CN218230506U - Transfer device for computer hardware production - Google Patents

Abstract

The utility model discloses a transfer device for computer hardware production, belong to computer hardware transportation equipment technical field, it does the horizontal motion in proper order to be provided with the drive placement machine on the first support frame of first production facility, the transport mechanism of vertical motion, place and to have placed in the placement machine and wait to transport the hardware, set up on the second support frame and be used for receiving to wait to transport the hardware and drive the transport mechanism who waits to transport the hardware transportation to second production facility, be provided with on the second support frame and be used for the storage to wait to transport the storage mechanism of hardware, be provided with the adjustment mechanism who is connected with transport mechanism on the first support frame, adjustment mechanism and transport mechanism, storage mechanism connects. The utility model discloses an adopted transport mechanism, transport mechanism will wait to transport the hardware and transported to higher second production facility by lower first production facility, satisfied the transportation demand that has the production facility of difference in height, had the advantage that the transfer efficiency is high.

Description

Transfer device for computer hardware production

Technical Field

The utility model belongs to the technical field of computer hardware transfer equipment, concretely relates to transfer device for computer hardware production.

Background

At present, most of computer hardware has the problem of transporting the difficulty in process of production, and when there was the difference in height when two kinds of equipment, when needs transferred computer hardware from a production facility to another kind of production facility, current transfer device area can't satisfy above transportation demand, when wherein next production facility breaks down, transports the product and will take place to pile up the phenomenon simultaneously.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that overcome above-mentioned prior art's shortcoming provides an efficient transfer device that is used for computer hardware production of transportation.

The technical scheme for solving the technical problems is as follows: the device comprises a first production device, a second production device and a storage mechanism, wherein the first production device is provided with a first support frame, the first support frame is provided with a transfer mechanism for driving a placing mechanism to move horizontally and vertically in sequence, the placing mechanism is provided with to-be-transported hardware, the second support frame is provided with a transport mechanism for receiving to-be-transported hardware and driving the to-be-transported hardware to be transported to the second production device, the second support frame is provided with a storage mechanism for storing the to-be-transported hardware, the first support frame is provided with an adjusting mechanism connected with the transfer mechanism, and the adjusting mechanism is connected with the transport mechanism and the storage mechanism.

Further, the transfer mechanism is: a motor for driving the main shaft to rotate is arranged on the first support frame, a first helical gear connected with the adjusting mechanism is arranged at one end of the main shaft, the main shaft is rotatably connected with two side plates of the first support frame, fourth gears clamped with clamping grooves formed in the two second chains are respectively arranged at two ends of the main shaft, a first rotating shaft located right above the main shaft is rotatably mounted on the two side plates of the first support frame, third gears clamped with the clamping grooves formed in the two second chains are respectively arranged at two ends of the first rotating shaft, fourth rotating shafts are respectively rotatably mounted on the two side plates of the first support frame, sixth gears clamped with the clamping grooves formed in the two second chains are respectively arranged on each fourth rotating shaft, second rotating shafts located right below the fourth rotating shafts are respectively rotatably mounted on the two side plates of the first support frame, first gears clamped with the clamping grooves formed in the two second chains are respectively arranged on each second rotating shaft, third rotating shafts are rotatably mounted on the two side plates of the first support frame, seventh gears clamped with the clamping grooves formed in the two second chains are respectively arranged at two ends of the third rotating shafts, and the two second chains are respectively connected with the placing mechanism; the two ends of the main shaft are respectively provided with a ninth gear connected with the clamping grooves formed in the two first chains in a clamped mode, the two ends of the first rotating shaft are respectively provided with a second gear connected with the clamping grooves formed in the two first chains in a clamped mode, the two side plates of the first support frame are respectively rotatably provided with a fifth rotating shaft located above the main shaft, each fifth rotating shaft is respectively provided with a tenth gear connected with the clamping grooves formed in the two first chains in a clamped mode, the two ends of the third rotating shaft are respectively provided with an eighth gear connected with the clamping grooves formed in the two first chains in a clamped mode, and the two first chains are respectively connected with the placing mechanism.

Furthermore, the center line of the fourth rotating shaft is parallel to the center line of the first rotating shaft, and the center line of the third rotating shaft is parallel to the center line of the main shaft.

Further, the placing mechanism is as follows: the two second chains are respectively connected with two ends of the baffle, the baffle is connected with the first movable plate, two ends of the first movable plate are respectively connected with the two first chains, a first connecting shaft is evenly arranged at the upper end of the first movable plate, a first sleeve which is connected with the first connecting shaft in an inserting mode is evenly arranged at the bottom of the placing plate above the first movable plate, a first spring is arranged on the outer circumference of the first connecting shaft and the first sleeve, one end of the first spring is connected with the bottom surface of the placing plate, and the other end of the first spring is connected with the top surface of the first movable plate.

