CN212917411U - Semi-automatic pin shearing and testing integrated machine - Google Patents

Abstract

A semi-automatic pin shearing and testing all-in-one machine comprises: the automatic feeding device comprises a rack, a feeding assembly, a positioning assembly, a pin shearing assembly, a turning assembly, a transmission assembly, a detection assembly, a sorting assembly, a control assembly and a power supply. The application provides a pair of semi-automatic pin-shearing test all-in-one machine can accomplish the input of transformer, unnecessary stitch subtract, upset, test and select separately the operation automatically, only need few artifical auxiliary work, has liberated manpower resources greatly, has improved work efficiency simultaneously.

Description

Semi-automatic pin shearing and testing integrated machine

Technical Field

The utility model belongs to the technical field of the transformer production, concretely relates to semi-automatic foot test all-in-one of cutting.

Background

In the process of manufacturing the transformer, the redundant pins on the transformer need to be subtracted, and the transformer needs to be tested to judge whether the pins are qualified or unqualified. But at present, the work is always completely carried out manually, which greatly reduces the production efficiency of the transformer.

SUMMERY OF THE UTILITY MODEL

In order to solve the problem, the utility model provides a semi-automatic foot test all-in-one of cutting, include:

the frame is used for mounting each component;

the feeding assembly is used for inputting the transformer; the feeding assembly is arranged on the rack;

the positioning assembly is used for positioning the transformer; the positioning assembly is arranged on the rack;

the pin shearing assembly is used for shearing pins on the transformer; the pin shearing assembly is arranged on the rack;

the overturning assembly is used for overturning the transformer with the pins cut off; the overturning assembly is arranged on the rack;

the transmission assembly is used for transmitting the turned transformer; the transmission assembly is arranged on the rack;

the detection component is used for detecting the transformer on the transmission component; the detection assembly is arranged on the rack;

the sorting assembly is used for sorting the detected transformers; the sorting assembly is arranged on the rack;

the control assembly is used for controlling each assembly; the control assembly is arranged on the rack and is respectively connected with the feeding assembly, the positioning assembly, the pin shearing assembly, the overturning assembly, the transmission assembly, the detection assembly and the sorting assembly;

the power supply is used for supplying power to each component; the power supply is arranged on the rack and is respectively connected with the feeding assembly, the positioning assembly, the pin shearing assembly, the overturning assembly, the transmission assembly, the detection assembly, the sorting assembly and the control assembly.

Preferably, the feed assembly comprises: the feeding device comprises a supporting block, a direct vibration block, a track cushion block and a feeding track, wherein the supporting block is arranged on the rack, the direct vibration block is arranged on the supporting block, the track cushion block is arranged on the direct vibration block, and the feeding track is arranged on the track cushion block and is connected with the positioning component.

Preferably, the positioning assembly comprises: the feeding mechanism comprises a fixed plate, a connecting plate, a positioning seat, a pressing piece, a supporting rod, a connecting block, a connecting rod, a cylinder mounting seat, a positioning cylinder and a pressing block, wherein the fixed plate is arranged on the rack, the connecting plate is connected with the fixed plate, the positioning seat is arranged on the connecting plate and connected with a feeding track in a feeding assembly, the pressing piece is arranged on the positioning seat, the supporting rod is arranged on the rack, the connecting block is respectively connected with the supporting rod and the connecting rod, the cylinder mounting seat is connected with the connecting rod, the positioning cylinder is arranged on the cylinder mounting seat, the cylinder mounting seat is connected with the pressing block, and the pressing piece is controlled to be in contact with or kept away from the cylinder mounting seat.

Preferably, the scissor assembly comprises: base, cylinder connecting plate, removal cylinder, mount pad connecting plate, gas are cut cylinder mount pad, gas and are cut cylinder and holding tank, wherein, the base set up in the frame, the cylinder connecting plate respectively with the base with the removal cylinder is connected, the mount pad connecting plate with the removal cylinder is connected, gas is cut the cylinder mount pad with the mount pad connecting plate is connected, gas cut the cylinder set up in on the cylinder mount pad is cut to gas to be close to the positioning seat, the holding tank set up in the frame, and be located under the positioning seat among the locating component.

