CN211495754U - Binary channels moves and carries lift - Google Patents

Abstract

The utility model discloses a double-channel transfer elevator, which drives a lifting power assembly through a speed reducer to further drive a synchronous belt conveying assembly to move up and down and realize the lifting function; the synchronous belt conveying assembly is connected left and right through an end power shaft and driven by a driving motor to realize the function of left and right translation; the blocking assembly of the line body controls the left and right transfer positions of the tool on the line body, so that the deviation is prevented, the accurate positioning is realized, and the tool is not positioned on the transfer assembly when descending; the transfer component is connected left and right through the end power shaft and driven by the middle driving component to realize the function of front and back translation; the middle blocking assembly controls the front and back access positions of the tool, so that accurate positioning at the first or second channel is realized, and wrong channel running is prevented.

Description

Binary channels moves and carries lift

Technical Field

The utility model relates to a lift conveying equipment, in particular to binary channels move carries lift.

Background

The elevator is material conveying equipment important in assembly and production processing procedures in the production and manufacturing industry, an upper layer power assembly is used for conveying workpieces in an up-and-down lifting mode, a lower layer synchronous belt line body is used for left-and-right backflow of the workpieces, a middle transfer assembly is used for front-and-back conveying of the workpieces, and the line body is generally arranged in a linear mode or a runway mode. For the elevator, how to control the position of the workpiece when moving along the left, right, front and rear channels, the accurate positioning is realized, the deviation is prevented, the drive can be arranged at any position of the line body, and the key for improving the service performance of the elevator is realized.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model provides a double-channel transfer elevator, which comprises a frame, a lifting power component, a double-channel synchronous belt conveying component and a transfer component; a first lifting mounting plate and a second lifting mounting plate are arranged below and behind the synchronous belt conveying assembly, a second reinforcing plate is arranged on the side face of the synchronous belt conveying assembly, a triangular auxiliary mounting plate is arranged between the first lifting mounting plate below and the second reinforcing plate on the side face, and a first sliding block is arranged on the second lifting mounting plate at the rear; a synchronous belt IV and a guide rail are arranged on the rack, the synchronous belt IV is driven by the lifting power assembly, the front of the synchronous belt IV is fixedly connected with the lifting mounting plate I and the lifting mounting plate II, the rear of the synchronous belt IV is fixed by a tooth-shaped fixing plate, and the tooth-shaped fixing plate is connected with the counterweight box through the guide rail and the sliding block II;

the lifting power assembly comprises a power bottom plate arranged on the rack, a speed reducer and an installation side plate, wherein the speed reducer and the installation side plate are arranged on the power bottom plate;

the synchronous belt conveying assembly comprises an end power shaft, line body profiles symmetrically arranged on two sides of the end power shaft, driving wheel assemblies and driven wheel assemblies respectively arranged on two sides of the line body profiles, and line body synchronous belts synchronously driven by the driving wheel assemblies and the driven wheel assemblies; the end part motor is sequentially driven by the end part motor to drive the bearing I, the synchronous wheel I, the synchronous belt II, the synchronous wheel II, the bearing II and the end power shaft; a first baffle plate driven by a first blocking cylinder and a second baffle plate driven by a second blocking cylinder are arranged between the line body profiles on the two sides; the first blocking cylinder is installed on the first blocking installation plate, the second blocking cylinder is installed on the second blocking installation plate, and two sides of the first blocking installation plate and the second blocking installation plate are fixed on the line body profiles at two sides;

the shifting assembly comprises a shifting bottom plate, four shifting side plates which are combined pairwise and are arranged on the shifting bottom plate, a shifting motor arranged on the outer side surface of one group of shifting side plates, a shifting driving shaft which is driven by the shifting motor and sequentially penetrates through the two groups of shifting side plates, two groups of bearings six and shifting driving wheels which are synchronously driven by the shifting driving shaft and are respectively arranged between the two groups of shifting side plates, and a front synchronous belt three and a rear synchronous belt three which are synchronously driven by the front and rear shifting driving wheels, wherein the synchronous belts three sequentially pass through six driven synchronous wheels which are arranged between each group of shifting side plates and are supported and arranged by a driven shaft I and a driven shaft II matched with a bearing VII and are arranged between each group of shifting side plates and are wound back to the shifting driving wheels; and a blocking cylinder III is arranged in the middle of the left side plate and the right side plate through a blocking mounting plate II, and a position of a baffle II for positioning a workpiece is arranged above the blocking cylinder III.

