CN115258698A

CN115258698A - SPC stone plastic floor processing pile up neatly system

Info

Publication number: CN115258698A
Application number: CN202211163518.8A
Authority: CN
Inventors: 易润林
Original assignee: Nantong Zhongda New Material Technology Co ltd
Current assignee: Nantong Zhongda New Material Technology Co ltd
Priority date: 2022-09-23
Filing date: 2022-09-23
Publication date: 2022-11-01

Abstract

The invention discloses an SPC stone plastic floor processing and stacking system which comprises a vertical frame, a stacking box and a conveying assembly, wherein the vertical frame, the stacking box and the conveying assembly are sequentially arranged on the ground from left to right; and a stacking groove is formed in the upper end of the stacking box. Compared with the prior art, the stacking system reasonably optimizes the whole stacking process, thereby ensuring that the movement speed of each structure and the movement of the negative pressure mechanism are quantitative in the whole stacking process, facilitating the design of subsequent external programs and the overall control to a certain extent.

Description

SPC stone plastic floor processing pile up neatly system

Technical Field

The invention relates to the field of SPC (random Access computer) stone plastic floor processing, in particular to a stacking system for SPC stone plastic floor processing.

Background

The stone-plastic floor is also called as a stone-plastic floor tile, has a formal name of PVC sheet floor, is a novel ground decoration material developed by high-quality and high-tech research, adopts stone powder to form a solid base layer with a high-density and high-fiber net-shaped structure, is processed by hundreds of procedures after being covered with a super-strong wear-resistant polymer PVC wear-resistant layer, and is generally formed by stacking cut plate bodies at the tail end of the production of the stone-plastic floor;

in the using process of the existing stacking system, generally, a disc plate body is adsorbed by a negative pressure adsorption structure and moves to the position above a stacking rack, then the disc plate body moves downwards to the position near the highest plate body of the stacking rack, a negative pressure structure is opened, the disc plate body is placed above the highest plate body of the stacking rack, then the negative pressure adsorption structure moves upwards firstly and then moves back to an initial position, and stacking is completed once.

Disclosure of Invention

Compared with the prior art, the stacking system reasonably optimizes the whole stacking process, so that the movement speed of each structure and the movement of a negative pressure mechanism are quantitative in the whole stacking process, the design of subsequent external programs is facilitated, and the overall control is facilitated to a certain extent.

In order to achieve the purpose, the invention adopts the following technical scheme:

a kind of SPC stone moulds the floor and processes the pile up neatly system, including installing on subaerial vertical shelf, pile up neatly case and conveying assembly from left to right sequentially, the upper end right side of the said vertical shelf connects with the crossbearer fixedly, the underpart of the said crossbearer has concrete chutes, rotate and connect with the reciprocating lead screw between the left and right sides inboard wall of the said concrete chute, the threaded part of the said reciprocating lead screw connects with the first slide block threadedly, the said first slide block is connected with inboard wall of the concrete chute slidably, the underpart of the said first slide block runs through the notch of the concrete chute, and connect with the diaphragm fixedly, there is negative pressure adsorption mechanism below the said diaphragm; the stacking box is characterized in that a stacking groove is formed in the upper end of the stacking box, a lifting plate capable of sliding up and down is horizontally arranged in the stacking groove, a stacking frame is placed at the upper end of the lifting plate, a rectangular cavity is formed in the stacking groove, an oil storage cylinder is embedded in the ground, the upper end of the oil storage cylinder extends into the stacking groove, and a moving mechanism for moving the lifting plate is jointly arranged in the rectangular cavity and the stacking groove; the left side of pile up neatly case is provided with the batch oil tank, be provided with in the batch oil tank and resume the mechanism.

Preferably, a motor is installed on the right side of the cross frame, and the tail end of an output shaft of the motor extends into the sliding groove and is fixedly connected with the right end of the reciprocating screw rod.

