CN116835257B

CN116835257B - Superimposed screw conveyor

Info

Publication number: CN116835257B
Application number: CN202311105875.3A
Authority: CN
Inventors: 丹尼洛·卡尼亚吉; 殷洁
Original assignee: Suzhou Danshi Intelligent Technology Co ltd
Current assignee: Suzhou Danshi Intelligent Technology Co ltd
Priority date: 2023-08-30
Filing date: 2023-08-30
Publication date: 2023-12-05
Anticipated expiration: 2043-08-30
Also published as: CN116835257A

Abstract

The utility model discloses a superimposed screw conveyor, and relates to the technical field of screw conveyors. The utility model relates to a conveyer assembly, which comprises a conveyer assembly, wherein a switching assembly, a control assembly, a rotating assembly and a switch assembly are arranged on the conveyer assembly, the conveyer assembly comprises a conveying shell, a baffle frame and a conveying frame are fixedly connected on the conveying shell, a spiral conveying rod is rotationally connected on the baffle frame, a first end of a worm is fixedly connected on the spiral conveying rod, a second bevel gear is fixedly connected on a second end of the worm, the switching assembly comprises a cylinder, the cylinder is fixedly connected on the baffle frame, a first end of a push rod is fixedly connected on an output rod of the cylinder, and a second end of the push rod is fixedly connected on a connecting rotating shaft.

Description

Superimposed screw conveyor

Technical Field

The utility model relates to the technical field of screw conveyors, in particular to a superimposed screw conveyor.

Background

The screw conveyer is a machine which uses a motor to drive a screw to rotate and push materials to realize the conveying purpose. In the textile industry, a large number of fabrics need to be dyed, the types and steps of dyed raw materials are many, and when conveying and mixing, the same raw materials need to be conveyed to different mixing steps by adopting a mode of overlapping a plurality of auger screw conveyors and the like.

The utility model patent with the publication number of CN216470390U discloses a conveying auger, wherein a bottom shell is separated from a plurality of cover bodies through a mounting assembly, blades are exposed, cleaning is convenient for personnel, the mounting and the dismounting of a shell are convenient, and the working efficiency is improved.

The above patent only pays attention to cleaning of the auger conveyor, in the blending process of dyeing and mixing, the same dye may need to participate in the mixing of a plurality of steps, or dyeing of a plurality of formulas, and when the mixing of a certain step is finished, the auger conveyor needs to be turned, the conveying direction of the conveyor is adjusted, the conveying objects are replaced, and the superimposed auger conveyor also needs to control the joint, so that the conveying and limiting of materials are ensured, the materials are prevented from directly passing through a plurality of auger conveyors, but the lower layer conveyor does not have conveying objects, and therefore the waste of the materials is caused.

Disclosure of Invention

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a superimposed screw conveyer, including the conveyer subassembly, be provided with switching component on the conveyer subassembly, control assembly, rotating assembly and switch module, the conveyer subassembly includes the conveying shell, fixedly connected with keeps off frame and carriage on the conveying shell, rotationally be connected with the screw conveyer pole on the fender frame, fixedly connected with worm's first end on the screw conveyer pole, fixedly connected with second bevel gear on the second end of worm, switching component includes the cylinder, cylinder fixed connection is on keeping off the frame, fixedly connected with push rod's first end on the output pole of cylinder, push rod's second end fixed connection is on connecting the axis of rotation, connect axis of rotation sliding connection on drive shaft and jackshaft, drive shaft swivelling joint is on keeping off the frame, fixedly connected with driving gear on the jackshaft, driving gear meshes with the worm, control assembly includes the ejector pad, fixedly connected with spacing first end of axle on the ejector pad, fixedly connected with second spring's first end on the dog, the second end sliding connection of spacing axle is on the limiting cylinder, rotating assembly includes pinion and large ring, swivelling ring and large ring is also connected on the carrier, large ring gear meshes with large ring.

Preferably, the baffle frame is also fixedly connected with a motor, an output shaft of the motor is fixedly connected with a first bevel gear, the first bevel gear is meshed with a second bevel gear, and the conveying shell is provided with a water injection valve for cleaning.

