one place, or may be distributed on a plurality of network units. Some or all of the units can be selected according to actual needs to achieve the purpose of the solution of the embodiment.

In addition, functional units in the embodiments of the present invention may be integrated into one processing unit, or each unit may exist alone physically, or two or more units are integrated into one unit.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (10)

1. The utility model provides a special lithium manganese button cell heat-seal production line of external tire pressure monitoring system which characterized in that includes:

a feeding device adapted to convey a feedstock;

the bearing device is arranged on one side of the feeding device and is suitable for bearing the raw materials conveyed by the feeding device and conveying the bearing raw materials to the conveying device;

the conveying device is arranged on the bearing device and is suitable for conveying the raw materials conveyed by the bearing device.

2. The external heat-sealing production line for lithium-manganese button cells dedicated for tire pressure monitoring systems of claim 1,

the feeding device comprises: a plurality of layers of feeding tracks;

the feeding track is arranged on the frame body, the tail end of the feeding track is arranged above the conveying device, and the tail end of the feeding track is arranged on one side of an annular belt in the bearing device;

a push block is arranged on the feeding track;

the feeding track is covered with a thermoplastic machine;

when the raw materials conveyed by the feeding device are received, the pushing block is suitable for pushing the raw materials on the feeding track into a thermoplastic molding machine for plastic packaging, and pushing the plastic-packaged raw materials onto the annular belt from the tail end of the feeding track.

3. The external heat-sealing production line for lithium-manganese button cells dedicated for tire pressure monitoring systems of claim 2,

the transportation device includes: a conveyor belt and a pair of baffles;

the baffles are oppositely arranged, and the conveying belt is arranged between the baffles;

the bearing device is arranged on the baffle and is positioned above the conveying belt;

the conveyor belt is adapted to transport the feedstock transported on the endless belt.

4. The external heat-sealing production line for lithium-manganese button cells dedicated for tire pressure monitoring system according to claim 3,

the receiving device includes: an adjusting mechanism and a bearing mechanism;

the adjusting mechanism is arranged on the baffle;

the bearing mechanism is arranged on the adjusting mechanism so as to arrange the bearing mechanism above the conveying belt;

the adjusting mechanism is suitable for adjusting the height of the bearing mechanism from the conveying belt and the angle between the bearing mechanism and the baffle.

5. The external heat-sealing production line for lithium-manganese button cells dedicated for tire pressure monitoring systems of claim 4,

the adjustment mechanism includes: a pair of support frames;

the supporting frames are oppositely arranged, and a rotating shaft is arranged between the supporting frames;

the rotating shaft is connected with a driving motor, and the driving motor is suitable for driving the rotating shaft to rotate;

the supporting mechanism is arranged on the rotating shaft, and the rotating shaft drives the supporting mechanism to rotate when rotating;

the supporting frame comprises a first supporting leg and a second supporting leg;

one end of each first supporting leg is hinged with the corresponding baffle, and the other end of each first supporting leg is hinged with one end of each second supporting leg;

the other end of the second supporting leg is connected with the baffle in a sliding manner;

the other end of the second supporting foot is connected with the cylinder, the cylinder is arranged on the baffle, and the cylinder is suitable for pushing the second supporting foot to slide on the conveying device.

6. The external heat-sealing production line for lithium-manganese button cells dedicated for tire pressure monitoring systems of claim 5,

the receiving mechanism includes: the device comprises an annular belt, a pair of connecting frames and a bearing hopper;

the connecting frames are sleeved on the rotating shaft and are oppositely arranged;

the annular belt is arranged between the two connecting frames;

the bearing hopper is arranged between the two connecting frames, and the bearing hopper is hinged with the connecting frames;

one surface of the bearing hopper is provided with an opening, and one surface adjacent to one surface of the opening is provided with a notch;

the driving motor is suitable for driving the rotating shaft to rotate and drive the connecting frame to rotate so as to adjust the distance between the bearing hopper and the feeding device.

7. The external heat-sealing production line for lithium-manganese button cells dedicated for tire pressure monitoring systems of claim 6,

when accepting the raw materials that the pay-off track carried, bear the weight of the fill and be close to the orbital tail end of pay-off, the slope of endless belt sets up this moment, and endless belt's one end is located the below of the orbital tail end of pay-off, and the other end is close to the conveyer belt, and the raw materials that the pay-off track carried passes through endless belt landing to the conveyer belt on, bear the piece that drops on the pay-off track through bearing the weight of the fill.

8. The external heat-sealing production line for lithium-manganese button cells dedicated for tire pressure monitoring systems of claim 7,

when the conveying belt is cleaned, the opening edge of the bearing hopper is driven to be in contact with the conveying belt through the rotating shaft, and impurities on the conveying belt are shoveled into the bearing hopper through the edge of the bearing hopper.

9. The external heat-sealing production line for lithium-manganese button cells dedicated for tire pressure monitoring system according to claim 8,

when cleaning the endless belt, drive through the pivot and bear fill breach border and endless belt contact, endless belt and conveyer belt contact this moment drive endless belt through the conveyer belt and rotate, and endless belt is by bearing fill breach top downwards rotation, shovels into the impurity of endless belt through bearing fill breach border and bears in the fill.

10. The working method of the external heat sealing production line of the lithium-manganese button cell special for the tire pressure monitoring system as claimed in claim 1 is characterized by comprising the following steps:

conveying the raw materials through a feeding device;

the material conveyed by the feeding device is received by the receiving device, and the received material is conveyed to the conveying device.

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