CN218694109U - Machining device suitable for cast molding positioning block on telescopic belt conveyor - Google Patents

Abstract

The utility model provides a processing device suitable for a casting positioning block on a telescopic belt conveyor, which comprises a main body frame, a turning part, a loading part, an unloading part, a detection and distribution part and a control part; the main body frame comprises a storage seat, a feeding seat and a discharging seat; the feeding part comprises a screw rod motor I, a screw rod motor II, a conveyor belt device I, an air cylinder I, a compressor and a pushing block; the discharging part comprises a screw rod motor III, a screw rod motor IV, a cylinder II, an n-shaped positioning column and an F-shaped grabbing rod. When can realize flexible band conveyer production, the semi-automatic material loading of casting type locating piece and unloading have reduced intensity of labour, need not hand contact casting spare, have reduced the potential safety hazard when reducing the load, and efficiency obtains promoting, and manufacturing cost is showing and is descending.

Description

Machining device suitable for cast molding positioning block on telescopic belt conveyor

Technical Field

The utility model relates to a flexible quick-witted field especially relates to a processingequipment suitable for cast molding locating piece on flexible band conveyer.

Background

The telescopic belt conveyer (also known as telescopic car loader) can be freely stretched in the length direction, and the length of the conveyer can be controlled at any time. The material conveying device can be operated in two directions to convey materials, is matched with other conveying equipment and a material sorting system to be used, realizes semi-automation of material warehousing and transportation and vehicle loading and unloading, and is widely applied to various industries.

The use of the telescopic belt conveyor shortens the distance between workers for carrying materials back and forth, can shorten the cargo loading and unloading time, reduces the labor intensity, reduces the damage of goods, reduces the loading and unloading cost, improves the working efficiency, and is firstly used for logistics express delivery and tobacco industry.

In the manufacturing process of the telescopic belt conveyor, holes need to be formed on casting positioning blocks (such as pin shaft positioning blocks, roller shaft positioning blocks or shaft positioning blocks) of one of the parts of the telescopic belt conveyor. Because the casting type positioning block shape specially used for the telescopic belt conveyor is different from that of a common positioning block, in the traditional process, the upper material and the lower material are mostly artificial, and the defects of high labor intensity, heavy burden of hands, low working efficiency, potential safety hazards and the like exist.

SUMMERY OF THE UTILITY MODEL

The utility model provides a processingequipment suitable for casting moulding locating piece on flexible band conveyer has solved flexible band conveyer casting moulding locating piece follow-up course of working, and material intensity of labour is big about having, the heavy load of hand, work efficiency hangs down and has the potential safety hazard scheduling problem.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a processing device suitable for a cast molding positioning block on a telescopic belt conveyor comprises a main body frame, a turning part, a feeding part, a discharging part, a detection and diversion part and a control part.

The main body frame comprises a storage seat, a feeding seat and a discharging seat.

The storage seat comprises a cuboid hollow container I, an L-shaped limiting block, an L-shaped vertical plate and a supporting column.

The support column is arranged on the outer wall of a lower bottom plate of the cuboid hollow container.

The L-shaped limiting blocks are equidistantly arranged on an upper bottom plate of the rectangular hollow container; the L-shaped limiting blocks are distributed in a rectangular shape.

The L-shaped vertical plate is arranged on an upper bottom plate of the cuboid hollow container.

The feeding seat comprises an L-shaped supporting plate I, a base plate I and a cuboid hollow container II.

The first substrate is arranged on the first L-shaped supporting plate.

And the first base plate is provided with an adjusting screw hole.

The first substrate is provided with two substrates which are detachably connected through a bidirectional adjusting screw rod.

The first base plate is provided with a limiting sliding groove.

And the second cuboid hollow container is connected with the limiting sliding chute in a sliding manner.

The unloading seat comprises an L-shaped support plate II, a substrate II, a U-shaped outer frame, a cuboid hollow container III and a cuboid hollow container IV.

The U-shaped outer frame is provided with a circular screw hole; an adjusting screw is arranged in the circular screw hole.

One end of the adjusting screw rod is arranged on the L-shaped support plate II through a rolling bearing.

The second substrate is arranged on the U-shaped outer frame.