Preferably, the flipping assembly comprises: motor mount pad, motor, finger cylinder mount pad, finger cylinder and press from both sides tight piece, wherein, the motor mount pad set up in the frame, the motor set up in on the motor mount pad, finger cylinder mount pad with hub connection between the motor, the finger cylinder set up in on the finger cylinder mount pad, two press from both sides tight piece respectively with the finger cylinder is connected, and sets up relatively.

Preferably, the transmission assembly comprises: the base plate, driven wheel bearings, driven wheels, driving wheel bearings, driving wheels, baffle plates, a belt and a driving motor, wherein the two base plates are arranged on the frame, the two driven wheel bearings are oppositely arranged on the base plate, the two driven wheels are respectively correspondingly sleeved on the two driven wheel bearings, the driving wheel bearings are arranged on the base plate and are positioned between the two driven wheel bearings, the driving wheel is sleeved on the driving wheel bearings, the belt is connected with the two driven wheels and the driving wheel, the two baffle plates are respectively correspondingly arranged on the two base plates and are respectively arranged on two sides of the belt, and the driving motor is arranged on the frame and is connected with the driving wheel bearings.

Preferably, the detection assembly comprises: aversion cylinder mounting panel, aversion cylinder, probe mount pad and test probe, wherein, aversion cylinder mounting panel set up in the frame, the aversion cylinder set up in on the aversion cylinder mounting panel, the probe mount pad with the aversion cylinder is connected, test probe set up in on the probe mount pad, and be located directly over the belt in the transmission assembly.

Preferably, the sorting assembly comprises: mounting bracket, material way, proximity switch, actuating cylinder, ejector pad, separation cylinder, sorting block, separation tank and silo, wherein, the mounting bracket set up in the frame, the material way set up in on the mounting bracket, and with belt among the transmission assembly is connected, proximity switch set up in on the mounting bracket, and with the belt is relative, actuating cylinder set up in on the mounting bracket, and with the ejector pad is connected, and control it and be in motion in the material way, the separation tank set up in on the mounting bracket, the silo set up in the frame, and be located under the export of separation tank, the separation cylinder set up in on the mounting bracket, and with the sorting block is connected to control its orientation or keep away from the entry motion of separation tank.

The application provides a pair of semi-automatic pin-shearing test all-in-one machine can accomplish the input of transformer, unnecessary stitch subtract, upset, test and select separately the operation automatically, only need few artifical auxiliary work, has liberated manpower resources greatly, has improved work efficiency simultaneously.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without inventive exercise.

Fig. 1 is a schematic structural view of a semi-automatic pin shearing and testing integrated machine provided by the present invention;

fig. 2 is a schematic structural view of a semi-automatic pin shearing and testing integrated machine provided by the present invention;

fig. 3 is a schematic structural view of a semi-automatic pin shearing and testing integrated machine provided by the present invention;

fig. 4 is a schematic structural diagram of a semi-automatic pin shearing and testing integrated machine provided by the present invention;

fig. 5 is a schematic structural view of a semi-automatic pin shearing and testing integrated machine provided by the present invention;

fig. 6 is a schematic structural view of a semi-automatic pin shearing and testing integrated machine provided by the present invention;

fig. 7 is a schematic structural view of a semi-automatic pin shearing and testing integrated machine provided by the present invention;

fig. 8 is a schematic structural view of a semi-automatic pin shearing and testing integrated machine provided by the present invention;

fig. 9 is a schematic structural diagram of a semi-automatic pin shearing and testing integrated machine provided by the utility model.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in detail with reference to the accompanying drawings. It should be understood that the description is intended to be illustrative only and is not intended to limit the scope of the present invention. Moreover, in the following description, descriptions of well-known structures and techniques are omitted so as to not unnecessarily obscure the concepts of the present invention.

As shown in fig. 1-9, in an embodiment of the present application, the present application provides a semi-automatic pin shearing and testing all-in-one machine, including: the rack 100, the feeding assembly 200, the positioning assembly 300, the cutting foot assembly 400, the overturning assembly 500, the transmission assembly 600, the detection assembly 700, the sorting assembly 800, the control assembly 900 and the power supply 1000, which are described in detail below.

