CN107814167A

CN107814167A - A kind of small-sized tiles material delivery system

Info

Publication number: CN107814167A
Application number: CN201711229741.7A
Authority: CN
Inventors: 周华国; 廖建勇; 周富强
Original assignee: Shenzhen Honest Mechatronic Equipment Co Ltd
Current assignee: Shenzhen Honest Mechatronic Equipment Co Ltd
Priority date: 2017-11-29
Filing date: 2017-11-29
Publication date: 2018-03-20
Anticipated expiration: 2037-11-29
Also published as: CN107814167B

Abstract

The invention provides a kind of small-sized tiles material delivery system, including magnetic shoe bottom plate, the magnetic shoe plate upper surface is provided with pusher sliding block, the pusher sliding block passes through second sleeve, the second sleeve and the magnetic shoe bottom plate mutually from surface, be from the close-by examples to those far off sequentially installed with the first sleeve, swivel plate and rotary cylinder；One cylinder, a rotary cylinder add some assembling parts to form, and stabilized structure, are not likely to produce deformation, and cost is cheap, and mechanism is compact, and it is broken can to prevent that magnetic shoe from producing by the device feeding for magnetic shoe.

Description

A kind of small-sized tiles material delivery system

Technical field

The invention belongs to machinery equipment field, more particularly to a kind of small-sized tiles material delivery system.

Background technology

When doing feeding feeding, the disk feeding aerating cylinder that can substantially be shaken using circle is carried out traditional small-sized tiles material Feeding, or directly carries out feeding feeding with the circle disk that shakes, circular vibration disk is a kind of auxiliary equipment of automatic assembling tool, energy handle Various products eject in order.Circular self-feeding vibrating disk is mainly supporting by hopper, chassis, controller, straight line feeder etc. Composition.There is individual impulse mgnet below the hopper of self-feeding vibrating disk, hopper vertical vibration can be made, due to spring leaf Inclination, hopper is rocked vibration around its vertical axis.Part in hopper, due to by this vibration, and along helical orbit Rise, until being sent to discharging opening.At present with circle shake disk carry out feeding when, there are some tiles materials to be circulated always in circle shakes disk Vibrate and crush；Circle shake disk making it is complicated, cost is high；Easily get stuck.

The content of the invention

It is an object of the invention to for above-mentioned the deficiencies in the prior art, there is provided a kind of small-sized tiles material supply dress Put, can preventing magnetic shoe from producing, broken, cost is cheap, and mechanism is compact.

To achieve the above object, present invention employs following technical scheme：

The invention provides a kind of small-sized tiles material delivery system, including magnetic shoe bottom plate, the magnetic shoe bottom plate upper table Face is provided with pusher sliding block, and the pusher sliding block passes through second sleeve, the second sleeve and the magnetic shoe bottom plate mutually from table Face, from the close-by examples to those far off it is sequentially installed with the first sleeve, swivel plate and rotary cylinder；Be provided with the second sleeve the first guide pad and Catch is buffered, first guide pad is arranged on the buffering catch, is provided with what can be rotated on first guide pad Sub-material axle, plectrum is installed in the middle part of the sub-material axle, the plectrum can rotate with the sub-material axle；The rotary cylinder Axle is fixedly connected with the sub-material axle, and the rotary cylinder can drive the sub-material axle to rotate；

First sleeve and the second sleeve mutually from one end be provided with opening；

It is also equipped with detecting seat and proximity switch on the magnetic shoe bottom plate, being provided with two on the detection seat can rotate Sensor block, the side adjacent with the pusher sliding block is provided with two optoelectronic switches in the second sleeve.

Further, the detection seat and the proximity switch are arranged on the lower surface of the magnetic shoe bottom plate, and with described the Two sleeves are corresponding.

Further, described pusher sliding block one end is provided with positive stop, and the pusher sliding block other end is provided with the second guide pad, Second guide pad has two pieces, is separately positioned on the both sides of the pusher sliding block, and be connected with the second sleeve.