The cuboid hollow container IV is arranged on the substrate II.

And the cuboid hollow container III is connected with the substrate II in a sliding manner through a sliding rail.

And a first rectangular through hole is formed in the three left side plates of the cuboid hollow container.

A rectangular through hole II is formed in the upper bottom plate of the cuboid hollow container III; the second rectangular through hole is superposed with one end of the first rectangular through hole.

A rectangular through hole III is formed in the front side plate of the cuboid hollow container III; and a defective product channel is arranged on the third rectangular through hole.

And a rectangular through hole IV is formed in the right side plate of the cuboid hollow container.

Rectangular through holes five are formed in the four left side plates and the right side plate of the cuboid hollow container.

A rectangular through hole six is formed in the upper bottom plate of the rectangular hollow container four; and six rectangular through holes are connected with cover plates through hinges.

The turning part comprises a linear motor I, a linear motor II, a servo motor, a scroll and an electromagnet.

The linear motor I is arranged on the L-shaped limiting block.

And the second linear motor is arranged on a rotor of the first linear motor.

And the servo motor and the scroll are arranged on a rotor of the linear motor II through a connecting frame.

The servo motor is in transmission connection with the reel through a reduction gear box.

The electromagnet is connected with the reel through a limiting pipe rope chain; and the upper end of the limiting pipe is arranged on the connecting frame.

The feeding part comprises a first screw rod motor, a second screw rod motor, a first conveyor belt device, a first air cylinder, a compressor and a pushing block.

The first conveyor belt device is arranged on an upper bottom plate of the second cuboid hollow container through an L-shaped guard plate.

The first screw rod motor is arranged on the first substrate.

And a rotor of the first screw rod motor is connected with a side plate of the second cuboid hollow container.

And the second screw rod motor is arranged on the second upper bottom plate of the cuboid hollow container.

The first air cylinder is arranged on a rotor of the second screw motor through an L-shaped mounting plate.

The pushing block is arranged on the movable end of the first air cylinder.

An L-shaped positioning through groove is formed in the pushing block.

The discharging part comprises a screw rod motor III, a screw rod motor IV, a cylinder II, an n-shaped positioning column and an F-shaped grabbing rod.

And the third screw rod motor is arranged on the second substrate.

And a rotor of the screw rod motor III is connected with a side plate of the cuboid hollow container III.

And the screw rod motor IV is arranged in the cuboid hollow container III.

And the second air cylinder is arranged on a rotor of the fourth screw rod motor.

The n-shaped positioning columns are arranged on the two movable ends of the cylinder in parallel through the fixing plate.

The F-shaped grabbing rod is connected to the n-shaped positioning column in a sliding mode; and the F-shaped grabbing rod spring is connected to the fixing plate.

The detection and flow-dividing part comprises a second conveyor belt device, a third conveyor belt device, a fourth conveyor belt device, a pressure sensor module, a pressure plate, a third air cylinder, a fourth air cylinder, a 'halberd' shaped adjusting plate, an 'I' shaped adjusting plate, a fifth screw rod motor and a first distance sensor module.

And the second conveyor belt device is arranged in the third cuboid hollow container.

The pressure sensor module and the pressure plate are arranged in the cuboid hollow container III through the mounting frame; the pressure sensor module is located below the pressure plate.

The second conveyor belt device is positioned on the rear side of the pressure plate, and the pressure plate is positioned below the second conveyor belt device.

And the pressure plate is provided with a limiting bulge.

And the cylinder III is arranged in the cuboid hollow container III through a mounting frame.

The cylinder is located behind the pressure plate.

The 'halberd' shaped adjusting plate is arranged at the movable end of the cylinder III; the Bu-shaped adjusting plate is matched with the pressure plate; the Bu-shaped adjusting plate is composed of a fixed plate and a telescopic rod.

And the cylinder IV is arranged in the cuboid hollow container III through a mounting frame.

The cylinder is four to the left of the pressure plate.

The I-shaped adjusting plate is arranged at the movable end of the cylinder IV; the I-shaped adjusting plate is matched with the pressure plate.

And the third conveyor belt device is arranged in the third cuboid hollow container.

