CN214383563U - Double-station high-speed interaction mechanism - Google Patents
Double-station high-speed interaction mechanism Download PDFInfo
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- CN214383563U CN214383563U CN202022994532.5U CN202022994532U CN214383563U CN 214383563 U CN214383563 U CN 214383563U CN 202022994532 U CN202022994532 U CN 202022994532U CN 214383563 U CN214383563 U CN 214383563U
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Abstract
A double-station high-speed interaction mechanism relates to the field of moving mechanisms in high-speed laminating equipment and comprises a driving assembly, a guide assembly, a first conveying assembly and a second conveying assembly; two groups of guide assemblies are arranged; the first conveying assembly and the second conveying assembly are driven by the driving assembly and move reversely and in a staggered mode along the group of guide assemblies respectively. The utility model realizes the synchronous rotation of the first rotating shaft and the second rotating shaft by the drive of a single motor and the matching of a transmission element, finally drives the first station and the second station to convey materials, and reduces the equipment cost; set up first station and the reverse synchronous defeated material of second station, reduce the time of waiting to through lifting member, gyro wheel and lift platform cooperation, solve the crisscross problem in duplex position, shorten the cycle of material change.
Description
Technical Field
The utility model relates to a moving mechanism field in the high-speed laminating class equipment especially relates to a high-speed mutual mechanism in duplex position.
Background
In the non-standard industry with increasingly strong competition, the requirements of customers on non-standard equipment are increasingly strict, and the customers require the equipment to be fast and stable. The designed mechanism has simple structure and can not be too complex. Although the existing single-station structure can meet the functional requirements of equipment, in high-speed laminating equipment, sometimes materials are conveyed by the single station, the working period of the equipment is influenced, if a structure which is the same as the structure is added, the working period of the equipment is shortened, the spatial layout of the equipment is enlarged, and the cost is increased.
SUMMERY OF THE UTILITY MODEL
Objects of the invention
For solving the technical problem who exists among the background art, the utility model provides a high-speed interactive mechanism in duplex position. The utility model realizes the synchronous rotation of the first rotating shaft and the second rotating shaft by the drive of a single motor and the matching of a transmission element, finally drives the first station and the second station to convey materials, and reduces the equipment cost; set up first station and the reverse synchronous defeated material of second station, reduce the time of waiting to through lifting member, gyro wheel and lift platform cooperation, solve the crisscross problem in duplex position, shorten the cycle of material change.
(II) technical scheme
In order to solve the problems, the utility model provides a double-station high-speed interaction mechanism, which comprises a driving component, a guiding component, a first conveying component and a second conveying component; two groups of guide assemblies are arranged; the first conveying assembly and the second conveying assembly are driven by the driving assembly and respectively move along the group of guide assemblies in a reverse and staggered manner; the guide assembly comprises a guide frame and a lead screw rotatably arranged on the guide frame; the driving assembly comprises a motor, a synchronizing wheel, a first transmission belt, a first transmission shaft, a first rotating shaft, a second transmission belt and a second rotating shaft; the synchronous wheel is connected with a main shaft of the motor through a key; the first transmission belt is sleeved with the synchronizing wheel and the first transmission shaft; the first rotating shaft and the second rotating shaft are connected with the two groups of screw rods in a one-to-one correspondence manner; the second transmission belt is sleeved with the first transmission shaft, the first rotating shaft and the second rotating shaft; the first conveying assembly comprises a first moving part and a first conveying plate; the first moving piece moving along the guide frame on one side is in threaded connection with the lead screw; the first material conveying plate is arranged at the upper end of the first moving part, and a first station is arranged on the first material conveying plate; the second conveying assembly comprises a second moving part, a second conveying plate, a sliding rail, a lifting part, a roller and a lifting platform; the second moving piece moving along the guide frame on the other side is in threaded connection with the screw rod; the sliding rail is arranged on the second moving piece along the vertical direction; the lifting piece is connected with the sliding rail in a sliding manner; the second material conveying plate is arranged at the upper end of the lifting piece, and a second station is arranged on the second material conveying plate; the lifting platform is arranged at the outer sides of the two groups of guide frames; the gyro wheel sets up the lower extreme at the lift, and when first defeated flitch and second defeated flitch dislocation, the gyro wheel roll connection lift platform.
