A sintering device
By designing the hinge structure between the support and moving parts and the heat dissipation components, the problem of low disassembly efficiency of the sintering processing mechanism in the sintering device was solved, achieving efficient disassembly and installation while improving heat dissipation efficiency.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUZHOU N SINGLE INTELLIGENT TECH CO LTD
- Filing Date
- 2025-06-24
- Publication Date
- 2026-06-19
Smart Images

Figure CN224382091U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of sintering technology, and in particular to a sintering apparatus. Background Technology
[0002] In the production and processing of photovoltaic panels, the sintering unit uses sintering lamps to perform low-temperature baking and high-temperature sintering on the panels, drying the slurry on the panels and burning off the organic components within the slurry, thereby forming good ohmic contact electrodes on the panels. Different panels require different sintering mechanisms. Currently, when sintering different panels or when the sintering mechanism needs to be moved, it is necessary to disassemble the sintering structure into multiple parts before it can be separated from the conveying mechanism. This disassembly process is cumbersome, resulting in low disassembly efficiency. Utility Model Content
[0003] Therefore, the technical problem to be solved by this utility model is to provide a sintering device that can improve the disassembly efficiency of the sintering processing mechanism in the sintering device.
[0004] To solve the above-mentioned technical problems, this utility model provides a sintering device, comprising: a support assembly including a support member; a movable assembly including a movable member and a sintering member, wherein the movable member is hinged to the support member, the sintering member is connected to the movable member, and a receiving cavity is formed between the movable member and the support member, wherein a feeding channel is provided in the receiving cavity, and the working side of the sintering member faces the feeding channel; and a conveying assembly including a conveyor belt, wherein the conveyor belt is movable, and the conveying path of the conveyor belt passes through the feeding channel.
[0005] In one embodiment of the present invention, the support assembly further includes a first heat dissipation component, the support component is provided with a first heat dissipation cavity, the first heat dissipation cavity is located within the receiving cavity, and the first heat dissipation component is located within the first heat dissipation cavity.
[0006] In one embodiment of the present invention, the first heat sink is provided with a heat dissipation port facing the feeding channel, the heat dissipation port penetrates the first heat sink, and the side wall of the heat dissipation port is provided with a groove.
[0007] In one embodiment of the present invention, the side wall of the support member is provided with a connector, the connector being in communication with the first heat dissipation cavity, and the connector being used to introduce inert gas into the first heat dissipation cavity.
[0008] In one embodiment of the present invention, the support assembly further includes a connecting rod with threads, the connecting rod passing through the side wall of the support member, the end of the connecting rod being connected to the first heat sink, and a locking member being threadedly connected to the connecting rod, the locking member being able to abut against the support member.
[0009] In one embodiment of the present invention, a cooling component is further included, the cooling component including a second heat sink, the output end of the second heat sink facing the conveyor belt, and a gap existing between the second heat sink and the conveyor belt.
[0010] In one embodiment of the present invention, the cooling component further includes a connecting frame, the connecting frame including at least two connecting columns, and a second heat dissipation cavity is formed between two adjacent connecting columns, and the conveyor belt is located between the second heat dissipation component and the second heat dissipation cavity.
[0011] In one embodiment of the present invention, the conveying assembly further includes at least two tension rollers and at least two driven rollers, the tension rollers being in contact with the conveyor belt, the driven rollers being located within the space surrounded by the conveyor belt, and the second heat sink being located between the two driven rollers.
[0012] In one embodiment of the present invention, the conveying assembly further includes a driving component and at least two mounting brackets. The mounting brackets are rotatably connected to rotating rollers. The output end of the driving component is connected to one of the rotating rollers. The conveyor belt is sleeved on the rotating rollers. The support component and the movable component are located between the two mounting brackets.
[0013] In one embodiment of this utility model, a plurality of positioning elements are provided on the conveyor belt along the conveying path. The positioning elements include positioning rods arranged symmetrically, and the angle between the center line of the positioning rod and the plane where the conveyor belt is located is an acute angle.