The third conveyor belt device is positioned on the right side of the pressure plate; the right end of the third conveyor belt device is arranged on the outer wall of the right side plate of the cuboid hollow container.

And the screw rod motor V is arranged on the inner wall of the upper bottom plate of the cuboid hollow container.

And the first distance sensor module is arranged on the rotor of the fifth screw rod motor in an equal distance through a fixed plate.

And the fourth conveyor belt device is arranged in the fourth cuboid hollow container.

The control part comprises a control mechanism, a PLC controller and a feedback mechanism.

The control mechanism comprises a starting switch, a feeding switch, a discharging switch and a pause switch.

The feedback mechanism comprises a second distance sensor module, a third distance sensor module and a photoelectric counting sensor module.

Preferably, the rectangular parallelepiped hollow vessel four is replaced with an "L" -shaped movable plate.

Preferably, the "F" shaped gripping bar is replaced by a vacuum cup and a mounting bar, and the vacuum cup is connected to the compressor by a solenoid valve.

Preferably, the L-shaped vertical plate is replaced by the eta-shaped supporting plate, and the short end of the eta-shaped supporting plate is arranged on the cuboid hollow container I, so that the load capacity is improved.

Preferably, the electric telescopic rod is used for replacing the screw rod motor IV, so that the load capacity is improved.

Furthermore, a light emitting diode is additionally arranged on the first substrate, a corresponding button battery and an infrared induction switch are additionally arranged, and the button battery and the light emitting diode are connected in series.

Compared with the prior art, the method has the beneficial effects that:

the utility model discloses in, through main body frame, transfer part, material loading part, the part of unloading, detect reposition of redundant personnel part and control unit's integration setting, when having realized flexible band conveyer production, the semi-automatic feeding of casting type locating piece with unload, reduced intensity of labour, need not hand contact cast member, reduced the potential safety hazard in the time of reducing the load, efficiency obtains promoting, manufacturing cost is showing and descends.

Drawings

Fig. 1 is a schematic view of the top view of the partial cross-sectional structure of the present invention;

FIG. 2 is a schematic view of the front view of the partial cross-section structure of the present invention;

FIG. 3 is a schematic top view of the part(s) processed by the present invention;

fig. 4 is a schematic diagram of the system structure of the present invention.

In the figure: 101. <xnotran> , 102. "L" , 103. "L" , 201. "L" , 202. , 203. , 204. , 301. "L" , 302. , 303. "U" , 304. , 305. , 306. , 307. , 308. , 309., 401. , 402. , 403. , 404., 501. , 502. , 503. , 504. , 505. , 506. "L" , 601. , 602. , 603. , 604. "F" , 701. , 702., 703. , 704. , 705. "" , 706. , 707. "I" , 708. , 709. , 801. , 901. , 902. . </xnotran>

Detailed Description

Embodiment 1, referring to fig. 1 to 4, a processing apparatus for a cast molding positioning block on a telescopic belt conveyor includes a main body frame, a turning section, a loading section, a discharging section, a detecting and diverting section, and a control section.

The main body frame comprises a storage seat, a feeding seat and a discharging seat.

The storage seat comprises a cuboid hollow container I101, an L-shaped limiting block 102, an L-shaped vertical plate 103 and a support column.

The support is arranged on the outer wall of the lower bottom plate of the first cuboid hollow container 101.

The L-shaped limiting blocks 102 are equidistantly arranged on an upper bottom plate of the first cuboid hollow container 101; the L-shaped stoppers 102 are arranged in a rectangular shape.

The L-shaped vertical plate 103 is arranged on the upper bottom plate of the first cuboid hollow container 101.

The feeding seat comprises a first L-shaped supporting plate 201, a first base plate 202 and a second cuboid hollow container 203.

The first substrate 202 is disposed on the first L-shaped supporting plate 201.

An adjusting screw hole is formed in the first substrate 202.

The first substrate 202 is arranged in two blocks and detachably connected with the first substrate through a bidirectional adjusting screw 204.

The first substrate 202 is provided with a limiting sliding groove.

The second cuboid hollow container 203 is connected to the limiting sliding groove in a sliding mode.

The discharging seat comprises a second L-shaped supporting plate 301, a second substrate 302, a U-shaped outer frame 303, a third cuboid hollow container 304 and a fourth cuboid hollow container 308.