Further, the adjusting mechanism is: a seventh rotating shaft is rotatably mounted on a third support frame on the first support frame, a second helical gear in meshing transmission with the first helical gear is arranged on the seventh rotating shaft, a first chute at the bottom of the third support frame is in sliding connection with a second connecting shaft, a third helical gear in meshing transmission with the second helical gear is arranged at one end of the second connecting shaft, a sixth rotating shaft is rotatably mounted at the upper side of the third support frame, one end of the sixth rotating shaft is connected with the conveying mechanism through a second belt, the other end of the sixth rotating shaft is connected with the first coupling assembly through the first belt, a second coupling assembly connected with the storage mechanism is arranged at the lower side of the third support frame, the other end of the second connecting shaft is respectively connected with the first coupling assembly and the second coupling assembly, a connecting plate fixedly connected with a handle is arranged on the second connecting shaft, and the handle is in sliding connection with a second chute on the third support frame; the third support frame is provided with a first clamping assembly and a second clamping assembly, and the structure of the first clamping assembly is the same as that of the second clamping assembly.

Furthermore, the structure of the first coupling assembly is the same as that of the second coupling assembly, and the center line of the first coupling assembly is perpendicular to that of the second coupling assembly.

Further, the second coupling component is: the third support frame is provided with a third sleeve, a second sleeve is arranged on the inner circumference of the third sleeve and connected with a second connecting shaft, the bottom of the second sleeve is connected with the inner bottom of the third sleeve through a second spring, an inserting block clamped with an inserting groove in the inner circumference of the third sleeve is arranged on the outer circumference of the second sleeve, and a connecting ring is arranged on the second sleeve.

Further, the second clamping assembly is: the third support frame is provided with a fixing plate, and an inserting rod connected with the handle in a clamping mode is connected in the fixing plate in a sliding mode.

Further, the transportation mechanism is: the two ends of the upper side of the second support frame are respectively rotatably provided with eighth rotating shafts, one of the second support frames is provided with a vertical sliding rail, the two eighth rotating shafts are provided with first support plates, the two ends of the two eighth rotating shafts are respectively in transmission connection with conveying belts, each conveying belt is uniformly provided with one-way teeth, the two conveying belts are horizontally and slidably connected with a second moving plate, one end of the second moving plate is movably connected with the vertical sliding rail, the two ends of the second moving plate are respectively and uniformly provided with fourth sleeves, each fourth sleeve is internally and movably connected with a fourth connecting shaft, one end of each fourth connecting shaft is provided with a clamping shaft clamped with a tooth socket between the one-way teeth, the outer circumference of each fourth connecting shaft is provided with a third spring, one end of each third spring is connected with the clamping shaft, and the other end of each third spring is connected with the second moving plate; the second belt is in transmission connection with a third connecting shaft, one end of the third connecting shaft is provided with a connecting wheel, and an eccentric shaft in contact with the vertical sliding rail is eccentrically arranged on the connecting wheel.

Further, the storage mechanism is: an eleventh rotating shaft and a twelfth rotating shaft which are parallel to each other are rotatably installed on the upper side of the second supporting frame, a thirteenth rotating shaft and a fourteenth rotating shaft which are parallel to each other are rotatably installed on the lower side of the second supporting frame, a third chain and a fourth chain are respectively arranged at two ends of the eleventh rotating shaft and two ends of the fourteenth rotating shaft in a transmission manner, a fifth chain and a seventh chain are respectively arranged at two ends of the twelfth rotating shaft and two ends of the thirteenth rotating shaft in a transmission manner, a second supporting plate is uniformly arranged on the third chain, a stop lever is arranged on the second supporting plate, eleventh gears which are connected with clamping grooves which are formed in the third chain in a clamping manner are respectively arranged on the eleventh rotating shaft, a thirteenth rotating shaft and a fourteenth rotating shaft are respectively provided with seventh bevel gears, a ninth rotating shaft which is connected with the third belt in a transmission manner is rotatably installed on the second supporting frame, a fourth bevel gear is arranged on the ninth rotating shaft, a tenth rotating shaft is respectively arranged on two sides of the second supporting frame in a rotation manner, a fifth bevel gear which is meshed with the fourth bevel gear is arranged at one end of each tenth rotating shaft, and a sixth bevel gear which is meshed with the seventh bevel gear.

The utility model has the advantages as follows: (1) The utility model discloses a transport mechanism, transport mechanism will wait to transport the hardware and transport to higher second production facility by lower first production facility, satisfy the transportation demand of the production facility that has the difference in height, have and transport efficient advantage.

(2) The utility model discloses a when the second production facility breaks down, the hardware of waiting to transport on the first backup pad no longer transports to second production facility, will wait to transport the hardware storage in storage mechanism, avoids waiting to transport the hardware and takes place to pile up the phenomenon.