Preferably, the first end of fixedly connected with telescopic link is gone up to the second end of push rod, and telescopic link's second end sliding connection is on drive gear, and drive gear's both ends are provided with the recess for telescopic link's rotation, fixedly connected with go-between on telescopic link's the second end, the first end of fixedly connected with first spring is gone up to the second end of push rod, and the second end fixed connection of first spring is gone up at the go-between.

Preferably, the turntable is further rotationally connected to the large toothed ring, the turntable is fixedly connected with a first end of the control connecting rod, a second end of the control connecting rod is fixedly connected to the rack, the rack is slidably connected to the support rack, the support rack is fixedly connected to the conveying frame, the conveying frame is further rotationally connected with a large gear, the large gear is meshed with the rack, and the length of the rack is only half of the length of the support rack.

Preferably, the rotating assembly further comprises a connecting shaft, the connecting shaft is rotationally connected to the conveying frame, a first end of a connecting chain is connected to the connecting shaft in a friction mode, and a second end of the connecting chain is connected to the shaft of the pinion in a friction mode.

Preferably, the switch assembly comprises a control rod, a control ring is fixedly connected to the control rod, a sliding groove is formed in the control ring, a sliding block of a switch stop block is connected to the sliding groove in a sliding mode, a sliding protruding shaft is fixedly connected to the switch stop block, and the sliding protruding shaft is connected to the limiting frame in a sliding mode.

Preferably, the switch assembly further comprises an arc-shaped sliding shaft, the first end of the arc-shaped sliding shaft is fixedly connected to the control rod, the second end of the arc-shaped sliding shaft is slidably connected to the support plate, the control rod is fixedly connected with the first end of the third spring, and the second end of the third spring is fixedly connected to the support plate.

Preferably, the control rod is further connected to the switch shell in a sliding manner, one end, close to the control rod, of the switch shell is fixedly connected to the conveying frame, and the limiting frame is further fixedly connected to the switch shell.

The utility model provides a superimposed screw conveyor, which has the following beneficial effects:

1. the utility model is provided with a pinion and a large toothed ring, and the rotation of the auger screw conveyor is controlled by driving the pinion to rotate, so that the conveying object is changed, and the same dyeing solvent is conveyed to different equipment.

2. The utility model is provided with the switching component, and the switching of the cleaning gear, the rotating gear and the switching gear is realized by controlling the movement of the connecting rotating shafts at two sides, so that different functions are used according to the needs.

3. The utility model is provided with the control component, and can continuously control the opening of the rotating component through the meshing relationship of the large gear and the control connecting rod, so that the upper layer material can continuously enter the lower layer auger screw conveyor, and the circulation of the material is stabilized.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a front view of the present utility model;

FIG. 3 is a side view of the present utility model;

FIG. 4 is a top view of the present utility model;

FIG. 5 is a schematic view of the conveyor assembly of the present utility model;

FIG. 6 is an enlarged view of a partial structure at A in FIG. 5;

FIG. 7 is a schematic diagram of a switching assembly according to the present utility model;

FIG. 8 is a schematic view of the structure of the connecting ring of the present utility model;

FIG. 9 is a schematic diagram of a control assembly according to the present utility model;

FIG. 10 is a schematic diagram of a switch assembly of the present utility model;

in the figure: 1-a conveyor assembly; 2-a switching component; 3-a control assembly; 4-rotating the assembly; a 5-switch assembly; 101-an electric motor; 102-a baffle frame; 103-first bevel gears; 104-a second bevel gear; 105-worm; 106-screw conveying rod; 107-a transport housing; 108-a conveying frame; 201-a cylinder; 202-connecting rods; 203-a push rod; 204-telescoping rod; 205-a first spring; 206-connecting the rotating shaft; 207-drive shaft; 208-an intermediate shaft; 209-a drive gear; 210-a connecting ring; 301-a large gear; 302-rack; 303-control links; 305-a limiting cylinder; 306-a second spring; 307-limiting shaft; 308-pushing blocks; 309-a turntable; 401-connecting shaft; 402-connecting a chain; 403-pinion; 404-large toothed ring; 405-supporting a rack; 501-a switch housing; 502-a lever; 503-arc slide shaft; 504-a third spring; 505-a support plate; 506-a control loop; 507—a switch stop; 508-sliding the male shaft; 509-a limiting frame.

