CN219442646U - Conveying device for cleaning workpieces - Google Patents

Abstract

The utility model provides a conveying device for cleaning a workpiece, which comprises a conveying belt mechanism and a floating pressing mechanism, wherein the floating pressing mechanism is positioned above the conveying belt mechanism, a space for floating and clamping the workpiece is formed between a conveying surface of the conveying belt mechanism and the floating pressing mechanism, the conveying belt mechanism is used for driving the workpiece to move through friction, and the floating pressing mechanism is used for floating pressing the workpiece to increase friction for driving the workpiece to move.

Description

Conveying device for cleaning workpieces

Technical Field

The utility model relates to the field of cleaning machines, in particular to a conveying device for cleaning workpieces.

Background

The conveying device is a part of a cleaning machine, as shown in fig. 6, the current conveying device comprises a frame A1, a plurality of groups of lower layer encapsulation rollers A3, a plurality of groups of upper layer encapsulation rollers A3 and a driving mechanism, wherein the plurality of groups of lower layer encapsulation rollers A3 and the plurality of groups of lower layer encapsulation rollers A3 are rotatably connected on the frame A1 and are in driving connection with the driving mechanism, a clamping space for clamping a plate-shaped workpiece is formed between the plurality of groups of upper layer encapsulation rollers A3 and the plurality of groups of lower layer encapsulation rollers A3 along the up-down direction, when the cleaning machine works, the plate-shaped workpiece enters the clamping space, and meanwhile the driving mechanism drives the plurality of groups of lower layer encapsulation rollers A3 to perform positive movement and drives the plurality of groups of upper layer encapsulation rollers A3 to perform reverse movement, under the friction effect of lower layer rubber coating roller and upper layer rubber coating roller to the plate-shaped work piece, make it along controlling the direction motion and pass through the washing function district, it includes washing district, dewatering area and drying area, plate-shaped work piece gets into washing district, dewatering area and drying area in succession, wash the upper and lower face of work piece through the mode that high pressure sprays in washing district, impurity such as get rid of greasy dirt on work piece surface, sweeps, in the dewatering area, blow away the moisture above the work piece and below through the high-pressure air current of air knife output, in the drying area, dry the work piece through high temperature environment.

The inventors have found that the conveying device has the disadvantage that the spacing between adjacent lower encapsulation rollers is relatively large and is not suitable for small plate-shaped workpieces, i.e. if the plate-shaped workpiece is conveyed by the conveying device, it can fall out from the gap between adjacent lower encapsulation rollers.

Disclosure of Invention

The present utility model is directed to a conveyor for cleaning a workpiece, which solves the above-mentioned problems of the prior art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

the utility model provides a conveyor that washs work piece was used, includes conveyer belt mechanism and floating pushing down mechanism, floating pushing down mechanism is located the top of conveyer belt mechanism, form the space that is used for carrying out floating centre gripping to the work piece between conveyer belt mechanism's the conveying face and the floating pushing down mechanism, conveyer belt mechanism is used for driving the work piece motion so that it passes through the washing district, floating pushing down mechanism is used for carrying out floating pushing down in order to increase the frictional force that drives the work piece motion to the work piece that is arranged in wasing the functional area, makes it overcome the resistance of marcing that receives in the washing district.

Further, the conveyer belt mechanism comprises a driving rubber coating roller, a driving roller support, a driving assembly, a driven rubber coating roller, a driven roller support and a conveying net belt, wherein the driving rubber coating roller and the driven rubber coating roller are respectively and rotatably connected to the driving roller support and the driven roller support, the driving assembly is arranged on the driving roller support and is in driving connection with one end of the driving rubber coating roller, and the driving assembly drives the driving rubber coating roller to be in rotary motion through the conveying net belt in linkage with the driven rubber coating roller.

Further, a front closed-loop raised line and a rear closed-loop raised line are arranged on the inner periphery of the conveying net belt.

Further, a front annular groove A and a rear annular groove A are formed in the periphery of the driving rubber coating roller, a front annular groove B and a rear annular groove B are formed in the periphery of the driven rubber coating roller, the front annular groove A and the front annular groove B are matched with the front closed-loop convex strips, and the rear annular groove A and the rear annular groove B are matched with the rear closed-loop convex strips.