(3) The utility model discloses an adjustment mechanism can switch mode, and adjustment mechanism and transport mechanism when being connected can realize will waiting to transport the hardware transportation to second production facility, and when adjustment mechanism and storage mechanism were connected, will wait to transport the hardware storage in storage mechanism, the utility model has the advantages of easy and simple to handle.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the transfer device for computer hardware production according to the present invention.

Fig. 2 is a schematic structural view of the transfer mechanism.

Fig. 3 is a schematic view of a part a of the enlarged structure in fig. 2.

Fig. 4 is a partially enlarged structural view at B in fig. 2.

Fig. 5 is a partially enlarged schematic view of a part C in fig. 2.

Fig. 6 is a partially enlarged schematic view of fig. 2 at D.

Fig. 7 is a schematic view of the structure of the second chain.

Fig. 8 is a schematic view of the structure of the first chain.

Fig. 9 is a schematic view of the placement mechanism.

Fig. 10 is a schematic view of the structure of the moving plate.

Fig. 11 is a schematic view of the structure of the placement board.

Fig. 12 is a schematic structural view of the adjustment mechanism.

Fig. 13 is a schematic structural view of the third support frame.

Fig. 14 is a partial structural schematic view of fig. 12.

FIG. 15 is a schematic structural view of a second coupling assembly.

Fig. 16 is an internal structural view of the third sleeve.

Fig. 17 is a schematic view of the structure of the third sleeve.

Fig. 18 is a schematic structural view of the second chucking assembly.

Fig. 19 is a schematic structural view of the transport mechanism and the storage mechanism.

Fig. 20 is a schematic view of the structure of the transport mechanism.

Fig. 21 is a partial schematic view of the structure of fig. 20.

Fig. 22 is a schematic view of the internal structure of the first support plate.

Fig. 23 is a schematic structural view of the second moving plate.

Fig. 24 is a schematic view of a connection structure of the chuck shaft and the fourth connecting shaft.

Fig. 25 is a partial structural schematic view of fig. 23.

Fig. 26 is a partial schematic view of the structure of fig. 19.

Fig. 27 is a schematic view of the structure of the third chain.

Fig. 28 is a schematic structural view of the fourteenth rotating shaft.

Reference numerals: 1. a first support frame; 201. a first rotating shaft; 202. a second rotating shaft; 203. a first gear; 204. a third rotating shaft; 205. a second gear; 206. a first chain; 207. a third gear; 208. a second chain; 209. a fourth gear; 210. a main shaft; 211. a motor; 212. a fourth rotating shaft; 214. a sixth gear; 215. a seventh gear; 216. an eighth gear; 217. a first helical gear; 218. a ninth gear; 219. a tenth gear; 220. a fifth rotating shaft; 301. a baffle plate; 302. a first moving plate; 303. placing the plate; 304. a first connecting shaft; 305. a first sleeve; 306. a first spring; 401. a first belt; 402. a sixth rotating shaft; 403. a second belt; 404. a third support frame; 405. a third belt; 406. a first chute; 407. a second chute; 408. a connecting plate; 409. a second helical gear; 410. a seventh rotating shaft; 411. a third bevel gear; 412. a handle; 413. a second connecting shaft; 414. a second sleeve; 415. a connecting ring; 416. a third sleeve; 417. inserting a block; 418. a second spring; 419. a slot; 420. inserting a rod; 421. a fixing plate; 501. a first support plate; 502. a vertical slide rail; 503. a third connecting shaft; 504. a connecting wheel; 505. an eccentric shaft; 506. a second moving plate; 507. an eighth rotating shaft; 508. a conveyor belt; 509. one-way teeth; 510. clamping the shaft; 511. a fourth connecting shaft; 512. a third spring; 513. a fourth sleeve; 601. a ninth rotating shaft; 602. a fourth helical gear; 603. a fifth helical gear; 604. a tenth rotating shaft; 605. a sixth helical gear; 606. a stop lever; 607. a second support plate; 608. a third chain; 609. an eleventh gear; 610. a seventh helical gear; 611. an eleventh rotating shaft; 612. a twelfth rotating shaft; 613. a thirteenth rotating shaft; 614. a fourteenth rotation shaft; 615. a fourth chain; 616. a fifth chain; 617. a seventh chain; 7. a second support frame; 8. the hardware is to be transported.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

As shown in fig. 1, the transfer device for computer hardware production according to the present embodiment is formed by connecting a first support frame 1, a transfer mechanism, a placement mechanism, an adjustment mechanism, a transportation mechanism, a storage mechanism, a second support frame 7, and hardware to be transported 8.

