CN111015214B - High efficiency pump valve parts machining assembly line - Google Patents

Abstract

The invention provides a high-efficiency pump valve part processing assembly line, which comprises a first conveying belt, a second conveying belt, a first processing table and a second processing table, wherein the first conveying belt is arranged above the first processing table, the second conveying belt is arranged above the second processing table, the first processing table penetrates through the second processing table, a first discharging plate and a second discharging plate are arranged on the first conveying belt, the high-efficiency pump valve part processing assembly line also comprises a telescopic ejection column, a pneumatic clamping jaw, an inductor, a control system and an infrared detector, the telescopic ejection column, the pneumatic clamping jaw, the inductor and the infrared detector are respectively in signal connection with the control system, the telescopic ejection column is arranged below the second processing table, the infrared detector is arranged on the telescopic ejection column, and the inductor is arranged on the second discharging plate. The machining efficiency of the pump valve parts is accelerated, and the number of workers on a pump valve part machining production line is reduced.

Description

High efficiency pump valve parts machining assembly line

Technical Field

The invention relates to a high-efficiency pump valve part machining assembly line.

Background

The invention aims to provide a high-efficiency pump valve part processing assembly line which can process various burst parts on one assembly line, greatly improves the processing efficiency of pump valve parts and reduces the production cost.

Disclosure of Invention

The purpose of the invention is as follows: the invention aims to provide a high-efficiency pump valve part processing line aiming at the defects in the prior art, and the processing efficiency of pump valve parts is greatly improved and the production cost is reduced by processing a plurality of pump valve parts on one pump valve part processing line.

The technical scheme is as follows: in order to achieve the purpose, the invention provides a high-efficiency pump valve part machining assembly line, which is characterized in that: including processing platform, motor, live-rollers and conveyer, the output shaft live-rollers of motor, the conveyer cover is established on the live-rollers, conveyer is including first conveyer and second conveyer, the processing platform is including first processing platform and second processing platform, first conveyer sets up in first processing bench side, second conveyer sets up in second processing bench side, and first processing platform passes second processing platform setting, first conveyer is located second conveyer below, be provided with first flitch and second flitch on the first conveyer, still including flexible fore-set, pneumatic clamping jaw, inductor, control system and infrared detector, flexible fore-set, pneumatic clamping jaw, inductor and infrared detector respectively with control system signal connection, the below at the second processing platform is installed to flexible fore-set, the infrared detector is installed on flexible fore-set, the inductor is installed on second blowing board, pneumatic clamping jaw is connected in one side of second conveyer and is set up along with the motion of second conveyer, and when flexible fore-set jack-up second blowing board to pneumatic clamping jaw position department, pneumatic clamping jaw passes through control system and presss from both sides tight second blowing board, flexible fore-set descends, and when second blowing board moved to second conveyer tip, control system control pneumatic clamping jaw loosens second blowing board.

As a refinement of this solution, the conveying rate of the first conveyor belt is greater than the conveying rate of the second conveyor belt.

As an improvement of the scheme, the device further comprises a sliding plate, the sliding plate is connected to the discharge port of the second processing table and located above the first conveying belt, and a gap for the first discharging plate to pass through is reserved between the first conveying belt and the bottom of the sliding plate.

As an improvement of the scheme, a fixed column is arranged below the second material placing plate, a placing groove is formed in the fixed column, when the second material placing plate is located above the telescopic top column, the telescopic top column jacks upwards, and the telescopic top column is abutted to the placing groove.

As an improvement of the scheme, the sliding plate is provided with a sliding chute, and the sliding chute is located in the middle of the sliding plate and corresponds to the fixed column in position.

As an improvement of the scheme, a fixing groove is formed in the second material placing plate, a magnetic sheet is arranged in the fixing groove, and the magnetic sheet is embedded into the bottom of the fixing groove.

As an improvement of the scheme, the telescopic top column comprises a base and a telescopic top column, and the base is fixedly installed at the bottom of the second machining table.

As an improvement of the scheme, the inductor is installed below the second material placing plate, the infrared detector is installed on the base of the telescopic top column, the inductor is located in the front of the material feeding direction, and the infrared detector is located behind the material feeding direction.