Preferably, the negative pressure adsorption mechanism comprises two hydraulic telescopic rods symmetrically installed at the lower end of the transverse plate, the lower ends of the two hydraulic telescopic rods are fixedly connected with a stacking tray together, the lower end of the stacking tray is fixedly connected with a plurality of negative pressure boxes, the lower end of each negative pressure box is fixedly connected with an adsorption head, the upper end of each adsorption head is communicated with the inside of the corresponding negative pressure box, a first magnetic piston capable of sliding up and down is arranged in each negative pressure box, a first electromagnet is embedded at the inner top of each negative pressure box, the upper end of each first magnetic piston is elastically connected with the inner top of the corresponding negative pressure box through a first spring, and each first electromagnet is oppositely attracted with the adjacent surface of the first magnetic piston after being electrified.

Preferably, a sliding cylinder is fixedly connected to the upper end of the stacking tray, second power connection blocks are embedded in the inner walls of the left side and the right side of the top space in the sliding cylinder, a connecting rod is fixedly connected to the lower end of the transverse plate, the lower end of the connecting rod extends into the sliding cylinder and is fixedly connected with a second sliding block, the second sliding block is conductive, and the two second power connection blocks are matched with the plurality of first electromagnets.

Preferably, moving mechanism includes the piston piece of sliding connection in an oil storage section of thick bamboo, the upper end fixedly connected with connecting rod of piston piece, the upper end of connecting rod runs through the interior top of an oil storage section of thick bamboo to extend to the pile up neatly inslot, the upper end of connecting rod and the lower extreme contact of lifter plate, be provided with gliding second magnetism piston from top to bottom in the rectangle chamber, the upper end of second magnetism piston passes through the interior top elastic connection of second spring with the rectangle chamber, the interior bottom in rectangle chamber inlays and is equipped with the second electro-magnet, the second electro-magnet circular telegram back is repelled with the adjacent surface homopolar of second magnetism piston, the interior bottom space in rectangle chamber passes through the interior bottom space intercommunication of first check pipe with the oil storage section of thick bamboo, the interior bottom space in rectangle chamber passes through second check pipe and oil storage tank intercommunication, install the type solenoid valve that closes in the first check pipe, install the type solenoid valve that opens in the second check pipe.

Preferably, the inner top of the sliding groove is symmetrically provided with two first electricity-connecting blocks, the first sliding block is provided with an electric conduction direction, and the two first electricity-connecting blocks are matched with the second electromagnet, the normally-open type electromagnetic valve and the normally-closed type electromagnetic valve.

Preferably, the recovery mechanism comprises a liquid pump installed on the left side of the oil storage tank, the liquid inlet end of the liquid pump extends to the inner bottom of the oil storage tank, the liquid outlet end of the liquid pump extends to the inner bottom of the oil storage barrel, and the liquid outlet end of the liquid pump is provided with a check valve.

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

the pallet all can move down the distance of a plate body, guarantee that the top plate body of pallet every time is in the constant height, can guarantee whole pile up neatly in-process like this, the distance of hydraulic telescoping rod up-and-down motion, the distance of slider side-to-side motion is under the unchangeable circumstances, just can guarantee that the speed of pile up neatly at every turn is the same, compared with the prior art, the pile up neatly in-process has been eliminated, the speed and the distance variable of each structure operation, the flow to whole pile up neatly has carried out reasonable optimization, thereby guarantee that each structure movement speed and the movement distance of negative pressure mechanism in the whole pile up neatly in-process are all the ration, the design and the maintenance of follow-up outside procedure have been made things convenient for, reduce the possibility that follow-up leak appears.

Drawings

Fig. 1 is a schematic structural diagram of an SPC stone plastic floor processing and stacking system according to the present invention;

FIG. 2 is an enlarged view of FIG. 1 at A;

FIG. 3 is an enlarged view of FIG. 1 at B;

FIG. 4 is an enlarged view at C of FIG. 1;

fig. 5 is an enlarged view of fig. 1 at D.