The power bottom plate of the lifting power assembly is provided with a mounting bottom plate, a first tensioning plate and a second tensioning plate are arranged between the power bottom plate and the mounting bottom plate, and the mounting side plate is vertically mounted on the mounting bottom plate; the bottom of the bearing seat is provided with a bearing seat cushion block arranged on the power bottom plate; a first reinforcing plate is arranged on one side of the mounting side plate; a protective cover is arranged outside the lifting power assembly.

A first connecting rod is arranged between the line body profiles on the two sides of the synchronous belt conveying assembly through a connecting rod end plate; the inner side of the line synchronous belt is also provided with a line wear-resistant strip, and the periphery of the outer side of the line wear-resistant strip is provided with a flange.

The driving wheel assembly comprises a first fixed side plate, a driving synchronous belt wheel, a third bearing, a first upper transition shaft roller, a first transition shaft, a fourth bearing, a first lower transition shaft roller, a second transition shaft, a first outer side guard plate and a first side plate extension strip; the driven wheel assembly comprises a second fixed side plate, a second driven synchronous belt wheel, a second upper transition shaft roller, a third transition shaft, a fifth bearing, a second lower transition shaft roller, a fourth transition shaft, a second outer side guard plate and a second side plate extension strip.

The shifting assembly further comprises a second connecting rod and a third connecting rod, wherein the second connecting rod is used for connecting the upper part of each group of shifting side plates, and the third connecting rod is used for connecting the lower part of each group of shifting side plates; the front position in the middle of the side plate for transferring load is provided with a first idler wheel and an idler wheel shaft, the rear position in the middle of the side plate for transferring load is provided with a second idler wheel and a tensioning shaft, and a tensioning block is arranged above the tensioning shaft.

And the inner sides of the tops of the three synchronous belts of the two shifting assemblies are provided with shifting supporting plates for supporting the three synchronous belts.

Wherein, move the below of carrying the subassembly and still install buffering mounting panel, buffer board and buffer.

Wherein, 4 foot cups are installed at the bottom of the machine frame.

Through the technical scheme, the lifting power assembly is driven by the speed reducer to further drive the synchronous belt conveying assembly to move up and down and realize the lifting function; the synchronous belt conveying assembly is connected left and right through an end power shaft and driven by a driving motor to realize the function of left and right translation; the blocking assembly of the line body controls the left and right transfer positions of the tool on the line body, so that the deviation is prevented, the accurate positioning is realized, and the tool is not positioned on the transfer assembly when descending; the transfer component is connected left and right through the end power shaft and driven by the middle driving component to realize the function of front and back translation; the middle blocking assembly controls the front and back access positions of the tool, so that accurate positioning at the first or second channel is realized, and wrong channel running is prevented.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly described below.

FIGS. 1-4 are schematic structural diagrams of a dual-path transfer elevator in an embodiment of the invention in a three-dimensional, left-view, rear-view and front-view configuration, respectively;

FIGS. 5 and 6 are schematic views of the lifting power assembly according to the embodiment;

FIG. 7 is a schematic diagram of a timing belt conveying assembly according to an embodiment of the disclosure;

FIGS. 8 and 9 are schematic structural views of a driving wheel assembly and a driven wheel assembly of the synchronous belt conveying assembly in the embodiment respectively;

fig. 10 is a schematic structural view of a transfer assembly according to an embodiment of the disclosure.