The U-shaped outer frame 303 is provided with a circular screw hole; an adjusting screw 305 is arranged in the circular screw hole.

One end of the adjusting screw 305 is arranged on the second L-shaped supporting plate 301 through a rolling bearing.

The second substrate 302 is disposed on a "U" shaped frame 303.

The cuboid hollow container four 308 is arranged on the substrate two 302.

The cuboid hollow container III 304 is connected with the substrate II 302 in a sliding mode through a sliding rail.

And a rectangular through hole I is formed in the left side plate of the cuboid hollow container III 304.

A rectangular through hole II 306 is formed in the upper bottom plate of the cuboid hollow container III 304; the second rectangular through hole 306 is overlapped with one end of the first rectangular through hole.

A rectangular through hole III is formed in the front side plate of the cuboid hollow container III 304; and a defective product channel 307 is arranged on the rectangular through hole III.

And a rectangular through hole IV is formed in the right side plate of the cuboid hollow container III 304.

And rectangular through holes five are formed in the left side plate and the right side plate of the rectangular hollow container four 308.

A rectangular through hole six is formed in the upper bottom plate of the rectangular hollow container four 308; the rectangular through hole is hinged with a cover plate 309.

The turning part comprises a first linear motor 401, a second linear motor 402, a servo motor 403, a reel and an electromagnet 404.

The first linear motor 401 is arranged on the L-shaped limiting block 102.

The second linear motor 402 is disposed on the mover of the first linear motor 401.

The servo motor 403 and the reel are arranged on a rotor of the second linear motor 402 through a connecting frame.

The servo motor 403 is in transmission connection with the reel through a reduction gear box.

The electromagnet 404 is connected with the reel through a limiting pipe rope chain; and the upper end of the limiting pipe is arranged on the connecting frame.

The feeding part comprises a first screw motor 501, a second screw motor 502, a first conveyor belt device 503, a first air cylinder 504, a compressor and a pushing block 505.

The first conveyor belt device 503 is arranged on the upper bottom plate of the second cuboid hollow container 203 through an L-shaped guard plate.

The first lead screw motor 501 is arranged on the first substrate 202.

And a rotor of the first screw rod motor 501 is connected with a side plate of the second cuboid hollow container 203.

The second screw rod motor 502 is arranged on the upper bottom plate of the second cuboid hollow container 203.

The first air cylinder 504 is arranged on a rotor of the second screw motor 502 through an L-shaped mounting plate.

The pushing block 505 is arranged on the movable end of the first cylinder 504.

An L-shaped positioning through groove 506 is arranged on the pushing block 505.

The discharging part comprises a third screw motor 601, a fourth screw motor 602, a second air cylinder 603, an n-shaped positioning column and an F-shaped grabbing rod 604.

The third screw motor 601 is arranged on the second substrate 302.

And a rotor of the screw motor III 601 is connected with a side plate of the cuboid hollow container III 304.

The screw rod motor IV 602 is arranged in the cuboid hollow container III 304.

The second air cylinder 603 is arranged on a rotor of the fourth screw motor 602.

The n-shaped positioning column is arranged on the movable end of the second cylinder 603 in parallel through a fixing plate.

The F-shaped grabbing rod 604 is connected to the n-shaped positioning column in a sliding mode; and the "F" shaped grab bar 604 is spring attached to the fixed plate.

The detection and shunting part comprises a second conveyor belt device 701, a third conveyor belt device 708, a fourth conveyor belt device 801, a pressure sensor module, a pressure plate 702, a third air cylinder 704, a fourth air cylinder, an adjusting plate 705 in the shape of a Bu, an adjusting plate 707 in the shape of an I, a fifth screw motor 709 and a first distance sensor module.

The second conveyor belt device 701 is arranged in the third cuboid hollow container 304.

The pressure sensor module and the pressure plate 702 are arranged in the cuboid hollow container III 304 through a mounting frame; the pressure sensor module is located below the pressure plate 702.

The second conveyor belt device 701 is located at the rear side of the pressure plate 702, and the pressure plate 702 is located below the second conveyor belt device 701.

The pressure plate 702 is provided with a limit protrusion 703.