[0014] In one embodiment of the present invention, the support member has a first opening on its opposite sidewall and the movable member has a second opening on its opposite sidewall. The first opening and the second opening constitute the input end and output end of the feeding channel.
[0015] In one embodiment of this utility model, a hinge block is connected between the support member and the movable member, a quick-lock member is connected to the side of the support member away from the hinge block, and a locking hook is connected to the side of the movable member away from the hinge block. The locking end of the quick-lock member can engage with the locking hook.
[0016] The above-mentioned technical solution of this utility model has the following advantages compared with the prior art:
[0017] The sintering device described in this utility model, through the hinged connection between the support member and the movable member, and the detachable connection between the support member and the support frame, allows the movable member to rotate and facilitates the disassembly of the support member, thereby facilitating the disassembly of the sintering processing mechanism. This eliminates the need to disassemble the sintering processing mechanism into multiple parts, thus improving both disassembly and installation efficiency. The first heat sink and its heat dissipation vents enable rapid heat dissipation from the receiving cavity. The second heat sink allows for heat dissipation from the conveyor belt. Attached Figure Description
[0018] To make the content of this utility model easier to understand, the present utility model will be further described in detail below with reference to specific embodiments and accompanying drawings.
[0019] Figure 1 This is a schematic diagram of the structure of a sintering device according to the present invention;
[0020] Figure 2 yes Figure 1 Partial structural diagram;
[0021] Figure 3 This is a schematic diagram of the sintering processing mechanism;
[0022] Figure 4 This is a structural diagram of the supporting components;
[0023] Figure 5 This is a top view of the sintering processing mechanism;
[0024] Figure 6 yes Figure 5 A cross-sectional view at position AA in the middle;
[0025] Figure 7 This is a structural diagram of the conveying component and the cooling component.
[0026] Explanation of reference numerals in the accompanying drawings: 1. Support frame; 2. Movable part; 3. Support component; 4. Conveying assembly; 5. Second heat sink; 6. Product to be processed; 21. Mounting component; 22. First vent pipe; 23. Sintered part; 24. Fan; 25. Second vent pipe; 26. Heat-insulating glass plate; 27. Filter glass plate; 28. Locking hook; 29. Third heat sink; 31. Hinge block; 32. Quick lock; 33. Connector; 34. First heat sink; 35. Connecting rod; 36. Heat dissipation port; 37. Groove; 41. Conveyor belt; 42. Positioning component; 43. Mounting frame; 44. Driving component; 45. Tensioning roller; 46. Driven roller; 47. Second connecting plate; 51. Connecting frame; 52. First connecting plate; 53. Connecting column; 201. Heating tube. Detailed Implementation
[0027] The present invention will be further described below with reference to the accompanying drawings and specific embodiments, so that those skilled in the art can better understand and implement the present invention. However, the embodiments are not intended to limit the present invention.
[0028] Reference Figure 1 and Figure 2 As shown, a sintering device of this utility model includes: a support assembly, including a support member 3; a movable assembly, including a movable member 2 and a sintering member 23, wherein the movable member 2 is hinged to the support member 3, the sintering member 23 is connected to the movable member 2, and the movable member 2 and the support member 3 form a receiving cavity, wherein a feeding channel is provided in the receiving cavity, and the working side of the sintering member 23 faces the feeding channel; and a conveying assembly 4, including a conveyor belt 41, wherein the conveyor belt 41 is movable, and the conveying path of the conveyor belt 41 passes through the feeding channel.
[0029] In this embodiment of the sintering apparatus, a conveyor belt 41 moves the product 6 to be processed to the feeding channel until the product 6 is moved to the corresponding position of the sintering component 23, thereby enabling the sintering component 23 to process the product 6. When it is necessary to disassemble the sintering processing mechanism, the electrical connection of the sintering component 23 is disconnected, the movable component 2 is rotated to flip it, thereby moving the sintering component 23 away from the conveyor belt 41. Finally, the support component 3 is disassembled, the conveyor belt 41 is pulled out of the receiving cavity, and the support component 3 and the movable component 2 are removed simultaneously, thus completing the disassembly of the sintering processing mechanism. The hinge between the support component 3 and the movable component 2 allows the movable component 2 to rotate, facilitating the disassembly of the sintering processing mechanism without having to disassemble it into multiple parts, thereby improving disassembly efficiency.