As shown in fig. 1-9, in the embodiment of the present application, a semi-automatic pin shearing and testing all-in-one machine provided by the present application includes:

a frame 100 for mounting components;

the feeding assembly 200 is used for inputting a transformer; the feeding assembly 200 is arranged on the rack 100;

a positioning assembly 300 for positioning the transformer; the positioning assembly 300 is disposed on the rack 100;

a pin cutting assembly 400 for cutting pins on the transformer; the pin shearing assembly 400 is arranged on the rack 100;

the overturning component 500 is used for overturning the transformer with the pins cut off; the turnover assembly 500 is disposed on the frame 100;

a transmission assembly 600 for transmitting the turned transformer; the transmission assembly 600 is disposed on the rack 100;

a detection assembly 700 for detecting a transformer on the transmission assembly 600; the detection assembly 700 is disposed on the rack 100;

a sorting assembly 800 for sorting the detected transformers; the sorting assembly 800 is arranged on the rack 100;

a control component 900 for controlling the components; the control assembly 900 is disposed on the rack 100 and is respectively connected to the feeding assembly 200, the positioning assembly 300, the foot shearing assembly 400, the turning assembly 500, the conveying assembly 600, the detecting assembly 700 and the sorting assembly 800;

a power supply 1000 for supplying power to the components; the power supply 1000 is disposed on the rack 100 and is respectively connected to the feeding assembly 200, the positioning assembly 300, the pin shearing assembly 400, the turning assembly 500, the transmission assembly 600, the detection assembly 700, the sorting assembly 800, and the control assembly 900.

When the semi-automatic pin-cutting and testing integrated machine works, the feeding assembly 200 inputs a transformer, the positioning assembly 300 positions the transformer temporarily, then the pin-cutting assembly 400 subtracts redundant pins on the transformer, the overturning assembly 500 clamps the transformer and overturns the transformer for 180 degrees and then places the transformer on the transmission assembly 600, the transmission assembly 600 conveys the transformer to the detection assembly 700 for detection, and the sorting assembly 800 sorts qualified and unqualified transformers to different positions according to the detection result of the detection assembly 700.

As shown in fig. 1-9, in the present embodiment, the feeding assembly 200 includes: the supporting block 201, directly shake 202, track cushion 203 and feeding track 204, wherein, the supporting block 201 set up in on the frame 100, directly shake 202 set up in on the supporting block 201, the track cushion 203 set up in directly shake 202 on, feeding track 204 set up in on the track cushion 203, and with locating component 300 is connected. The transformer is conveyed into the feeding track 204 through automatic equipment such as manpower or a mechanical arm, the control assembly 900 controls the direct vibration 202 to vibrate, and the direct vibration 202 drives the track cushion block 203 and the feeding track 204 to vibrate, so that the transformer is conveyed to the positioning assembly 300.

As shown in fig. 1-9, in the embodiment of the present application, the positioning assembly 300 includes: a fixed plate 301, a connecting plate 302, a positioning seat 303, a pressing sheet 304, a supporting rod 305, a connecting block 306, a connecting rod 307, a cylinder mounting seat 308, a positioning cylinder 309 and a pressing block 310, wherein the fixing plate 301 is disposed on the rack 100, the connecting plate 302 is connected to the fixing plate 301, the positioning seat 303 is disposed on the connecting plate 302, and is connected with the feeding track 204 in the feeding assembly 200, the pressing sheet 304 is disposed on the positioning seat 303, the support bar 305 is disposed on the frame 100, the connecting blocks 306 are respectively connected with the support bar 305 and the connecting bar 307, the cylinder mounting seat 308 is connected to the connecting rod 307, the positioning cylinder 309 is disposed on the cylinder mounting seat 308, the cylinder mounting block 308 is connected with the pressing block 310 and is controlled to contact with or separate from the pressing sheet 304.

When the transformer is conveyed into the positioning seat 303 through the feeding rail 204, the positioning cylinder 309 controls the pressing block 310 to move towards the pressing sheet 304, the pressing block 310 abuts against the pressing sheet 304, and since the distance from the pressing sheet 304 to the bottom wall of the positioning seat 303 is less than or equal to the height of the transformer, when the pressing sheet 304 abuts against downwards, the transformer is pressed, and the pressing sheet temporarily stays in the positioning seat 303.