Further, pusher sliding block one end adjacent with the positive stop is provided with magnetic shoe cylinder block, the magnetic shoe Cylinder block and the positive stop mutually from side telescopic cylinder is installed, the telescopic cylinder by M5 vigor joint with it is described Pusher sliding block is connected；Under the drive of the telescopic cylinder, direction of the pusher sliding block along the second sleeve is back and forth Motion.

Further, the sensor block and the proximity switch have two, are separately mounted to the both sides of the detection seat.

Further, two optoelectronic switches are arranged on the both sides of the pusher sliding block.

Further, the corner of the magnetic shoe bottom plate lower surface is separately installed with column.

The present invention also provides a kind of operation method of small-sized tiles material delivery system, comprises the following steps：

S1, first magnetic shoe enter from the opening of the first sleeve, and second sleeve intracavitary is fallen into by the gravity of itself, and first Piece magnetic shoe pushes down the sensor block of the opening side of the first sleeve, and this sensor block is rotated by the proximity switch sense of opening side Should；

S2, second magnetic shoe enter from the opening of the first sleeve, first dropped to by the gravity of itself in second sleeve On piece magnetic shoe, the optoelectronic switch of the opening side of the first sleeve senses second magnetic shoe, and now rotary cylinder is made a response, Plectrum, sub-material axle rotation 180 degree are driven, plectrum then drives second magnetic shoe to rotate the another side chamber that 180 degree falls into second sleeve It is interior；

S3, second magnetic shoe are pushed down the sensor block of another side by the gravity of itself, and this sensor block is rotated by the close of homonymy Inductive switching；3rd magnetic shoe enters from the opening of the first sleeve, and first magnetic in second sleeve is dropped to by the gravity of itself On watt, the optoelectronic switch of the opening side of first sleeve senses the 3rd magnetic shoe, and now rotary cylinder is made a response, Plectrum, sub-material axle rotation 180 degree are driven, plectrum then drives the 3rd magnetic shoe to rotate the another side chamber that 180 degree falls into second sleeve It is interior；

S4, the 3rd magnetic shoe are dropped in second sleeve on second magnetic shoe by the gravity of itself, the first sleeve another side Optoelectronic switch senses the 3rd magnetic shoe, and now two optoelectronic switches, two proximity switches have sensing, then telescopic cylinder, which is done, stretches Go out action, first magnetic shoe, second magnetic shoe are released second sleeve, first magnetic shoe, second magnetic shoe are transported to next Individual station；Second guide pad, the first guide pad are oriented to first magnetic shoe, second magnetic shoe of release.

Beneficial effects of the present invention are：One cylinder, a rotary cylinder add some assembling parts to form, stabilized structure, Deformation is not likely to produce, cost is cheap, and mechanism is compact, and it is broken can to prevent that magnetic shoe from producing by the device feeding for magnetic shoe.

1) trigger rotary cylinder by optoelectronic switch to rotate so that magnetic shoe turns to opposite side from the side of sleeve, passes through Magnetic shoe triggers the optoelectronic switch of both sides；

2) dropped to by the gravity of magnetic shoe itself on sensor block so that sensor block rotates, so as to trigger proximity switch, when two When the optoelectronic switch and proximity switch of side all trigger, telescopic cylinder drives pusher slide block movement, so as to which magnetic shoe be exported, this process Continuity is strong, will not produce the phenomenon of card magnetic shoe.

Brief description of the drawings

Fig. 1 is a kind of structural representation of small-sized tiles material delivery system；

Fig. 2 is a kind of cross section structure diagram of small-sized tiles material delivery system；

1st, positive stop；2nd, pusher sliding block；3rd, swivel plate；4th, rotary cylinder；5th, second sleeve；6th, the first sleeve；7th, light Electric switch；8th, the second guide pad；9th, column；10th, sensor block；11st, proximity switch；12nd, magnetic shoe bottom plate；13rd, telescopic cylinder；14、 Magnetic shoe cylinder block；15th, M5 active joints；16th, magnetic shoe；17th, plectrum；18th, sub-material axle；19th, the first guide pad；20th, seat is detected； 21st, catch is buffered.