The figures in the drawings represent: 10. a frame; 20. a lifting power assembly; 30. a synchronous belt conveying assembly; 40, moving and carrying the assembly; 201. a speed reducer; 202. a speed reducer belt wheel; 203. a driven pulley; 204. shaft end fixing columns; 205. a drive shaft; 206. a first synchronous belt; 207. a driving pulley; 208. a bearing block cushion block; 209. a bearing seat; 210. a first reinforcing plate; 211. a first tensioning plate; 212. a second tensioning plate; 213. mounting a bottom plate; 214, mounting the side plate; 215. a power backplane; 216. a protective cover; 301. a tip power shaft; 302. an end motor; 303. a first synchronizing wheel; 304. a second synchronizing wheel; 305. a second synchronous belt; 306. a first bearing; 307. a second bearing; 308. a linear synchronous belt; 309. a line body section bar; 310. a first blocking cylinder; 311. a second blocking cylinder; 312. blocking the first mounting plate; 313. a first baffle plate; 314. a first connecting rod; 315. connecting the rod end plate; 316, wear-resistant strip; 317. blocking edges; 30a. a drive wheel assembly; 301a, fixing a first side plate; 302a. a drive timing pulley; 303a bearing three; 304a. a first upper transition shaft; 305a, a transition shaft one; 306a, bearing four; 307a, a lower transition shaft roller I; 308a, a second transition shaft; 309a, a first outer side guard plate; 310a, side panel extension bar one; 30b. a driven wheel assembly; 301b, fixing a second side plate; 302b. a driven synchronous pulley; 303b, an upper transition shaft roller II; 304b. transition shaft three; 305b, bearing five; 306b, a lower transition shaft roller II; 307b, transition shaft four; 308b, an outer guard plate II; 309b, a side plate extension bar II; 401. transferring a driving shaft; 402. a transfer motor; 4034. a transfer driving wheel; 405. a sixth bearing; 406. transferring a bottom plate; 407, side plate shifting; 4089. a second connecting rod; 40123. a third connecting rod; six 414, driven synchronizing wheel; six 415. bearing seven; six 416. driven shafts one; 417. transferring a driven wheel; 418. eighthly, a bearing; 419. a second driven shaft; 420. an idler wheel I; 421. an idler shaft; 422. an idler wheel II; 423. tensioning the shaft; 424. a tensioning block; 425. a synchronous belt III; 426. a blocking cylinder III; 427. a second baffle plate; 428. a second blocking mounting plate; 429. shifting a pallet; 50. a first lifting mounting plate; 60. a second lifting mounting plate; 70. a second reinforcing plate; 80. an auxiliary mounting plate; 90. a first sliding block; 100. a synchronous belt IV; 110. a guide rail; 120. a tooth-shaped fixing plate; 130. a second sliding block; 140. a weight box; 150. a buffer mounting plate; 160. a buffer plate; 170. a buffer; 180. a foot cup.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-4, the dual-channel transfer elevator provided by the present invention comprises a frame 10 with 4 foot cups 180 mounted at the bottom, a lifting power assembly 20, a dual-channel synchronous belt conveying assembly 30 and a transfer assembly 40; a first lifting mounting plate 50 and a second lifting mounting plate 60 are arranged below and behind the synchronous belt conveying assembly 30, a second reinforcing plate 70 is arranged on the side surface of the synchronous belt conveying assembly 30, a triangular auxiliary mounting plate 80 is arranged between the first lifting mounting plate 50 on the lower side and the second reinforcing plate 70 on the side surface, and a first sliding block 90 is arranged on the second lifting mounting plate 60 on the rear side; the rack 10 is provided with a synchronous belt IV 100 and a guide rail 110, the synchronous belt IV 100 is driven by a lifting power assembly 20, the front of the synchronous belt IV 100 is fixedly connected with a lifting mounting plate I50 and a lifting mounting plate II 60, the rear of the synchronous belt IV 100 is fixed by a tooth-shaped fixing plate 120, and the tooth-shaped fixing plate 120 is connected with a counterweight box 140 through the guide rail 110 and a sliding block II 130.