The cylinder III 704 is arranged in the cuboid hollow container III 304 through a mounting frame.

The cylinder three 704 is located behind the pressure plate 702.

The 'halberd' shape adjusting plate 705 is arranged at the movable end of the cylinder III 704; the "halberd" shaped adjustment plate 705 is adapted to the pressure plate 702; the "Bu" shape adjustment plate 705 is composed of a fixed plate and an expansion rod.

The cylinder four 706 is arranged in the cuboid hollow container three 304 through a mounting frame.

Cylinder four 706 is located to the left of pressure plate 702.

The I-shaped adjusting plate 707 is arranged at the movable end of the cylinder IV 706; an "I" shaped adjustment plate 707 is adapted to the pressure plate 702.

The third conveyor belt device 708 is arranged in the third cuboid hollow container 304.

The third conveyor belt assembly 708 is positioned on the right side of the pressure plate 702; the right end of the third conveyor belt device 708 is arranged on the outer wall of the right side plate of the third cuboid hollow container 304.

And the five screw rod motors 709 are arranged on the inner wall of the upper bottom plate of the cuboid hollow container III 304.

And the first distance sensor module is arranged on a rotor of the five screw rod motors 709 at equal intervals through a fixing plate.

The fourth conveyor belt device 801 is arranged in the fourth cuboid hollow container 308.

The control part comprises a control mechanism, a PLC controller and a feedback mechanism.

The control mechanism comprises a starting switch, a feeding switch, a discharging switch and a pause switch.

The starting switch, the feeding switch, the discharging switch and the pause switch are arranged on the four 308 front side plates of the cuboid hollow container.

The PLC controller is arranged in the cuboid hollow container I101.

The feedback mechanism comprises a second distance sensor module and a third distance sensor module;

and the distance sensor module II is arranged on the L-shaped guard plate.

The third distance sensor module is disposed on a sidewall of the pushing block 505.

The device comprises a linear motor I401, a linear motor II 402, a servo motor 403, an electromagnet 404, a screw motor I501, a screw motor II 502, a conveyor belt device I503, a compressor, a screw motor III 601, a screw motor IV 602, a conveyor belt device II 701, a conveyor belt device III 708, a conveyor belt device IV 801, a pressure sensor module, a screw motor V709, a distance sensor module I, a starting switch, a feeding switch, a discharging switch, a pause switch, a distance sensor module II, a distance sensor module III and a PLC.

The working principle and the using method are as follows:

step one, presetting:

will the utility model discloses a material loading seat and discharge carriage install on the processing diaphragm of trompil device 901 (like the drilling machine), are located the both sides of mold processing respectively. The distance between the first L-shaped supporting plates 201 can be adjusted through the bidirectional adjusting screw 204, and the position of the second L-shaped supporting plate 301 can be adjusted through the adjusting screw 305.

And placing the part 902 (with the wide head facing right) to be processed into a space surrounded by the L-shaped limiting block 102 on the first cuboid hollow container 101.

And respectively placing the collection box and the defective product temporary storage box below the rectangular through hole six and the rectangular through hole four.

And supplying power to the device, and pressing a starting switch to debug.

Step two, feeding:

and (3) clicking the feeding switch, and outputting signals to the linear motor I401, the linear motor II 402, the servo motor 403 and the electromagnet 404 by the PLC.

The first linear motor 401 and the second linear motor 402 cooperate to move the electromagnet 404 over the part 902 to be machined.

Then, the servo motor is started to move the electromagnet 404 downward, and the electromagnet 404 is started in a delayed manner to capture the part 902 to be processed. The servo motor drives the electromagnet 404 to reset.

Thereafter, the first linear motor 401 and the second linear motor 402 cooperate to transport the part 902 to be processed above the first conveyor means 503. The servo motor drives the electromagnet 404 to move downwards, the electromagnet 404 is turned off in a delayed mode, and the part 902 to be processed falls onto the first conveyor belt device 503.

The distance sensor module II detects a part 902 to be processed, transmits a signal to the PLC, and outputs a signal to the conveyor belt device I503, the screw rod motor I501, the screw rod motor II 502 and the compressor.