Preferably, the drive assembly further comprises a second drive shaft; the positions of the first transmission shaft, the second transmission shaft and the second rotating shaft form a triangle; one end of the second transmission belt is sequentially sleeved on the first transmission shaft, the second transmission shaft and the second rotating shaft to form a bending section, and the other end of the second transmission belt is sleeved on the first rotating shaft.
Preferably, the second drive belt is a double-toothed timing belt.
Preferably, the drive assembly further comprises a mount; the mounting seat is arranged on the group of guide frames; synchronizing wheel, first transmission shaft, second transmission shaft and second pivot rotate to set up on the mount pad.
Preferably, the starting end and the terminal end of the lifting platform are both provided with slopes; a platform is arranged between the two groups of slopes and forms a trapezoidal structure with the platform.
Preferably, the two sets of screws are provided with opposite threads.
Preferably, the second conveying assembly further comprises a tension spring; the lower extreme of extension spring is connected the second moving member, and the upper end is connected the lift piece.
Preferably, the first conveyor assembly further comprises a support platform; the supporting platform is arranged at the other side of the two groups of guide frames corresponding to the lifting platform; when the first material conveying plate is positioned at the position where the second material conveying plate is staggered, the first material conveying plate is connected with the supporting platform in a sliding mode.
The above technical scheme of the utility model has following profitable technological effect:
the utility model realizes the synchronous rotation of the first rotating shaft and the second rotating shaft by the drive of a single motor and the matching of a transmission element, finally drives the first station and the second station to convey materials, and reduces the equipment cost;
two, the utility model discloses set up first station and the defeated material of second station reversal synchronization, reduce the time of waiting to through lift piece, gyro wheel and lift platform cooperation, solve the crisscross problem in duplex position, shorten the cycle that the material was changed.
Drawings
Fig. 1 is a schematic structural diagram of a first viewing angle of the double-station high-speed interaction mechanism provided by the utility model.
Fig. 2 is a schematic structural diagram of a second viewing angle of the double-station high-speed interaction mechanism provided by the utility model.
Fig. 3 is an enlarged view of a position a in the double-station high-speed interaction mechanism provided by the present invention.
The attached drawings are marked as follows: 1. a drive assembly; 101. a motor; 102. a synchronizing wheel; 103. a first drive belt; 104. a first drive shaft; 105. a first rotating shaft; 106. a second belt; 107. a second drive shaft; 108. a second rotating shaft; 2. a guide assembly; 201. a guide frame; 202. a lead screw; 3. a first conveying assembly; 301. a first moving member; 302. a first material conveying plate; 303. a support platform; 4. a second transport assembly; 401. a second moving member; 402. a second material conveying plate; 403. a slide rail; 404. a lifting member; 405. a roller; 406. a lifting platform; 407. a tension spring.
Detailed Description
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.
As shown in fig. 1-3, the double-station high-speed interaction mechanism provided by the present invention comprises a driving assembly 1, a guiding assembly 2, a first conveying assembly 3 and a second conveying assembly 4; two groups of guide assemblies 2 are arranged; the first conveying assembly 3 and the second conveying assembly 4 are both driven by the driving assembly 1 and respectively move along the group of guide assemblies 2 in a reverse direction and in a staggered manner; the guide assembly 2 comprises a guide frame 201 and a lead screw 202 rotatably arranged on the guide frame 201; the driving assembly 1 comprises a motor 101, a synchronous wheel 102, a first transmission belt 103, a first transmission shaft 104, a first rotating shaft 105, a second transmission belt 106 and a second rotating shaft 108; the synchronizing wheel 102 is keyed to the main shaft of the motor 101; a first transmission belt 103 is sleeved with the synchronous wheel 102 and a first transmission shaft 104; the first rotating shaft 105 and the second rotating shaft 108 are correspondingly connected with the two groups of lead screws 202 one by one; the second transmission belt 106 is sleeved with the first transmission shaft 104, the first rotating shaft 105 and the second rotating shaft 108; the first conveying assembly 3 comprises a first moving part 301 and a first conveying plate 302; a first moving member 301 moving along the one-side guide frame 201 is threadedly connected with the lead screw 202; the first material conveying plate 302 is arranged at the upper end of the first moving part 301, and a first station is arranged on the first material conveying plate 302; the second conveying assembly 4 comprises a second moving part 401, a second conveying plate 402, a slide rail 403, a lifting part 404, a roller 405 and a lifting platform 406; a second moving member 401 moving along the other side guide frame 201 is in threaded connection with the lead screw 202; the slide rail 403 is arranged on the second moving member 401 in the vertical direction; the lifting piece 404 is slidably connected with the sliding rail 403; the second material conveying plate 402 is arranged at the upper end of the lifting piece 404, and a second station is arranged on the second material conveying plate 402; the lifting platform 406 is arranged at the outer sides of the two groups of guide frames 201; the roller 405 is disposed at a lower end of the elevating member 404, and the roller 405 is rollingly coupled to the elevating platform 406 when the first material transferring plate 302 and the second material transferring plate 402 are misaligned.