Compared with the prior art, the invention has the following beneficial effects: the first processing table is used for processing the pump valve parts on the first discharging plate, the second processing table is used for processing the parts on the second discharging plate, so that different parts can be placed at one time, the effect of processing on one production line can be realized, the cost of production machines is reduced, the processing efficiency of the pump valve parts is improved, and the number of workers on the pump valve part processing production line is reduced.

Drawings

FIG. 1 is a schematic perspective view of a pump valve part processing line according to the present invention;

FIG. 2 is a schematic side view of a pump valve component processing line according to the present invention;

FIG. 3 is a schematic view of a second conveyor belt according to the present invention.

List of reference numerals: 1. a first processing table; 11. a first conveyor belt; 2. a second processing table; 21. a second conveyor belt; 3. a first discharge plate; 4. a second discharge plate; 41. fixing grooves; 5. a slide plate; 6. a chute; 7. a telescopic top pillar; 71; a base; 72; a telescopic column; 8. fixing a column; 81. a placement groove; 9; an inductor; 10. an infrared detector; 101. pneumatic clamping jaw.

Detailed Description

The present invention will be further illustrated with reference to the accompanying drawings and specific embodiments, which are to be understood as merely illustrative of the invention and not as limiting the scope of the invention. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

As shown in fig. 1-3, the high-efficiency pump valve part processing line comprises a processing table, a motor, a rotating roller and a conveyor belt, wherein an output shaft of the motor is connected with the rotating roller, the conveyor belt is sleeved on the rotating roller, the conveyor belt comprises a first conveyor belt 11 and a second conveyor belt 21, the processing table comprises a first processing table 1 and a second processing table 2, the first conveyor belt 11 is arranged above the first processing table 1, the second conveyor belt 21 is arranged above the second processing table 2, the first processing table 1 passes through the second processing table 2, the first conveyor belt 11 is arranged below the second conveyor belt 21, the first conveyor belt 11 is provided with a first material discharge plate 3 and a second material discharge plate 4, and the high-efficiency pump valve part processing line further comprises a telescopic ejection column 7, a pneumatic clamping jaw 101, an inductor 9, a control system and an infrared detector 10, flexible fore-set 7, pneumatic clamping jaw 101, inductor 9 and infrared detector 10 respectively with control system signal connection, flexible fore-set 7 is installed in the below of second processing platform 2, infrared detector 10 is installed on flexible fore-set 7, inductor 9 is installed on second blowing board 4, pneumatic clamping jaw 101 is connected in one side of second conveyer 21 and is set up along with the motion of second conveyer 21, when flexible fore-set 7 jack-up second blowing board 4 to pneumatic clamping jaw 101 position department, pneumatic clamping jaw 101 presss from both sides tight second blowing board 4 through control system, flexible fore-set 7 descends, when second blowing board 4 moves to second conveyer 21 tip, control system control pneumatic clamping jaw 101 loosens second blowing board 4.

In this embodiment: the conveying speed of the first conveyor belt 11 is greater than the conveying speed of the second conveyor belt 21.

In the above structure: the invention provides a high-efficiency bursting part processing assembly line, which realizes processing of more than two pump valve parts by one-time discharging, can reduce the need of additionally arranging two assembly lines and can greatly reduce the production cost, and comprises a processing table, a motor, a rotating roller and a conveying belt, wherein an output shaft of the motor is connected with the rotating roller, the conveying belt is sleeved on the rotating roller and comprises a first conveying belt 11 and a second conveying belt 21, the processing table comprises a first processing table 1 and a second processing table 2, the first conveying belt 11 is arranged above the first processing table 1, the second conveying belt 21 is arranged above the second processing table 2, the first processing table 1 is arranged by penetrating through the second processing table 2, the second conveying belt 21 is arranged below the first conveying belt 11, the first conveying belt 11 is provided with a first discharging plate 3 and a second discharging plate 4, the first processing table 1 is used for processing pump valve parts on a first material discharging plate 3 on a first conveying belt 11, the second processing table 2 is used for processing pump valve parts on a second material discharging plate 4 on a second conveying belt 21, the first processing table further comprises a telescopic ejection column 7, a pneumatic clamping jaw 101, an inductor 9, a control system and an infrared detector 10, when a motor is pneumatic, different pump valve parts are respectively placed on the first material discharging plate 3 and the second material discharging plate 4 through manpower, the motor drives a rotating roller to rotate, the rotating roller drives the first conveying belt 11 and the second conveying belt 21 to move, the first conveying belt 11 and the second conveying belt 21 respectively drive the first material discharging plate 3 and the second material discharging plate 4 to move, the second material discharging plate 4 is provided with the inductor 9, the telescopic ejection column 7 is provided with the infrared detector 10, when the infrared detector 10 on the telescopic ejection column 7 detects the inductor 9 on the second material discharging plate 4, the control system controls the telescopic jacking column 7 to move upwards, jacks up the second discharging plate 4 on the first conveying belt 11, and when the second discharging plate 4 is jacked up to the position of the pneumatic clamping jaw 101, the control system controls the pneumatic clamping jaw 101 to clamp the second discharging plate 4 to fix the second discharging plate 4, the second conveying belt 21 drives the second discharging plate 4 to move, and when the second conveying belt moves to the end of the second conveying belt, the control system controls the pneumatic clamping jaw 101 to loosen the second discharging plate 4.