As shown in fig. 1-9, in the present embodiment, the shear foot assembly 400 includes: base 401, cylinder connecting plate 402, remove cylinder 403, mount pad connecting plate 404, gas shear cylinder mount pad 405, gas shear cylinder 406 and holding tank 407, wherein, base 401 set up in on the frame 100, cylinder connecting plate 402 respectively with base 401 with remove cylinder 403 connects, mount pad connecting plate 404 with remove cylinder 403 connects, gas shear cylinder mount pad 405 with mount pad connecting plate 404 connects, gas shear cylinder 406 set up in on the gas shear cylinder mount pad 405 to be close to positioning seat 303, holding tank 407 set up in on the frame 100, and be located under positioning seat 303 in locating component 300.

When the transformer is pressed by the pressing piece 304 and temporarily stays in the positioning socket 303, the moving cylinder 403 controls the cylinder connecting plate 402 and the mounting socket connecting plate 404 to move towards the positioning socket 303, and the air shear cylinder 406 connects to the transformer and subtracts the excess pins on the transformer, and the excess pins fall into the receiving slots 407 right below.

As shown in fig. 1-9, in the present embodiment, the flipping module 500 comprises: motor mount 501, motor 502, finger cylinder mount 503, finger cylinder 504 and press from both sides tight piece 505, wherein, motor mount 501 set up in on the frame 100, motor 502 set up in on the motor mount 501, finger cylinder mount 503 with the hub connection between the motor 502, finger cylinder 504 set up in on the finger cylinder mount 503, two press from both sides tight piece 505 respectively with finger cylinder 504 is connected, and sets up relatively.

When the redundant pins are subtracted from the transformer, the motor 502 rotates and drives the finger cylinder mounting seat 503 and the finger cylinder 504 to rotate towards the positioning seat 303, and when the finger cylinder 504 is close to the positioning seat 303, the finger cylinder 504 controls the two opposite clamping pieces 505 to move oppositely and clamp the transformer together; then the motor 502 controls the finger cylinder mounting seat 503 and the finger cylinder 504 to rotate towards the transmission assembly 600, when the finger cylinder 504 approaches the transmission assembly 600, the finger cylinder 504 controls the two opposite clamping pieces 505 to move back and forth, and the transformer is released into the transmission assembly 600.

As shown in fig. 1-9, in the embodiment of the present application, the transmission assembly 600 includes: a base plate 601, a driven wheel bearing 602, a driven wheel 603, a driving wheel bearing 604, a driving wheel 605, a baffle 606, a belt 607 and a driving motor 608, wherein, two base plates 601 are arranged on the machine frame 100, two driven wheel bearings 602 are oppositely arranged on the base plates 601, two driven wheels 603 are respectively correspondingly sleeved on the two driven wheel bearings 602, the driving wheel bearing 604 is arranged on the base plates 601, and is located between the two driven wheel bearings 602, the driving wheel 605 is sleeved on the driving wheel bearing 604, the belt 607 connects the two driven wheels 603 and the driving wheel 605, the two baffles 606 are respectively correspondingly arranged on the two base plates 601, and are respectively disposed at two sides of the belt 607, and the driving motor 608 is disposed on the frame 100 and is connected with the driving wheel bearing 604 through a shaft.

When the transformer is released into the transmission assembly 600, specifically, the transformer is placed on the belt 607, at this time, the driving motor 608 is started and drives the driving pulley bearing 604 and the driving pulley 605 to rotate, thereby driving the belt 607 to move and driving the two driven pulleys 603 to rotate, and the transformer on the belt 607 is conveyed to the detection assembly 700 for detection.

As shown in fig. 1-9, in the embodiment of the present application, the detecting assembly 700 includes: the device comprises a shifting cylinder mounting plate 701, a shifting cylinder 702, a probe mounting seat 703 and a detection probe 704, wherein the shifting cylinder mounting plate 701 is arranged on the rack 100, the shifting cylinder 702 is arranged on the shifting cylinder mounting plate 701, the probe mounting seat 703 is connected with the shifting cylinder 702, and the detection probe 704 is arranged on the probe mounting seat 703 and is positioned right above a belt 607 in the transmission assembly 600.

When the transformer is transported to a predetermined position on the inspection assembly 700, specifically, when the transformer is transported to a position directly below the inspection probe 704, the shift cylinder 702 controls the probe mounting base 703 to move downward to be close to the transformer, and the inspection probe 704 contacts the transformer and inspects the transformer to determine whether the transformer is qualified.