In an alternative embodiment, the drive assembly 1 further comprises a second transmission shaft 107; the positions of the first transmission shaft 104, the second transmission shaft 107 and the second rotating shaft 108 form a triangle; one end of the second transmission belt 106 is sequentially sleeved on the first transmission shaft 104, the second transmission shaft 107 and the second rotating shaft 108 to form a bent section, and the other end is sleeved on the first rotating shaft 105.
In an alternative embodiment, the second drive belt 106 is a double-toothed timing belt.
In an alternative embodiment, the drive assembly 1 further comprises a mounting seat; the mounting seats are arranged on a group of guide frames 201; the synchronizing wheel 102, the first transmission shaft 104, the second transmission shaft 107 and the second rotating shaft 108 are rotatably arranged on the mounting seat.
In an alternative embodiment, the beginning and ending ends of the lift platform 406 are each provided with a ramp; a platform is arranged between the two groups of slopes and forms a trapezoidal structure with the platform.
In an alternative embodiment, opposing threads are provided on both sets of lead screws 202.
In an alternative embodiment, the second conveyor assembly 4 further comprises a tension spring 407; the lower end of the tension spring 407 is connected with the second moving part 401, and the upper end is connected with the lifting part 404.
In an alternative embodiment, the first conveyor assembly 3 further comprises a support platform 303; the supporting platform 303 is arranged at the other side of the two groups of guide frames 201 corresponding to the lifting platform 406; the first material conveying plate 302 is slidably connected with the supporting platform 303 when the second material conveying plate 402 is dislocated.
When materials are conveyed, the driving assembly 1 acts, the motor 101 drives the synchronizing wheel 102 to rotate, the first transmission shaft 104 rotates after being transmitted by the first transmission belt 103, and the second transmission belt 106 transmits, so that the first rotating shaft 105 and the second rotating shaft 108 synchronously rotate, and further two groups of lead screws 202 synchronously rotate; then, the first material conveying plate 302 and the second material conveying plate 402 filled with materials start from two ends of the guide frame 201 respectively, reverse movement is started along the guide frame 201, when the materials move to the position of the lifting platform 406, the roller 405 moves upwards to the platform along the slope on one side, the second material conveying plate 402 is lifted and staggered with the first material conveying plate 302, the roller 405 moves downwards along the slope on the other side, the second material conveying plate 402 is reset, once dislocation is completed, reverse feeding can be continued, and materials are replaced.
It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.
