阅读说明：本技术 一种焊锡环热缩管组装设备 (Soldering tin ring heat-shrinkable tube assembling equipment ) 是由 王成 于 2021-07-21 设计创作，主要内容包括：本发明公开一种焊锡环热缩管组装设备,包括层叠分布的工作台、转盘和安装置放板,所述转盘可旋转活动连接在所述工作台上,所述安装置放板连接在所述工作台上：所述转盘上设有至少一个工件模具；所述安装置放板包括锡环上料装置、热缩管上料装置、脱模剂涂抹装置、加热成型装置和至少两个热熔胶环上料装置,所述脱模剂涂抹装置、其一所述热熔胶环上料装置、锡环上料装置、另一所述热熔胶环上料装置、热缩管上料装置和加热成型装置顺次环形分布在所述安装置放板上。本发明的技术方案能够充分利用设备整体结构的所占有空间,节省了人工的投入,提高了生产加工的效率。(The invention discloses soldering tin ring heat-shrinkable tube assembling equipment which comprises a workbench, a rotary table and a mounting device placing plate, wherein the workbench, the rotary table and the mounting device placing plate are distributed in a stacked mode, the rotary table is rotatably and movably connected to the workbench, and the mounting device placing plate is connected to the workbench: at least one workpiece die is arranged on the turntable; the mounting and placing plate comprises a tin ring feeding device, a heat shrinkable tube feeding device, a release agent smearing device, a heating forming device and at least two hot melt adhesive ring feeding devices, wherein the release agent smearing device, one of the hot melt adhesive ring feeding devices, the tin ring feeding device, the other hot melt adhesive ring feeding device, the heat shrinkable tube feeding device and the heating forming device are sequentially and annularly distributed on the mounting device placing plate. The technical scheme of the invention can fully utilize the occupied space of the whole structure of the equipment, save the labor input and improve the production and processing efficiency.)

1. The utility model provides a soldering tin ring pyrocondensation pipe equipment which characterized in that, puts the board including workstation, carousel and the device of laying up the distribution, the rotatable swing joint of carousel is in on the workstation, it puts the board connection to put the device on the workstation:

the turntable is provided with a plurality of workpiece molds, and at least part of the plurality of tool molds are arranged in an arc shape in the edge area of the turntable;

the mounting and placing plate comprises a tin ring feeding device, a heat shrinkable tube feeding device, a release agent smearing device, a heating forming device and at least two hot melt adhesive ring feeding devices, wherein the release agent smearing device, one of the hot melt adhesive ring feeding devices, the tin ring feeding device, the other hot melt adhesive ring feeding device, the heat shrinkable tube feeding device and the heating forming device are sequentially and annularly distributed on the mounting device placing plate.

2. The soldering tin ring heat shrinkable tube assembling device as claimed in claim 1, further comprising a rotation driving structure, wherein the rotation driving structure can pull the workpiece mold to make the workpiece mold autorotate.

3. The soldering tin ring heat shrinkable tube assembling device as claimed in claim 2, wherein the rotary driving structure comprises a rotary driving member and a transmission member, the rotary driving member is connected to the workbench and is in transmission connection with the transmission member, and the transmission member can pull the workpiece mold to rotate.

4. The soldering tin ring heat shrinkable tube assembling device as claimed in claim 3, wherein the workpiece mold comprises a support part, a rotating part, a positioning pin and a driven traction part, the driven traction part is in transmission connection with the rotary driving structure, the support part is connected to the turntable, a first end of the rotating part is connected with the driven traction part, a second end of the rotating part penetrates through the support part to be connected with the positioning pin, and the rotating part can pull the positioning pin to rotate.

5. A soldering tin ring heat shrinkable tube assembling device as claimed in claim 4, wherein the mounting device placing plate passes through the middle of the rotary table through a mounting shaft and is connected to the workbench; the end of the middle inner side of the rotary disc is movably connected to the mounting shaft, and the rotary disc rotates around the mounting shaft.

6. The soldering tin ring heat shrinkable tube assembling device as claimed in claim 1, wherein the thermoforming device comprises a heating assembly and a first support assembly, and the first support assembly is connected to the mounting device placing plate; the heating assembly comprises a hot air gun and a heat collection air cover, the height-adjustable type movable connection of the hot air gun is arranged on the first supporting assembly, the heat collection air cover is connected to the outlet of the hot air gun, and the outlet end of the heat collection air cover faces the workpiece die.