Further, still include and go up direction rubber coating roller and lower direction rubber coating roller, go up direction rubber coating roller and lower direction rubber coating roller and all install on floating pushing down the mechanism, go up the top that direction rubber coating roller is located lower direction rubber coating roller, be equipped with preceding ring channel C and back ring channel C on going up the periphery of direction rubber coating roller, be equipped with preceding ring channel D and back ring channel D on the periphery of lower direction rubber coating roller, preceding ring channel C and preceding ring channel D all cooperate with preceding closed loop sand grip, back ring channel C and back ring channel D all cooperate with back closed loop sand grip.

Further, the device also comprises a conveying surface stabilizing mechanism, wherein the conveying surface stabilizing mechanism is arranged on the floating pressing mechanism, and the conveying surface passes through the conveying surface stabilizing mechanism.

Further, conveying surface stabilizing mean is including being the roller support that mirror image set up, down rubber coating roller, preceding elasticity push down actuating assembly, back elasticity push down actuating assembly and last rubber coating roller, down rubber coating roller's both ends respectively with be the rotatable coupling of roller support that mirror image set up, preceding elasticity push down actuating assembly and back elasticity push down actuating assembly respectively install on being the roller support that mirror image set up, go up rubber coating roller's both ends respectively with preceding elasticity push down actuating assembly and back elasticity push down actuating assembly rotatable coupling, preceding elasticity push down actuating assembly and back elasticity push down actuating assembly and all press conveying surface on rubber coating roller down through the elastic drive.

Further, back elasticity pushes down drive assembly includes spacing module B, bearing B and spring B on the spring, U-shaped mouth B has been seted up on the upper portion of roller support, spacing module B installs on the roller support on the spring, bearing B can cooperate in U-shaped mouth B and overlap the tip of establishing down the rubber coating roller with sliding from top to bottom, spring B sets up between spacing module B and bearing B on the spring, spring B drives the rubber coating roller through elasticity drive bearing B and presses the transport face on the rubber coating roller down.

Further, floating pushing down the mechanism includes the chassis, is the roller support that the mirror image set up, preceding elasticity reset assembly, back elasticity reset assembly and many along controlling the rubber coating roller of direction interval arrangement, is the mirror image setting the roller support is all installed on the chassis, preceding elasticity reset assembly and back elasticity reset assembly are installed respectively on the roller support that is the mirror image setting, many the both ends of rubber coating roller respectively with preceding elasticity reset assembly and back elasticity reset assembly rotatable coupling and all span the top that sets up at the transport face, many form between rubber coating roller and the transport face and be used for carrying out the space of floating centre gripping to the work piece.

Further, back elasticity reset assembly includes spacing module A on the spring, a plurality of bearing A and a plurality of spring A, a plurality of U-shaped mouthful A have been seted up on the upper portion of roller support, spacing module A installs on the roller support on the spring, a plurality of bearing A respectively can match in a plurality of U-shaped mouthful A and overlap respectively and establish outside the tip of many encapsulation roller from top to bottom slidingly, spring A sets up between spacing module A and bearing A on the spring, a plurality of spring A passes through elasticity and drives a plurality of bearing A respectively and laminate respectively on the bottom of a plurality of U-shaped mouthful A.

The utility model has the beneficial effects that:

when the device works, small plate-shaped workpieces are manually placed on the conveying surface of the conveying belt mechanism, the conveying belt mechanism drives the plate-shaped workpieces to move in the left-right direction, the plate-shaped workpieces pass through the cleaning function area, and the problem that the plate-shaped workpieces fall out from gaps between adjacent lower-layer rubber coating rollers in the prior art can be solved by the mode that the conveying belt drives the plate-shaped workpieces; the floating type pressing mechanism is used for floating type pressing the workpiece to increase the friction force for driving the workpiece to move, so that the plate-shaped workpiece can overcome the running resistance of the plate-shaped workpiece in the process of passing through the cleaning function area, the running resistance is prevented from interfering the normal running of the plate-shaped workpiece, the running resistance is embodied in the resistance of high-pressure spraying water flow to the plate-shaped workpiece in the flushing area, and the running resistance is embodied in the resistance of high-pressure air flow to the plate-shaped workpiece in the dewatering area.

