CN108991717B - Two-drill one-planting type large disc glass brush drilling and hair planting device and method - Google Patents

Abstract

The invention discloses a two-drill one-plant type large-scale disc glass brush drilling and hair planting device, and relates to a two-drill one-plant type large-scale disc glass brush drilling and hair planting device. It includes fuselage base, planting hair mechanism, drilling mechanism and puts a set mechanism, put a set mechanism including putting a set base and carousel base, putting a set base lower extreme and passing through fuselage slider and fuselage lead screw threaded connection, putting a set base upper end and installing and putting a set motor and putting a set lead screw, put the output of a set motor and put a set lead screw and be connected, carousel base lower extreme with put a set lead screw threaded connection, put rotatable two interval arrangement's of installing glass brush disc in a set base upper end, every glass brush disc lower extreme all is connected with the carousel motor of installing on the carousel base separately. The invention can realize the mechanized production of the large-scale disc glass brush, and not only has low labor intensity of workers, but also has high working efficiency.

Description

Two-drill one-planting type large disc glass brush drilling and hair planting device and method

Technical Field

The invention relates to a device for processing a large-scale disc glass brush, in particular to a two-drill one-planting type large-scale disc glass brush drilling and hair planting device. The invention also relates to a two-drill one-planting type large disc glass brush drilling and hair planting method.

Background

When the prior art needs to polish large glass, a large disc glass brush needs to be used for processing.

Because the large disc glass brush manufactured by a machine at present has the problem of small tension force (in the existing disc brush, the disc brush with the largest tension force is only 10-20 kg, and the disc glass brush manufactured by the machine with the tension force exceeding 20 kg is not found at present), the large disc glass brush obviously does not meet the tension force requirement of the disc glass brush; meanwhile, the number of the large-scale disc glass drill holes is large (the number of the drill holes is 3000), and the tension force of the large-scale disc glass manufactured by a machine is small, so that when the large-scale disc glass brush manufactured by the machine is used for polishing the surface of the glass, the disc glass brush can often fall off when brushing hairs or nails fall off, the polishing effect of the surface of the glass is greatly influenced, defective products are easily formed, and even the glass processed by the brush can be scrapped sometimes, therefore, the large-scale disc glass brush is manufactured basically in the prior art.

However, since the manual fabrication of a large disk glass brush has problems of not only a high labor intensity (requiring a worker to plant bristles on each drill hole of the disk glass brush in turn using a hammer) but also a low working efficiency (the average time required for the worker to plant bristles on a single drill hole is about 6 to 8 seconds), there is a need for improvement.

Disclosure of Invention

The invention aims to overcome the defects of the background art, and provides a two-drill one-implant type large disk glass brush drilling and hair-planting device, which not only can ensure that the tension of a large disk glass brush reaches more than 50 kilograms, but also ensures that bristles and nails on the disk glass brush are not easy to fall off.

The second purpose of the invention is to overcome the defects of the background art, and provide a method for planting bristles by drilling holes in a two-drill one-plant type large disk glass brush, which not only can ensure that the tension of the large disk glass brush reaches more than 50 kilograms, but also can ensure that bristles and nails on the disk glass brush are not easy to fall off.

In order to achieve the first object, the technical scheme of the invention is as follows: two bore one and plant the large-scale disc glass brush drilling of formula and plant the hair device, its characterized in that: the automatic hair planting machine comprises a machine body base, two hair planting mechanisms, drilling mechanisms and a tray placing mechanism, wherein the two drilling mechanisms are arranged on the machine body base, and the hair planting mechanism is positioned between the two drilling mechanisms and is arranged on the machine body base;

the machine body base is provided with a machine body motor and a machine body screw rod, and the output end of the machine body motor is connected with the machine body screw rod;

the tray placing mechanism comprises a tray placing base and a turntable base, the lower end of the tray placing base is in threaded connection with a machine body lead screw through a machine body sliding block, a tray placing motor and a tray placing lead screw are installed at the upper end of the tray placing base, the output end of the tray placing motor is connected with the tray placing lead screw, the lower end of the turntable base is in threaded connection with the tray placing lead screw, two glass brush discs which are arranged at intervals are rotatably installed at the upper end of the tray placing base, and the lower end of each glass brush disc is respectively connected with a turntable motor installed on the turntable base;