7. The solder ring heat shrink tube assembling equipment as claimed in claim 1, wherein the solder ring feeding device comprises a vibration disc, a third bracket and a second pushing assembly, the second pushing assembly is connected to a side end face of the vibration disc, and the vibration disc is connected to the mounting device placing plate;

the vibrating disc can convey the tin ring to the third support in a vibrating mode, and then the second pushing assembly pushes the tin ring on the third support to the workpiece die.

8. The soldering tin ring heat shrinkable tube assembling equipment as claimed in claim 1, wherein the hot melt adhesive ring feeding device comprises a first support, a first lower die, a first upper die, a first cutting assembly and a first pushing assembly, the first support is connected to the mounting device placing plate, the first lower die is connected to the lower end of the first support, and the first upper die is connected to the upper end of the first support and used for clamping a hot melt adhesive tube;

the first pushing assembly can clamp and push the clamped hot melt pipe to move to penetrate through the first lower die, and then the first cutting assembly drives the hot melt pipe penetrating through the first lower die to cut and fall to the workpiece die.

9. The soldering tin ring heat shrink tube assembling equipment as claimed in claim 1, wherein the heat shrink tube feeding device comprises a fourth support, a second cutting assembly, a second lower die, a second upper die and a third pushing assembly, the fourth support is connected to the mounting device placing plate, the second lower die is connected to the lower end face of the fourth support, and the second upper die is connected to the upper end face of the fourth support and used for clamping a heat shrink tube;

the third pushing assembly can push the clamped heat shrinkable tube to move through the second lower die, and then the second cutting assembly operates to cut the heat shrinkable tube penetrating through the second lower die, so that the heat shrinkable tube falls off to the workpiece die.

10. The solder ring heat shrink tube assembly equipment as claimed in claim 1, further comprising a cooling device located at an exit end of the rotary table in a rotation processing direction;

the cooling device comprises a blowing gun and a second supporting assembly, the second supporting assembly is connected to the placing plate of the placing device, and the blowing gun is movably connected to the second supporting assembly in a height-adjustable mode and is aligned to the workpiece mold.

Technical Field

The invention relates to the technical field of soldering tin ring heat-shrinkable tubes, in particular to soldering tin ring heat-shrinkable tube assembling equipment.

Background

The soldering tin ring heat-shrinkable tube is also called a soldering tin ring wire welding tube, and the soldering tin is connected with the heat-shrinkable tube, the soldering tin ring and the heat-shrinkable shielding soldering tin ring. The welding wire is formed by placing a section of hot melt adhesive ring on the left side and the right side of a low-melting-point welding tin ring at a certain distance respectively and then sleeving a section of heat-shrinkable tube outside. The method can replace the old construction method of electric soldering iron welding, can complete the connection of conductors, can protect the contacts from the influence of air oxidation and other corrosive gases, can prevent the contacts from contacting with each other, and can be widely applied to the fields of railways, ships, aerospace, power, electronics and the like. The wire connection, the shielding and the water prevention are completed at one time, and the device is safe and reliable.

However, the existing production equipment for the soldering tin ring heat shrinkable tube occupies a large space, is low in operation order and is low in working efficiency.

Disclosure of Invention

The invention mainly aims to provide soldering tin ring heat-shrinkable tube assembling equipment, which aims to reasonably utilize space and improve production efficiency.

The above problems to be solved by the present invention are achieved by the following technical solutions:

the utility model provides a soldering tin ring pyrocondensation pipe equipment, puts the board including workstation, carousel and the ann device of range upon range of distribution, the rotatable swing joint of carousel is in on the workstation, it puts the board connection to put the device on the workstation:

at least one workpiece die is arranged on the turntable;

the mounting and placing plate comprises a tin ring feeding device, a heat shrinkable tube feeding device, a release agent smearing device, a heating forming device and at least two hot melt adhesive ring feeding devices, wherein the release agent smearing device, one of the hot melt adhesive ring feeding devices, the tin ring feeding device, the other hot melt adhesive ring feeding device, the heat shrinkable tube feeding device and the heating forming device are sequentially and annularly distributed on the mounting device placing plate.