Drawings

Fig. 1: the utility model is a perspective schematic view.

Fig. 2: a schematic perspective view of the conveyor belt mechanism of the present utility model.

Fig. 3: the utility model is a partial schematic perspective view.

Fig. 4: an enlarged schematic view is shown at a in fig. 3.

Fig. 5: fig. 3 is an enlarged schematic diagram at B.

Fig. 6: a partial schematic front view of the current conveying device.

Detailed Description

The utility model is further described below with reference to the accompanying drawings:

referring to fig. 1, a conveying device for cleaning a workpiece includes a conveying belt mechanism 1 and a floating pressing mechanism 2, the floating pressing mechanism 2 is located above the conveying belt mechanism 1, a space for floating and clamping the workpiece is formed between a conveying surface of the conveying belt mechanism 1 and the floating pressing mechanism 2, the conveying belt mechanism 1 is used for driving the workpiece to move so as to enable the workpiece to pass through a cleaning area, and the floating pressing mechanism 2 is used for floating pressing the workpiece located in the cleaning function area so as to increase friction force for driving the workpiece to move, so that the travelling resistance received in the cleaning area is overcome.

Referring to fig. 2, the conveyor belt mechanism 1 includes a driving rubber coating roller 11, a driving roller support 12, a driving component 13, a driven rubber coating roller 14, a driven roller support 15 and a transmission net belt 16 with a hollow structure, the driving rubber coating roller 11 and the driven rubber coating roller 14 are respectively rotatably connected to the driving roller support 12 and the driven roller support 15, the driving component 13 is installed on the driving roller support 12 and is in driving connection with one end of the driving rubber coating roller 11, and the driving component 13 drives the driving rubber coating roller 11 to link the driven rubber coating roller 14 to perform rotary motion through the transmission net belt 16. The conveying surface is the upper section of the conveyor belt 16.

Referring to fig. 2, the transmission mesh belt 16 is a kevlar mesh belt, and a front closed loop protruding strip 16-1 and a rear closed loop protruding strip 16-2 are provided on the inner periphery thereof.

The periphery of the driving rubber coating roller 11 is provided with a front annular groove A and a rear annular groove A, the periphery of the driven rubber coating roller 14 is provided with a front annular groove B and a rear annular groove B, the front annular groove A and the front annular groove B are matched with the front closed-loop raised strips 16-1 for limiting the shifting of the conveying mesh belt 16 along the front-back direction, and the rear annular groove A and the rear annular groove B are matched with the rear closed-loop raised strips 16-2 for limiting the shifting of the conveying mesh belt 16 along the front-back direction.

Referring to fig. 2 and 3, the belt conveyer further comprises an upper guiding rubber coating roller 17 and a lower guiding rubber coating roller 18, wherein the upper guiding rubber coating roller 17 and the lower guiding rubber coating roller 18 are both installed on the floating type pressing mechanism 2, the upper guiding rubber coating roller 17 is located above the lower guiding rubber coating roller 18, a front annular groove C17-1 and a rear annular groove C17-2 are formed in the periphery of the upper guiding rubber coating roller 17, a front annular groove D and a rear annular groove D are formed in the periphery of the lower guiding rubber coating roller 18, the front annular groove C17-1 and the front annular groove D are both matched with the front closed-loop raised strips 16-1 to limit the belt conveyer 16 to deviate in the front-rear direction, and the rear annular groove C17-2 and the rear annular groove D are both matched with the rear closed-loop raised strips 16-2 to limit the belt conveyer 16 to deviate in the front-rear direction.

Referring to fig. 3, the floating pressing mechanism 2 includes a chassis 21, a roller support 22 disposed in a mirror image manner, a front elastic reset assembly 23, a rear elastic reset assembly 24, and a plurality of rubber coating roller shafts 25 arranged at intervals along a left-right direction, wherein the roller support 22 disposed in a mirror image manner is mounted on the chassis 21, the front elastic reset assembly 23 and the rear elastic reset assembly 24 are respectively mounted on the roller support 22 disposed in a mirror image manner, two ends of the rubber coating roller shafts 25 are respectively rotatably connected with the front elastic reset assembly 23 and the rear elastic reset assembly 24 and are respectively disposed above a conveying surface in a crossing manner, an interval is provided between adjacent rubber coating roller shafts 25, and a space for floating and clamping a workpiece is formed between the rubber coating roller shafts 25 and the conveying surface.

