CN110154365B

CN110154365B - Vibration drill distribution method and device, and water drill plastic sucking disc forming method and equipment

Info

Publication number: CN110154365B
Application number: CN201910389352.3A
Authority: CN
Inventors: 虞雅仙
Original assignee: Individual
Current assignee: Individual
Priority date: 2016-01-29
Filing date: 2016-01-29
Publication date: 2021-10-15
Anticipated expiration: 2036-01-29
Also published as: CN105522717B; CN110154365A; CN109895357B; CN105522717A; CN109895357A

Abstract

The invention discloses a vibration drill distribution method and device, and a water drill plastic sucking disc forming method and device, wherein the vibration drill distribution device comprises a drill distribution disc and a vibration device, wherein a material collecting hopper is arranged on one side of the drill distribution disc, a first tooling disc is arranged on the drill distribution disc, the first tooling disc is driven by the vibration device to vibrate, a vent hole is arranged at the bottom of an embedding hole in the first tooling disc, and the vent hole is communicated with a vacuum pump through an air pipe; when the drill is distributed, the water drill is laid on the first tool plate along with vibration and is embedded into the embedding hole of the first tool plate; after the drill distribution is finished, the drill distribution disc and the first tool disc are inclined, the water drill embedded into the embedding hole of the first tool disc is fixed by vacuum adsorption, and the redundant water drill falls into the material collecting hopper. This scheme has the range embedding fast, the location is accurate, and the rhinestone embedding is firm, efficient advantage such as high.

Description

Vibration drill distribution method and device, and water drill plastic sucking disc forming method and equipment

The present application is the following:

application No. 201610064427.7;

the application date is 2016, 1 and 29;

the application name is a vibration drill distribution device and full-automatic water drill plastic sucking disc forming equipment;

the divisional application of the patent.

Technical Field

The invention relates to the field of crystal material processing, in particular to the field of rhinestone processing, and particularly relates to a vibration rhinestone distribution method and device, and a rhinestone plastic sucking disc forming method and device.

Background

The end face grinding and polishing processing and spraying processing of the rhinestones adopt processing methods for manufacturing plastic-absorbing films in order to improve the processing efficiency, and the patent with the publication number of CN100484711 discloses a rhinestone end face grinding and polishing processing method.

The publication No. CN100484711 discloses a water bores frock dish vibration distributing device, the device sets up horizontal vibration platform through the slope, and set up mount and cloth board on vibration mesa, make water bore frock dish can inlay in the middle of the cloth board, open the vibration, slowly fall down water bores from the frock dish top, can fall into in the embedded hole through vibrating most water bores, unnecessary slide into the tray through the unloading breach, repeat a plurality of times and just can make all imbed water bores in the embedded hole of frock dish, then close the vibration, turn up the cloth board, take out the frock dish and just can get into next process. Because in this patent literature, the frock dish sets up the vibration cloth and bores into the slope, shakes out the water brill that has imbedded the downthehole once more easily in the vibration process, influences cloth brill efficiency and cloth brill location's accuracy degree, also leads to the water to bore out of inlaying because of rocking easily at the in-process of taking out the frock dish of slope to the device still needs artifical the back-off drill, has increased operating personnel's intensity of labour.

Disclosure of Invention

In order to solve the above technical problems, a first object of the present invention is to provide a method and an apparatus for distributing rhinestones by vibration, which have the advantages of fast arrangement and embedding, accurate positioning, firm rhinestone embedding, high efficiency, etc. The second purpose of the invention is to provide a method and equipment for forming a rhinestone blister tray, and the method and the device for distributing rhinestones by adopting the vibration.

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

a vibration drill distribution device is characterized by comprising a drill distribution disc (11) and a vibration device (13), wherein a material collection hopper (113) is arranged on one side of the drill distribution disc (11), a first tool disc (112) is arranged on the drill distribution disc (11), the first tool disc (112) is driven by the vibration device to vibrate, a vent hole is arranged at the bottom of an embedding hole in the first tool disc (112), and the vent hole is communicated with a vacuum pump through an air pipe (14); when the drill is distributed, the water drill is laid on the first tool plate along with vibration and is embedded into the embedding hole of the first tool plate; after the drill distribution is finished, the drill distribution disc (11) and the first tool disc (112) are inclined, the water drills embedded into the embedding holes of the first tool disc are fixed by vacuum adsorption, and the redundant water drills fall into the collecting hopper (113).