Detailed Description

The technical scheme of the utility model is further described below by the specific embodiments with reference to the accompanying drawings.

Referring to fig. 1 to 10, the present utility model provides a technical solution: the superimposed spiral conveyor comprises a conveyor assembly 1, wherein a switching assembly 2, a control assembly 3, a rotating assembly 4 and a switch assembly 5 are arranged on the conveyor assembly 1, the conveyor assembly 1 comprises a conveying shell 107, a baffle frame 102 and a conveying frame 108 are fixedly connected to the conveying shell 107, a spiral conveying rod 106 is rotatably connected to the baffle frame 102, a first end of a worm 105 is fixedly connected to the spiral conveying rod 106, a second bevel gear 104 is fixedly connected to a second end of the worm 105, the switching assembly 2 comprises a cylinder 201, the cylinder 201 is fixedly connected to the baffle frame 102, a first end of a push rod 203 is fixedly connected to an output rod of the cylinder 201, a second end of the push rod 203 is fixedly connected to a connecting rotating shaft 206, the connecting rotating shaft 206 is slidably connected to a driving shaft 207 and an intermediate shaft 208, the driving shaft 207 is rotatably connected to the baffle frame 102, a driving gear 209 is fixedly connected to the intermediate shaft 208, the driving gear 209 is meshed with the worm 105, a first end of a limit shaft 307 is fixedly connected to the push block 308, a second end of the limit shaft 307 is fixedly connected to the second bevel gear 104, a second end of the limit shaft 307 is fixedly connected to the second end of the push block 306, a second end of the limit shaft 306 is fixedly connected to the second end of the limit shaft 108, a second end of the limit shaft 403 is also fixedly connected to the second spring 403, a second end of the limit shaft 403 is fixedly connected to the second end of the rotary shaft 403 is connected to the small gear 403, and a large gear 403 is connected to the large gear 404.

The baffle frame 102 is also fixedly connected with a motor 101, an output shaft of the motor 101 is fixedly connected with a first bevel gear 103, the first bevel gear 103 is meshed with a second bevel gear 104, and a water injection valve for cleaning is arranged on the conveying shell 107.

As shown in fig. 1, two auger screw conveyors are installed one above the other to convey the same dyeing solvent to different objects, respectively.

As shown in fig. 5, when the screw conveyor is used, the motor 101 is started, and power is transmitted to the worm 105 through the meshing relationship of the first bevel gear 103 and the second bevel gear 104, so that the worm 105 drives the screw conveyor rod 106 to rotate, and the material is conveyed. When the switch assembly 2 is in the washing range. The switch assembly 5 above the screw conveyor is in a closed state, and water is conveyed through the water injection valve on the conveying shell 107, so that the screw conveying rod 106 and the inner wall of the conveying shell 107 are cleaned through rotation of the screw conveying rod 106, and the color and the like of the dyeing solvent are prevented from being influenced when the dyeing solvent is conveyed in a replacement mode.

The first end of telescopic link 204 is fixedly connected with the second end of push rod 203, the second end sliding connection of telescopic link 204 is on drive gear 209, and drive gear 209's both ends are provided with the recess for the rotation of telescopic link 204, fixedly connected with go-between 210 on the second end of telescopic link 204, fixedly connected with first spring 205's first end on the second end of push rod 203, first spring 205's second end fixed connection is on go-between 210.

As shown in fig. 5, 7 and 8, the push rods 203 on both sides are fixedly connected together by the connecting rods 202. The driving gear 209 both sides are provided with parts such as connection axis of rotation 206, through the synchronous removal of push rod 203 of cylinder 201 control both sides, when push rod 203 removed, drive connection axis of rotation 206 is close to or keeps away from jackshaft 208, all be provided with the slider on jackshaft 208 and the drive shaft 207, be provided with corresponding spout on connection axis of rotation 206, thereby control jackshaft 208 through the cooperation of slider and spout, the power transmission between connection axis of rotation 206 and the drive shaft 207, when connection axis of rotation 206 is close to driving gear 209, and the spout on connection axis of rotation 206 cooperates with the slider on jackshaft 208, thereby jackshaft 208 drive connection axis of rotation 206 rotates, connection axis of rotation 206 is in drive shaft 207 rotation, and the connection axis of rotation 206 of opposite side is opposite for keeping away from driving gear 209.