Referring to fig. 5 and 6, the lifting power assembly 20 includes a power bottom plate 215 mounted on the frame 10, and a speed reducer 201 and a mounting side plate 214 disposed on the power bottom plate 215, wherein a shaft end fixing column 204 of the speed reducer 201 passes through the mounting side plate 214 and drives a speed reducer pulley 202, the speed reducer pulley 202 drives a driven pulley 203 and a driving shaft 205 through a synchronous belt one 206, and the driving shaft 205 drives a driving pulley 207 mounted on the power bottom plate 215 through a bearing seat 209; wherein, the power bottom plate 215 of the lifting power assembly 20 is provided with an installation bottom plate 213, a first tensioning plate 211 and a second tensioning plate 212 are arranged between the power bottom plate 215 and the installation bottom plate 213, and an installation side plate 214 is vertically arranged on the installation bottom plate 213; the bottom of the bearing seat 209 is provided with a bearing seat cushion block 208 arranged on the power bottom plate 215; one side of the mounting side plate 214 is provided with a first reinforcing plate 210; a protective cover 216 is provided on the exterior of the lift power assembly 20.

Referring to fig. 7, the synchronous belt conveying assembly includes an end power shaft 301, line body profiles 309 symmetrically disposed at both sides of the end power shaft 301, driving wheel assemblies and driven wheel assemblies respectively disposed at both sides of the line body profiles 309, and a line body synchronous belt 308 synchronously driven by the driving wheel assemblies and the driven wheel assemblies; the device also comprises an end motor 302, a first bearing 306, a first synchronous wheel 303, a second synchronous belt 305, a second synchronous wheel 304, a second bearing 307 and an end power shaft 301 which are sequentially driven by the end motor 302; a first baffle 313 driven by a first blocking cylinder 310 and a second baffle driven by a second blocking cylinder 311 are arranged between the linear body profiles 309 on the two sides; the first blocking cylinder 310 is installed on the first blocking installation plate 312, the second blocking cylinder 311 is installed on the second blocking installation plate, and the two sides of the first blocking installation plate 312 and the second blocking installation plate are fixed on the line body sectional materials 309 on the two sides; a first connecting rod 314 is further arranged between the line body profiles 309 on the two sides of the synchronous belt conveying assembly through a connecting rod end plate 315; the inner side of the line synchronous belt 308 is also provided with a line wear-resistant strip 316, and the periphery of the outer side is provided with a flange 317.

Referring to fig. 8, the capstan assembly 30a includes a first fixed side plate 301a, a driving synchronous pulley 302a, a third bearing 303a, a first upper transition shaft roller 304a, a first transition shaft 305a, a fourth bearing 306a, a first lower transition shaft roller 307a, a second transition shaft 308a, a first outer guard plate 309a, and a first side plate extension strip 310 a; referring to fig. 9, the driven wheel assembly 30b includes a second fixed side plate 301b, a second driven synchronous pulley 302b, a second upper transition shaft roller 303b, a third transition shaft 304b, a fifth bearing 305b, a second lower transition shaft roller 306b, a fourth transition shaft 307b, a second outer guard plate 308b, and a second side plate extension bar 309b.

Referring to fig. 10, the transferring assembly 40 includes a transferring base plate 406, four transferring side plates 407 mounted on the transferring base plate 406 and combined in pairs, a transferring motor 402 mounted on the outer side of one transferring side plate 407, a transferring drive shaft 401 driven by the transferring motor 402 and sequentially passing through the two transferring side plates 407, two sets of bearings 405 and a transferring drive wheel 4034 respectively disposed between the two transferring side plates 407 and synchronously driven by the transferring drive shaft 401, and two front and back synchronous belts three 425 driven synchronously by the two front and back transfer driving wheels 4034, the synchronous belts three 425 sequentially pass through six driven synchronous wheels 414 arranged between each group of transfer side plates 407 and supported and installed by a driven shaft one 416 and a matching bearing seven 415, and pass through transfer driven wheels 417 arranged between each group of transfer side plates 407 and supported and installed by a driven shaft two 419 and a matching bearing eight 418 to wind back to the transfer driving wheels 4034; a blocking cylinder III 426 is arranged between the left side plate and the right side plate through a blocking mounting plate II 428, and a baffle plate II 427 is arranged above the blocking cylinder III 426 to position the workpiece; wherein, the inner sides of the upper parts of the two synchronous belt three 425 of the transferring component 40 are respectively provided with a transferring supporting plate 429 for supporting the synchronous belt three 425; a buffer mounting plate 150, a buffer plate 160 and a buffer 170 are further mounted below the transfer unit 40. The shifting component 40 further comprises two connecting rods II 4089 used for connecting the upper part of each group of shifting side plates 407 and four connecting rods III 40123 used for connecting the lower part of each group of shifting side plates 407; the first idler wheel 420 and the idler wheel shaft 421 are installed at the middle front position of the shifting side plate 407, the second idler wheel 422 and the tension shaft 423 are installed at the middle rear position, and the tension block 424 is installed above the tension shaft 423.