Preferably, the soldering tin ring heat shrink tube assembling equipment further comprises a rotary driving structure, and the rotary driving structure can pull the workpiece mold to enable the workpiece mold to rotate.

Preferably, the rotary driving structure comprises a rotary driving part and a transmission part, the rotary driving part is connected to the workbench and is in transmission connection with the transmission part, and the transmission part can pull the workpiece die to perform rotary motion.

Preferably, the workpiece mold comprises a supporting portion, a rotating portion, a positioning needle and a driven traction portion, the driven traction portion is in transmission connection with the rotary driving structure, the supporting portion is connected to the turntable, a first end of the rotating portion is connected with the driven traction portion, a second end of the rotating portion penetrates through the supporting portion to be connected with the positioning needle, and the rotating portion can pull the positioning needle to rotate.

Preferably, the mounting device placing plate penetrates through the middle part of the turntable through a mounting shaft and is connected to the workbench; the end of the middle inner side of the rotary disc is movably connected to the mounting shaft, and the rotary disc rotates around the mounting shaft.

Preferably, the heating forming device comprises a heating component and a first supporting component, and the first supporting component is connected to the placing plate of the placing device; the heating assembly comprises a hot air gun and a heat collection air cover, the height-adjustable type movable connection of the hot air gun is arranged on the first supporting assembly, the heat collection air cover is connected to the outlet of the hot air gun, and the outlet end of the heat collection air cover faces the workpiece die.

Preferably, the tin ring feeding device comprises a vibrating disc, a third support and a second pushing assembly, the second pushing assembly is connected to the side end face of the vibrating disc, and the vibrating disc is connected to the device placing plate;

the vibrating disc can convey the tin ring to the third support in a vibrating mode, and then the second pushing assembly pushes the tin ring on the third support to the workpiece die.

Preferably, the hot melt adhesive ring feeding device comprises a first support, a first lower die, a first upper die, a first cutting assembly and a first pushing assembly, the first support is connected to the mounting device placing plate, the first lower die is connected to the lower end of the first support, and the first upper die is connected to the upper end of the first support and used for clamping the hot melt adhesive pipe;

the first pushing assembly can clamp and push the clamped hot melt pipe to move to penetrate through the first lower die, and then the first cutting assembly drives the hot melt pipe penetrating through the first lower die to cut and fall to the workpiece die.

Preferably, the heat shrinkable tube feeding device comprises a fourth support, a second cutting assembly, a second lower die, a second upper die and a third pushing assembly, the fourth support is connected to the placing plate of the installing device, the second lower die is connected to the lower end face of the fourth support, and the second upper die is connected to the upper end face of the fourth support and used for clamping the heat shrinkable tube;

the third pushing assembly can push the clamped heat shrinkable tube to move through the second lower die, and then the second cutting assembly operates to cut the heat shrinkable tube penetrating through the second lower die, so that the heat shrinkable tube falls off to the workpiece die.

Preferably, the soldering tin ring heat shrink tube assembling equipment further comprises a cooling device, wherein the cooling device is positioned at an outlet end of the rotary table in the rotating and processing direction;

the cooling device comprises a blowing gun and a second supporting assembly, the second supporting assembly is connected to the placing plate of the placing device, and the blowing gun is movably connected to the second supporting assembly in a height-adjustable mode and is aligned to the workpiece mold.

Has the advantages that: according to the technical scheme, the soldering tin ring heat-shrinkable tube assembling equipment is classified and split into the workbench, the rotary table and the mounting device placing plates which are distributed in a stacked mode, so that the workbench, the rotary table for the machining process, the tin ring feeding device for machining, the heat-shrinkable tube feeding device, the release agent smearing device and the mounting placing plates of at least two hot melt adhesive ring feeding devices can be separated, the orderliness of machining and the stability of equipment placing are guaranteed, and the manual investment is saved; meanwhile, the specification of the whole structure of the equipment is greatly reduced, the space of the production environment is fully utilized, the structure is more compact and ordered, and the production and processing efficiency is improved.

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 description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic axial structure diagram of a solder ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 2 is a front sectional view of a part of the structure of the soldering tin ring heat shrinkable tube assembling device.