Be provided with on first support frame 1 of first production facility and drive placement mechanism and do horizontal motion in proper order, the transport mechanism of vertical motion, placement mechanism is last to have placed and is waited to transport hardware 8, set up on second support frame 7 and be used for receiving to wait to transport hardware 8 and drive to wait to transport the transport mechanism that hardware 8 transported to second production facility, be provided with on second support frame 7 and be used for the storage to wait to transport hardware 8's storage mechanism, be provided with the adjustment mechanism who is connected with transport mechanism on first support frame 1, adjustment mechanism and transport mechanism, storage mechanism connects.

As shown in fig. 2 to 8, the transfer mechanism is formed by coupling a first rotating shaft 201, a second rotating shaft 202, a first gear 203, a third rotating shaft 204, a second gear 205, a first chain 206, a third gear 207, a second chain 208, a fourth gear 209, a main shaft 210, a motor 211, a fourth rotating shaft 212, a sixth gear 214, a seventh gear 215, an eighth gear 216, a first helical gear 217, a ninth gear 218, a tenth gear 219, and a fifth rotating shaft 220.

The transfer mechanism is: a motor 211 for driving a main shaft 210 to rotate is arranged on the first support frame 1, a first helical gear 217 connected with an adjusting mechanism is arranged at one end of the main shaft 210, the main shaft 210 is rotatably connected with two side plates of the first support frame 1, fourth gears 209 clamped with clamping grooves formed in the two second chains 208 are respectively arranged at two ends of the main shaft 210, a first rotating shaft 201 located right above the main shaft 210 is rotatably mounted on the two side plates of the first support frame 1, third gears 207 clamped with the clamping grooves formed in the two second chains 208 are respectively arranged at two ends of the first rotating shaft 201, fourth rotating shafts 212 are rotatably mounted on the two side plates of the first support frame 1 respectively, the center line of each fourth rotating shaft 212 is parallel to the center line of the first rotating shaft 201, a sixth gear 214 clamped with the two second chains 208 is respectively arranged on each fourth rotating shaft 212, second rotating shafts 202 located right below the fourth rotating shafts 212 are rotatably mounted on the two side plates of the first support frame 1 respectively, a first rotating shaft 203 clamped with the two first gears 203 arranged in the two second clamping grooves formed in the two second chains 208 is respectively arranged on each second rotating shaft 202, a third rotating shaft 215 is mounted on the two side plates of the first support frame 1, two rotating shafts 215, and a third rotating shaft 204 connected with the second clamping grooves 204 are respectively, and two clamping grooves formed in parallel to the two clamping grooves 204, and the second chains 204, and the second rotating shaft 204 are arranged on the main shaft 204, and the second rotating shafts 204, and the two clamping grooves 204, and the second rotating shafts are arranged on the two supporting frame 1, and the two clamping grooves 204, and the second rotating shafts are arranged on the two clamping grooves 204, and the second rotating shafts 204, and the two clamping grooves 204, and the second rotating shafts 204 are arranged on the second supporting frame 1, and the two clamping mechanisms are arranged in parallel to be connected with the main shaft 210.

The two ends of the main shaft 210 are respectively provided with a ninth gear 218 connected with the two first chains 206 in a clamped manner, the two ends of the first rotating shaft 201 are respectively provided with a second gear 205 connected with the two first chains 206 in a clamped manner, the two side plates of the first support frame 1 are respectively rotatably provided with a fifth rotating shaft 220 positioned above the main shaft 210, each fifth rotating shaft 220 is respectively provided with a tenth gear 219 connected with the two first chains 206 in a clamped manner, the two ends of the third rotating shaft 204 are respectively provided with an eighth gear 216 connected with the two first chains 206 in a clamped manner, and the two first chains 206 are respectively connected with the placing mechanism.

As shown in fig. 9 to 11, the placing mechanism is constituted by coupling a baffle plate 301, a first moving plate 302, a placing plate 303, a first connecting shaft 304, a first sleeve 305, and a first spring 306.

The placing mechanism is as follows: the two second chains 208 are respectively connected with two ends of the baffle plate 301, the baffle plate 301 is connected with the first moving plate 302, two ends of the first moving plate 302 are respectively connected with the two first chains 206, the upper end of the first moving plate 302 is uniformly provided with first connecting shafts 304, the bottom of the placing plate 303 above the first moving plate 302 is uniformly provided with first sleeves 305 inserted with the first connecting shafts 304, the first connecting shafts 304 and the first sleeves 305 are provided with first springs 306 on the outer circumferences, one end of each first spring 306 is connected with the bottom surface of the placing plate 303, and the other end of each first spring 306 is connected with the top surface of the first moving plate 302.

As shown in fig. 12 to 18, the adjusting mechanism is formed by coupling a first belt 401, a sixth rotating shaft 402, a second belt 403, a third supporting frame 404, a third belt 405, a first sliding slot 406, a second sliding slot 407, a connecting plate 408, a second helical gear 409, a seventh rotating shaft 410, a third helical gear 411, a handle 412, a second connecting shaft 413, a second sleeve 414, a connecting ring 415, a third sleeve 416, an insert block 417, a second spring 418, an insert slot 419, an insert rod 420, and a fixing plate 421.