As shown in fig. 1-9, in the present embodiment, the sorting assembly 800 includes: a mounting rack 801, a material channel 802, a proximity switch 803, a pushing cylinder 804, a pushing block 805, a sorting cylinder 806, a sorting block 807, a sorting groove 808 and a material groove 809, wherein the mounting rack 801 is arranged on the rack 100, the material channel 802 is arranged on the mounting rack 801, and is connected with the belt 607 of the transmission assembly 600, the proximity switch 803 is arranged on the mounting block 801, and opposite to the belt 607, the push cylinder 804 is provided on the mounting block 801, and is connected with the push block 805 and controls the push block to move in the material channel 802, the sorting groove 808 is arranged on the mounting rack 801, the material channel 809 is arranged on the rack 100, and is located right below the outlet of the sorting trough 808, the sorting cylinder 806 is provided on the mounting block 801, and is connected to the sorting block 807 and controls its movement toward or away from the inlet of the sorting chute 808.

After the transformer is detected at the detecting assembly 700, the transformer is continuously inputted into the material channel 802 by the belt 607. Before that, the pushing cylinder 804 controls the pushing block 805 to move in the material channel 802 in a direction away from the sorting block 807, when the approach switch 803 can detect the entering of the transformer after the transformer enters the material channel 802, at this time, the pushing cylinder 804 controls the pushing block 805 to move towards the sorting block 807, in the process, the pushing block 805 pushes the transformer to move towards the sorting block 807 and moves to the sorting block 807. At this time, the sorting cylinder 806 may control the sorting block 807 to move to the sorting slot 808 indicating the qualification, or control the sorting block 807 to move to the sorting slot 808 indicating the disqualification, according to the detection result of the detection assembly 700, so as to push the transformer at the sorting block 807 into the corresponding sorting slot 808, and then into the corresponding trough 809.

In this embodiment, the control component 900 may be a PLC controller, and the power supply 1000 may be a built-in power supply or an external power supply.

The application provides a pair of semi-automatic pin-shearing test all-in-one machine can accomplish the input of transformer, unnecessary stitch subtract, upset, test and select separately the operation automatically, only need few artifical auxiliary work, has liberated manpower resources greatly, has improved work efficiency simultaneously.

It is to be understood that the above-described embodiments of the present invention are merely illustrative of or explaining the principles of the invention and are not to be construed as limiting the invention. Therefore, any modification, equivalent replacement, improvement and the like made without departing from the spirit and scope of the present invention should be included in the protection scope of the present invention. Further, it is intended that the appended claims cover all such variations and modifications as fall within the scope and boundaries of the appended claims or the equivalents of such scope and boundaries.

Claims (8)

1. The utility model provides a semi-automatic foot test all-in-one of cutting which characterized in that includes:

the frame is used for mounting each component;

the feeding assembly is used for inputting the transformer; the feeding assembly is arranged on the rack;

the positioning assembly is used for positioning the transformer; the positioning assembly is arranged on the rack;

the pin shearing assembly is used for shearing pins on the transformer; the pin shearing assembly is arranged on the rack;

the overturning assembly is used for overturning the transformer with the pins cut off; the overturning assembly is arranged on the rack;

the transmission assembly is used for transmitting the turned transformer; the transmission assembly is arranged on the rack;

the detection component is used for detecting the transformer on the transmission component; the detection assembly is arranged on the rack;

the sorting assembly is used for sorting the detected transformers; the sorting assembly is arranged on the rack;

the control assembly is used for controlling each assembly; the control assembly is arranged on the rack and is respectively connected with the feeding assembly, the positioning assembly, the pin shearing assembly, the overturning assembly, the transmission assembly, the detection assembly and the sorting assembly;

the power supply is used for supplying power to each component; the power supply is arranged on the rack and is respectively connected with the feeding assembly, the positioning assembly, the pin shearing assembly, the overturning assembly, the transmission assembly, the detection assembly, the sorting assembly and the control assembly.

2. The semi-automatic foot shearing and testing all-in-one machine according to claim 1, wherein the feeding assembly comprises: the feeding device comprises a supporting block, a direct vibration block, a track cushion block and a feeding track, wherein the supporting block is arranged on the rack, the direct vibration block is arranged on the supporting block, the track cushion block is arranged on the direct vibration block, and the feeding track is arranged on the track cushion block and is connected with the positioning component.