Preferably, the cloth drilling disc (11) is driven by a driving device to incline and reset.

Preferably, the driving device is a first cylinder (12).

Preferably, enclosing plates (111) are arranged on the periphery of the cloth drilling disc (11).

Preferably, the vibration device drives the first tool plate (112) and the drilling cloth plate (11) to vibrate together.

Preferably, the cloth drilling disc (11) is hinged with one side of the vibration device (13), a material collecting hopper (113) is arranged on the side, hinged with the vibration device (13), of the cloth drilling disc (11), and the bottom of the material collecting hopper (113) is hinged with the piston end of the first air cylinder (12).

Preferably, the vibration device comprises a vibration motor (133), a vibration bottom plate (131) and a first guide rail (132), the first guide rail (132) is fixed on the frame (9), the vibration bottom plate (131) is arranged on the first guide rail (132), the vibration bottom plate (131) is hinged to the drilling cloth disk (11), the hinged side of the vibration bottom plate (131) and the drilling cloth disk (11) is parallel to the extending direction of the first guide rail (132), the vibration motor (133) is fixed on the frame (9) at the bottom of the vibration bottom plate (131), and the vibration motor (133) drives the vibration bottom plate (131) to reciprocate along the first guide rail (132).

A vibration drill distribution method adopts the vibration drill distribution device.

The utility model provides a water bores plastic sucking plate former, bores station and blister work station including vibration cloth, the vibration cloth is bored and is provided with on the station and is bored the device as above, be provided with base (33), suction mould board (34), pressure frame board (35) and heater (36) on the blister work station.

A method for forming a rhinestone plastic sucking disc adopts the forming equipment for the rhinestone plastic sucking disc.

According to the technical scheme, the water drill is vibrated into the embedding hole through the vibration tool disc, the bottom of the tool disc is further subjected to vacuum adsorption, positioning and embedding of the water drill are accelerated, meanwhile, after the water drill is embedded, the tool disc is inclined to pour the excess water drill into the material collecting hopper for next material distribution, and in the process, due to the vacuum adsorption at the bottom of the tool disc, the distributed water drill is firmly positioned and is not easy to fall off. After the cloth drill is finished, the cloth drill plate and the first tool plate return to the horizontal state, and the cloth drill plate and the first tool plate are convenient to take and place. In addition, due to the arrangement of the collecting hopper, manual reverse drilling is not needed in the working process of the device, and multiple times of material distribution can be automatically completed only by placing a proper amount of water drill into the collecting hopper once.

Drawings

FIG. 1 is a schematic structural diagram of a rhinestone blister tray molding device;

FIG. 2 is a schematic structural diagram of the rhinestone plastic sucking disc forming equipment after a vibrating drill distribution station on one side is removed;

FIG. 3 is a schematic structural diagram of a plastic suction station of the rhinestone plastic suction disc forming device;

FIG. 4 is a schematic structural diagram of another view angle of a plastic suction station of the rhinestone plastic suction disc forming device;

FIG. 5 is a schematic structural diagram of a water drill plastic sucking disc forming device when a drilling distribution disc of a vibration drilling distribution station is horizontal;

FIG. 6 is a schematic structural diagram of a water drill plastic sucking disc forming device when a drilling distribution disc of a vibration drilling distribution station is inclined;

FIG. 7 is a schematic side view of a vibrating drill distribution station of the rhinestone blister tray molding device;

FIG. 8 is a schematic overall structure diagram of a cutting station of the rhinestone blister tray molding apparatus;

fig. 9 is a schematic structural diagram of a cutting disc, a supporting plate and a driving mechanism of a cutting station of the rhinestone plastic suction disc forming device.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are illustrative and intended to be illustrative of the invention and are not to be construed as limiting the invention.