The adjusting mechanism is as follows: a seventh rotating shaft 410 is rotatably mounted on a third supporting frame 404 on the first supporting frame 1, a second helical gear 409 in meshing transmission with the first helical gear 217 is arranged on the seventh rotating shaft 410, a second connecting shaft 413 is slidably connected to a first sliding groove 406 at the bottom of the third supporting frame 404, a third helical gear 411 in meshing transmission with the second helical gear 409 is arranged at one end of the second connecting shaft 413, a sixth rotating shaft 402 is rotatably mounted at the upper side of the third supporting frame 404, one end of the sixth rotating shaft 402 is connected with the transportation mechanism through a second belt 403, the other end of the sixth rotating shaft 402 is connected with the first coupling assembly through the first belt 401, a second coupling assembly connected with the storage mechanism is arranged at the lower side of the third supporting frame 404, the other end of the second connecting shaft 413 is respectively connected with the first coupling assembly and the second coupling assembly, a connecting plate 408 fixedly connected with the handle 412 is arranged on the second connecting shaft 413, the handle 412 is slidably connected with a second sliding groove 407 on the third supporting frame 404, and the second sliding groove 407 is an arc-shaped sliding groove 407.

The structure of the first coupling assembly is the same as that of the second coupling assembly, and the center line of the first coupling assembly is perpendicular to that of the second coupling assembly. The second coupling component is: the third supporting frame 404 is provided with a third sleeve 416, the inner circumference of the third sleeve 416 is provided with a second sleeve 414, the second sleeve 414 is connected with a second connecting shaft 413, the bottom of the second sleeve 414 is connected with the inner bottom of the third sleeve 416 through a second spring 418, the outer circumference of the second sleeve 414 is provided with an insertion block 417 which is clamped with an insertion groove 419 of the inner circumference of the third sleeve 416, and the second sleeve 414 is provided with a connecting ring 415.

The third supporting frame 404 is provided with a first clamping assembly and a second clamping assembly, the structure of the first clamping assembly is the same as that of the second clamping assembly, and the center line of the first clamping assembly is perpendicular to that of the second clamping assembly. The second clamping component is as follows: the third supporting frame 404 is provided with a fixing plate 421, and an inserting rod 420 clamped with the handle 412 is slidably connected to the fixing plate 421.

As shown in fig. 19 to 25, the transport mechanism is formed by coupling a first support plate 501, a vertical slide rail 502, a third connecting shaft 503, a connecting wheel 504, an eccentric shaft 505, a second moving plate 506, an eighth rotating shaft 507, a conveyor belt 508, a one-way tooth 509, a clamping shaft 510, a fourth connecting shaft 511, a third spring 512 and a fourth sleeve 513.

The conveying mechanism is as follows: eight rotating shafts 507 are rotatably mounted at two ends of the upper side of the second support frame 7 respectively, a vertical sliding rail 502 is movably mounted on one of the second support frames 7, a first support plate 501 is arranged on the two eighth rotating shafts 507, two ends of the two eighth rotating shafts 507 are in transmission connection with conveyor belts 508 respectively, one-way teeth 509 are uniformly arranged on each conveyor belt 508, a second moving plate 506 is horizontally and slidably connected onto the two conveyor belts 508, one end of the second moving plate 506 is movably connected with the vertical sliding rail 502, the second moving plate 506 can also slide in the vertical direction in the vertical sliding rail 502, four sleeves 513 are uniformly arranged at two ends of the second moving plate 506 respectively, a fourth connecting shaft 511 is movably connected into each fourth sleeve 513, one end of the fourth connecting shaft 511 is provided with a clamping shaft 510 clamped with a tooth socket between the one-way teeth 509, a third spring 512 is arranged on the outer circumference of the fourth connecting shaft 511, one end of the third spring 512 is connected with the clamping shaft 510, and the other end of the third spring is connected with the second moving plate 506. The second belt 403 is in transmission connection with a third connecting shaft 503, one end of the third connecting shaft 503 is provided with a connecting wheel 504, and an eccentric shaft 505 which is in contact with the vertical slide rail 502 is eccentrically arranged on the connecting wheel 504.

As shown in fig. 19 and 26 to 28, the storing mechanism is formed by coupling a ninth rotating shaft 601, a fourth helical gear 602, a fifth helical gear 603, a tenth rotating shaft 604, a sixth helical gear 605, a stopper 606, a second support plate 607, a third chain 608, an eleventh gear 609, a seventh helical gear 610, an eleventh rotating shaft 611, a twelfth rotating shaft 612, a thirteenth rotating shaft 613, a fourteenth rotating shaft 614, a fourth chain 615, a fifth chain 616, and a seventh chain 617.