Fig. 3 is a schematic structural diagram of a transmission part of a rotation driving device of a solder ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 4 is a schematic structural diagram of a mold release agent application device of the solder ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 5 is a schematic structural diagram of a hot melt adhesive ring feeding device of the solder ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 6 is a schematic structural diagram of a workpiece positioning device of a solder ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 7 is a schematic structural diagram of a solder ring feeding device of the solder ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 8 is a schematic structural diagram of a heat shrinkable tube feeding device of the solder ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 9 is a schematic structural diagram of a thermoforming device of the soldering tin ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 10 is a schematic structural diagram of a cooling device of the solder ring heat shrinkable tube assembling apparatus according to the present invention.

Fig. 11 is a schematic structural diagram of a discharging device of the solder ring heat shrinkable tube assembling apparatus according to the present invention.

The reference numbers illustrate: 100-a workbench; 201-installing a device placing plate; 200-a turntable mechanism; 202-a turntable; 203-a turntable drive motor; 204-a transmission; 2041-a first connecting shaft; 2042 — drive wheel section; 2043-main traction sheave portion; 205-workpiece die; 2051-a support; 2052-a rotating part; 2053-driven traction part; 2054-positioning needle; 300-a release agent application device; 301-a first support shaft; 302-a first mounting plate; 3021-oil reservoir; 303-oil absorption plate; 3031-a guide channel; 400-hot melt adhesive ring feeding device; 401-a first scaffold; 402-a first cutting knife; 403-first lower die; 404-a first drive cylinder; 405-a first upper die; 406-a first gripper cylinder; 407-a first feed cylinder; 408-hot melt hose; 500-a workpiece positioning device; 501-a second bracket; 502-positioning the drive; 503-positioning sleeve seats; 504-a positioning sleeve; 600-a tin ring feeding device; 602-vibrating a disc; 6021-a flow channel; 603-a third scaffold; 6031-loading gap; 6032-feed channel; 604-a second feed cylinder; 605-a first pusher block; 700-a heat shrinkable tube feeding device; 701-a fourth bracket; 702-a second cutting knife; 703-a second lower die; 704-a second drive cylinder; 705-a limit shaft; 706-adjusting the spring; 707-an adjustment axis; 708-heat shrink tubing; 709-a second upper die; 710-a feed wheel; 711-pinch rollers; 712-a feed motor; 800-a thermoforming device; 801-a heating assembly; 8011-Heat gun; 8012-heat collecting hood; 803 — a first support assembly; 8031-a first support block; 8032-a first conditioning block; 8033-a second support shaft; 8034-a second connecting shaft; 900-a cooling device; 901-air blowing gun; 902-a second support assembly; 9021-a second support block; 9022-a second regulating block; 1000-a discharge device; 1001-rotation adjustment; 1003-fifth carriage; 1004-height adjustment; 1005-discharge clamp.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture, and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, if the meaning of "and/or" and/or "appears throughout, the meaning includes three parallel schemes, for example," A and/or B "includes scheme A, or scheme B, or a scheme satisfying both schemes A and B. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The invention provides a soldering tin ring heat-shrinkable tube assembling device.

As shown in fig. 1-2, in one embodiment of the present invention, the solder ring heat shrink tube assembly apparatus; including the workstation 100, carousel 202 and the installation of range upon range of distribution place board 201, the rotatable swing joint of carousel 202 is in on the workstation 100, it connects to place board 201 on the workstation 100 to install the device:

at least one workpiece die 205 is arranged on the turntable 202;

the mounting device placing plate 201 comprises a tin ring feeding device 600, a heat shrinkable tube feeding device 700, a release agent smearing device 300 and at least two hot melt adhesive ring feeding devices 400, wherein the release agent smearing device 300, one of the hot melt adhesive ring feeding devices 400, the tin ring feeding device 600, the other of the hot melt adhesive ring feeding devices 400 and the heat shrinkable tube feeding device 700 are annularly distributed on the mounting device placing plate 201.

In this embodiment, the release agent coating device 300, one of the hot melt adhesive ring feeding devices 400, the solder ring feeding device 600, the other of the hot melt adhesive ring feeding devices 400 and the heat shrinkable tube feeding device 700 are sequentially and annularly distributed on the installation device placing plate 201.