When the push rod 203 moves, the first end of the telescopic rod 204 is pushed, and the first spring 205 on the telescopic rod 204 is extruded, and when the push rod 203 drives the connecting rotating shaft 206 to be close to the driving gear 209, because the sliding block on the intermediate shaft 208 cannot be aligned with the sliding slot on the connecting rotating shaft 206 all the time due to the rotation of the intermediate shaft 208, after the connecting rotating shaft 206 contacts with the sliding block on the intermediate shaft 208, the sliding block can block the movement of the connecting rotating shaft 206, at the moment, the air cylinder 201 cannot control the push rod 203 and the connecting rotating shaft 206 to continue to move, and when the sliding block on the intermediate shaft 208 rotates until the sliding block on the intermediate shaft 208 corresponds to the sliding slot on the connecting rotating shaft 206, the air cylinder 201 can continue to push the connecting rotating shaft 206 to move through the push rod 203, so that the connecting rotating shaft 206 is driven to rotate by the intermediate shaft 208 through the cooperation of the sliding block and the sliding slot.

The switching assembly 2 is provided with three gears, namely a cleaning gear, a rotating gear and a switching gear. In the initial state, the switching assembly 2 is in a cleaning gear, namely the air cylinder 201 does not drive the push rod 203 to move, and the connecting rotating shafts 206 on two sides are not contacted with the sliding blocks on the intermediate shaft 208; when the air cylinder 201 controls the push rod 203 to drive the connecting rotating shaft 206 to move towards the direction approaching the big gear 301, the connecting rotating shaft 206 approaching the big gear 301 is far away from the driving gear 209, the connecting rotating shaft 206 far away from the big gear 301 is close to the driving gear 209, so that a sliding groove on the connecting rotating shaft 206 far away from the big gear 301 is contacted with a sliding block on the intermediate shaft 208, the intermediate shaft 208 is further used for driving the connecting rotating shaft 206, the connecting rotating shaft 206 is further used for driving the driving shaft 207 far away from one side of the big gear 301 to rotate, thereby realizing the switching of the rotation gears, and the driving rotating assembly 4 is used for controlling the rotation angle of the conveying frame 108 to change the conveying objects; the reverse movement push rod 203 is switched to the switch gear, and when the screw conveyer rod 106 rotates, the switch assembly 5 is continuously driven to be in an opened state.

The turntable 309 is further rotatably connected to a large toothed ring 404, a first end of the control link 303 is fixedly connected to the turntable 309, a second end of the control link 303 is fixedly connected to the rack 302, the rack 302 is slidably connected to the support rack 405, the support rack 405 is fixedly connected to the carriage 108, the large gear 301 is further rotatably connected to the carriage 108, the large gear 301 is meshed with the rack 302, and the length of the rack 302 is only half that of the support rack 405.

As shown in fig. 6 and 9, because of the limitation of the length of the rack 302, the large gear 301 drives the rack 302 to slide on the support rack 405, and when the support rack 405 slides to the limit, the large gear 301 no longer engages the rack 302. The large gear 301 is connected to the drive shaft 207 via a chain, and transmits power.

When the upper switch is required to be turned on, the large gear 301 is driven to rotate through the driving shaft 207 and the chain, the large gear 301 drives the rack 302 to slide on the supporting rack 405, and when the rack 302 moves, the control link 303 drives the rotary table 309 to rotate, and then the rotary table 309 drives the limiting cylinder 305 to move, so that the push block 308 pushes the control rod 502 to slide on the switch shell 501, and then the switch is turned on, so that the solvent in the screw conveyer arranged above or the device filled with the dyeing solvent can enter the screw conveyer arranged below and be conveyed out. When rack 302 moves to the limit, the teeth on large gear 301 and the teeth on rack 302 are no longer engaged, but because of the action of arcuate slide shaft 503, both lever 502 and push block 308 have a restoring force, thereby driving rack 302 to slide in the opposite direction, causing rack 302 to continuously engage large gear 301 and continuously drive push block 308 to push lever 502.