Embodiment

In order to make the purpose , technical scheme and advantage of the present invention be clearer, below in conjunction with the accompanying drawings and embodiment, it is right The present invention is further elaborated.It should be appreciated that specific embodiment described herein is only to explain the present invention, not For limiting the present invention.

Refer to Fig. 1 and Fig. 2, a kind of small-sized tiles material delivery system, including magnetic shoe bottom plate 12, the magnetic shoe bottom plate 12 upper surfaces are provided with pusher sliding block 2, and the pusher sliding block 2 passes through second sleeve 5, the second sleeve 5 and the magnetic shoe bottom The phase of plate 12 from surface, be from the close-by examples to those far off sequentially installed with the first sleeve 6, swivel plate 3 and rotary cylinder 4；In the second sleeve 5 Provided with the first guide pad 19 and buffering catch 21, first guide pad 19 is arranged on the buffering catch 21, and described first The sub-material axle 18 that can be rotated is installed, the middle part of the sub-material axle 18 is provided with plectrum 17, the plectrum 17 on guide pad 19 It can be rotated with the sub-material axle 18；The axle of the rotary cylinder 4 is fixedly connected with the sub-material axle 18, the rotary cylinder 4 The sub-material axle 18 can be driven to rotate；

That is, rotary cylinder 4 is connected by swivel plate 3 with the first sleeve 6.Buffer catch 21 be arranged on second sleeve 5 with The relative bottom of first sleeve 6.

First sleeve 6 and the phase of second sleeve 5 from one end be provided with opening；

It is also equipped with detecting seat 20 and proximity switch 11 on the magnetic shoe bottom plate 12, two is provided with the detection seat 20 The sensor block 10 that can be rotated, the side adjacent with the pusher sliding block 2 is provided with two optoelectronic switches 7 in the second sleeve 5.

The detection seat 20 and the proximity switch 11 are arranged on the lower surface of the magnetic shoe bottom plate 12, and with described second Sleeve 5 is corresponding.

That is, proximity switch 11 is arranged on the side of detection seat 20.

Described one end of pusher sliding block 2 is provided with positive stop 1, and the other end of pusher sliding block 2 is provided with the second guide pad 8, institute Stating the second guide pad 8 has two pieces, is separately positioned on the both sides of the pusher sliding block 2, and be connected with the second sleeve 5.The Magnetic shoe 16 can be imported next process by two guide runners 8.

The pusher sliding block 2 one end adjacent with the positive stop 1 is provided with magnetic shoe cylinder block 14, the magnetic shoe cylinder Seat 14 with the phase of positive stop 1 from side telescopic cylinder 13 is installed, the telescopic cylinder 13 passes through M5 vigor joint 15 It is connected with the pusher sliding block 2；Under the drive of the telescopic cylinder 13, the pusher sliding block 2 is along the second sleeve 5 Direction move back and forth.

That is, under the drive of telescopic cylinder 13, the magnetic shoe in second sleeve 5 can be released from second sleeve 5 is interior.

The sensor block 10 and the proximity switch 11 have two, are separately mounted to the both sides of the detection seat 20.

That is, sensor block 10 and proximity switch 11 be separately mounted to the first sleeve 6 opening homonymy and with the first sleeve 6 Opening mutually from side.

Two optoelectronic switches 7 are arranged on the both sides of the pusher sliding block 2.

The corner of the lower surface of magnetic shoe bottom plate 12 is separately installed with column 9.