the drilling mechanism comprises a bottom plate, a first support, a second support and a V-shaped deflector rod, wherein a power shaft is arranged on the first support, and a first eccentric wheel is arranged at one end, penetrating through the first support, of the power shaft; one end of the V-shaped deflector rod is hinged with the first eccentric wheel through a connecting rod, and the other end of the V-shaped deflector rod is hinged with the clamping plate through V-shaped deflector rod bearings arranged at two ends of a V-shaped deflector rod fixing shaft;

the bottom plate is provided with a motor fixing plate, and an eccentric motor is fixed on the motor fixing plate; an output shaft of the eccentric motor is connected with a second eccentric wheel, and the second eccentric wheel is fixedly connected with a cam bearing; the cam bearing is fixedly connected with the swinging plate through a connecting plate; a groove is formed in one side, close to the cam bearing, of the connecting plate, and the cam bearing is located in the groove; the left side of the swinging plate is connected with a swinging slide rail in a sliding manner, and the swinging slide rail is fixed on the slide rail fixing plate through a swinging slide rail limiting groove;

the swing plate is provided with a first opening, and the clamping plate penetrates through the opening and is fixedly connected with the lifting plate through a clamping plate fixing plate; the right side of the lifting plate is connected with a lifting slide rail, and the lifting slide rail is fixed on the right side of the swinging plate through a lifting slide rail limiting groove;

the lifting plate fixes the electric spindle through the electric spindle positioning plate, and the output end of the electric spindle is vertically provided with a drill bit downwards.

In the technical scheme, the machine body base is further provided with a tray placing slide rail, and the lower end of the tray placing base is slidably arranged on the tray placing slide rail through the machine body slide block.

In the technical scheme, a motor main board is fixed on one side of an output shaft of the eccentric motor; the motor main board comprises a first main board fixed on one side of an output shaft of the eccentric motor and a second main board which is positioned at the top of the first main board and is far away from the eccentric motor; the center of the first main plate is provided with a second opening.

In the technical scheme, a marble is arranged in the middle of one end, far away from the eccentric motor, of the second main board; the marble is vertically arranged downwards and penetrates through the second main board; the second eccentric wheel is positioned below the marble and is provided with a spherical positioning hole matched with the marble.

In the above technical solution, the number of the electric spindle positioning plates is 1 to 4.

In the technical scheme, the drill tip comprises a first cylinder, a second cylinder and a drilling tool bit which are sequentially connected from top to bottom, the diameter of the second cylinder is smaller than that of the first cylinder and that of the drilling tool bit, the two sides of the second cylinder are provided with retreating grooves, the lower end of the drilling tool bit is inverted V-shaped or inverted W-shaped along the cross section of the vertical direction, and the upper end of the drilling tool bit is I-shaped along the interface of the horizontal direction.

In order to achieve the second object, the invention has the technical scheme that: two bores one and plants large-scale disc glass brush drilling of formula and plant hair, its characterized in that: the method comprises the following process steps of,

the method comprises the following steps: the tray placing base on the tray placing mechanism moves to a proper position on the machine body base for the first time through the machine body motor and the machine body screw rod, so that the first glass brush disc is positioned under the bristle planting mechanism, and the second glass brush disc is positioned under the second drilling mechanism;

step two: the second drilling mechanism is used for drilling holes in the second glass brush disc;

step three: continuously moving the tray placing base on the tray placing mechanism to a proper position on the machine body base through the machine body motor and the machine body screw rod, so that the first glass brush disc is positioned under the first drilling mechanism, and the second glass brush disc is positioned under the bristle planting mechanism;

step four: the bristle planting mechanism is used for drilling a second glass brush disc which is positioned right below the bristle planting mechanism, meanwhile, the first drilling mechanism is used for drilling a hole in the first glass brush disc, and after the bristle planting mechanism finishes bristle planting, the disc glass brush on the second glass brush disc is moved out of the disc placing mechanism;