In the description of the present invention, it is to be understood that the terms "center", "longitudinal", "lateral", "length", "width", "thickness", "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "clockwise", "counterclockwise", and the like, indicate orientations and positional relationships based on those shown in the drawings, and are used only for convenience of description and simplicity of description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus, are not to be considered as limiting the present invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present invention, unless otherwise specified, "a plurality" means two or more unless explicitly defined otherwise.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

As shown in fig. 1, a full-automatic water bores plastic sucking plate former, including frame 9, the at least one side in the 9 left and right sides of frame is equipped with the vibration cloth and bores the station, be equipped with the plastic uptake station in the frame 9 at middle part, still be equipped with the manipulator between vibration cloth brill station and the plastic uptake station, reciprocating motion between two stations of manipulator, be equipped with plastic uptake material cylinder 41 in the place ahead frame 9 of plastic uptake station, be equipped with on the rear frame 9 of plastic uptake station and cut the station, and the rear that cuts the station is equipped with double-layered roller 43, and plastic uptake material 42 is connected to on the double-layered roller 43 after drawing forth the plastic uptake station of passing by plastic uptake material cylinder 41.

The vibration drilling cloth station shown in fig. 1, 5, 6 and 7 comprises a drilling cloth disk 11, a first air cylinder 12 and a vibration device 13, wherein the vibration device is fixed on the frame 9, the drilling cloth disk 11 is hinged with the vibration device 13, and the first air cylinder 12 is hinged between the frame 9 and the drilling cloth disk 11. The center of the cloth drilling disc 11 is also provided with a first tool disc 112, the first tool disc 112 is driven by the vibration device 13 to reciprocate, the first tool disc 112 is provided with a plurality of embedding holes, the bottoms of the embedding holes are provided with vent holes, and the vent holes are communicated with a vacuum pump through air pipes 14.

Be equipped with bounding wall 111 around cloth drill plate 11, cloth drill plate 11 still is equipped with aggregate bin 113 with vibrating device 13 looks articulated one side, aggregate bin 113's bottom interval is equipped with two connection ear pieces 114, is connected through first pivot 115 between two connection ear pieces 114, the piston end of first cylinder 12 is fixed with the lantern ring, the lantern ring cover is established on first pivot 115. When the cloth bores the dish and is in horizontal position, the water in the collecting hopper bores and can not spread to first frock dish, when the cloth bores the beginning, the water bores along with the vibration spreads to first frock dish, after all imbedding the water in the embedded hole of first frock dish and bores, first cylinder 12 drive one side of cloth bores dish 11 rises and makes the cloth bores dish keep the tilt state, unnecessary water bores just falls into the collecting hopper, treat that the water bores all fall into behind the collecting hopper first cylinder 12 makes cloth bores dish 11 keep the level so that the manipulator will arrange the diamond takeaway.

The vibrating device comprises a vibrating motor 133, a vibrating bottom plate 131 and a first guide rail 132, the first guide rail 132 is fixed on the frame 9, the vibrating bottom plate 131 is arranged on the first guide rail 132, the vibrating bottom plate 131 is hinged to the drilling cloth tray 11, the hinged sides of the vibrating bottom plate 131 and the drilling cloth tray 11 are parallel to the extending direction of the first guide rail 132, the vibrating motor 133 is fixed on the frame at the bottom of the vibrating bottom plate 131, and the vibrating motor 133 drives the vibrating bottom plate 131 to reciprocate along the first guide rail 132, so that the water drill is vibrated into the embedding hole.

As shown in fig. 2, 3 and 4, the blister station includes base 33, second frock dish 32, suction mould board 34, pressure frame board 35 and heater 36, base 33 installs in frame 9, and is equipped with a columniform step face on the base 33, be equipped with second frock dish 32 on the step face, be equipped with a plurality of caulking holes on the second frock dish 32, the bottom of caulking hole is equipped with the air vent, and the air vent communicates with the vacuum pump, press frame board 35 and heater 36 to install respectively on the frame 9 on upper portion, and press frame board 35 ability oscilaltion, suction mould board 34 becomes hollow cylinder, and suction mould board 34 cover establishes in the outside of second frock dish 32, suction mould board passes through the sealing connection when realizing relative movement in the fixed range between the step face of ring packing and base.

The annular sealing ring is fixedly arranged on the suction template or the cylindrical step surface of the base in a sealing manner and is connected with the step surface or the suction template in a sleeved insertion manner; or preferably, the annular sealing ring is sleeved outside the step surface in a manner of moving up and down and is elastically supported by the elastic mechanism, and a sealing element is arranged between the annular sealing ring and the step surface; and a gap is reserved between the circumference of the side surface of the second tool disc and the suction template or the annular sealing ring, and the gap is communicated with the vacuum pump through a ventilation channel arranged on the step surface of the second tool disc or the base.