Starting the first conveyor belt device 503, carrying the part 902 to be processed to move right and pass through the side wall of the pushing block 505; and the distance sensor module III outputs signals to the PLC.

And starting the first screw motor 501 and the second screw motor 502 in sequence, and connecting the right end of the first conveyor belt device 503 with the die set. Thereafter, the compressor drives the cylinder so that the push block 505 moves downward. And the second screw motor 502 is started in a delayed mode, and the part 902 to be processed is pushed into the die set. And (5) processing.

Step three, unloading:

after the machining is finished, the discharging switch is pressed, and the PLC outputs signals to the third screw rod motor 601 and the fourth screw rod motor 602.

And the third screw motor 601 and the fourth screw motor 602 are sequentially started. The third screw motor 601 drives the third cuboid hollow container 304 to move left, so that the third cuboid hollow container 304 is connected with the mold. The fourth lead screw motor 602 drives the "F" shaped grabbing rod 604 to move to the left above the mold. The second cylinder 603 is activated, and the "F" shaped gripper bar 604 moves down to grip the machined part 902. Then, the fourth screw motor 602 resets to drive the component 902 to enter the second conveyor belt device 701. And the screw rod motor III 601 and the air cylinder II reset.

Then, the method is divided into two boxing modes:

mode A, detecting and boxing:

the second conveyor belt device 701 is started in a delayed mode, the part 902 is sent to the pressure plate 702, and the first distance sensor module outputs a signal to the PLC. The PLC controls the cooperation of the air cylinder three 704 and the air cylinder four 706 to correct the position of the part 902.

Then, the screw motor five 709 drives the distance sensor module one to move back and forth in order, scans the part 902, and detects whether defects (such as residual waste, gaps, hole positions and the like) exist by the PLC.

Then, cylinder four 706 pushes part 902 into conveyor three 708.

If there is a defect, the third cylinder 704 pushes it into the defective item passage 307 through the "halter" shaped adjustment plate 705, and finally enters the defective item temporary storage box.

If the parts are qualified, the third conveyor belt device 708 is started to transport the parts 902 to the collection box.

Mode B, direct binning:

the second conveyor assembly 701 is delayed to move the part 902 onto the pressure plate 702, and then the fourth cylinder 706 pushes the part 902 into the third conveyor assembly 708. The third conveyor assembly 708 is activated to transport the component 902 into the collection bin.

Embodiment 2, on the basis of embodiment 1, replace cuboid hollow container four 308 with "L" shape fly leaf, optimize the structure, conveniently observe the maintenance.

Example 3 on the basis of example 1, the "F" -shaped gripping bar 604 was replaced by a vacuum cup and a mounting bar, and the vacuum cup was connected to a compressor by a solenoid valve.

In example 4, based on example 1, the L-shaped vertical plate is replaced with the η -shaped support plate, and the short end of the η -shaped support plate is disposed on the rectangular hollow container i 101, so as to improve the load capacity.

Embodiment 5, on the basis of embodiment 1, replaces lead screw motor four 602 with electric telescopic link, improves load capacity.

Embodiment 6 is based on embodiment 1, a light emitting diode is additionally arranged on the first substrate 202, and a corresponding button battery and an infrared sensing switch are additionally arranged, and the button battery and the light emitting diode are connected in series for illumination.

Claims (10)

1. The utility model provides a processingequipment suitable for cast moulding locating piece on flexible band conveyer which characterized in that: comprises a main body frame, a turning part, a loading part, a discharging part, a detection and diversion part and a control part; the main body frame comprises a storage seat, a feeding seat and a discharging seat; the turning part comprises a linear motor I, a linear motor II, a servo motor, a scroll and an electromagnet; the feeding part comprises a screw rod motor I, a screw rod motor II, a conveyor belt device I, an air cylinder I, a compressor and a pushing block; the discharging part comprises a screw rod motor III, a screw rod motor IV, a cylinder II, an n-shaped positioning column and an F-shaped grabbing rod; the screw motor III is arranged on the substrate II; a rotor of the screw motor III is connected with a side plate of the cuboid hollow container III; the screw rod motor IV is arranged in the cuboid hollow container III; the second air cylinder is arranged on a rotor of the fourth screw rod motor; the n-shaped positioning column is arranged on the movable end of the cylinder II through the fixing plate; the F-shaped grabbing rod is connected to the n-shaped positioning column in a sliding mode; and the F-shaped grabbing rod is connected to the fixing plate through a spring.