According to the technical scheme, the soldering tin ring heat-shrinkable tube assembling equipment is classified and split into the workbench 100, the turntable 202 and the mounting placement plates 201 which are distributed in a stacked mode, so that the workbench, the turntable used for the machining process, the tin ring feeding device used for machining, the heat-shrinkable tube feeding device, the release agent smearing device and the mounting placement plates of at least two hot melt adhesive ring feeding devices can be separated, the orderliness of machining and the stability of equipment placement are guaranteed, and the labor input is saved; meanwhile, the specification of the whole structure of the equipment is greatly reduced, the space of the production environment is fully utilized, the structure is more compact and ordered, and the production and processing efficiency is improved.

The stacking distribution may be a stacking distribution in the transverse direction or a stacking distribution in the longitudinal direction.

Specifically, as shown in fig. 1, in the present embodiment, the turntable 202 is located above the table 100 in the vertical direction, and the mounting device placement plate 201 is located above the turntable 202 along the vertical direction of the table 100; the horizontal transverse space of the equipment placing environment can be effectively reduced through the vertical distribution installation mode, the smoothness of processing can be guaranteed, and the overall production efficiency is improved.

In this embodiment, two hot melt adhesive ring feeding devices 400 are selected, one tin ring feeding device 600 is selected, one heat shrink tube feeding device 700 is selected, and the first hot melt adhesive ring feeding device 400, the second hot melt adhesive ring feeding device 600, the other hot melt adhesive ring feeding device 400, and the heat shrink tube feeding device 700 are sequentially arranged on the mounting device placing plate 201 from the beginning to the end of the processing along the rotation direction of the turntable 202; and then the heat shrinkable tube can be sequentially processed into a hot melt adhesive ring layer, a tin ring layer, another hot melt adhesive ring layer and a heat shrinkable tube layer from top to bottom.

Specifically, as shown in fig. 1, the soldering tin ring heat shrinkable tube assembling apparatus further includes a heating and forming device 800 and a cooling device 900, the heating and forming device 800 and the cooling device 900 are respectively connected to the mounting device placing plate 201, and the heating and forming device 800 and the cooling device 900 are sequentially distributed at an outlet end of the rotating disc in the rotating processing direction.

In an embodiment, as shown in fig. 9, the thermoforming apparatus 800 includes a heating assembly 801 and a first supporting assembly 803, and the first supporting assembly 803 is connected to the mounting apparatus placing plate 201; the heating assembly 801 comprises a heat gun 8011 and a heat collecting hood 8012, the heat gun 8011 is movably connected to the first supporting assembly 803 in a height adjustable manner, the heat collecting hood 8012 is connected to an outlet of the heat gun 8011, and an outlet end of the heat collecting hood 8012 faces to the workpiece mold 205; in an embodiment of the present invention, the first supporting component 803 includes a first supporting block 8031, a first adjusting block 8032, a second supporting shaft 8033 and a second connecting shaft 8034, the second supporting shaft 8033 is connected to the mounting device placing plate 21, the first adjusting block 8032 is movably connected to the outer wall of the second supporting shaft 8033, a first end of the second connecting shaft 8034 is connected to a first side end face of the first adjusting block 8032, a second end of the second connecting shaft 8034 is connected to a first side end face of the first supporting block 8031, and the heat gun 8011 is telescopically and movably connected to the first supporting block 8031. The distance between the horizontal position and the vertical position of the hot air gun and the workpiece mould 205 can be adjusted through the first supporting block and the first adjusting block, when the rotary disc rotates, the mould can pass through the heat collection fan cover 8012, and when the rotary disc stops, the mould just stops in the heat collection fan cover 8012, and the product can be heated and molded at constant temperature.

In one embodiment, as shown in fig. 10, the cooling device 900 includes a blowing gun 901 and a second support assembly 902, the second support assembly 902 is connected to the mounting plate 201, and the blowing gun 901 is movably connected to the second support assembly 902 in a height adjustable manner and aligned with the workpiece mold 205.

In one embodiment, the second support assembly 902 includes a second support block 9021 and a second adjusting block 9022, the second support block 9021 is connected to the mounting device placing plate 21, the second adjusting block 9022 is connected to a first end surface of the second support block 9021, and an adjusting cavity is disposed in the second adjusting block 9022, and is used for fixing the blowing gun 901 and adjusting the height position of the blowing gun 901. Compressed air is connected to the one end of the air blowing gun, a vertical long and narrow gap is formed in the other end of the air blowing gun, the compressed air is sprayed out through the gap, and the gap is adjusted to the product through the height position of the air blowing gun, so that the product is cooled.