The storage mechanism is as follows: an eleventh rotating shaft 611 and a twelfth rotating shaft 612 which are parallel to each other are rotatably installed on the upper side of the second supporting frame 7, a thirteenth rotating shaft 613 and a fourteenth rotating shaft 614 which are parallel to each other are rotatably installed on the lower side of the second supporting frame 7, both ends of the eleventh rotating shaft 611 and the fourteenth rotating shaft 614 are respectively driven by a third chain 608 and a fourth chain 615, both ends of the twelfth rotating shaft 612 and the thirteenth rotating shaft 613 are respectively driven by a fifth chain 616 and a seventh chain 617, the third chain 608, the fourth chain 615, the fifth chain 616 and the seventh chain 617 are respectively and uniformly provided with a second supporting plate 607, the second supporting plate 607 is provided with a stopper 606, the eleventh rotating shaft 611 is respectively provided with an eleventh gear 609 which is clamped with a clamping groove arranged on the third chain 608, the thirteenth rotating shaft 613 and the fourteenth rotating shaft 614 are respectively provided with a seventh rotating shaft 610, a ninth rotating shaft 601 which is rotatably installed on the second supporting frame 7 and is in transmission connection with the third belt 405, the ninth rotating shaft 601 is provided with a fourth helical gear 602, both sides of the second supporting frame 7 are respectively rotatably provided with a tenth rotating shaft 604, one end of each tenth rotating shaft 604 is engaged with a sixth helical gear 604, and each helical gear 610 is provided with a sixth helical gear 604 engaged with a sixth helical gear 604.

The working principle of this embodiment is as follows, (1) the transfer mechanism transports the hardware 8 to be transported from the lower first production facility to the higher second production facility: the motor 211 is started, an output shaft of the motor 211 drives the spindle 210 to rotate, two fourth gears 209 on the spindle 210 respectively drive two second chains 208 to transmit, each second chain 208 transmits through the spindle 210, the first rotating shaft 201, the fourth rotating shaft 212, the second rotating shaft 202 and the third rotating shaft 204, and the two second chains 208 drive the baffle 301 to move in the transmission process.

The two ninth gears 218 on the main shaft 210 respectively drive the two first chains 206 to transmit, each first chain 206 transmits through the main shaft 210, the first rotating shaft 201 and the fifth rotating shaft 220, the two first chains 206 drive the first moving plate 302 to move in the transmission process, and the baffle 301 and the first moving plate 302 drive the placing plate 303 to be transported to the first supporting plate 501 through the placing plate 303.

The main shaft 210 drives the first bevel gear 217 to rotate in the rotating process, the first bevel gear 217 drives the second connecting shaft 413 to rotate sequentially through the second bevel gear 409 and the third bevel gear 411, the second connecting shaft 413 is connected with and drives the first belt 401 to move through the first coupling component, the first belt 401 drives the sixth rotating shaft 402 to rotate, the sixth rotating shaft 402 drives the third connecting shaft 503 to rotate through the second belt 403, the third connecting shaft 503 drives the vertical sliding rail 502 to move through the eccentric shaft 505, the vertical sliding rail 502 drives the second moving plate 506 to horizontally move, the clamping shaft 510 on the second moving plate 506 is clamped with the tooth socket between the one-way teeth 509 on the conveying belt 508, the conveying belt 508 is driven to transmit, and the to-be-transported hardware 8 located on the first supporting plate 501 and the conveying belt 508 is transported to the second production equipment.

(2) When the second production equipment fails, the hardware 8 to be transported on the first production equipment is stored in the storage mechanism: the connecting ring 415 of the first coupling assembly is manually pulled, the second sleeve 414 of the first coupling assembly is separated from the second connecting shaft 413, the inserting rod 420 of the first clamping assembly is manually pulled, the inserting rod 420 of the first clamping assembly is separated from the shaft of the handle 412, the handle 412 is manually pulled to slide in the second sliding slot 407, the second connecting shaft 413 slides in the first sliding slot 406, the second connecting shaft 413 moves to and is connected with the second sleeve 414 of the second coupling assembly, the inserting rod 420 of the second clamping assembly is tightly clamped with the shaft of the handle 412, the second coupling assembly drives the ninth rotating shaft 601 to rotate through the third belt 405, the ninth rotating shaft 601 drives the two tenth rotating shafts 604 to rotate sequentially through the fourth helical gear 602 and the fifth helical gear 603, the two tenth rotating shafts 604 respectively drive the fourteenth rotating shaft 614 and the thirteenth rotating shaft 613 to rotate sequentially through the sixth helical gear 605 and the seventh helical gear 610, the two ends of the fourteenth rotating shaft 614 respectively drive the eleventh rotating shaft 608 and the eleventh rotating shaft 608 through the third chain 608 and the seventh chain 613 to rotate, and the twelfth supporting plate 501 through the fifth and the seventh chain 613 respectively. The first supporting plate 501 on the second supporting plate 607 on the fourth chain 615 and the fifth chain 616 moves, the hardware 8 to be transported on the first supporting plate 501 is no longer transported to the second production equipment, the hardware 8 to be transported is stored in the storage mechanism, and the phenomenon that the hardware 8 to be transported is stacked is avoided.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.