The suction mould plate 34 is driven to lift by a fourth cylinder 342 fixed on the lower surface of the base mounting plate, a piston rod of the fourth cylinder 342 penetrates through the base mounting plate and then is fixed with the connecting lug plates 341 on two sides of the suction mould plate 34, and the frame pressing plate 35 is driven to lift by a fifth cylinder 351 fixed on the frame 9.

The heater 36 is mounted on the frame 9 through a third rotating shaft 361, a second motor 362 is further disposed on one side of the third rotating shaft 361 on the frame 9, and the third rotating shaft 361 and the second motor 362 are engaged through a gear. The second motor 362 drives the heater 36 to rotate, so that heating is more uniform during the blister process.

When the both sides of plastic uptake station all were equipped with the vibration cloth and bore the station, second frock dish 32 and suction mould board 34 on the base 33 are two, and base 33 is installed on the second guide rail 91 of frame 9, and the one end of base 33 is fixed mutually with the third cylinder 31 of fixing on frame 9, and drive base 33 is reciprocating motion on second guide rail 91, makes the in-process of plastic uptake station at work like this, and the manipulator can shift the diamond on the first frock dish to another second frock dish of base 33 simultaneously, and the process that two second frock dishes carried out cloth simultaneously in turn and bored and the plastic uptake has improved production efficiency greatly.

When the plastic suction process is carried out, the pressing frame plate descends and the suction template clamps the plastic suction material and enables the plastic suction material to be slightly higher than the top end of the rhinestone, then the heater heats the plastic suction material to enable the plastic suction material to arch upwards, the heater continuously heats the plastic suction material, the plastic suction material continuously descends to the second height, the edge plane of the plastic suction material is lower than the top end of the rhinestone, the vacuum pump sucks vacuum to complete the plastic suction process, the guide sleeve 353 is arranged on the periphery of the pressing frame plate, the guide posts 352 are arranged on the base on the periphery of the suction template, and the positioning of the pressing frame plate and the suction template is realized through the matching of the guide sleeve 353 and the guide posts 352 in the descending process of the pressing frame plate so as to clamp the plastic suction material tightly and guarantee the sealing performance.

The manipulator setting shown in fig. 1 and 2 is between vibration cloth drill station and blister-molding station, the manipulator includes first motor 21, second pivot 24, support 25, second cylinder 26 and sucking disc 27, and two second pivots 24 are respectively through the one end that the support frame setting is close to vibration cloth drill station in the frame and the one end that is close to the blister-molding station, and the both ends of second pivot 24 all are fixed with runner 23, and the runner 23 of 24 homonymies of two second pivots all is equipped with conveyer belt 22, first motor 21 is fixed in the frame and is driven second pivot 24 and rotate, support 25 is fixed on conveyer belt 22, the sucking disc passes through the second cylinder and is fixed with the support looks level, the bottom of sucking disc 27 is equipped with a plurality of caulking holes, and the upper portion in caulking hole is equipped with the air vent, air vent and vacuum pump intercommunication.

In order to facilitate the manipulator to transfer the arranged rhinestones from the vibration cloth drilling station to the plastic suction station, the quantity of the embedding holes on the first tooling plate, the shape of the embedding holes, the distance between the adjacent embedding holes and the arrangement mode of the embedding holes are all the same as those of the second tooling plate, the quantity of the embedding holes on the sucker, the shape of the embedding holes, the embedding hole depth, the distance between the adjacent embedding holes and the arrangement mode of the embedding holes are all the same as those of the first tooling plate, and simultaneously, in the process of satisfying the cloth drilling and plastic suction, the rhinestones expose different requirements of the height of the embedding holes, the embedding hole depth of the first tooling plate is higher than the waist height of the rhinestones, and the embedding hole depth of the second tooling plate is lower than the waist height of the rhinestones.