The distance between the adjacent encapsulation roller shafts 25 is smaller than the length of the plate-shaped workpiece in the left-right direction.

Referring to fig. 4, the front elastic reset assembly 23 and the rear elastic reset assembly 24 have the same structure, the front elastic reset assembly 23 includes a spring upper limit module a231, a plurality of bearings a232 and a plurality of springs a233, a plurality of U-shaped openings a22-1 are formed in the upper portion of the roller shaft support 22, the spring upper limit module a231 is mounted on the roller shaft support 22, the plurality of bearings a232 are respectively slidably fitted in the plurality of U-shaped openings a22-1 up and down and respectively sleeved outside the ends of the plurality of encapsulation roller shafts 25, the springs a233 are disposed between the spring upper limit module a231 and the bearings a232, and the plurality of springs a233 respectively drive the plurality of bearings a232 to respectively attach to the bottoms of the plurality of U-shaped openings a22-1 through elastic force.

The spring upper limit module A231 comprises a cover plate A and a plurality of bolts A, a plurality of threaded holes A are formed in the cover plate A, the screw rod parts of the bolts A are respectively in threaded connection with the threaded holes A and respectively extend into the U-shaped openings A22-1, a plurality of springs A233 are respectively sleeved outside the screw rod parts of the bolts A, and the springs A233 are located between the bearings A232 and the cover plate A.

Referring to fig. 1, the device further includes a conveying surface stabilizing mechanism 3, the conveying surface stabilizing mechanism 3 is mounted on the floating pressing mechanism 2, and the conveying surface passes through the conveying surface stabilizing mechanism 3.

Referring to fig. 4, the conveying surface stabilizing mechanism 3 includes a roller support 31, a lower rubber coating roller 32, a front elastic pressing driving assembly 33, a rear elastic pressing driving assembly 34 and an upper rubber coating roller 35, wherein the roller support 31 is in mirror image arrangement, two ends of the lower rubber coating roller 32 are respectively and rotatably connected with the roller support 31 in mirror image arrangement, the front elastic pressing driving assembly 33 and the rear elastic pressing driving assembly 34 are respectively mounted on the roller support 31 in mirror image arrangement and can move up and down, two ends of the upper rubber coating roller 35 are respectively and rotatably connected with the front elastic pressing driving assembly 33 and the rear elastic pressing driving assembly 34, and the front elastic pressing driving assembly 33 and the rear elastic pressing driving assembly 34 are respectively and elastically driven to press the conveying surface on the lower rubber coating roller 32.

The lower encapsulation roller 32 is used for supporting the upper section of the conveyor belt 16 to improve sagging caused by overlong length, and the upper encapsulation roller 35 presses the conveying surface on the lower encapsulation roller 32 to limit local upward movement of the conveying surface, so as to improve up-and-down fluctuation of the conveying surface caused by vibration and improve the stability of conveying the plate-shaped workpiece.

Referring to fig. 5, the front elastic pressing driving assembly 33 and the rear elastic pressing driving assembly 34 have the same structure, the rear elastic pressing driving assembly 34 includes a spring upper limit module B341, a bearing B342 and a spring B343, a U-shaped opening B31-1 is provided on the upper portion of the roller support 31, the spring upper limit module B341 is mounted on the roller support 31, the bearing B342 is slidably fitted in the U-shaped opening B31-1 up and down and sleeved outside the end of the lower encapsulation roller 32, the spring B343 is disposed between the spring upper limit module B341 and the bearing B342, and the spring B343 drives the upper encapsulation roller 35 to press the conveying surface on the lower encapsulation roller 32 through the elastic driving bearing B342.

Referring to fig. 5, the sprung-position limiting module B341 includes a cover plate B3411 and a bolt B3412, the cover plate B3411 is provided with a threaded hole B, a screw portion of the bolt B3412 is in threaded connection with the threaded hole B and extends into the U-shaped opening B31-1, and the spring B233 is sleeved outside the screw portion of the bolt B3412 and is located between the bearing B232 and the cover plate B3411.