[0030] The supporting components and the moving components together constitute the sintering processing mechanism, which is used to sinter the product 6 to be processed.
[0031] The sintering apparatus also includes a support frame 1, and the support components, movable components, conveying components 4 and cooling components are all connected to the support frame 1.
[0032] Reference Figure 3As shown, the support assembly includes a support member 3, which is detachably connected to the support frame 1 by bolts. The movable assembly includes a movable member 2 and a sintered member 23. The movable member 2 is hinged to the support member 3. Specifically, a hinge block 31 is connected between the support member 3 and the movable member 2. The hinge block 31 can be regarded as a hinge. Two quick-locking members 32 are connected to the side of the support member 3 away from the hinge block 31. The quick-locking members 32 can be regarded as quick-locking fasteners. Two locking hooks 28 are connected to the side of the movable member 2 away from the hinge block 31. The locking hooks 28 correspond to the positions of the quick-locking members 32. The locking end of the quick-locking member 32 is provided with a movable collar. The movement of the collar allows the collar to be fitted onto the locking hooks 28, thereby allowing the locking end of the quick-locking member 32 to engage with the locking hooks 28, thus fixing the positions of the support member 3 and the movable member 2, and keeping the support member 3 and the movable member 2 in abutment. When the sintering mechanism is in operation, the locking hook 28 and the quick-locking member 32 are locked, and the bottom side of the movable member 2 abuts against the top side of the support member 3, at which time the movable member 2 and the support member 3 are in a closed state. When the sintering mechanism is in a detachable state, the locking hook 28 and the quick-locking member 32 are unlocked, and the movable member 2 is in a rotatable state. When the sintered part 23 is removed from the receiving cavity, the movable member 2 and the support member 3 are in an open state.
[0033] The movable part 2 and the supporting part 3 form a receiving cavity, and the receiving cavity is provided with a feeding channel for the product 6 to be processed to pass through. The sintered part 23 can be regarded as a lamp for sintering processing. The sintering device also includes a controller, and the sintered part 23 is electrically connected to the controller. The working side of the sintered part 23 faces the feeding channel, so as to process the product 6 to be processed located in the feeding channel. The working side of the sintered part 23 is the light-emitting side of the sintered part 23.
[0034] The movable component 2 has an opening on the side near the support component 3. The movable component 2 includes a third heat dissipation cavity, which is located inside the receiving cavity. The movable component 2 is provided with a first vent pipe 22, which communicates with the third heat dissipation cavity and is connected to an external air extraction device. The air extraction device can discharge the gas in the receiving cavity to the outside through the first vent pipe 22, thereby dissipating heat from the product 6 to be processed and the conveyor belt 41 located in the receiving cavity.
[0035] The movable component also includes a mounting member 21, which is detachably connected to the movable member 2 and located within the third heat dissipation cavity. The mounting member 21 contains a fourth heat dissipation cavity, and an opening is provided at one end of the mounting member 21 near the support member 3. A sintered component 23 is connected to the mounting member 21, with both ends of the sintered component 23 located outside the fourth heat dissipation cavity, i.e., the sintered component 23 penetrates the mounting member 21. Both ends of the sintered component 23 are electrically connected to the controller. The working position of the sintered component 23 is located within the fourth heat dissipation cavity. The detachable connection between the mounting member 21 and the movable member 2 allows the sintered component 23 to move along with the mounting member 23, facilitating the replacement and maintenance of the sintered component 23. The top of the mounting component 21 is also connected to a fan 24 and a second vent pipe 25. The second vent pipe 25 is connected to the fourth heat dissipation cavity. The fan 24 can blow external air toward the sintered part 23 to cool it down. After exchanging heat with the sintered part 23, the air is discharged to the outside through the second vent pipe 25, thus enabling the sintered part 23 to continuously dissipate heat and cool down. The open end of the mounting component 21 is also connected to a heat-insulating glass plate 26. The heat-insulating glass plate 26 is transparent, and the working side of the sintered part 23 faces the heat-insulating glass plate 26, so that the light emitted by the sintered part 23 can pass through the heat-insulating glass plate 26 to process the product 6 to be processed. The edge of the heat-insulating glass plate 26 is sealed to the edge of the open end of the mounting component 21 to prevent hot air from the fourth heat dissipation cavity from overflowing into the receiving cavity. The third heat dissipation chamber is also equipped with a filter glass plate 27, which is detachably connected to the side wall of the mounting component 21. The filter glass plate 27 corresponds to the heat insulation glass plate 26. The filter glass plate 27 can filter part of the wavelength of light emitted by the sintered part 23. Since the filter glass plate 27 is detachably connected to the mounting component 21, different filter glass plates 27 can be replaced according to the processing requirements of the product 6 to be processed. The third heat dissipation chamber is also equipped with a heating pipe 201, which is connected to the side wall of the mounting component 21 and extends towards the feeding channel. When the temperature of the receiving cavity is too low, the heating pipe 201 heats up the receiving cavity, thereby maintaining the temperature inside the receiving cavity within the specified temperature range.