The utility model drives the lifting power component 20 through the speed reducer 201 to further drive the synchronous belt conveying component to move up and down and realize the lifting function; the synchronous belt conveying assembly is connected left and right through an end power shaft 301 and driven by a driving motor to realize the function of left and right translation; the blocking assembly of the line body controls the left and right transferring positions of the tool on the line body, so that the deviation is prevented, the accurate positioning is realized, and the tool is not positioned on the transferring assembly 40 when descending; the transfer assembly 40 is connected left and right through an end power shaft 301 and driven by a middle driving assembly to realize the function of front and back translation; the middle blocking assembly controls the front and back access positions of the tool, so that accurate positioning at the first or second channel is realized, and wrong channel running is prevented.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to the above-described embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (8)

1. A dual-channel transfer elevator is characterized by comprising a rack (10), a lifting power assembly (20), a dual-channel synchronous belt conveying assembly (30) and a transfer assembly (40); a first lifting mounting plate (50) and a second lifting mounting plate (60) are mounted below and behind the synchronous belt conveying assembly (30), a second reinforcing plate (70) is mounted on the side face of the synchronous belt conveying assembly (30), a triangular auxiliary mounting plate (80) is mounted between the first lifting mounting plate (50) below and the second reinforcing plate (70) on the side face, and a first sliding block (90) is arranged on the second lifting mounting plate (60) behind the first lifting mounting plate; a synchronous belt IV (100) and a guide rail (110) are arranged on the rack (10), the synchronous belt IV (100) is driven by the lifting power assembly (20), the front of the synchronous belt IV (100) is fixedly connected with the lifting mounting plate I (50) and the lifting mounting plate II (60), the rear of the synchronous belt IV (100) is fixed by a tooth-shaped fixing plate (120), and the tooth-shaped fixing plate (120) is connected with a counterweight box (140) through the guide rail (110) and the sliding block II (130);

the lifting power assembly (20) comprises a power bottom plate (215) installed on a rack (10), a speed reducer (201) and an installation side plate (214) which are arranged on the power bottom plate (215), a shaft end fixing column (204) of the speed reducer (201) penetrates through the installation side plate (214) and drives a speed reducer belt wheel (202), the speed reducer belt wheel (202) drives a driven belt wheel (203) and a driving shaft (205) through a synchronous belt I (206), and the driving shaft (205) drives a driving belt wheel (207) installed on the power bottom plate (215) through a bearing seat (209);

the synchronous belt conveying assembly (30) comprises an end power shaft (301), line body profiles (309) symmetrically arranged on two sides of the end power shaft (301), driving wheel assemblies (30a) and driven wheel assemblies (30b) respectively arranged on two sides of the line body profiles (309), and line body synchronous belts (308) synchronously driven by the driving wheel assemblies (30a) and the driven wheel assemblies (30 b); the end part power shaft device is characterized by further comprising an end part motor (302), a first bearing (306), a first synchronous wheel (303), a second synchronous belt (305), a second synchronous wheel (304), a second bearing (307) and the end head power shaft (301), wherein the first bearing (306), the first synchronous wheel (303), the second synchronous belt (305), the second synchronous wheel (304), the second bearing (307) and the end head power shaft (301) are; a first baffle (313) driven by a first blocking cylinder (310) and a second baffle driven by a second blocking cylinder (311) are arranged between the line body profiles (309) on the two sides; the first blocking cylinder (310) is installed on the first blocking installation plate (312), the second blocking cylinder (311) is installed on the second blocking installation plate, and the two sides of the first blocking installation plate (312) and the second blocking installation plate are fixed on the line body profiles (309) on the two sides;