step five: continuously moving the tray placing base on the tray placing mechanism to a proper position on the machine body base through the machine body motor and the machine body screw rod, so that the first glass brush disc is positioned under the bristle planting mechanism, and the second glass brush disc is positioned under the second drilling mechanism;

step six: the bristle planting mechanism is used for drilling a first glass brush disc which is positioned right below the bristle planting mechanism, meanwhile, the second drilling mechanism is used for drilling a second glass brush disc, and after the bristle planting mechanism finishes bristle planting, the disc glass brush on the first glass brush disc is moved out of the disc placing mechanism;

step seven: repeating the third step to the sixth step until a plurality of disc glass brushes are obtained;

wherein the drilling method of the first drilling mechanism (B31) and the second drilling mechanism (B32) comprises the following steps,

step 1: firstly, a power shaft sequentially passes through a first eccentric wheel, a connecting rod, a V-shaped deflector rod fixing shaft and a clamping plate to enable a lifting plate to move up and down along a lifting slide rail; meanwhile, the lifting plate drives the electric main shaft and the drill bit to integrally move up and down through the electric main shaft positioning plate, and the electric main shaft drives the drill bit to do rotary motion at the moment so as to complete the drilling work from top to bottom;

step 2: the eccentric motor drives the cam bearing to eccentrically rotate through the second eccentric wheel, the cam bearing drives the swing plate to move left and right on the swing slide rail through the connecting plate, and simultaneously drives the electric main shaft and the drill bit to complete leftward and rightward chambering and form an inverted T-shaped hole;

and step 3: after the inverted T-shaped hole is finished, the drill bit is moved to the middle position of the inverted T-shaped hole, the electric main shaft is enabled to move upwards along the lifting slide rail through the power shaft, the drilled inverted T-shaped hole is withdrawn, and then the drilling work of the inverted T-shaped hole is finished.

The invention can realize the mechanized production of the large-scale disc glass brush, not only has small labor intensity of workers (no need of manually hammering the nails), has high working efficiency (the average time required for flocking on a single drill hole is about 0.5 second), but also can ensure that the tensioning force of the large-scale disc glass brush reaches more than 50 kilograms, and the bristles and the nails are not easy to fall off, thereby being worthy of large-scale popularization.

Drawings

FIG. 1 is a schematic structural view of a brush drilling mechanism for drilling an inverted T-shaped hole according to the present invention.

FIG. 2 is a schematic structural view of the eccentric motor driving the left and right drilling holes of the electric spindle according to the present invention.

FIG. 3 is a schematic structural view of the power shaft driving the electric spindle to drill holes up and down through the V-shaped pulling rod according to the present invention.

Fig. 4 is a schematic structural diagram of the lifting slide rail, the swinging slide rail, the eccentric motor, the electric spindle and the V-shaped pull rod of the present invention.

FIG. 5 is a schematic structural diagram of the eccentric motor, the transmission mechanism and the swing plate according to the present invention.

Fig. 6.1 is a schematic front view of the second eccentric wheel and the cam bearing of the invention.

Fig. 6.2 is a schematic structural diagram of the second eccentric wheel and the cam bearing in the invention.

Fig. 7.1 is a schematic structural diagram of a drill tip suitable for metal drilling.

Fig. 7.2 is a schematic structural diagram of a drill tip suitable for plastic drilling.

Fig. 7.3 is a schematic view of a drill tip suitable for wood drilling.

Fig. 8.1 and 8.2 are schematic views of the connection structure of the existing nails, bristles and drill holes.

Fig. 8.3, 8.4 and 8.5 are schematic views of the connection structure of the stud, the bristle and the drill hole by using different drill heads in the application.

Fig. 9 is a schematic structural diagram of the present application.

Fig. 10 is a schematic structural view of the tray placing mechanism.