Specifically, as shown in fig. 1 to 3, the solder ring heat shrinkable tube assembling apparatus further includes a rotary driving structure, where the rotary driving structure includes a rotary driving element and a transmission element 204, the rotary driving element is connected to the workbench 100 and is in transmission connection with the transmission element 204, and the transmission element 204 can pull the workpiece mold 205 to perform a rotary motion. The installation area of the transmission member 204 at least includes the area between the thermoforming device 800 and the discharging device 1000, that is, a plurality of transmission members 204 are installed on the worktable 100 and are arranged below the turntable mechanism 200 along the arc-shaped edge of the turntable mechanism in an arc shape. The workpiece mold 205 is supported by the turntable mechanism 200, and the lower end of the workpiece mold 205 is driven by the transmission member 204 in a rotating friction or engagement manner, so as to drive the component for positioning the semi-finished solder ring at the upper end to rotate. Thus, the transmission member 204 drives the workpiece mold 205 to rotate when the semi-finished solder ring is to be heated by the heat forming device 800, so that the semi-finished solder ring is heated uniformly. Before entering the unloading device 1000, the semi-finished solder ring is not stopped and is cooled by the driving member 204 driving the workpiece mold 205 to rotate.

In other words, in the present embodiment, as shown in fig. 2, the rotary driving member is connected to the upper surface of the working table 100, the workpiece dies 205 are distributed in a ring shape and connected to the turntable 202, the rotary driving member drives the transmission member 204 to move, and the transmission member 204 pulls the workpiece dies 205 to rotate.

In the present embodiment, the mounting device placing plate 201 is connected to the worktable 100 through a mounting shaft passing through the middle of the turntable 202; the middle inner end of the turntable 202 is movably connected to the mounting shaft, and the turntable 202 rotates around the mounting shaft. The transverse and longitudinal supports of the turntable 202 can guarantee the stability of the installation and operation of the turntable 202 and the stability of processing.

In one embodiment, the turntable 202 is driven by a first driving motor to rotate a first rotating member, and the first rotating member passes through the middle portion and the side wall of the mounting shaft to drive the turntable 202 to rotate.

In the present embodiment, as shown in fig. 2 to 3, the rotary driving member may be a turntable driving motor 203, the turntable driving motor 203 is connected to the worktable 100 and is in transmission connection with the transmission member 204, and the transmission member 204 can drive the workpiece mold 205 to rotate; the turntable driving motor 203 may be a DD motor, a cam divider, or a servo hollow rotary platform.

In one embodiment, as shown in fig. 3, the turntable driving motor 203 is a DD motor; the transmission member 204 comprises a driving wheel portion 2042, a first connecting shaft 2041 and a main traction wheel portion 2043, a first end of the first connecting shaft 2041 is connected with the main traction wheel portion 2043, a second end of the first connecting shaft 2041 is connected with the driving wheel portion 2042, the driving wheel portion 2042 is in transmission connection with the turntable driving motor 203, and the main traction wheel portion 2043 is in transmission connection with the workpiece mold 205; the turntable 202 can be precisely driven to rotate by a specific angle through the DD motor rotor, so that each die on the turntable can be precisely stopped on a working station every time, and the circular circulation of the die on each working station is realized.

Specifically, as shown in fig. 3, the workpiece mold 205 includes a supporting portion 2051, a rotating portion 2052, a positioning pin 2054 and a driven pulling portion 2053, the driven pulling portion 2053 is in transmission connection with the main pulling wheel portion 2043, the supporting portion 2051 is connected to the turntable 202, a first end of the rotating portion 2052 is connected to the driven pulling portion 2053, and a second end of the rotating portion 2052 passes through the supporting portion 2051 to be connected to the positioning pin 2054; when the turntable 202 moves to the heating and forming device 800, the rotation of the rotating part 2052 drives the positioning pins 2054 to rotate, so that the formed product is heated more uniformly in the heating and assembling process, and the phenomenon that the processed product becomes a defective product due to nonuniform heating is avoided.