When the switch is needed to be closed, the large gear 301 is stopped to be driven to rotate, and the control rod 502 is automatically reset under the action of the arc sliding shaft 503. As the carriage 108 is rotated, the lever 502 and push block 308 will follow the carriage 108 for rotation.

The rotating assembly 4 further comprises a connecting shaft 401, the connecting shaft 401 is rotatably connected to the conveying frame 108, a first end of a connecting chain 402 is connected to the connecting shaft 401 in a friction mode, and a second end of the connecting chain 402 is connected to a shaft of a pinion 403 in a friction mode.

As shown in fig. 9, the large ring gear 404 is engaged with a plurality of pinion gears 403, and the pinion gears 403 on the side close to the large gear 301 are simultaneously engaged with the support rack 405 and the large ring gear 404. The connecting shaft 401 is connected to the drive shaft 207 by a chain, and transmits power. The large toothed ring 404 is also fixed on the lower switch housing 501, when the conveying object needs to be changed, the gear is switched to a rotation gear, the connecting shaft 401 is driven to rotate, the connecting shaft 401 drives the pinion 403 to rotate through the connecting chain 402, the pinion 403 is meshed with the large toothed ring 404, and the large toothed ring 404 is fixed on the lower switch housing 501, so that when the pinion 403 rotates, the pinion 403 and the conveying frame 108 rotate on the large toothed ring 404 under the action of the large toothed ring 404, thereby realizing the adjustment of the conveying housing 107, and realizing the change of the conveying object. While the other support rack 405 rotates on the large toothed ring 404 via the pinion 403.

The switch assembly 5 comprises a control rod 502, a control ring 506 is fixedly connected to the control rod 502, a sliding groove is formed in the control ring 506, a sliding block of a switch stop block 507 is connected to the sliding groove in a sliding mode, a sliding protruding shaft 508 is fixedly connected to the switch stop block 507, and the sliding protruding shaft 508 is connected to a limiting frame 509 in a sliding mode.

The switch assembly 5 further comprises an arc-shaped sliding shaft 503, a first end of the arc-shaped sliding shaft 503 is fixedly connected to the control rod 502, a second end of the arc-shaped sliding shaft 503 is slidably connected to the support plate 505, a first end of a third spring 504 is fixedly connected to the control rod 502, and a second end of the third spring 504 is fixedly connected to the support plate 505.

The control rod 502 is also slidably connected to the switch housing 501, one end of the switch housing 501, which is close to the control rod 502, is fixedly connected to the conveying frame 108, and the limit frame 509 is also fixedly connected to the switch housing 501.

As shown in fig. 10, when the control lever 502 rotates, the control ring 506 is driven to rotate on the switch housing 501, and the sliding blocks on the switch blocks 507 are driven by the sliding grooves on the control ring 506, so that when the control lever rotates, the sliding blocks on the switch blocks 507 are driven to move, and the sliding protruding shafts 508 on the switch blocks 507 slide on the limiting frames 509 by the limitation of the sliding protruding shafts 508, so that a plurality of switch blocks 507 are opened, and feeding is realized.

The auger screw conveyor which is overlapped up and down is connected by installing the large toothed ring 404 on the upper layer on the switch shell 501 on the lower layer, openings are arranged at the upper end and the lower end of the conveying frame 108, the opening above is controlled by the switch assembly 5 on the conveying frame 108, and the opening below is controlled by the switch assembly 5 on the lower layer. The multiple screw conveyors can be repeatedly overlapped, so that the dyeing solvent can be conveyed to multiple conveying objects at the same time. The opening below the carriage 108 on the bottommost auger screw is blocked by a stopper to close it.