In the figure, A1-bottom plate, A11-power shaft, A12-first support, A121-first eccentric wheel, A13-second support, A14-V deflector rod, A141-connecting rod, A142-V deflector rod fixing shaft, A143-V deflector rod positioning shaft, A144-V deflector rod bearing, A15-splint, A16-lifting plate, A161-lifting slide rail, A162-slide rail limiting groove, A21-motor fixing plate, A22-eccentric motor, A23-cam bearing, A24-second eccentric wheel, A25-connecting plate, A251-groove, A26-swinging plate, A261-first opening, A27-swinging slide rail, A271-slide rail limiting groove, A272-slide rail fixing plate, A28-motor main plate, A281-first main plate, A282-second main plate, A291-marble, a292-spherical positioning hole, A31-electric spindle positioning plate, A32-electric spindle, A4-drilling nozzle, A41-first column, A42-second column, A421-receding groove, A43-drilling tool bit, B1-machine body base, B11-machine body motor, B12-machine body screw rod, B2-hair planting mechanism, B3-drilling mechanism, B31-first drilling mechanism, B32-second drilling mechanism, B4-tray placing mechanism, B41-tray placing base, B42-turntable base, B43-machine body sliding block, B44-tray placing motor, B45-tray placing screw rod, B46-glass brush disk, B47-turntable motor, B48-first glass brush disk, B49-first glass disk brush.

Detailed Description

The embodiments of the present invention will be described in detail with reference to the accompanying drawings, which are not intended to limit the present invention, but are merely exemplary. While the advantages of the invention will be clear and readily understood by the description.

With reference to the accompanying drawings: two bore one and plant the large-scale disc glass brush drilling of formula and plant the hair device, its characterized in that: the device comprises a machine body base B1, a hair planting mechanism B2, a drilling mechanism B3 and a tray placing mechanism B4, wherein two of the drilling mechanisms B3 are arranged on the machine body base B1, and the hair planting mechanism B2 is positioned between the two drilling mechanisms B3 and is arranged on the machine body base B1;

the machine body base B1 is provided with a machine body motor B11 and a machine body screw rod B2, and the output end of the machine body motor B11 is connected with a machine body screw rod B2;

put a set mechanism B4 including putting a set base B41 and carousel base B42, put a set base B41 lower extreme and pass through fuselage slider B43 and fuselage lead screw B2 threaded connection, put a set base B41 upper end and install and put a set motor B44 and put a set lead screw B45, put a set motor B44's output and put a set lead screw B45 and be connected, carousel base B42 lower extreme and put a set lead screw B45 threaded connection, put rotatable the glass brush disc B46 of installing two interval arrangements in a set base B41 upper end, every glass brush disc B46 lower extreme all is connected with carousel motor B47 of installing on carousel base B42 respectively.

In actual operation, the two drilling mechanisms B3 are respectively a first drilling mechanism B3 located on the left side of the hair planting mechanism B2 and a second drilling mechanism B32 located on the right side of the hair planting mechanism B2, and the two glass brush discs B46 are respectively a first glass brush disc B48 located on the left side of the turntable base B42 and a second glass brush disc B49 located on the right side of the turntable base B42.

In the above technical scheme, still install on fuselage base B1 and put a set slide rail, put a set base B41 lower extreme and pass through fuselage slider slidable and install on putting a set slide rail.

The drilling mechanism B3 comprises a bottom plate A1, a first support A12, a second support A13 and a V-shaped shifting lever A14, wherein a power shaft A11 is arranged on the first support A12, and a first eccentric wheel A121 is arranged at one end, penetrating through the first support A12, of the power shaft A11; one end of the V-shaped deflector rod A14 is hinged with the first eccentric wheel A121 through a connecting rod A141, and the other end of the V-shaped deflector rod A14 is hinged with the splint A15 through a V-shaped deflector rod bearing A144 arranged at the two ends of a V-shaped deflector rod fixing shaft A142;

the method is characterized in that: the bottom plate A1 is provided with a motor fixing plate A21, and an eccentric motor A22 is fixed on the motor fixing plate A21; an output shaft of the eccentric motor A22 is connected with a second eccentric wheel A24, and a second eccentric wheel A24 is fixedly connected with a cam bearing A23; the cam bearing A23 is fixedly connected with the swinging plate A26 through a connecting plate A25; a groove A251 is formed in one side, close to the cam bearing A23, of the connecting plate A25, and the cam bearing A23 is located in the groove A251; the left side of the swinging plate A26 is connected with a swinging slide rail A27 in a sliding manner, and the swinging slide rail A27 is fixed on the slide rail fixing plate A272 through a swinging slide rail limiting groove A271;