A kind of operation method of small-sized tiles material delivery system, comprises the following steps：

S1, first magnetic shoe 16 enter from the opening of the first sleeve 6, and the intracavitary of second sleeve 5 is fallen into by the gravity of itself, First magnetic shoe 16 pushes down the sensor block 10 of the opening side of the first sleeve 6, and this sensor block 10 is rotated by opening side Proximity switch 11 senses；

S2, second magnetic shoe 16 enter from the opening of the first sleeve 6, are dropped to by the gravity of itself in second sleeve 5 On first magnetic shoe 16, the optoelectronic switch 7 of the opening side of the first sleeve 6 senses second magnetic shoe 16, now rotary pneumatic Cylinder 4 is made a response, and drives plectrum 17, sub-material axle 18 to rotate 180 degree, and plectrum 17 then drives second rotation of magnetic shoe 16 180 degree to fall Enter the another side intracavitary of second sleeve 5；

S3, second magnetic shoe 16 are pushed down the sensor block 10 of another side by the gravity of itself, and this sensor block 10 is rotated by homonymy Proximity switch 11 sense；3rd magnetic shoe 16 enters from the opening of the first sleeve 6, and second sleeve is dropped to by the gravity of itself In 5 on first magnetic shoe 16, the optoelectronic switch 7 of the opening side of first sleeve 6 senses the 3rd magnetic shoe 16, now Rotary cylinder 4 is made a response, and drives plectrum 17, sub-material axle 18 to rotate 180 degree, plectrum 17 then drives the 3rd magnetic shoe 16 to rotate 180 degree falls into the another side intracavitary of second sleeve 5；

S4, the 3rd magnetic shoe 16 are dropped in second sleeve 5 on second magnetic shoe 16 by the gravity of itself, and the first sleeve 6 is another The optoelectronic switch 7 on one side senses the 3rd magnetic shoe 16, and now two optoelectronic switches, 7, two proximity switches 11 have sensing, then Telescopic cylinder 13 does extending action, and first magnetic shoe, 16, second magnetic shoes 16 are released second sleeve 5, first magnetic shoe 16, Second magnetic shoe 16 is transported to next station；Second guide pad 8, the first guide pad 19 are to first magnetic shoe of release 16th, second magnetic shoe 16 is oriented to.

Embodiment described above only expresses embodiments of the present invention, and its description is more specific and detailed, but can not Therefore it is interpreted as the limitation to the scope of the claims of the present invention.It should be pointed out that for the person of ordinary skill of the art, Without departing from the inventive concept of the premise, various modifications and improvements can be made, these belong to the protection model of the present invention Enclose.Therefore, the protection domain of patent of the present invention should be determined by the appended claims.

Claims

A kind of 1. small-sized tiles material delivery system, it is characterised in that：Including magnetic shoe bottom plate (12), the magnetic shoe bottom plate (12) Upper surface is provided with pusher sliding block (2), and the pusher sliding block (2) passes through second sleeve (5), the second sleeve (5) with it is described Magnetic shoe bottom plate (12) mutually from surface, be from the close-by examples to those far off sequentially installed with the first sleeve (6), swivel plate (3) and rotary cylinder (4)； The first guide pad (19) and buffering catch (21) are provided with the second sleeve (5), first guide pad (19) is arranged on institute State on buffering catch (21), the sub-material axle (18) that can be rotated, the sub-material axle are installed on first guide pad (19) (18) plectrum (17) is installed, the plectrum (17) can rotate with the sub-material axle (18) in the middle part of；The rotary cylinder (4) Axle be fixedly connected with the sub-material axle (18), the rotary cylinder (4) can drive the sub-material axle (18) to rotate；

First sleeve (6) and the second sleeve (5) mutually from one end be provided with opening；