In the above structure: in order to ensure that the first conveying belt 11 can catch the second discharging plate 4 after the second discharging plate 4 is processed when the first conveying belt 11 and the second conveying belt 21 convey the first discharging plate 3 and the second discharging plate 4, the conveying speed of the first conveying belt 11 is set to be smaller than the conveying speed of the second conveying belt 21.

In this embodiment: still including slide 5, slide 5 is connected in the discharge gate department of second processing platform 2 and is located first conveyer belt 11 top, reserve the clearance that supplies first flitch 3 to pass through between first conveyer belt 11 and the slide 5 bottom.

In the above structure: a sliding plate 5 is further arranged at the discharge port of the second machining table 2, after the second material placing plate 4 passes through the second machining table 2, the second material placing plate 4 is clamped by the pneumatic clamping jaws 101 when the second material placing plate 4 is machined on the second machining table 2, when the second material placing plate 4 moves to the end of the second machining table 2, the control system controls the pneumatic clamping jaws 101 to be loosened, at the moment, the second material placing plate 4 slides down through the sliding plate 5 and falls into the previous position on the first conveying belt 11, a gap for the first material placing plate 3 to pass through is reserved between the first conveying belt 11 and the bottom of the sliding plate 5, the first conveying belt 11 passes through the second machining table 2, the first conveying belt 11 passes below the second conveying belt 21, when the second material placing plate 4 on the second conveying belt 21 falls down, the first conveying belt 11 just falls onto the first conveying belt 11, and the pump valve part on the first material placing plate 3 machined on the first conveying belt 11, are conveyed together by the first conveyor belt.

In this embodiment: a fixing column 8 is arranged below the second material placing plate 4, a placing groove 81 is formed in the fixing column 8, when the second material placing plate 4 is located above the telescopic top pillar 7, the telescopic top pillar 7 is jacked upwards, and the telescopic top pillar 7 is abutted to the placing groove 81.

In the above structure: be provided with fixed column 8 below second blowing board 4, be provided with standing groove 81 on the fixed column 8, fixed column 8 and standing groove 81 are used for when upwards jack-up second blowing board 4 to flexible fore-set 7, guarantee its balance.

In this embodiment: the sliding plate 5 is provided with a sliding chute 6, and the sliding chute 6 is positioned in the middle of the sliding plate 5 and corresponds to the fixed column 8.

In the above structure: when the second material placing plate 4 slides down through the sliding plate 5, the fixing column 8 slides in the sliding groove 6 for ensuring the balance thereof.

In this embodiment: the second material placing plate 4 is provided with a fixing groove 41, a magnetic sheet is arranged in the fixing groove 41, and the magnetic sheet is embedded into the bottom of the fixing groove 41.

In the above structure: still be provided with fixed slot 41 on second blowing board 4, inlay at the bottom of fixed slot 41 and have magnet, fix the pump valve part through magnet, prevent that it from when upwards jacking up through flexible fore-set 7, producing rocks, leading to processing mistake.

In this embodiment: the inductor 9 is installed below the second material discharging plate 4, the infrared detector 10 is installed on the base 71 of the telescopic ejection column 7, the inductor 9 is located in front of the feeding direction, and the infrared detector 10 is located behind the feeding direction.