The plastic uptake material is drawn out by the plastic uptake material cylinder 41, and the back between the pressure frame plate and the suction template that pass the plastic uptake station is drawn in between two clamp rollers 43 that are located the frame rear portion, still be equipped with in the lower part frame of plastic uptake material cylinder 41 and be used for driving plastic uptake material cylinder 41 pivoted third motor 44, and two clamp rollers 43 are installed in the frame through the riser 45 of both sides, riser 45 is equipped with fore-and-aft logical groove, and the both ends of two clamp rollers 43 set up in the logical inslot of riser 45 through the bearing piece respectively, and is equipped with spring 46 between the bearing piece of the clamp roller 43 both sides on upper portion and the logical groove upper end, still be equipped with in the frame of the below of the clamp roller 43 of lower part and be used for driving clamp roller pivoted fourth motor 47.

The cutting station that is shown in fig. 8 and 9 is located the rear of blister-molding station, the cutting station includes cutting dish 51 and layer board 53, cutting dish 51 is located the top of blister-molding material, and the upper portion of cutting dish 51 is equipped with and is used for driving the wobbling sixth cylinder 56 of cutting dish, sixth cylinder 56 is fixed mutually through connecting plate and the seventh cylinder 57 that is used for driving the cutting dish to go up and down, seventh cylinder 57 is fixed in the frame, still equidistant interval is fixed with a plurality of blades 52 around cutting dish 51, layer board 53 is located the below of blister-molding material, one side of layer board 53 is articulated mutually with the frame through hinge 55, the bottom of layer board 53 still is connected with the eighth cylinder 54 that is used for the slope layer board so that the ejection of compact of shaping blister-molding dish. The cutting disc 51 can also be driven to rotate by a motor, so that the cutting purpose is realized, and the supporting plate is inclined by the air cylinder so as to smoothly send out the cut plastic suction disc.

The working process of the present invention is as follows,

1) a water drill is placed in the collecting hopper in advance, the vibration motor drill distribution disc is started to reciprocate along the first guide rail along with the vibration bottom plate, the water drill in the vibration collecting hopper is gradually paved on the drill distribution disc in a horizontal state until all the embedding holes of the first tool disc are fully distributed with the water drill, the vibration is stopped, the first air cylinder 12 drives one side, far away from the collecting hopper, of the drill distribution disc 11 to ascend, and redundant water drills fall back into the collecting hopper;

2) the first motor 21 drives the sucker to reach the position above the first tooling plate through the conveyor belt, the second air cylinder 26 drives the sucker to descend to the position above the rhinestone, the rhinestone is matched with the position of an embedding hole in the sucker, after the sucker sucks all the rhinestones on the first tooling plate, the sucker is lifted up by the second air cylinder 26, the sucker is taken to a plastic suction station by the first motor 21 through the conveyor belt, the sucker is descended above the second tooling plate, the rhinestones on the sucker are all transferred to the second tooling plate, and the sucker, the first tooling plate, the sucker and the second tooling plate are accurately positioned in a guide sleeve and guide column mode;

3) the third cylinder drives the base to slide, so that the second tooling plate with the distributed rhinestones moves to the position below the pressing frame plate and the heater, the suction template descends to a first height, at the moment, the blister materials are clamped and fixed and sealed by the pressing frame plate and the suction template, the height of the blister materials is higher than that of the top end of the rhinestones on the second tooling plate, the suction template is connected with the step surface of the base in a sealing mode through the annular sealing ring, and the heater heats the blister materials to enable the blister materials to be heated, softened and arched upwards; the heater continuously heats, the frame pressing plate and the mold sucking plate descend to a second height, and at the moment, the plane of the edge of the plastic absorbing material clamped by the frame pressing plate and the mold sucking plate is lower than the top end of the rhinestone on the tooling plate; vacuumizing by a vacuum pump, and forming a plastic-suction forming rhinestone plastic-suction disc; meanwhile, the other second tooling plate is matched with the vibration station and the manipulator on the other side to complete the process of transferring the distributed rhinestones to the second tooling plate, when the previous second tooling plate completes the plastic suction process, the third cylinder drives the base to slide so that the base waits for the distributed rhinestones of the manipulator again, and the other second tooling plate moves to the bottom of the frame pressing plate to perform the plastic suction process;

4) press the deckle board and rise simultaneously with the suction mould board, loosen the plastic uptake material, fourth motor drive clamp roller rotates and drives the plastic uptake material and move backward, with fashioned water bores plastic uptake dish remove to cutting station below, the too big and plastic uptake material fracture that leads to of resistance when avoiding plastic uptake material cylinder 41 to rotate simultaneously, set up the third motor in plastic uptake material cylinder 41 below, like this when the fourth motor starts, the third motor also starts simultaneously, greatly reduced plastic uptake material cylinder 41's rotation resistance, avoided the fracture of shaping plastic uptake dish for in-process plastic uptake material.