the transfer assembly (40) comprises a transfer base plate (406), four transfer side plates (407) which are combined in pairs and mounted on the transfer base plate (406), a transfer motor (402) which is mounted on the outer side surface of the transfer side plates (407), a transfer driving shaft (401) which is driven by the transfer motor (402) and sequentially penetrates through the two transfer side plates (407), two groups of synchronous driving shafts (401) are respectively arranged between the two groups of transfer side plates (407) and comprise a bearing six (405) and a transfer driving wheel (4034), and a front synchronous belt three (425) and a rear synchronous belt three (425) which are synchronously driven by the front transfer driving wheel (4034) are sequentially arranged between the transfer side plates (407) of each group and comprise six driven synchronous wheels (414) arranged above the driven shafts I (416) matched with the bearing seven (415) and supported and mounted between the driven shafts (407) of each group and a transfer side plate (407) of each group and each transfer side plate (407 Secondly (419) supports the mounted transfer driven wheel (417) to be wound around the transfer driving wheel (4034) by matching with an eighth bearing (418); a blocking cylinder III (426) is arranged between the left side plate and the right side plate through a blocking mounting plate II (428), and a baffle plate II (427) is arranged above the blocking cylinder III (426) to position the workpiece.

2. The dual-channel transfer elevator as claimed in claim 1, wherein the power bottom plate (215) of the lifting power assembly (20) is provided with a mounting bottom plate (213), a first tensioning plate (211) and a second tensioning plate (212) are arranged between the power bottom plate (215) and the mounting bottom plate (213), and the mounting side plate (214) is vertically mounted on the mounting bottom plate (213); the bottom of the bearing seat (209) is provided with a bearing seat cushion block (208) arranged on the power bottom plate (215); a first reinforcing plate (210) is arranged on one side of the mounting side plate (214); and a protective cover (216) is arranged outside the lifting power assembly (20).

3. The dual-channel transfer lifting machine as claimed in claim 1, wherein a first connecting rod (314) is further arranged between the line body profiles (309) on both sides of the synchronous belt conveying assembly (30) through a connecting rod end plate (315); the inner side of the line synchronous belt (308) is also provided with a line wear-resistant strip (316), and the periphery of the outer side of the line wear-resistant strip is provided with flanges (317).

4. The dual-channel transfer elevator as claimed in claim 1 or 3, wherein the driving wheel assembly (30a) comprises a first fixed side plate (301a), a driving synchronous pulley (302a), a third bearing (303a), a first upper transition shaft roller (304a), a first transition shaft (305a), a fourth bearing (306a), a first lower transition shaft roller (307a), a second transition shaft (308a), a first outer guard plate (309a) and a first side plate extension bar (310 a); the driven wheel assembly (30b) comprises a second fixed side plate (301b), a driven synchronous pulley (302b), a second upper transition shaft roller (303b), a third transition shaft (304b), a fifth bearing (305b), a second lower transition shaft roller (306b), a fourth transition shaft (307b), a second outer side guard plate (308b) and a second side plate extension strip (309 b).

5. The dual transfer lift of claim 1, wherein said transfer assembly (40) further comprises a second connecting bar (4089) above and a third connecting bar (40123) below each set of said transfer side plates (407); move and carry the middle front position of curb plate (407) and install idler (420) and idler axle (421), middle back position is installed idler two (422) and tensioning axle (423), tensioning piece (424) are equipped with to tensioning axle (423) top.

6. The dual-lane transfer lifting machine according to claim 1, wherein a transfer pallet (429) is mounted on the upper inner side of each of the three timing belts of the transfer assembly (40) for supporting the three timing belts.

7. The dual lane transfer elevator as claimed in claim 1, wherein a buffer mounting plate (150), a buffer plate (160) and a buffer (170) are further installed below the transfer component (40).

8. A dual lane transfer elevator as claimed in claim 1 wherein 4 goblets (190) are mounted to the bottom of the frame (10).

Images