In the above structure: inductor 9 installs the below at second blowing board 4, infrared detector 10 installs on the base 71 of flexible fore-set 7, inductor 9 is located the place ahead of pay-off direction, infrared detector 10 is located the rear of pay-off direction, when first blowing board 3 and second blowing board 4 are carried in first conveyer belt, inductor 9 of second blowing board 4 below can be earlier step earlier and infrared detector 10 on the base 71 produce the response, at this moment, flexible fore-set 7 just can upwards rise a bit of time in advance, when fixed column 8 moves flexible fore-set 7 below, in the standing groove 81 on fixed column 8 just can be inserted to flexible fore-set 7, the realization is carried out the jack-up with second blowing board 4.

The technical means disclosed in the invention scheme are not limited to the technical means disclosed in the above embodiments, but also include the technical scheme formed by any combination of the above technical features.

Claims (8)

1. The utility model provides a high efficiency pump valve parts machining assembly line which characterized in that: including processing platform, motor, live-rollers and conveyer, the output shaft of motor live-rollers, the conveyer cover is established on the live-rollers, conveyer is including first conveyer (11) and second conveyer (21), the processing platform is including first processing platform (1) and second processing platform (2), first conveyer (11) set up in first processing platform (1) top, second conveyer (21) set up in second processing platform (2) top, and first processing platform (1) passes second processing platform (2) and sets up, first conveyer (11)) is located second conveyer (21) below, be provided with first flitch (3) and second flitch (4) of putting on first conveyer (11), still including flexible fore-set (7), pneumatic clamping jaw (101), inductor (9), Control system and infrared detector (10), flexible fore-set (7), pneumatic clamping jaw (101), inductor (9) and infrared detector (10) are connected with control system signal respectively, flexible fore-set (7) are installed in the below of second processing platform (2), infrared detector (10) are installed on flexible fore-set (7), inductor (9) are installed on second blowing board (4), pneumatic clamping jaw (101) are connected in one side of second conveyer belt (21) and are set up along with the motion of second conveyer belt (21), when flexible fore-set (7) jack-up second blowing board (4) to pneumatic clamping jaw (101) position department, pneumatic clamping jaw (101) press from both sides tight second blowing board (4) through control system, flexible fore-set (7) descend, when second blowing board (4) move to second conveyer belt (21) tip, and the control system controls the pneumatic clamping jaws (101) to release the second discharging plate (4).

2. The high efficiency pump and valve parts manufacturing line of claim 1, wherein: the conveying speed of the first conveying belt (11) is greater than the conveying speed of the second conveying belt (21).

3. A high efficiency pump and valve parts manufacturing line as claimed in claim 2, wherein: still including slide (5), slide (5) are connected in the discharge gate department of second processing platform (2) and are located first conveyer belt (11) top, it has the clearance that supplies first blowing board (3) to pass through to reserve between first conveyer belt (11) and slide (5) bottom.

4. A high efficiency pump and valve parts manufacturing line as claimed in claim 3, wherein: the telescopic jacking device is characterized in that fixing columns (8) are arranged below the second material placing plate (4), a placing groove (81) is formed in each fixing column (8), when the second material placing plate (4) is located above the telescopic jacking columns (7), the telescopic jacking columns (7) jack upwards, and the telescopic jacking columns (7) are abutted to the placing groove (81).

5. The high efficiency pump valve parts production line of claim 4, wherein: the sliding plate (5) is provided with a sliding chute (6), and the sliding chute (6) is positioned in the middle of the sliding plate (5) and corresponds to the fixing column (8).

6. The high efficiency pump valve parts production line of claim 5, wherein: the second material placing plate (4) is provided with a fixing groove (41), a magnetic sheet is arranged in the fixing groove (41), and the magnetic sheet is embedded into the bottom of the fixing groove (41).

7. The high efficiency pump valve parts production line of claim 6, wherein: the telescopic top column (7) comprises a base (71) and the telescopic top column (7), and the base (71) is fixedly installed at the bottom of the second machining table (2).

8. The high efficiency pump and valve parts manufacturing line of claim 7, wherein: the sensor (9) is installed below the second material discharging plate (4), the infrared detector (10) is installed on a base (71) of the telescopic ejection column (7), the sensor (9) is located in front of the feeding direction, and the infrared detector (10) is located behind the feeding direction.

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