5) After the formed rhinestone plastic-suction disc reaches the lower part of the cutting station, the eighth cylinder 54 drives the supporting plate to enable the supporting plate to be kept horizontal and support the formed rhinestone plastic-suction disc, then the seventh cylinder 57 drives the cutting disc to descend, meanwhile, the sixth cylinder 56 drives the cutting disc to swing, blades 52 on the periphery of the cutting disc cut the formed rhinestone plastic-suction disc from the whole plastic-suction material conveying belt, then the eighth cylinder 54 resets to enable the supporting plate to incline, the rhinestone plastic-suction disc falls into the material frame, and discharging of the plastic-suction disc is completed.

In the step 3), a vacuum pump is used for pumping part of air to control the upward arched deformation degree of the blister material; in the step 4), before the frame pressing plate and the suction template are opened, partial air is sent by a vacuum pump so that the rhinestone suction plastic plate is peeled from the tool disc to avoid damage and convenient displacement during opening.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

Although embodiments of the present invention have been shown and described above, it is understood that the above embodiments are exemplary and should not be construed as limiting the present invention, and that variations, modifications, substitutions and alterations can be made in the above embodiments by those of ordinary skill in the art without departing from the principle and spirit of the present invention.

Claims

1. A vibration cloth drilling device is characterized by comprising a cloth drilling disc (11), a first air cylinder (12) and a vibration device (13), wherein a material collecting hopper (113) is arranged on one side of the cloth drilling disc (11), a first tool disc (112) is arranged on the cloth drilling disc (11), the first tool disc (112) is driven by the vibration device to vibrate, vent holes are formed in the bottoms of embedding holes in the first tool disc (112), and the vent holes are communicated with a vacuum pump through air pipes (14); when the drill is distributed, the water drill is laid on the first tool plate along with vibration and is embedded into the embedding hole of the first tool plate; after the drill distribution is finished, the drill distribution disc (11) and the first tool disc (112) are inclined, the water drills embedded into the embedding holes of the first tool disc are fixed by vacuum adsorption, and the redundant water drills fall into a collecting hopper (113); wherein, the cloth drill plate (11) is driven by a first air cylinder (12) to incline and reset.

2. A vibrating drill distribution device according to claim 1, characterized in that the drill distribution plate (11) is provided with surrounding plates (111) around it.

3. A vibrating feed auger apparatus as claimed in claim 1, wherein the vibrating means drives the first tooling plate (112) and the feed auger plate (11) to vibrate together.

4. A vibrating auger spreading device according to claim 3, wherein the auger spreading disk (11) is hinged to one side of the vibrating device (13), and a hopper (113) is arranged at the side of the auger spreading disk (11) hinged to the vibrating device (13), and the bottom of the hopper (113) is hinged to the piston end of the first cylinder (12).

5. A vibrating bur distribution device according to claim 3, characterized in that the vibrating device comprises a vibrating motor (133), a vibrating bottom plate (131) and a first guide rail (132), the first guide rail (132) is fixed on the frame (9), the vibrating bottom plate (131) is arranged on the first guide rail (132), the vibrating bottom plate (131) is hinged with the bur distribution plate (11), the hinged side of the vibrating bottom plate (131) and the bur distribution plate (11) is parallel to the extending direction of the first guide rail (132), the vibrating motor (133) is fixed on the frame (9) at the bottom of the vibrating bottom plate (131), and the vibrating motor (133) drives the vibrating bottom plate (131) to reciprocate along the first guide rail (132).

6. A vibrating bur distribution method, characterized in that a vibrating bur distribution device according to any one of claims 1 to 5 is used.

7. A rhinestone plastic sucking disc forming device is characterized by comprising a vibrating cloth drill station and a plastic sucking station, wherein the vibrating cloth drill station is provided with a vibrating cloth drill device according to any one of claims 1 to 5, and the plastic sucking station is provided with a base (33), a suction template (34), a pressing frame plate (35) and a heater (36).

8. A method for forming a rhinestone blister tray, characterized by using the rhinestone blister tray forming apparatus according to claim 7.