Working principle:

the small plate-shaped workpiece is placed at the left end of the conveying net belt 16 by the last station or manually, the driving assembly 13 drives the driving rubber coating roller 11 to move rotationally through the conveying net belt 16 in a linkage way and the driven rubber coating roller 14, so that the conveying net belt 16 drives the plate-shaped workpiece to move left to right, the plate-shaped workpiece sequentially passes through a flushing area, a dewatering area and a drying area, in the cleaning area, high-pressure spraying water flow output from an upper high-pressure spraying device passes through the interval between adjacent rubber coating roller shafts 25 from top to bottom to reach the upper part of the plate-shaped workpiece, and high-pressure spraying water flow output from a lower high-pressure spraying device passes through the conveying net belt 16 from bottom to top to reach the bottom of the plate-shaped workpiece, so that the plate-shaped workpiece is finally flushed; in the water removal area, the high-pressure air flow output from the upper air knife passes through the interval between the adjacent rubber coating roller shafts 25 from top to bottom to reach the upper part of the plate-shaped workpiece, and the high-pressure air flow output from the lower air knife passes through the conveying mesh belt 16 from bottom to top to reach the bottom of the plate-shaped workpiece, so that the water on the plate-shaped workpiece is finally blown off;

the floating type pressing mechanism 2 is respectively arranged in the flushing area and the dewatering area, and enters a space for floating clamping the workpiece formed between the plurality of rubber coating roller shafts 25 and the conveying surface when the plate-shaped workpiece enters the flushing area or the dewatering area, and in the process that the plate-shaped workpiece passes through the space, the plate-shaped workpiece pushes the rubber coating roller shafts 25 to drive the bearings A232 to move upwards, the springs A233 are driven to compress, the reaction force generated by compression drives the bearings A232 to drive the rubber coating roller shafts 25 to apply downward force to the plate-shaped workpiece so as to increase the pressure of the plate-shaped workpiece on the conveying net belt 16, and the friction force between the plate-shaped workpiece and the conveying net belt is increased along with the pressure in a proportional relation, and is larger than the travelling resistance of the plate-shaped workpiece in the flushing area or the dewatering area, so that the travelling resistance can be overcome, and the plate-shaped workpiece is prevented from being hindered from normally travelling;

the travelling resistance of the plate-shaped workpiece in the flushing area is the resistance of the high-pressure spray water flow to the plate-shaped workpiece, and the travelling resistance of the plate-shaped workpiece in the water removing area is the resistance of the high-pressure air flow to the plate-shaped workpiece.

The above description should not be taken as limiting the scope of the utility model, and any modifications, equivalent changes and modifications made to the above embodiments according to the technical principles of the present utility model still fall within the scope of the technical solutions of the present utility model.

Claims (10)

1. The conveying device for cleaning the workpiece is characterized in that: the floating type pressing device comprises a conveying belt mechanism and a floating type pressing mechanism, wherein the floating type pressing mechanism is located above the conveying belt mechanism, a space for floating and clamping a workpiece is formed between a conveying surface of the conveying belt mechanism and the floating type pressing mechanism, the conveying belt mechanism is used for driving the workpiece to move through friction, and the floating type pressing mechanism is used for floating type pressing the workpiece to increase friction for driving the workpiece to move.

2. A conveyor for cleaning workpieces as defined in claim 1, wherein: the conveying belt mechanism comprises a driving rubber coating roller, a driving roller support, a driving assembly, a driven rubber coating roller, a driven roller support and a conveying net belt, wherein the driving rubber coating roller and the driven rubber coating roller are respectively and rotatably connected to the driving roller support and the driven roller support, the driving assembly is arranged on the driving roller support and is in driving connection with one end of the driving rubber coating roller, and the driving assembly drives the driving rubber coating roller to do rotary motion through the conveying net belt in a linkage mode.

3. A conveyor for cleaning workpieces as claimed in claim 2, wherein: the inner periphery of the conveying net belt is provided with a front closed-loop raised line and a rear closed-loop raised line.