[0036] Reference Figure 4 to Figure 6As shown, the support assembly also includes a first heat sink 34. The support 34 has a first heat sink cavity located within the receiving cavity. The feeding channel is located between the first heat sink cavity and the third heat sink cavity. The first heat sink 34 is located within the first heat sink cavity. Specifically, the first heat sink 34 can be considered a liquid-cooled heat sink. The first heat sink 34 is connected to two liquid flow pipes, both of which are connected to an external cooling component. The two liquid flow pipes are used for the input and output of coolant from the first heat sink 34, respectively. The cooling component can cool the coolant, thereby enabling the first heat sink 34 to dissipate heat from the receiving cavity, and further dissipate heat from the conveyor belt 41 and the product 6 to be processed located on the conveyor belt 41. Preferably, the first heat sink 34 has a heat dissipation port 36 facing the feeding channel. The heat dissipation port 36 penetrates the first heat sink 34 vertically, making the cross-section of the first heat sink 34 rectangular and annular. The side wall of the heat dissipation port 36 has a groove 37. The arrangement of the heat dissipation port 36 allows the coolant to flow quickly through the first heat sink 34, thereby enabling the first heat sink 34 to quickly dissipate heat from the receiving cavity and improving the heat dissipation efficiency of the first heat sink 34. In this embodiment, two first heat sinks 34 are provided in the first heat dissipation cavity. The number of first heat sinks 34 can be set according to the volume of the receiving cavity and the heat dissipation efficiency.
[0037] The support assembly also includes a connecting rod 35, which is threaded and passes through the bottom sidewall of the support member 3. The end of the connecting rod 35 is connected to the first heat sink 34. A locking member, which can be considered a nut, is threaded onto the connecting rod 35. By rotating the locking member, it can abut against the support member 3, thereby fixing the position of the first heat sink 34. By rotating the locking member, it can be moved away from the support member 3, allowing the position of the first heat sink 34 to be adjusted. Preferably, a third heat sink 29 is provided in the fourth receiving cavity. The third heat sink 29 is connected to the mounting member 21. The structure of the third heat sink 29 is the same as that of the first heat sink 34, and the connection method between the third heat sink 29 and the mounting member 21 is the same as the connection method between the first heat sink 34 and the support member 3, which will not be described further. With the third heat sink 29, during the process of the fan 24 driving airflow towards the sintered part 23, the airflow can pass through the third heat sink 29, allowing the third heat sink 29 to cool the air, thereby further improving the heat dissipation efficiency of the sintered part 23.
[0038] The side wall of the support member 3 is also provided with two connectors 33, which are connected to the first heat dissipation cavity and to an external air supply device. The air supply device can introduce inert gas into the first heat dissipation cavity through the connectors 33, and the inert gas can diffuse to the rest of the cavity. Preferably, the inert gas is nitrogen. By introducing inert gas into the cavity, rapid oxidation of the product 6 to be processed can be avoided. Preferably, the bottom of the support member 3 is also connected to a vent hole, which is connected to the cavity and to an external oxygen detection device. The oxygen detection device can detect the oxygen content in the cavity, and when the oxygen content is too high, the air flow rate of the air supply device to the first heat dissipation cavity is increased.