the swing plate A26 is provided with a first opening A261, the clamping plate A15 penetrates through the opening A261 and is fixedly connected with the lifting plate A16 through a clamping plate fixing plate A151; the right side of the lifting plate A16 and the lifting slide rail A161 are fixed on the right side of the swinging plate A26 through a lifting slide rail limiting groove A162;

the lifting plate A16 fixes the electric spindle A32 through the electric spindle positioning plate A31, and the output end of the electric spindle A32 is vertically provided with a drill bit A4 downwards.

A motor main board A28 is fixed on one side of an output shaft of the eccentric motor A22; the motor main board a28 comprises a first main board a281 fixed on one side of the output shaft of the eccentric motor a22, and a second main board a282 located on the top of the first main board a281 and far away from the eccentric motor a 22; a second opening a283 is arranged in the center of the first main plate a 281.

The middle part of one end of the second main plate A282, which is far away from the eccentric motor A22, is provided with a marble A291; the marble A291 is vertically arranged downwards and penetrates through a second main plate A282; the second eccentric wheel A24 is positioned below the marble A291 and is provided with a spherical positioning hole A292 matched with the marble A291.

The number of the electric spindle positioning plates A31 is 1 to 4.

Drill tip A4 includes first cylinder A41, second cylinder A42 and drilling tool bit A43 that top-down connected gradually, the diameter of second cylinder A42 is less than the diameter of first cylinder A41 and drilling tool bit A43's diameter, and open the both sides of second cylinder A42 has the groove A421 that moves back, drilling tool bit A43 lower extreme is for falling V style of calligraphy or the style of calligraphy of falling W along vertical direction's cross-section, and the interface of drilling tool bit A43 upper end along the horizontal direction is the I shape.

In actual operation, the invention comprises the following process steps,

the method comprises the following steps: the tray placing base B41 on the tray placing mechanism B4 is firstly moved to a proper position on the machine body base B1 through a machine body motor B11 and a machine body screw rod B2, so that the first glass brush disc B48 is positioned right below the hair planting mechanism B2, and the second glass brush disc B49 is positioned right below the second drilling mechanism B32;

step two: the second drilling mechanism B32 drills a hole in the second glass brush disk B49;

step three: continuing to move the tray placing base B41 on the tray placing mechanism B4 to a proper position on the machine body base B1 through the machine body motor B11 and the machine body screw rod B2, so that the first glass brush disc B48 is positioned right below the first drilling mechanism B31, and the second glass brush disc B49 is positioned right below the hair planting mechanism B2;

step four: the hair planting mechanism B2 is used for drilling a second glass brush disk B49 which is positioned right below the second glass brush disk B3578, meanwhile, the first drilling mechanism B31 is used for drilling a first glass brush disk B48, and after the hair planting mechanism B2 finishes hair planting, the disk glass brush on the second glass brush disk B49 is moved out of the disk placing mechanism B4;

step five: continuously moving a tray placing base B41 on the tray placing mechanism B4 to a proper position on a machine body base B1 through a machine body motor B11 and a machine body screw rod B2, enabling a first glass brush disc B48 to be located right below a hair planting mechanism B2, and enabling a second glass brush disc B49 to be located right below a second drilling mechanism B32;

step six: the hair planting mechanism B2 is used for drilling a first glass brush disk B48 which is positioned right below the first glass brush disk B3578, meanwhile, the second drilling mechanism B32 is used for drilling a second glass brush disk B49, and after the hair planting mechanism B2 finishes hair planting, the disk glass brush on the first glass brush disk B48 is moved out of the disk placing mechanism B4;

step seven: repeating the third step to the sixth step until a plurality of disc glass brushes are obtained;

wherein the drilling method of the first drilling mechanism (B31) and the second drilling mechanism (B32) comprises the following steps,