Specifically, as shown in fig. 5, the hot melt adhesive ring feeding device 400 includes a first support 401, a first lower mold 403, a first upper mold 405, a first cutting assembly and a first pushing assembly, the first support 401 is connected to the mounting device placing plate 201, the first lower mold 403 is connected to the lower end of the first support 401, the first upper mold 405 is connected to the upper end of the first support 401 and is used for clamping the hot melt adhesive tube 408, the first pushing assembly can clamp and push the clamped hot melt adhesive tube 408 to move through the first lower mold 403, and the hot melt adhesive tube 408 passing through the first lower mold 403 is cut and dropped to the workpiece mold 205 by the driving of the first cutting assembly.

In one embodiment, the first cutting assembly includes a first cutting blade 402 and a first driving cylinder 404, the first driving cylinder 404 is fixed on the first support 401 and is in driving connection with the first cutting blade 402, and the first cutting blade 402 can move telescopically to cut off the hot melt tube 408 passing through the first lower die 403 through the gap of the first lower die 403.

In one embodiment, the first pushing assembly includes a first clamping cylinder 406 and a first feeding cylinder 407, the first feeding cylinder 407 is connected to the first bracket 401, the first clamping cylinder 406 is connected to a telescopic shaft of the first feeding cylinder 407, and the clamping shaft of the first clamping cylinder 406 is retractable to clamp the hot melt tube 408.

When the hot melt adhesive ring clamping device works, the hot melt adhesive pipe is clamped by the first clamping cylinder, the first feeding cylinder extends out to realize fixed-length feeding of the hot melt adhesive pipe, and the up-and-down movement distance of the feeding cylinder can be adjusted by the differential head, so that the width of the hot melt adhesive ring is adjusted.

Specifically, as shown in fig. 7, the tin ring feeding device 600 includes a vibration disk 602, a third support 603, and a second pushing assembly, where the second pushing assembly is connected to a side end surface of the vibration disk 602, and the vibration disk 602 is connected to the mounting device placing plate 201; the vibrating plate 602 can vibrate to convey a tin ring to the third support 603, and the second pushing assembly pushes the tin ring on the third support 603 to the workpiece mold 205;

in the present embodiment, a material outlet channel 6021 is provided on the vibration plate 602; a feeding gap 6031 is formed in the third support 603, the feeding gap 6031 is communicated with an outlet of the discharging channel 6021, and the second pushing assembly can push the tin ring on the third support 603 to the feeding channel 6032 so that the tin ring falls to the workpiece mold 205;

in the embodiment, the second pushing assembly comprises a second feeding cylinder 604 and a first pushing block 605, wherein the second feeding cylinder 604 is connected to the third bracket 603 and is in transmission connection with the first pushing block 605; the first material pushing block 605 is provided with a feeding channel 6032, and the feeding channel 6032 is aligned with the feeding gap 6031.

During operation, the vibrating disc sends the tin ring into the feeding notch through the discharging channel, finally stops in the feeding channel of the first material pushing block, the air cylinder rod extends out, and due to the action of gravity, the tin ring falls from the ring falling opening and is sleeved on the workpiece mold 205 which is opposite to the ring falling opening.

Specifically, as shown in fig. 8, the heat shrinkable tube feeding device 700 includes a fourth support 701, a second cutting assembly, a second lower mold 703, a second upper mold 709, and a third pushing assembly, where the fourth support 701 is connected to the mounting device placing plate 201, the second lower mold 703 is connected to a lower end surface of the fourth support 701, the second upper mold 709 is connected to an upper end surface of the fourth support 701 and is configured to clamp a heat shrinkable tube 708, the third pushing assembly can push the clamped heat shrinkable tube 708 to move through the second lower mold 703, and the second cutting assembly operates to cut the heat shrinkable tube 708 passing through the second lower mold 703, so that the heat shrinkable tube 708 falls off to the workpiece mold 205.

In this embodiment, the third pushing assembly includes a second cutting blade 702 and a second driving cylinder 704, the second driving cylinder 704 is connected to the fourth support 701 and is in driving connection with the second cutting blade 702, and the second cutting blade 702 can move to a cutting gap of the second lower die 703 to cut the heat shrinkable tube 708.