[0039] The support member 3 has a first opening on its opposite sidewall, and the movable member 2 has a second opening on its opposite sidewall. Both the first and second openings communicate with the receiving cavity. When the support member 3 and the movable member 2 are in a closed state, the first and second openings constitute the input and output ends of the feeding channel. Specifically, the feeding channel is arranged horizontally, the conveyor belt 41 is located inside the first opening, and the second opening is used for the passage of the product 6 to be processed on the conveyor belt 41. By setting the first and second openings, the conveyor belt 41 and the product 6 to be processed can pass through the receiving cavity, while also preventing the inert gas in the receiving cavity from leaking rapidly to the outside, thus reducing the leakage rate of the inert gas.
[0040] Reference Figure 7 As shown, the conveying assembly 4 includes a conveyor belt 41, and also includes a drive unit 44 and at least two mounting frames 43. The mounting frames 43 are connected to the support frame 1, and rotating rollers are rotatably connected to opposite sides of the mounting frames 43. The drive unit 44 can be considered as a motor, and is connected to the support frame 1. The output end of the drive unit 44 is connected to the end of one of the rotating rollers, and the drive unit 44 can drive the rotating roller to rotate. In this embodiment, there are two rotating rollers. The conveyor belt 41 is generally ring-shaped, and the rotating roller is located within the enclosure of the conveyor belt 41. The conveyor belt 41 is sleeved on the rotating roller and is tensioned and in contact with the rotating roller. The drive unit 44 drives the rotating roller to rotate, thereby driving the conveyor belt 41 to move. The conveying path of the conveyor belt 41 passes through the feeding channel. Specifically, the feeding channel is generally located on the conveying path of the conveyor belt 41, so that the conveyor belt 41 can carry the product to be processed 6 to the receiving cavity. The sintering part 23 processes the product to be processed 6 located on the conveyor belt 41.
[0041] Multiple positioning elements 42 are provided along the conveying path on the conveyor belt 41. Each positioning element 42 includes a positioning rod and a support rod arranged symmetrically. The bottom end of the support rod is connected to the conveyor belt 41 and is perpendicular to the conveyor belt 41. One end of the positioning rod is connected to the top end of the support rod, and the other end of the positioning rod is connected to the conveyor belt 41. The centerline of the positioning rod forms an acute angle with the plane of the conveyor belt 41, thereby making the positioning rod inclined. The product to be processed 6 is placed on the positioning rod. Since the positioning rod is inclined and symmetrically arranged, the product to be processed 6 can be engaged with the positioning component 42. The positioning component 42 can position the product to be processed 6 and prevent the product to be processed 6 from shaking during movement. At the same time, the product to be processed 6 is placed on the positioning component 42, so that there is a gap between the product to be processed 6 and the conveyor belt 41, which allows the product to be processed 6 to be heated evenly. The gap between the product to be processed 6 and the conveyor belt 41 can dissipate heat, preventing the temperature of the contact side from becoming too high after the product to be processed 6 and the conveyor belt 41 are attached, which would cause damage to the product to be processed 6 and the conveyor belt 41.
[0042] The sintering apparatus also includes a cooling component, which comprises a second heat sink 5. The output end of the second heat sink 5 faces the bottom side of the conveyor belt 41, and the top side of the conveyor belt 41 is used to transport the product 6 to be processed. The second heat sink 5 can be considered as an air-cooled heat dissipation device. There is a gap between the second heat sink 5 and the conveyor belt 41 to avoid mutual friction between the conveyor belt 41 and the second heat sink 5. The second heat sink 5 can cool the conveyor belt 41 without interfering with the position of the sintering processing mechanism.
[0043] The cooling assembly also includes a connecting frame 51, which is connected to the support frame 1. The connecting frame 51 includes at least two connecting posts 53, and a second heat dissipation cavity is formed between two adjacent connecting posts 53. The conveyor belt 41 is located between the second heat dissipation component 5 and the second heat dissipation cavity. The second heat dissipation cavity can dissipate heat from the conveyor belt 41 and also prevent the positioning component 42 from colliding with the support frame 1 during movement.