step 1: firstly, a power shaft A11 sequentially passes through a first eccentric wheel A121, a connecting rod A141, a V-shaped deflector rod A14, a V-shaped deflector rod fixing shaft A142 and a clamping plate A15 to enable a lifting plate A16 to move up and down along a lifting slide rail A161; meanwhile, the lifting plate A16 drives the electric spindle A32 and the drill bit A4 to integrally move up and down through the electric spindle positioning plate A31, and at the moment, the electric spindle A32 drives the drill bit A4 to rotate to complete the drilling work from top to bottom;

step 2: the eccentric motor A22 drives the cam bearing A23 to eccentrically rotate through the second eccentric wheel A24, the cam bearing A23 drives the swing plate A26 to move left and right on the swing slide rail A27 through the connecting plate A25, and simultaneously drives the electric main shaft A32 and the drill bit A4 to complete leftward and rightward chambering and form an inverted T-shaped hole;

and step 3: after the inverted T-shaped hole is finished, the drill tip A4 is moved to the middle position of the inverted T-shaped hole, the electric main shaft A32 is enabled to move upwards along the lifting slide rail A161 through the power shaft A11, the drilled inverted T-shaped hole is withdrawn, and the drilling work of the inverted T-shaped hole is finished.

During actual work, the power shaft A11 drives the first eccentric wheel A121 to rotate, the first eccentric wheel A121 drives the connecting rod A141 and the V-shaped driving lever A14 to move, the V-shaped driving lever A14 drives the drill tip A4 fixed at the lower end of the electric main shaft A32 to move up and down through the clamping plate A15, and the lifting slide rail A161 drives the electric main shaft A32 to move up and down integrally through the electric main shaft positioning plate A31; a plurality of electric spindle positioning plates A31 are provided to facilitate replacement of different drill tips A4, wherein an eccentric motor A22 drives a cam bearing A23 to rotate through a second eccentric wheel A24, a cam bearing A23 drives a swing plate A26 to move left and right on a swing slide rail A27 through a connecting plate A25, and an electric spindle A32 drives the drill tip A4 to rotate. When the section of the lower end of the drilling head A43 along the vertical direction is in an inverted V shape (as shown in figure 7.2), the drill tip A4 is suitable for plastic drilling; when the section of the lower end of the drilling head A43 along the vertical direction is in an inverted W shape, and the lowest point of the drilling head A43 is positioned at the side part of the drill tip A4 (as shown in figure 7.3), the drill tip A4 is suitable for wood drilling; when the lower end of the drilling head A43 has an inverted W-shaped vertical cross section and the lowest point of the drilling head A43 is located at the middle of the drill tip A4 (see FIG. 7.1), the drill tip A4 is suitable for metal drilling. Two sides of the second cylinder A42 are provided with a return groove A421, and the return groove A421 plays a role in removing scraps in the drilling process; the interface of the upper end of the drilling cutter head A43 along the horizontal direction is I-shaped, so that the abdicating function is achieved; when the drill tip A4 starts to drill from top to bottom and returns to the middle position of the drilled hole after left and right drilling and then exits from the drill tip A4, the marble A291 plays a role in auxiliary positioning, namely when the marble A291 is positioned in the spherical positioning hole A292, the drill tip A4 is in a state of starting to drill or a state of exiting from the drill tip A4 after the drilling is finished.

Other parts not described belong to the prior art.

Claims (7)

1. The two-drill one-planting type large disc glass brush drilling and hair planting device comprises a machine body base (B1), a hair planting mechanism (B2), a drilling mechanism (B3) and a tray placing mechanism (B4), wherein two drilling mechanisms (B3) are arranged on the machine body base (B1), and the hair planting mechanism (B2) is positioned between the two drilling mechanisms (B3) and is arranged on the machine body base (B1);

the machine body base (B1) is provided with a machine body motor (B11) and a machine body screw rod (B2), and the output end of the machine body motor (B11) is connected with the machine body screw rod (B2);

the method is characterized in that:

the tray placing mechanism (B4) comprises a tray placing base (B41) and a rotary table base (B42), the lower end of the tray placing base (B41) is in threaded connection with a machine body screw rod (B2) through a machine body sliding block (B43), a tray placing motor (B44) and a tray placing screw rod (B45) are installed at the upper end of the tray placing base (B41), the output end of a tray placing motor (B44) is connected with the tray placing screw rod (B45), the lower end of the rotary table base (B42) is in threaded connection with the tray placing screw rod (B45), two glass brush discs (B46) which are arranged at intervals are rotatably installed at the upper end of the tray placing base (B41), and the lower end of each glass brush disc (B46) is respectively connected with the rotary table motor (B47) installed on the rotary table base (B42);

the drilling mechanism (B3) comprises a bottom plate (A1), a first support (A12), a second support (A13) and a V-shaped shifting rod (A14), wherein a power shaft (A11) is arranged on the first support (A12), and a first eccentric wheel (A121) is arranged at one end, penetrating through the first support (A12), of the power shaft (A11); one end of the V-shaped deflector rod (A14) is hinged with the first eccentric wheel (A121) through a connecting rod (A141), and the other end of the V-shaped deflector rod (A14) is hinged with the clamp plate (A15) through V-shaped deflector rod bearings (A144) arranged at two ends of a V-shaped deflector rod fixing shaft (A142);

the bottom plate (A1) is provided with a motor fixing plate (A21), and an eccentric motor (A22) is fixed on the motor fixing plate (A21); an output shaft of the eccentric motor (A22) is connected with a second eccentric wheel (A24), and the second eccentric wheel (A24) is fixedly connected with a cam bearing (A23); the cam bearing (A23) is fixedly connected with the swinging plate (A26) through a connecting plate (A25); one side of the connecting plate (A25) close to the cam bearing (A23) is provided with a groove (A251), and the cam bearing (A23) is positioned in the groove (A251); the left side of the swing plate (A26) is connected with a swing slide rail (A27) in a sliding manner, and the swing slide rail (A27) is fixed on a slide rail fixing plate (A272) through a swing slide rail limiting groove (A271);

the swing plate (A26) is provided with a first opening (A261), the clamping plate (A15) penetrates through the opening (A261) and is fixedly connected with the lifting plate (A16) through a clamping plate fixing plate (A151); the right side of the lifting plate (A16) is connected with a lifting slide rail (A161), and the lifting slide rail (A161) is fixed on the right side of the swinging plate (A26) through a lifting slide rail limiting groove (A162);

the lifting plate (A16) fixes the electric spindle (A32) through the electric spindle positioning plate (A31), and the output end of the electric spindle (A32) is vertically provided with a drill bit (A4) downwards.

2. The two-drill one-plant large-sized disc glass brush drilling and hair planting device according to claim 1, which is characterized in that: still install on fuselage base (B1) and put a set slide rail, put a set base (B41) lower extreme and install on putting a set slide rail through putting a set slider slidable.

3. The two-drill one-implant large disc glass brush drilling and hair-planting device according to claim 2, characterized in that: a motor main board (A28) is fixed on one side of an output shaft of the eccentric motor (A22); the motor main board (A28) comprises a first main board (A281) fixed on one side of the output shaft of the eccentric motor (A22), and a second main board (A282) which is positioned on the top of the first main board (A281) and is far away from the eccentric motor (A22); the center of the first main plate (A281) is provided with a second opening hole (A283) through which the output shaft of the eccentric motor (A22) can pass.

4. The two-drill one-implant large disc glass brush drilling and hair-planting device according to claim 3, characterized in that: a marble (A291) is arranged in the middle of one end, far away from the eccentric motor (A22), of the second main plate (A282); the marble (A291) is vertically arranged downwards and penetrates through a second main plate (A282); the second eccentric wheel (A24) is positioned below the marble A291) and is provided with a spherical positioning hole (A292) matched with the marble A291.

5. The two-drill one-implant large disc glass brush drilling and hair-planting device according to claim 4, characterized in that: the number of the electric spindle positioning plates (A31) is 1 to 4.