In the figure: the device comprises a vertical frame 1, a transverse frame 2, a sliding groove 3, a reciprocating screw rod 4, a motor 5, a first sliding block 6, a first electricity receiving block 7, a transverse plate 8, a hydraulic telescopic rod 9, a stacking disc 10, a first one-way pipe 11, a conveying assembly 12, a stacking box 13, an oil storage box 14, a liquid pump 15, a stacking groove 16, a connecting rod 17, a lifting plate 18, a stacking frame 19, an oil storage cylinder 20, a negative pressure box 21, a first electromagnet 22, a first spring 23, a first magnetic piston 24, an adsorption head 25, a sliding cylinder 26, a connecting rod 27, a piston block 28, a second sliding block 29, a second electricity receiving block 30, a rectangular cavity 31, a second magnetic piston 32, a second spring 33, a second electromagnet 34 and a one-way pipe 35.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-5, an SPC stone-plastic floor processing and stacking system comprises a vertical frame 1, a stacking box 13 and a conveying assembly 12, wherein the conveying assembly 12 is a conventional technique and is used for conveying a cut stone-plastic floor, and actually comprises a right-side transmission wheel body (a solid-line wheel body part in the figure) and a left-side unpowered wheel body (a dotted-line wheel body part in the figure), the unpowered wheel body cannot automatically rotate, the plate stops moving when moving to the unpowered wheel body part, a transverse frame 2 is fixedly connected to the right side of the upper end of the vertical frame 1, a sliding groove 3 is formed in the lower end of the transverse frame 2, a reciprocating screw rod 4 is rotatably connected between the inner walls of the left side and the right side of the sliding groove 3, a first sliding block 6 is in threaded connection with the threaded part of the reciprocating screw rod 4, a motor 5 is installed on the right side of the transverse frame 2, the tail end of an output shaft of the motor 5 extends into the sliding groove 3 and is fixedly connected with the right end of the reciprocating screw rod 4, the first sliding block 6 is slidably connected with the inner wall of the sliding groove 3, and the lower end of the first sliding block 6 penetrates through the notch of the sliding groove 3 and is fixedly connected with a transverse plate 8;

as an embodiment of the invention, a negative pressure adsorption mechanism is arranged below the transverse plate 8, the negative pressure adsorption mechanism comprises two hydraulic telescopic rods 9 symmetrically arranged at the lower end of the transverse plate 8, the lower ends of the two hydraulic telescopic rods 9 are fixedly connected with a pallet 10 together, the lower end of the pallet 10 is fixedly connected with a plurality of negative pressure boxes 21, the lower end of each negative pressure box 21 is fixedly connected with an adsorption head 25, the upper end of each adsorption head 25 is communicated with the inside of the negative pressure box 21, a first magnetic piston 24 capable of sliding up and down is arranged in each negative pressure box 21, an opening communicated with the outside is arranged on the front side of the inner top space of each negative pressure box 21, a first electromagnet 22 is embedded in the inner top of each negative pressure box 21, the upper end of each first magnetic piston 24 is elastically connected with the inner top of the corresponding negative pressure box 21 through a first spring 23, and each first electromagnet 22 is oppositely attracted to the adjacent surface of the first magnetic piston 24 after being electrified;

as an embodiment of the present invention, a sliding barrel 26 is fixedly connected to the upper end of the pallet 10, second power connection blocks 30 are embedded in the inner walls of the left and right sides of the top space in the sliding barrel 26, a connecting rod 27 is fixedly connected to the lower end of the transverse plate 8, the lower end of the connecting rod 27 extends into the sliding barrel 26 and is fixedly connected to a second slider 29, the second slider 29 has conductivity, the two second power connection blocks 30 are matched with the plurality of first electromagnets 22, and when the second slider 29 contacts the two second power connection blocks 30, the plurality of first electromagnets 22 are powered on;