[0044] The conveying assembly 4 also includes at least two tension rollers 45 and at least two driven rollers 46. The two tension rollers 45 are arranged opposite each other and are in contact with the outer wall of the conveyor belt 41. The driven rollers 46 are located within the space surrounded by the conveyor belt 41 and are in contact with the inner wall of the conveyor belt 41. The second heat sink 5 is located between the two driven rollers 46 and within the space surrounded by the conveyor belt 41. Preferably, the tension roller 45 is provided with a receiving groove corresponding to the position of the positioning member 42. The positioning member 42 can pass through the receiving groove during movement, thereby preventing the positioning member 42 from colliding with the tension roller 45 during movement. The tension rollers 45 ensure that the conveyor belt 41 is in a tensioned state. The driven rollers 46 increase the distance between the top and bottom sides of the conveyor belt 41, improving the heat dissipation effect of the conveyor belt 41. The second heat sink 5 is located within the space surrounded by the conveyor belt 41, thus avoiding the second heat sink 5 being located externally and occupying more volume, thereby reducing the overall volume of the sintering device.
[0045] The second heat sink 5 is connected to the support frame 1 via the first connecting plate 52, and the driven roller 46 is connected to the support frame 1 via the second connecting plate 47. Specifically, the first connecting plate 52 is L-shaped, and the side of the first connecting plate 52 connected to the second heat sink 5 has multiple horizontally arranged connecting holes. The connecting holes are oblong holes, and the multiple connecting holes are arranged vertically. By setting multiple connecting holes, the position of the second heat sink 5 can be adjusted within the range of the connecting holes. By connecting the second heat sink 5 to different connecting holes, the height of the second heat sink 5 can be adjusted. The structure of the second connecting plate 47 is the same as that of the first connecting plate 52, and will not be described again, so that the position of the driven roller 46 can be adjusted to adapt to conveyor belts 41 of different sizes. The connection method between the tension roller 45 and the support frame 1 and the second heat sink 5 and the support frame 1 is the same, and will not be described again, so that the position of the tension roller 45 can be adjusted, thereby adjusting the tension of the conveyor belt 41.
[0046] In use, the product to be processed 6 is placed on the positioning part 42 of the conveyor belt 41. The conveyor belt 41 drives the product to be processed 6 to move to the feeding channel until the product to be processed 6 moves to the corresponding position of the sintered part 23, so that the sintered part 23 can process the product to be processed 6. At the same time, the fan 24 blows the outside air to the sintered part 23 to cool it down. After the air exchanges heat with the sintered part 23, it is discharged to the outside through the second vent pipe 25. The air extraction part discharges the gas in the receiving cavity to the outside through the first vent pipe 22, thereby dissipating heat from the receiving cavity, the conveyor belt 41 and the product to be processed 6. The first heat dissipation part 34 dissipates heat from the receiving cavity, the conveyor belt 41 and the product to be processed 6. The air supply device introduces inert gas into the first heat dissipation cavity through the connector 33. The third heat dissipation part 29 dissipates heat from the conveyor belt 41.
[0047] When the sintered structure needs to be disassembled, the following steps are included: S1: Disconnect the electrical connection of the sintered component 23; S2: Rotate the movable component 2 to move the sintered component 23 away from the conveyor belt 41; S3: Remove the support component 3, pull the conveyor belt 41 out of the receiving cavity, and simultaneously remove the support component 3 and the movable component 2. An unlocking step is also included between steps S1 and S2, which includes releasing the locking state of the locking hook 28 and the quick-lock component 32, allowing the movable component 2 to rotate. Step S3 also includes removing the support component 3 from the support frame 1, pulling the support component 3 out from between the mounting brackets 43, and moving the conveyor belt 41 out through the first opening.