3. The semi-automatic pin shearing and testing all-in-one machine according to claim 1, wherein the positioning assembly comprises: the feeding mechanism comprises a fixed plate, a connecting plate, a positioning seat, a pressing piece, a supporting rod, a connecting block, a connecting rod, a cylinder mounting seat, a positioning cylinder and a pressing block, wherein the fixed plate is arranged on the rack, the connecting plate is connected with the fixed plate, the positioning seat is arranged on the connecting plate and connected with a feeding track in a feeding assembly, the pressing piece is arranged on the positioning seat, the supporting rod is arranged on the rack, the connecting block is respectively connected with the supporting rod and the connecting rod, the cylinder mounting seat is connected with the connecting rod, the positioning cylinder is arranged on the cylinder mounting seat, the cylinder mounting seat is connected with the pressing block, and the pressing piece is controlled to be in contact with or kept away from the cylinder mounting seat.

4. The semi-automatic pin-shearing testing all-in-one machine according to claim 1, wherein the pin-shearing assembly comprises: base, cylinder connecting plate, removal cylinder, mount pad connecting plate, gas are cut cylinder mount pad, gas and are cut cylinder and holding tank, wherein, the base set up in the frame, the cylinder connecting plate respectively with the base with the removal cylinder is connected, the mount pad connecting plate with the removal cylinder is connected, gas is cut the cylinder mount pad with the mount pad connecting plate is connected, gas cut the cylinder set up in on the cylinder mount pad is cut to gas to be close to the positioning seat, the holding tank set up in the frame, and be located under the positioning seat among the locating component.

5. The semi-automatic pin shearing and testing all-in-one machine according to claim 1, wherein the overturning assembly comprises: motor mount pad, motor, finger cylinder mount pad, finger cylinder and press from both sides tight piece, wherein, the motor mount pad set up in the frame, the motor set up in on the motor mount pad, finger cylinder mount pad with hub connection between the motor, the finger cylinder set up in on the finger cylinder mount pad, two press from both sides tight piece respectively with the finger cylinder is connected, and sets up relatively.

6. The semi-automatic pin shearing and testing all-in-one machine according to claim 1, wherein the transmission assembly comprises: the base plate, driven wheel bearings, driven wheels, driving wheel bearings, driving wheels, baffle plates, a belt and a driving motor, wherein the two base plates are arranged on the frame, the two driven wheel bearings are oppositely arranged on the base plate, the two driven wheels are respectively correspondingly sleeved on the two driven wheel bearings, the driving wheel bearings are arranged on the base plate and are positioned between the two driven wheel bearings, the driving wheel is sleeved on the driving wheel bearings, the belt is connected with the two driven wheels and the driving wheel, the two baffle plates are respectively correspondingly arranged on the two base plates and are respectively arranged on two sides of the belt, and the driving motor is arranged on the frame and is connected with the driving wheel bearings.

7. The semi-automatic pin shearing and testing all-in-one machine according to claim 1, wherein the detection assembly comprises: aversion cylinder mounting panel, aversion cylinder, probe mount pad and test probe, wherein, aversion cylinder mounting panel set up in the frame, the aversion cylinder set up in on the aversion cylinder mounting panel, the probe mount pad with the aversion cylinder is connected, test probe set up in on the probe mount pad, and be located directly over the belt in the transmission assembly.

8. The semi-automatic pin shearing and testing all-in-one machine according to claim 1, wherein the sorting assembly comprises: mounting bracket, material way, proximity switch, actuating cylinder, ejector pad, separation cylinder, sorting block, separation tank and silo, wherein, the mounting bracket set up in the frame, the material way set up in on the mounting bracket, and with belt among the transmission assembly is connected, proximity switch set up in on the mounting bracket, and with the belt is relative, actuating cylinder set up in on the mounting bracket, and with the ejector pad is connected, and control it and be in motion in the material way, the separation tank set up in on the mounting bracket, the silo set up in the frame, and be located under the export of separation tank, the separation cylinder set up in on the mounting bracket, and with the sorting block is connected to control its orientation or keep away from the entry motion of separation tank.

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