as an embodiment of the invention, a stacking groove 16 is formed in the upper end of the stacking box 13, the stacking groove 16 is actually a groove body with an open upper end and a front side, and it is ensured that a subsequent worker can take out the stacking frame 19, a lifting plate 18 capable of sliding up and down is horizontally arranged in the stacking groove 16, the stacking frame 19 is placed at the upper end of the lifting plate 18, a rectangular cavity 31 is arranged in the stacking groove 16, an oil storage cylinder 20 is buried in the ground, the upper end of the oil storage cylinder 20 extends into the stacking groove 16, a moving mechanism for moving the lifting plate 18 is jointly arranged in the rectangular cavity 31 and the stacking groove 16, the moving mechanism comprises a piston block 28 slidably connected in the oil storage cylinder 20, a connecting rod 17 is fixedly connected to the upper end of the piston block 28, the upper end of the connecting rod 17 penetrates through the inner top of the oil storage cylinder 20 and extends into the stacking groove 16, and the upper end of the connecting rod 17 is in contact with the lower end of the lifting plate 18;

as an embodiment of the present invention, a second magnetic piston 32 capable of sliding up and down is disposed in the rectangular cavity 31, a limit ring may be fixedly connected to an inner wall of the rectangular cavity 31, the limit ring is disposed above the second magnetic piston 32 to ensure that the second magnetic piston 32 can only move up a fixed distance each time, an upper end of the second magnetic piston 32 is elastically connected to an inner top of the rectangular cavity 31 through a second spring 33, a second electromagnet 34 is embedded in an inner bottom of the rectangular cavity 31, the adjacent surface of the second electromagnet 34 and the second magnetic piston 32 repel each other with like polarity after being energized, the inner bottom space of the rectangular cavity 31 is communicated with the inner bottom space of the oil storage cylinder 20 through a first check pipe 11, the inner bottom space of the rectangular cavity 31 is communicated with the oil storage tank 14 through a second check pipe 35, a normally closed type electromagnetic valve is disposed in the first check pipe 11, a normally open type electromagnetic valve is disposed in the second check pipe 35, two first contact blocks 7 are symmetrically disposed on an inner top of the chute 3, the first sliding block 6 has a conductive direction, the two first contact blocks 7 are in cooperation with the second electromagnetic valve 34, the normally open type electromagnetic valve, and the normally closed type electromagnetic valve are both matched with the second electromagnetic valve 34, and the normally open type electromagnetic valve 34;

as an embodiment of the present invention, an oil storage tank 14 is disposed on the left side of the pallet tank 13, high-density oil is filled in both the oil storage tank 14 and the oil storage cylinder 20, a recovery mechanism is disposed in the oil storage tank 14, the recovery mechanism includes a liquid pump 15 mounted on the left side of the oil storage tank 14, a liquid inlet end of the liquid pump 15 extends to the inner bottom of the oil storage tank 14, a liquid outlet end of the liquid pump 15 extends to the inner bottom of the oil storage cylinder 20, and a check valve is mounted on a liquid outlet end of the liquid pump 15.

In the invention, in the specific stacking process, firstly, two hydraulic telescopic rods 9 extend to enable the stacking tray 10 to move downwards, when the stacking tray 10 moves downwards and an adsorption head 25 contacts a plate body, at the moment, a second slide block 29 just contacts two second electricity-connecting blocks 30, a plurality of first electromagnets 22 are electrified to enable a plurality of first magnetic pistons 24 to move upwards, the air pressure of the bottom parts of the adsorption head 25 and a negative pressure box 21 is reduced, negative pressure adsorption is carried out on the plate body, then a motor 5 is started, a reciprocating screw rod 4 is rotated to drive a first slide block 6 to move left, after the left side of the first slide block 6 reaches a limit position, the motor 5 is closed, at the moment, the plate body is positioned right above a stacking groove 16 and slightly higher than the uppermost plate body (the actual distance is close and almost in a contact state), at the moment, the hydraulic telescopic rods 9 move upwards to an initial height and drive the stacking tray 10 to move upwards;

when the stacking tray 10 just moves upwards, the second sliding blocks 29 are not in contact with the two second power connection blocks 30 any more due to the upward movement of the sliding barrel 26, the first electromagnets 22 are powered off, the first magnetic pistons 24 move downwards under the elastic action of the first springs 23, the negative pressure in the adsorption heads 25 disappears, the plate bodies are not adsorbed and limited any more, and the plate bodies move downwards under the action of self gravity and are in contact with the plate body which is originally positioned at the uppermost part of the stacking rack 19, so that stacking is realized;