Claims

1. A superimposed screw conveyor comprising a conveyor assembly (1), characterized in that: the conveyer assembly (1) is provided with a switching assembly (2), a control assembly (3), a rotating assembly (4) and a switch assembly (5), the conveyer assembly (1) comprises a conveying shell (107), a baffle frame (102) and a conveying frame (108) are fixedly connected to the conveying shell (107), a spiral conveying rod (106) is rotatably connected to the baffle frame (102), a first end of a worm (105) is fixedly connected to the spiral conveying rod (106), a second bevel gear (104) is fixedly connected to a second end of the worm (105), the switching assembly (2) comprises a cylinder (201), the cylinder (201) is fixedly connected to the baffle frame (102), a first end of a push rod (203) is fixedly connected to an output rod of the cylinder (201), a second end of the push rod (203) is fixedly connected to a connecting rotating shaft (206), the connecting rotating shaft (206) is slidably connected to a driving shaft (207) and a middle shaft (208), the driving shaft (207) is rotatably connected to the baffle frame (102), a driving gear (209) is fixedly connected to the middle shaft (208), the driving gear (209) is meshed with a limit stop block (307) is fixedly connected to an output shaft (307) of the output rod (201), the output rod of the cylinder (201) comprises a limit stop block (308), the stop block is fixedly connected with a first end of a second spring (306), a second end of the second spring (306) is fixedly connected to a rotary table (309), a second end of a limiting shaft (307) is slidably connected to a limiting cylinder (305), the rotating assembly (4) comprises a pinion (403) and a large toothed ring (404), the pinion (403) is rotatably connected to the conveying frame (108), the large toothed ring (404) is also rotatably connected to the conveying frame (108), and the pinion (403) is meshed with the large toothed ring (404); the baffle frame (102) is also fixedly connected with a motor (101), an output shaft of the motor (101) is fixedly connected with a first bevel gear (103), the first bevel gear (103) is meshed with a second bevel gear (104), and a water injection valve for cleaning is arranged on the conveying shell (107); the rotary table (309) is further rotationally connected to the large toothed ring (404), the rotary table (309) is fixedly connected with a first end of the control connecting rod (303), a second end of the control connecting rod (303) is fixedly connected to the rack (302), the rack (302) is slidably connected to the support rack (405), the support rack (405) is fixedly connected to the conveying frame (108), the conveying frame (108) is further rotationally connected with the large gear (301), the large gear (301) is meshed with the rack (302), and the length of the rack (302) is only half of that of the support rack (405); the switch assembly (5) comprises a control rod (502), a control ring (506) is fixedly connected to the control rod (502), a sliding groove is formed in the control ring (506), a sliding block of a switch stop block (507) is connected to the sliding groove in a sliding mode, a sliding protruding shaft (508) is fixedly connected to the switch stop block (507), and the sliding protruding shaft (508) is connected to a limiting frame (509) in a sliding mode; the switch assembly (5) further comprises an arc-shaped sliding shaft (503), a first end of the arc-shaped sliding shaft (503) is fixedly connected to the control rod (502), a second end of the arc-shaped sliding shaft (503) is slidably connected to the support plate (505), a first end of a third spring (504) is fixedly connected to the control rod (502), and a second end of the third spring (504) is fixedly connected to the support plate (505).

2. A stacked screw conveyor as claimed in claim 1 wherein: the telescopic device is characterized in that a first end of a telescopic rod (204) is fixedly connected to a second end of the push rod (203), the second end of the telescopic rod (204) is slidably connected to a driving gear (209), grooves are formed in two ends of the driving gear (209) and used for rotating the telescopic rod (204), a connecting ring (210) is fixedly connected to the second end of the telescopic rod (204), a first end of a first spring (205) is fixedly connected to the second end of the push rod (203), and the second end of the first spring (205) is fixedly connected to the connecting ring (210).

3. A stacked screw conveyor as claimed in claim 1 wherein: the rotating assembly (4) further comprises a connecting shaft (401), the connecting shaft (401) is rotatably connected to the conveying frame (108), a first end of a connecting chain (402) is connected to the connecting shaft (401) in a friction mode, and a second end of the connecting chain (402) is connected to the shaft of the pinion (403) in a friction mode.

4. A stacked screw conveyor as claimed in claim 1 wherein: the control rod (502) is further connected to the switch shell (501) in a sliding mode, one end, close to the control rod (502), of the switch shell (501) is fixedly connected to the conveying frame (108), and the limiting frame (509) is further fixedly connected to the switch shell (501).