Claims (10)

1. A transfer device for computer hardware production, characterized in that: be provided with on first support frame (1) of first production facility and drive placement mechanism and do horizontal motion in proper order, the transport mechanism of vertical motion, placement mechanism is last to have placed and is waited to transport hardware (8), set up on second support frame (7) and be used for receiving and wait to transport hardware (8) and drive and wait to transport the transport mechanism that hardware (8) transported to second production facility, be provided with the storage mechanism who is used for the storage to wait to transport hardware (8) on second support frame (7), be provided with the adjustment mechanism who is connected with transport mechanism on first support frame (1), adjustment mechanism and transport mechanism, storage mechanism connects.

2. The transfer device for computer hardware production according to claim 1, wherein the transfer mechanism is: a motor (211) for driving a main shaft (210) to rotate is arranged on the first support frame (1), a first helical gear (217) connected with an adjusting mechanism is arranged at one end of the main shaft (210), the main shaft (210) is rotatably connected with two side plates of the first support frame (1), fourth gears (209) clamped with clamping grooves formed in two second chains (208) are respectively arranged at two ends of the main shaft (210), first rotating shafts (201) positioned right above the main shaft (210) are rotatably installed on the two side plates of the first support frame (1), third gears (207) clamped with the clamping grooves formed in the two second chains (208) are respectively arranged at two ends of the first rotating shaft (201), fourth rotating shafts (212) are rotatably installed on the two side plates of the first support frame (1), sixth gears (214) clamped with the two second chains (208) are respectively arranged on each fourth rotating shaft (212), second rotating shafts (202) positioned right below the fourth rotating shafts (212) are respectively arranged on the two side plates of the first support frame (1), a seventh gear (204) and a seventh gear (204) are respectively arranged on the two side plates of the second rotating shafts (202), the second rotating shafts (208) and the two clamping grooves formed on the two clamping grooves of the second rotating shafts (208), the first rotating shafts (204), the two second chains (208) are respectively connected with the placing mechanism;

the two ends of the main shaft (210) are respectively provided with a ninth gear (218) which is connected with the two first chains (206) in a clamping manner, the two ends of the first rotating shaft (201) are respectively provided with a second gear (205) which is connected with the two first chains (206) in a clamping manner, the two side plates of the first support frame (1) are respectively rotatably provided with a fifth rotating shaft (220) which is positioned above the main shaft (210), each fifth rotating shaft (220) is respectively provided with a tenth gear (219) which is connected with the two first chains (206) in a clamping manner, the two ends of the third rotating shaft (204) are respectively provided with an eighth gear (216) which is connected with the two first chains (206) in a clamping manner, and the two first chains (206) are respectively connected with the placing mechanism.

3. The transfer device for computer hardware production according to claim 2, wherein the centerline of the fourth rotating shaft (212) is parallel to the centerline of the first rotating shaft (201), and the centerline of the third rotating shaft (204) is parallel to the centerline of the main shaft (210).

4. The transfer device for computer hardware production of claim 2, wherein the placement mechanism is: two second chains (208) are respectively connected with two ends of a baffle (301), the baffle (301) is connected with a first moving plate (302), two ends of the first moving plate (302) are respectively connected with two first chains (206), a first connecting shaft (304) is uniformly arranged at the upper end of the first moving plate (302), first sleeves (305) inserted with the first connecting shaft (304) are uniformly arranged at the bottoms of placing plates (303) above the first moving plate (302), first springs (306) are arranged on the outer circumferences of the first connecting shaft (304) and the first sleeves (305), one ends of the first springs (306) are connected with the bottom surface of the placing plate (303), and the other ends of the first springs (306) are connected with the top surface of the first moving plate (302).