after the hydraulic telescopic rod 9 is moved, the motor 5 rotates to drive the first sliding block 6 to move right, so that the whole negative pressure adsorption mechanism moves right, the state of the drawing 1 is restored, and the movement is stopped, in the stacking process, the first sliding block 6 reciprocates left and right once, because of the initial state, the first sliding block 6 contacts two first power-on blocks 7, the second electromagnet 34, the normally-open electromagnetic valve and the normally-closed electromagnetic valve are in the power-on state, the second magnetic piston 32 is in the power-on state at the moment, the second spring 33 is in the compression state, the first one-way pipe 11 is dredged, the second one-way pipe 35 is sealed, the second magnetic piston 32 is pushed to move downwards, the oil is pressed into the oil storage tank 14, when the first sliding block 6 moves left, the second electromagnet 34, the normally-open electromagnetic valve and the normally-closed electromagnetic valve are in the power-off state, the first one-way pipe 35 is sealed at the moment, the second spring 33 extends to push the second magnetic piston 32 to move downwards, the oil is pressed into the oil storage tank 14, and the subsequent first sliding block 6 moves back to contact with the two first power-on blocks 7, the second electromagnetic valve 34, the normally-on electromagnetic valve 34 and the normal electromagnetic valve 32 moves upwards, and the distance between the piston connecting rod 27 and the piston moves upwards;

because the amount of the oil liquid sucked away each time is constant, the distance that the transverse plate 8 and the stacking frame 19 move downwards each time is the same, namely, the method is adopted, after one plate is added each time, the stacking frame 19 can move downwards by the distance of one plate, and the uppermost plate of the stacking frame 19 is ensured to be at a constant height each time, so that the speed of stacking each time can be ensured to be the same under the condition that the distance of the up-and-down movement of the hydraulic telescopic rod 9 and the distance of the left-and-right movement of the slide block 6 are not changed in the whole stacking process, and compared with the prior art, the whole stacking process is reasonably optimized, so that the moving speed of each structure and the moving distance of the negative pressure mechanism in the whole stacking process are both quantitative, the design and maintenance of subsequent external programs are facilitated, and the possibility of occurrence of subsequent leaks is reduced;

after the lifting plate 18 finally moves down to the extreme position, the staff can directly lift the pallet 19 together with the plate bodies thereon by an external forklift, and inject oil into the oil storage cylinder 20 again by the liquid pump 15, so that the lifting plate 18 moves up to the initial state again.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The SPC stone plastic floor processing and stacking system comprises a vertical frame (1), a stacking box (13) and a conveying assembly (12) which are sequentially installed on the ground from left to right, and is characterized in that a cross frame (2) is fixedly connected to the right side of the upper end of the vertical frame (1), a sliding groove (3) is formed in the lower end of the cross frame (2), a reciprocating screw rod (4) is rotatably connected between the inner walls of the left side and the right side of the sliding groove (3), a threaded part of the reciprocating screw rod (4) is in threaded connection with a first sliding block (6), the first sliding block (6) is in sliding connection with the inner wall of the sliding groove (3), the lower end of the first sliding block (6) penetrates through a groove opening of the sliding groove (3) and is fixedly connected with a transverse plate (8), and a negative pressure adsorption mechanism is arranged below the transverse plate (8);

a stacking groove (16) is formed in the upper end of the stacking box (13), a lifting plate (18) capable of sliding up and down is horizontally arranged on the stacking groove (16), a stacking frame (19) is placed at the upper end of the lifting plate (18), a rectangular cavity (31) is formed in the stacking groove (16), an oil storage cylinder (20) is buried in the ground, the upper end of the oil storage cylinder (20) extends into the stacking groove (16), and a moving mechanism for moving the lifting plate (18) is jointly arranged in the rectangular cavity (31) and the stacking groove (16);

an oil storage tank (14) is arranged on the left side of the stacking tank (13), and a recovery mechanism is arranged in the oil storage tank (14).