In one embodiment, the third pushing assembly includes a feeding motor 712, a feeding wheel 710 and an adjusting structure, the feeding motor 712 is connected to the fourth support 701 and is in transmission connection with the feeding wheel 710, the adjusting structure is movably connected to the fourth support 701, and the heat shrinkable tube 708 can pass through between the feeding wheel 710 and the adjusting structure; in one embodiment, the adjusting structure includes a limiting shaft 705, an adjusting spring 706, an adjusting shaft 707 and a pressing wheel 711, the pressing wheel 711 is matched with the feeding wheel 710 to enable the heat shrinkable tube 708 to move straightly, a first end of the adjusting shaft 707 is connected with the pressing wheel 711, a second end of the adjusting shaft 707 is connected with a first end of the adjusting spring 706, a second end of the adjusting spring 706 is connected with a first end of the limiting shaft 705, and a second end of the limiting shaft 705 is connected to the fourth bracket 701; in other words, the limit shaft 705, the adjustment spring 706 and the adjustment shaft 707 form an adjustment swing joint.

Specifically, as shown in fig. 1, the product conveying structure further includes at least one workpiece positioning device 500, and the workpiece positioning device 500 is installed between one of the hot melt adhesive ring feeding devices 400 and the solder ring feeding device 600, and/or between one of the solder ring feeding devices 600 and the other of the hot melt adhesive ring feeding devices 400, and/or between the other of the hot melt adhesive ring feeding devices 400 and the heat shrinkable tube feeding device 700.

As shown in fig. 6, the workpiece positioning device 500 includes a second bracket 501, a positioning driving member 502, a positioning sleeve seat 503, and a positioning sleeve 504, the second bracket 501 is connected to the mounting device placing plate 201, the positioning driving member 502 is connected to the second bracket 501, and a driving shaft of the positioning driving member 502 is in driving connection with the positioning sleeve seat 503, and the positioning sleeve 504 is located on the positioning sleeve seat 503 and can be moved to the workpiece mold 205 to press and position the raw material on the workpiece mold 205. During operation, different positioning sleeves can be replaced according to different products, one positioning differential head can be fixed on the positioning sleeve seat, the extending length of the positioning differential head is adjusted, and the downward moving position of the positioning sleeve seat can be accurately adjusted, so that the material sleeved on the workpiece mold in the previous process can be accurately pushed into the corresponding position of the mold.

Specifically, as shown in fig. 1, the product conveying structure further comprises a discharging device 1000, and the discharging device 1000 is connected to the mounting device placing plate 201 and is located at the outlet end of the rotation processing direction of the processing layer.

In the present embodiment, as shown in fig. 11, the discharging device 1000 includes a rotation adjusting member 1001, a fifth holder 1003, a height adjusting member 1004, and a discharging clamp 1005, the rotation adjusting member 1001 is connected to the mounting device mounting plate 201, a first end surface of the fifth holder 1003 is connected to a rotation shaft of the rotation adjusting member 1001, the height adjusting member 1004 is connected to a second end surface of the fifth holder 1003, an adjusting shaft of the height adjusting member 1004 is connected to the discharging clamp 1005, and a clamping shaft of the discharging clamp 1005 can clamp and move a processed product to a next apparatus. In one embodiment, the discharge clamping member 1005 is a clamping cylinder, the height adjusting member 1004 is a lifting cylinder, and the rotation adjusting member 1001 is a rotation cylinder; during operation, the rotary cylinder swings to one side, the center of the clamping cylinder is aligned with the workpiece mold, the lifting cylinder descends, the clamping cylinder clamps a product on the workpiece mold, the lifting cylinder ascends, the product on the workpiece mold is taken out, then the product is swung back to the position above the discharge opening, the clamping cylinder is loosened, the product falls, and the material taking process is completed.

Specifically, in the present embodiment, as shown in fig. 4, the mold release agent application device 300 includes a first support shaft 301, a first mounting plate 302, and an oil suction plate 303, the first support shaft 301 is connected to the mounting device placing plate 201, the first mounting plate 302 is provided with an oil reservoir 3021 and a first end surface of the first mounting plate 302 is connected to a side end surface of the first support shaft 301, the oil suction plate 303 is provided with a guide groove 3031 and the oil suction plate 303 is obliquely connected to a second end surface of the first mounting plate 302, and the guide groove 3031 communicates with the oil reservoir 3021. The oil storage tank can store liquid release agent, one side of the oil storage tank close to the flexible oil absorption plate is provided with the guide groove, the liquid release agent can be adsorbed on the flexible oil absorption plate through the guide groove, and when the turntable drives the workpiece mold to stop at the station, the workpiece mold rotates close to the flexible oil absorption plate, so that the release agent is uniformly coated.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.