5. The transfer device for computer hardware production of claim 2, wherein the adjustment mechanism is: a third support frame (404) on the first support frame (1) is rotatably provided with a seventh rotating shaft (410), the seventh rotating shaft (410) is provided with a second bevel gear (409) in meshing transmission with the first bevel gear (217), a first chute (406) at the bottom of the third support frame (404) is slidably connected with a second connecting shaft (413), one end of the second connecting shaft (413) is provided with a third bevel gear (411) in meshing transmission with the second bevel gear (409), the upper side of the third support frame (404) is rotatably provided with a sixth rotating shaft (402), one end of the sixth rotating shaft (402) is connected with the transportation mechanism through a second belt (403), the other end of the sixth rotating shaft (402) is connected with the first coupling assembly through a first belt (401), the lower side of the third support frame (404) is provided with a second coupling assembly connected with the storage mechanism, the other end of the second connecting shaft (413) is respectively connected with the first coupling assembly and the second coupling assembly, a connecting plate (408) fixedly connected with a handle (412) is arranged on the second connecting shaft (413), and the connecting shaft (407) is slidably connected with the second chute (407) on the third support frame (404);

the third supporting frame (404) is provided with a first clamping assembly and a second clamping assembly, and the structure of the first clamping assembly is the same as that of the second clamping assembly.

6. The transfer device for computer hardware production according to claim 5, wherein: the structure of the first coupling assembly is the same as that of the second coupling assembly, and the center line of the first coupling assembly is perpendicular to that of the second coupling assembly.

7. The transfer device for computer hardware production of claim 6, wherein the second coupling assembly is: the third supporting frame (404) is provided with a third sleeve (416), the inner circumference of the third sleeve (416) is provided with a second sleeve (414), the second sleeve (414) is connected with a second connecting shaft (413), the bottom of the second sleeve (414) is connected with the inner bottom of the third sleeve (416) through a second spring (418), the outer circumference of the second sleeve (414) is provided with an inserting block (417) clamped with a slot (419) in the inner circumference of the third sleeve (416), and the second sleeve (414) is provided with a connecting ring (415).

8. The transfer device for computer hardware production of claim 5, wherein the second clamping assembly is: a fixing plate (421) is arranged on the third supporting frame (404), and an inserting rod (420) clamped with the handle (412) is connected in the fixing plate (421) in a sliding mode.

9. The transfer device for computer hardware production according to claim 5, wherein the transport mechanism is: eight rotating shafts (507) are respectively rotatably mounted at two ends of the upper side of the second support frame (7), a vertical sliding rail (502) is arranged on one second support frame (7), a first support plate (501) is arranged on the two eighth rotating shafts (507), two conveying belts (508) are respectively connected at two ends of the two eighth rotating shafts (507) in a transmission mode, one unidirectional tooth (509) is uniformly arranged on each conveying belt (508), a second moving plate (506) is horizontally and slidably connected on the two conveying belts (508), one end of the second moving plate (506) is movably connected with the vertical sliding rail (502), fourth sleeves (513) are respectively and uniformly arranged at two ends of the second moving plate (506), a fourth connecting shaft (511) is movably connected in each fourth sleeve (513), a clamping shaft (510) clamped with a tooth socket between the unidirectional teeth (509) is arranged at one end of the fourth connecting shaft (511), a third spring (512) is arranged on the outer circumference of the fourth connecting shaft (511), one end of the third spring (512) is connected with the clamping shaft (510), and the other end of the second moving plate (506) is connected with the second connecting shaft;

the second belt (403) is in transmission connection with a third connecting shaft (503), one end of the third connecting shaft (503) is provided with a connecting wheel (504), and an eccentric shaft (505) which is in contact with the vertical sliding rail (502) is eccentrically arranged on the connecting wheel (504).

10. The transfer device for computer hardware production according to claim 5, wherein the storage mechanism is: an eleventh rotating shaft (611) and a twelfth rotating shaft (612) which are parallel to each other are rotatably installed on the upper side of the second supporting frame (7), a thirteenth rotating shaft (613) and a fourteenth rotating shaft (614) which are parallel to each other are rotatably installed on the lower side of the second supporting frame (7), both ends of the eleventh rotating shaft (611) and the fourteenth rotating shaft (614) are respectively driven by a third chain (608) and a fourth chain (615), both ends of the twelfth rotating shaft (612) and the thirteenth rotating shaft (613) are respectively driven by a fifth chain (616) and a seventh chain (617), second supporting plates (607) are uniformly arranged on the third chain (608), the fourth chain (615), the fifth chain (616) and the seventh chain (617), a stop lever (606) is arranged on the second support plate (607), an eleventh gear (609) which is clamped with a clamping groove arranged on the third chain (608) is arranged on the eleventh rotating shaft (611) respectively, a seventh bevel gear (610) is arranged on the thirteenth rotating shaft (613) and the fourteenth rotating shaft (614) respectively, a ninth rotating shaft (601) which is in transmission connection with the third belt (405) is rotatably arranged on the second support frame (7), a fourth bevel gear (602) is arranged on the ninth rotating shaft (601), a tenth rotating shaft (604) is rotatably arranged on each of two sides of the second support frame (7) respectively, and a fourth bevel gear (602) is arranged at one end of each tenth rotating shaft (604) And a fifth bevel gear (603), wherein a sixth bevel gear (605) in meshing transmission with the seventh bevel gear (610) is arranged on each tenth rotating shaft (604).

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