2. An SPC plastic-stone floor processing and stacking system as claimed in claim 1, wherein a motor (5) is installed on the right side of the cross frame (2), and the tail end of the output shaft of the motor (5) extends into the chute (3) and is fixedly connected with the right end of the reciprocating screw rod (4).

3. The SPC stone plastic floor processing and stacking system as claimed in claim 1, wherein the negative pressure adsorption mechanism comprises two hydraulic telescopic rods (9) symmetrically installed at the lower end of a transverse plate (8), the lower ends of the two hydraulic telescopic rods (9) are fixedly connected with a stacking tray (10) together, the lower end of the stacking tray (10) is fixedly connected with a plurality of negative pressure boxes (21), the lower end of each negative pressure box (21) is fixedly connected with an adsorption head (25), the upper end of each adsorption head (25) is communicated with the inside of the negative pressure box (21), a first magnetic piston (24) capable of sliding up and down is arranged in each negative pressure box (21), a first electromagnet (22) is embedded at the inner top of each negative pressure box (21), the upper end of each first magnetic piston (24) is elastically connected with the inner top of the corresponding negative pressure box (21) through a first spring (23), and after being electrified, each first electromagnet (22) is adjacent to the first magnetic piston (24) in an opposite attraction manner.

4. An SPC stone plastic floor processing and stacking system as claimed in claim 3, wherein a sliding cylinder (26) is fixedly connected to the upper end of the stacking tray (10), second electricity-connecting blocks (30) are embedded on the inner walls of the left side and the right side of the top space in the sliding cylinder (26), a connecting rod (27) is fixedly connected to the lower end of the transverse plate (8), the lower end of the connecting rod (27) extends into the sliding cylinder (26) and is fixedly connected with a second sliding block (29), the second sliding block (29) has electric conductivity, and the two second electricity-connecting blocks (30) are matched with the first electromagnets (22).

5. The system of claim 1, a floor processing pile up neatly system is moulded to SPC stone, characterized in that, moving mechanism includes piston block (28) of sliding connection in oil storage cylinder (20), the upper end fixedly connected with connecting rod (17) of piston block (28), the upper end of connecting rod (17) runs through the interior top of oil storage cylinder (20) to extend to in pile up neatly groove (16), the upper end of connecting rod (17) and the lower extreme contact of lifter plate (18), be provided with gliding second magnetism piston (32) from top to bottom in rectangular chamber (31), the upper end of second magnetism piston (32) passes through the interior top elastic connection of second spring (33) and rectangular chamber (31), the interior bottom of rectangular chamber (31) is inlayed and is equipped with second electro-magnet (34), the second electro-magnet (34) switch on the back and the adjacent surface homopolar repulsion mutually of second magnetism piston (32), the interior bottom space of rectangular chamber (31) passes through the interior bottom space of first unidirectional tube (11) and oil storage cylinder (20) and communicates, the interior bottom space of rectangular chamber (31) is installed through the second unidirectional tube (11) and the electromagnetic valve (35) of the normal open type.

6. An SPC stone plastic floor processing and stacking system as claimed in claim 5, wherein the inner top of the chute (3) is symmetrically provided with two first electricity-connecting blocks (7), the first sliding block (6) has a conductive direction, and the two first electricity-connecting blocks (7) are matched with a second electromagnet (34), a normally open type electromagnetic valve and a normally closed type electromagnetic valve.

7. An SPC stone plastic floor processing palletization system according to claim 1, wherein the recovery mechanism comprises a liquid pump (15) installed at the left side of the oil storage tank (14), the liquid inlet end of the liquid pump (15) extends to the inner bottom of the oil storage tank (14), the liquid outlet end of the liquid pump (15) extends to the inner bottom of the oil storage barrel (20), and the liquid outlet end of the liquid pump (15) is provided with a check valve.