2. The processing device suitable for the cast positioning block on the telescopic belt conveyor as claimed in claim 1, wherein: the linear motor I is arranged on the L-shaped limiting block; the linear motor II is arranged on a rotor of the linear motor I; the servo motor and the scroll are arranged on a rotor of the linear motor II through a connecting frame; the servo motor is in transmission connection with the reel through a reduction gear box; the electromagnet is connected with the reel through a limiting pipe rope chain; and the upper end of the limiting pipe is arranged on the connecting frame.

3. The machining device suitable for the cast positioning block on the telescopic belt conveyor as claimed in claim 1, wherein: the first conveyor belt device is arranged on the feeding seat; the first screw rod motor is arranged on the first base plate, and a rotor of the first screw rod motor is connected with the side plate of the feeding base; the screw rod motor II is arranged on the feeding seat; the first air cylinder is arranged on a rotor of the second screw rod motor through an L-shaped mounting plate; the pushing block is arranged on the movable end of the first air cylinder, and an L-shaped positioning through groove is formed in the pushing block.

4. The machining device suitable for the cast positioning block on the telescopic belt conveyor as claimed in claim 1, wherein: the storage seat is positioned on one side of the feeding seat and comprises a cuboid hollow container I, an L-shaped limiting block, an L-shaped vertical plate and a support column; the L-shaped limiting block is arranged on an upper bottom plate of the cuboid hollow container; the L-shaped vertical plate is arranged on an upper bottom plate of the cuboid hollow container; the feeding seat comprises an L-shaped supporting plate I, a base plate I and a cuboid hollow container II; the first base plate is arranged on the first L-shaped supporting plate, and an adjusting screw hole is formed in the first base plate; the first base plates are connected through a bidirectional adjusting screw rod, and a limiting sliding groove is formed in each first base plate; the second cuboid hollow container is connected to the limiting sliding groove in a sliding mode.

5. The processing device suitable for the cast positioning block on the telescopic belt conveyor as claimed in claim 1, wherein: the discharging seat comprises an L-shaped support plate II, a substrate II, a U-shaped outer frame, a cuboid hollow container III and a cuboid hollow container IV; the U-shaped outer frame is provided with a circular screw hole; an adjusting screw is arranged in the circular screw hole; one end of the adjusting screw rod is arranged on the L-shaped support plate II through a rolling bearing; the second substrate is arranged on the U-shaped outer frame; the rectangular hollow container IV is arranged on the substrate II; the cuboid hollow container III is connected with the substrate II in a sliding manner through a sliding rail; a rectangular through hole III is formed in the front side plate of the cuboid hollow container III; a defective product channel is arranged on the third rectangular through hole; a rectangular through hole six is formed in an upper bottom plate of the rectangular hollow container four; and six rectangular through holes are connected with cover plates through hinges.

6. The processing device suitable for the cast positioning block on the telescopic belt conveyor as claimed in claim 1, wherein: and replacing the screw rod motor IV with an electric telescopic rod.

7. The processing device suitable for the cast positioning block on the telescopic belt conveyor as claimed in claim 1, wherein: the 'F' -shaped grabbing rod is replaced by a vacuum chuck and a mounting rod, and the vacuum chuck is connected with a compressor through an electromagnetic valve.

8. The processing device for the cast positioning block on the telescopic belt conveyor as claimed in claim 4, wherein: the L-shaped vertical plate is replaced by the eta-shaped supporting plate, and the short end of the eta-shaped supporting plate is arranged on the cuboid hollow container I, so that the load capacity is improved.

9. The processing device for the cast positioning block on the telescopic belt conveyor as claimed in claim 4, wherein: the first substrate is additionally provided with a light emitting diode, and a corresponding button battery and an infrared induction switch are additionally arranged, wherein the button battery and the light emitting diode are connected in series.

10. The processing device suitable for the cast positioning block on the telescopic belt conveyor as claimed in claim 5, wherein: and the rectangular hollow container IV is replaced by an L-shaped movable plate.

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