4. A conveyor for cleaning workpieces as claimed in claim 3, wherein: the periphery of the driving rubber coating roller is provided with a front annular groove A and a rear annular groove A, the periphery of the driven rubber coating roller is provided with a front annular groove B and a rear annular groove B, the front annular groove A and the front annular groove B are matched with the front closed-loop convex strips, and the rear annular groove A and the rear annular groove B are matched with the rear closed-loop convex strips.

5. A conveyor for cleaning workpieces as claimed in claim 3, wherein: the novel rubber coating machine is characterized by further comprising an upper guide rubber coating roller and a lower guide rubber coating roller, wherein the upper guide rubber coating roller and the lower guide rubber coating roller are both arranged on a floating type pressing mechanism, the upper guide rubber coating roller is located above the lower guide rubber coating roller, a front annular groove C and a rear annular groove C are arranged on the periphery of the upper guide rubber coating roller, a front annular groove D and a rear annular groove D are arranged on the periphery of the lower guide rubber coating roller, the front annular groove C and the front annular groove D are matched with a front closed-loop convex strip, and the rear annular groove C and the rear annular groove D are matched with a rear closed-loop convex strip.

6. A conveyor for cleaning workpieces as defined in claim 1, wherein: the floating type pushing mechanism comprises a bottom frame, a roller shaft support, a front elastic reset assembly, a rear elastic reset assembly and a plurality of rubber coating roller shafts which are arranged at intervals along the left and right directions, wherein the roller shaft support is arranged in a mirror image mode, the front elastic reset assembly and the rear elastic reset assembly are respectively arranged on the roller shaft support which is arranged in the mirror image mode, two ends of the rubber coating roller shafts are respectively and rotatably connected with the front elastic reset assembly and the rear elastic reset assembly, and all transversely span the upper portion of a conveying surface, and a space for floating and clamping workpieces is formed between the rubber coating roller shafts and the conveying surface.

7. A conveyor for cleaning workpieces as defined in claim 6, wherein: the back elastic reset assembly comprises a spring upper limit module A, a plurality of bearings A and a plurality of springs A, wherein a plurality of U-shaped openings A are formed in the upper portion of the roll shaft support, the spring upper limit module A is installed on the roll shaft support, the bearings A are respectively matched in the plurality of U-shaped openings A in a sliding mode up and down and are respectively sleeved outside the end portions of the plurality of rubber coating roll shafts, the springs A are arranged between the spring upper limit module A and the bearings A, and the springs A respectively drive the plurality of bearings A to be respectively attached to the bottoms of the plurality of U-shaped openings A through elasticity.

8. A conveyor for cleaning workpieces as defined in claim 1, wherein: the conveying surface stabilizing mechanism is arranged on the floating pressing mechanism, and the conveying surface passes through the conveying surface stabilizing mechanism.

9. A conveyor for cleaning workpieces as defined in claim 8, wherein: the conveying surface stabilizing mechanism comprises a roller support, a lower rubber coating roller, a front elastic pressing driving assembly, a rear elastic pressing driving assembly and an upper rubber coating roller, wherein the roller support is arranged in a mirror image mode, the lower rubber coating roller is rotatably connected with the roller support which is arranged in a mirror image mode, the front elastic pressing driving assembly and the rear elastic pressing driving assembly are respectively arranged on the roller support which is arranged in a mirror image mode, the two ends of the upper rubber coating roller are respectively rotatably connected with the front elastic pressing driving assembly and the rear elastic pressing driving assembly, and the front elastic pressing driving assembly and the rear elastic pressing driving assembly are respectively used for driving the upper rubber coating roller to press a conveying surface on the lower rubber coating roller through elastic force.

10. A conveyor for cleaning workpieces as defined in claim 9, wherein: the back elasticity pushes down drive assembly includes spacing module B, bearing B and spring B on the spring, U-shaped mouth B has been seted up on the upper portion of roller support, spacing module B installs on the roller support on the spring, bearing B can slide from top to bottom and cooperate in U-shaped mouth B and overlap and establish under the rubber coating roller's tip outside, spring B sets up on the spring between spacing module B and bearing B, spring B drives the rubber coating roller through elasticity drive bearing B and presses the transport plane on lower rubber coating roller.