6. The two-drill one-implant large disc glass brush drilling and hair-planting device according to claim 5, characterized in that: the drill tip (A4) comprises a first cylinder (A41), a second cylinder (A42) and a drilling tool bit (A43) which are sequentially connected from top to bottom; the diameter of the second cylinder (A42) is smaller than that of the first cylinder (A41) and that of the drilling tool bit (A43), and retreat grooves (A421) are formed in two sides of the second cylinder (A42); the cross section of the lower end of the drilling cutter head (A43) along the vertical direction is inverted V-shaped or inverted W-shaped, and the cross section of the upper end of the drilling cutter head (A43) along the horizontal direction is I-shaped.

7. The two-drill one-planting type large disc glass brush drilling and hair planting method is characterized by comprising the following steps of: the method comprises the following process steps of,

the method comprises the following steps: enabling a tray placing base (B41) on a tray placing mechanism (B4) to move to a proper position on a machine body base (B1) for the first time through a machine body motor (B11) and a machine body screw rod (B2), so that a first glass brush disc (B48) is located right below a hair planting mechanism (B2), and a second glass brush disc (B49) is located right below a second drilling mechanism (B32);

step two: a second drilling mechanism (B32) drills a second glass brush disk (B49);

step three: continuously moving a tray placing base (B41) on the tray placing mechanism (B4) to a proper position on a machine body base (B1) again through a machine body motor (B11) and a machine body screw rod (B2), so that a first glass brush disc (B48) is positioned right below a first drilling mechanism (B31), and a second glass brush disc (B49) is positioned right below a hair planting mechanism (B2);

step four: the hair planting mechanism (B2) is used for drilling a second glass brush disc (B49) which is positioned right below the second glass brush disc, meanwhile, the first drilling mechanism (B31) is used for drilling a first glass brush disc (B48), and after the hair planting mechanism (B2) finishes hair planting, the disc glass brush on the second glass brush disc (B49) is moved out of the disc placing mechanism (B4);

step five: continuously moving a tray placing base (B41) on the tray placing mechanism (B4) to a proper position on a machine body base (B1) again through a machine body motor (B11) and a machine body screw rod (B2), enabling a first glass brush disc (B48) to be located right below a hair planting mechanism (B2), and enabling a second glass brush disc (B49) to be located right below a second drilling mechanism (B32);

step six: the hair planting mechanism (B2) is used for drilling a first glass brush disc (B48) which is positioned right below the glass brush disc and is drilled, meanwhile, the second drilling mechanism (B32) is used for drilling a second glass brush disc (B49), and after the hair planting mechanism (B2) finishes hair planting, the disc glass brush on the first glass brush disc (B48) is moved out of the disc placing mechanism (B4);

step seven: repeating the third step to the sixth step until a plurality of disc glass brushes are obtained;

wherein the drilling method of the first drilling mechanism (B31) and the second drilling mechanism (B32) comprises the following steps,

step 1: firstly, a power shaft (A11) sequentially passes through a first eccentric wheel (A121), a connecting rod (A141), a V-shaped deflector rod (A14), a V-shaped deflector rod fixing shaft (A142) and a clamping plate (A15) to enable a lifting plate (A16) to move up and down along a lifting slide rail (A161); meanwhile, the lifting plate (A16) drives the electric spindle (A32) and the drill bit (A4) to integrally move up and down through the electric spindle positioning plate (A31), and at the moment, the electric spindle (A32) drives the drill bit (A4) to rotate to complete the drilling work from top to bottom;

step 2: the eccentric motor (A22) drives the cam bearing (A23) to eccentrically rotate through the second eccentric wheel (A24), the cam bearing (A23) drives the swing plate (A26) to move left and right on the swing slide rail (A27) through the connecting plate (A25), and simultaneously drives the electric main shaft (A32) and the drill bit (A4) to complete leftward and rightward chambering and form an inverted T-shaped hole;

and step 3: after the inverted T-shaped hole is finished, the drill bit (A4) is moved to the middle position of the inverted T-shaped hole, the electric main shaft (A32) is enabled to move upwards along the lifting slide rail (A161) through the power shaft (A11)), and the drilled inverted T-shaped hole is withdrawn, namely the drilling work of the inverted T-shaped hole is finished.

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