[0048] This utility model discloses a sintering device. Through the hinge connection between the support member 3 and the movable member 2, and the detachable connection between the support member 3 and the support frame 1, the movable member 2 can rotate, facilitating the disassembly of the support member 3 and consequently the disassembly of the sintering processing mechanism. This eliminates the need to disassemble the sintering processing mechanism into multiple parts, thus improving disassembly efficiency. It also simplifies the installation and maintenance steps of the sintering processing mechanism, improving its installation and maintenance efficiency. The first heat sink 34 and its heat dissipation vents 36 enable the first heat sink 34 to quickly dissipate heat from the receiving cavity. The second heat sink 5 enables heat dissipation from the conveyor belt 41.
[0049] Obviously, the above embodiments are merely illustrative examples for clear explanation and are not intended to limit the implementation. Those skilled in the art will recognize that other variations or modifications can be made based on the above description. It is neither necessary nor possible to exhaustively list all possible implementations here. However, obvious variations or modifications derived therefrom are still within the protection scope of this invention.
Claims
1. A sintering apparatus, characterized in that, include: Support components, including support parts; The movable component includes a movable part and a sintered part. The movable part is hinged to the support member, and the sintered part is connected to the movable part. A receiving cavity is formed between the movable part and the support member. A feeding channel is provided in the receiving cavity, and the working side of the sintered part faces the feeding channel. A conveying assembly includes a conveyor belt that is movable and whose conveying path passes through the feeding channel.
2. The sintering apparatus according to claim 1, characterized in that: The support assembly further includes a first heat sink, the support assembly having a first heat sink cavity, the first heat sink cavity being located within the receiving cavity, and the first heat sink being located within the first heat sink cavity.
3. The sintering apparatus according to claim 2, characterized in that: The first heat sink has a heat dissipation port facing the feeding channel, the heat dissipation port penetrates the first heat sink, and the side wall of the heat dissipation port has a groove.
4. The sintering apparatus according to claim 2, characterized in that: The side wall of the support member is provided with a connector, which is connected to the first heat dissipation cavity and is used to introduce inert gas into the first heat dissipation cavity.
5. The sintering apparatus according to claim 2, characterized in that: The support assembly further includes a connecting rod with threads, the connecting rod passing through the side wall of the support member, the end of the connecting rod being connected to the first heat sink, and a locking member being threadedly connected to the connecting rod, the locking member being able to abut against the support member.
6. The sintering apparatus according to claim 1, characterized in that: It also includes a cooling component, which includes a second heat sink, the output end of which faces the conveyor belt, and there is a gap between the second heat sink and the conveyor belt.
7. The sintering apparatus according to claim 6, characterized in that: The cooling component also includes a connecting frame, which includes at least two connecting columns, with a second heat dissipation cavity formed between two adjacent connecting columns, and the conveyor belt is located between the second heat dissipation component and the second heat dissipation cavity.
8. The sintering apparatus according to claim 6, characterized in that: The conveying assembly further includes at least two tension rollers and at least two driven rollers, the tension rollers being in contact with the conveyor belt, the driven rollers being located within the space enclosed by the conveyor belt, and the second heat sink being located between the two driven rollers.
9. The sintering apparatus according to claim 1, characterized in that: The conveying assembly further includes a drive unit and at least two mounting frames, each mounting frame being rotatably connected to a rotating roller. The output end of the drive unit is connected to one of the rotating rollers. The conveyor belt is fitted onto the rotating roller. The support member and the movable member are located between the two mounting frames.
10. The sintering apparatus according to claim 1, characterized in that: The conveyor belt is provided with multiple positioning elements along the conveying path. The positioning elements include positioning rods arranged symmetrically, and the angle between the center line of the positioning rod and the plane where the conveyor belt is located is an acute angle.
11. The sintering apparatus according to claim 1, characterized in that: The support member has a first opening on its opposite sidewall, and the movable member has a second opening on its opposite sidewall. The first opening and the second opening together constitute the input and output ends of the feeding channel.
12. The sintering apparatus according to claim 1, characterized in that: A hinge block connects the support member and the movable member. A quick-lock member is connected to the side of the support member away from the hinge block, and a locking hook is connected to the side of the movable member away from the hinge block. The locking end of the quick-lock member can engage with the locking hook.