It is also equipped with detecting seat (20) and proximity switch (11) on the magnetic shoe bottom plate (12), is provided with the detection seat (20) Two sensor blocks (10) that can be rotated, the side adjacent with the pusher sliding block (2) is provided with two on the second sleeve (5) Optoelectronic switch (7).
A kind of 2. small-sized tiles material delivery system according to claim 1, it is characterised in that：The detection seat (20) The lower surface of the magnetic shoe bottom plate (12) is arranged on the proximity switch (11), and it is corresponding with the second sleeve (5).
A kind of 3. small-sized tiles material delivery system according to claim 1, it is characterised in that：The pusher sliding block (2) one end is provided with positive stop (1), and pusher sliding block (2) other end is provided with the second guide pad (8), second guide pad (8) there are two pieces, be separately positioned on the both sides of the pusher sliding block (2), and be connected with the second sleeve (5).
A kind of 4. small-sized tiles material delivery system according to claim 3, it is characterised in that：The pusher sliding block (2) magnetic shoe cylinder block (14), the magnetic shoe cylinder block (14) and the limit are installed with the adjacent one end of the positive stop (1) Position block (1) mutually from side telescopic cylinder (13) is installed, the telescopic cylinder (13) passes through M5 vigor joint (15) and institute Pusher sliding block (2) is stated to be connected；Under the drive of the telescopic cylinder (13), the pusher sliding block (2) is along described second set The direction of cylinder (5) moves back and forth.
A kind of 5. small-sized tiles material delivery system according to claim 2, it is characterised in that：The sensor block (10) There are two with the proximity switch (11), be separately mounted to the both sides of the detection seat (20).
A kind of 6. small-sized tiles material delivery system according to claim 1, it is characterised in that：Two photoelectricity are opened Close the both sides that (7) are arranged on the pusher sliding block (2).
A kind of 7. small-sized tiles material delivery system according to claim 1, it is characterised in that：The magnetic shoe bottom plate (12) corner of lower surface is separately installed with column (9).
8. a kind of operation method of small-sized tiles material delivery system, it is characterised in that comprise the following steps：

S1, first magnetic shoe (16) enter from the opening of the first sleeve (6), and second sleeve (5) chamber is fallen into by the gravity of itself Interior, first magnetic shoe (16) pushes down the sensor block (10) of the opening side of the first sleeve (6), and this sensor block (10) is rotated and opened Proximity switch (11) sensing of Kou Chu sides；

S2, second magnetic shoe (16) enter from the opening of the first sleeve (6), are dropped to by the gravity of itself in second sleeve (5) First magnetic shoe (16) on, the optoelectronic switch (7) of the opening side of the first sleeve (6) senses second magnetic shoe (16), Now rotary cylinder (4) is made a response, and drives plectrum (17), sub-material axle (18) rotation 180 degree, and plectrum (17) then drives second Magnetic shoe (16) rotation 180 degree falls into the another side intracavitary of second sleeve (5)；

S3, second magnetic shoe (16) are pushed down the sensor block (10) of another side by the gravity of itself, and this sensor block (10) rotates same Proximity switch (11) sensing of side；3rd magnetic shoe (16) enters from the opening of the first sleeve (6), is dropped to by the gravity of itself In second sleeve (5) on first magnetic shoe (16), the optoelectronic switch (7) of the opening side of first sleeve (6) senses 3rd magnetic shoe (16), now rotary cylinder (4) make a response, drive plectrum (17), sub-material axle (18) rotation 180 degree, plectrum (17) the 3rd magnetic shoe (16) rotation 180 degree is then driven to fall into the another side intracavitary of second sleeve (5)；

S4, the 3rd magnetic shoe (16) are dropped in second sleeve (5) on second magnetic shoe (16) by the gravity of itself, the first sleeve (6) optoelectronic switch (7) of another side senses the 3rd magnetic shoe (16), now two optoelectronic switches (7), two proximity switches (11) there is sensing, then telescopic cylinder (13) does extending action, and first magnetic shoe (16), second magnetic shoe (16) are released second Sleeve (5), first magnetic shoe (16), second magnetic shoe (16) are transported to next station；Second guide pad (8), One guide pad (19) is oriented to first magnetic shoe (16), second magnetic shoe (16) of release.