Claims (8)
1. A double-station high-speed interaction mechanism is characterized by comprising a driving assembly (1), a guide assembly (2), a first conveying assembly (3) and a second conveying assembly (4); two groups of guide assemblies (2) are arranged; the first conveying assembly (3) and the second conveying assembly (4) are driven by the driving assembly (1) and respectively move along the group of guide assemblies (2) in a reverse and staggered mode;
the guide assembly (2) comprises a guide frame (201) and a lead screw (202) rotatably arranged on the guide frame (201);
the driving assembly (1) comprises a motor (101), a synchronous wheel (102), a first transmission belt (103), a first transmission shaft (104), a first rotating shaft (105), a second transmission belt (106) and a second rotating shaft (108); the synchronizing wheel (102) is connected with a main shaft of the motor (101) by a key; the first transmission belt (103) is sleeved with the synchronous wheel (102) and the first transmission shaft (104); the first rotating shaft (105) and the second rotating shaft (108) are correspondingly connected with the two groups of lead screws (202) one by one; the second transmission belt (106) is sleeved with the first transmission shaft (104), the first rotating shaft (105) and the second rotating shaft (108);
the first conveying assembly (3) comprises a first moving part (301) and a first conveying plate (302); a first moving piece (301) moving along the guide frame (201) on one side is in threaded connection with a lead screw (202); the first material conveying plate (302) is arranged at the upper end of the first moving part (301), and a first station is arranged on the first material conveying plate (302);
the second conveying assembly (4) comprises a second moving part (401), a second conveying plate (402), a sliding rail (403), a lifting part (404), a roller (405) and a lifting platform (406); a second moving piece (401) moving along the guide frame (201) at the other side is in threaded connection with the lead screw (202); the sliding rail (403) is arranged on the second moving part (401) along the vertical direction; the lifting piece (404) is connected with the sliding rail (403) in a sliding manner; the second material conveying plate (402) is arranged at the upper end of the lifting piece (404), and a second station is arranged on the second material conveying plate (402); the lifting platform (406) is arranged at the outer sides of the two groups of guide frames (201); the roller (405) is arranged at the lower end of the lifting piece (404), and when the first material conveying plate (302) and the second material conveying plate (402) are staggered, the roller (405) is connected with the lifting platform (406) in a rolling mode.
2. The double-station high-speed interaction mechanism according to claim 1, characterized in that the drive assembly (1) further comprises a second transmission shaft (107); the positions of the first transmission shaft (104), the second transmission shaft (107) and the second rotating shaft (108) form a triangle; one end of a second transmission belt (106) is sequentially sleeved on the first transmission shaft (104), the second transmission shaft (107) and the second rotating shaft (108) to form a bent section, and the other end of the second transmission belt is sleeved on the first rotating shaft (105).
3. The dual-station high-speed interaction mechanism according to claim 1, wherein the second belt (106) is a double-sided toothed timing belt.
4. The double-station high-speed interaction mechanism according to claim 2, characterized in that the drive assembly (1) further comprises a mounting seat; the mounting seats are arranged on a group of guide frames (201); the synchronizing wheel (102), the first transmission shaft (104), the second transmission shaft (107) and the second rotating shaft (108) are rotatably arranged on the mounting seat.
5. The double-station high-speed interaction mechanism according to claim 1, wherein a slope is arranged at the starting end and the ending end of the lifting platform (406); a platform is arranged between the two groups of slopes and forms a trapezoidal structure with the platform.
6. The double-station high-speed interaction mechanism according to claim 1, wherein two sets of lead screws (202) are provided with reverse threads.
7. The double-station high-speed interaction mechanism according to claim 1, wherein the second conveyor assembly (4) further comprises a tension spring (407); the lower end of the tension spring (407) is connected with the second moving part (401), and the upper end is connected with the lifting part (404).
8. The double-station high-speed interaction mechanism according to claim 1, characterized in that the first conveyor assembly (3) further comprises a support platform (303); the supporting platform (303) is arranged at the other side of the two groups of guide frames (201) corresponding to the position of the lifting platform (406); the first material conveying plate (302) is connected with the supporting platform (303) in a sliding mode when the second material conveying plate (402) is staggered.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN202022994532.5U CN214383563U (en) | 2020-12-14 | 2020-12-14 | Double-station high-speed interaction mechanism |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
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CN202022994532.5U CN214383563U (en) | 2020-12-14 | 2020-12-14 | Double-station high-speed interaction mechanism |
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CN214383563U true CN214383563U (en) | 2021-10-12 |
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CN202022994532.5U Active CN214383563U (en) | 2020-12-14 | 2020-12-14 | Double-station high-speed interaction mechanism |
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CN (1) | CN214383563U (en) |
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2020
- 2020-12-14 CN CN202022994532.5U patent/CN214383563U/en active Active
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