CN112874222B - Soft pottery simulation finger shaping and nail engraving device - Google Patents

Abstract

The invention relates to the field of plastic mud, in particular to a soft ceramic simulation finger shaping and nail engraving device. The technical problem of the invention is that: provides a soft ceramic simulation finger shaping and nail engraving device. The technical implementation scheme of the invention is as follows: a soft ceramic simulation finger shaping and nail engraving device comprises a shaping component, an engraving component, a power component, an electric control plastic mud conveying cylinder, a conveyor belt part, a collecting disc, a support table and a control table; the shaping component is connected with the imprinting component; the shaping component is connected with the power component; the shaping component is connected with the support platform; the engraving component is connected with the power component; the marking component is connected with the support platform. The invention realizes the sequential heating treatment, the finger shape shaping treatment and the nail engraving treatment of the plasticine, the double-unit synchronous treatment can replace the manual work to improve the working efficiency of the artificial finger production, and the operation is simple, safe and reliable.

Description

Soft pottery simulation finger shaping and nail engraving device

Technical Field

The invention relates to the field of plastic mud, in particular to a soft ceramic simulation finger shaping and nail engraving device.

Background

Polymer clay, also called plasticine, originates from Europe and means a plasticine of plastics. It is not pottery clay, is a PVC artificial low-temperature polymerization material, looks like plasticine, is substantially close to plastics, has more vivid modeling capability, and is one of professional sculpture materials.

When carrying out soft pottery emulation finger sculpture, need artifically will mould the mud compaction to rely on the multiunit mould to mould the mud to rub the irregular ellipse shape model that presses into type finger under hot-blast, nevertheless the processing personnel when moulding the processing personnel, can not once take the back of holding between the fingers when the volume of grabbing moulding the mud, still need mend the volume that lacks or reject unnecessary volume, later carry out nail carving with the burin to the model and handle, a set of finger model is handled and is got off need consume not a short time.

Therefore, an automatic device capable of replacing the manual operation of shaping the fingers and engraving the nails on the plastic mud is urgently needed to solve the problems.

Disclosure of Invention

In order to overcome the defects that the steps of manually carrying out finger shaping and nail engraving on the plastic mud are complicated, a processing person cannot accurately grasp the plastic mud at one time, and the plastic mud needs to be shaped by a plurality of groups of molds, and the working speed of manually carrying out nail engraving on the mold is slow, the invention has the technical problems that: provides a soft ceramic simulation finger shaping and nail engraving device.

The technical implementation scheme of the invention is as follows: a soft ceramic simulation finger shaping and nail engraving device comprises a shaping component, an engraving component, a power component, an electric control plastic mud conveying cylinder, a conveyor belt part, a collecting disc, a support table and a control table; the shaping component is connected with the imprinting component; the shaping component is connected with the power component; the shaping component is connected with the support platform; the engraving component is connected with the power component; the engraving component is connected with the support platform; the power assembly is connected with the support platform; the electric control plastic mud conveying cylinder is connected with the support platform; the conveyor belt part is connected with the support table; the console is connected with the support table.

More preferably, the shaping component comprises a mud box, a hot air blower regulating and controlling part, a heating pipe, a fan, a partition plate, a first rotating shaft, a first driving wheel, a rotating ring, an upper push rod, a lower push rod, a double-slider connecting rod, an extrusion block and an extrusion rod; a mud loading box is fixedly connected with the support platform below a discharge plate of the electric control plastic mud conveying cylinder; one side of the mud box is provided with an air heater regulating and controlling part; the inner side surface of the mud containing box is provided with a heating pipe; a group of fans are respectively arranged on two sides of the heating pipe; the heating pipe and the two groups of fans are respectively connected with the air heater regulating and controlling part; a partition plate is fixedly connected inside the mud containing box on one side of the heating pipe; the first rotating shaft is rotatably connected with the support platform above one side of the air heater regulating and controlling part; the first driving wheel and the rotating ring are fixedly connected with the first rotating shaft respectively; the first driving wheel is connected with the power assembly; the upper push rod and the lower push rod are respectively fixedly connected with the side ring surface of the rotating ring; the sliding blocks on two sides of the double-sliding-block connecting rod are respectively connected with the support platform in a sliding manner above the mud box; the extrusion block is fixedly connected with the middle cross rod part of the double-slider connecting rod above the mud containing box; the extrusion block is rotationally connected with the upper push rod; the extrusion rod is inserted into the mud containing box in a penetrating way, and the extrusion rod is connected with the mud containing box in a sliding way; on one side of the mud box, the extrusion rod is rotationally connected with the lower push rod.

More preferably, the engraving component comprises a second rotating shaft, a first bevel gear, a second driving wheel, a third driving wheel, a left screw rod, a right screw rod, a fourth driving wheel, a fifth driving wheel, a first slider bracket, a half-finger mold, a third rotating shaft, a tilting rod, a fourth rotating shaft, a fifth rotating shaft, a sixth rotating shaft, a pressing plate, a U-shaped engraving knife, a limiting rod, a second slider bracket, a transfer block, a transfer rod, a support plate, a third slider bracket and an arc-shaped blade; the second rotating shaft is rotatably connected with one side of the mud containing box far away from the lower push rod; the first bevel gear, the second driving wheel and the third driving wheel are fixedly connected with the second rotating shaft respectively; the first bevel gear is connected with the power assembly; the left screw rod and the right screw rod are respectively in rotary connection with the second rotating shaft below the second rotating shaft; the insection directions of the left screw rod and the right screw rod are opposite; the fourth driving wheel is fixedly connected with the left screw rod; the fifth driving wheel is fixedly connected with the right screw rod; the second transmission wheel is in transmission connection with the fourth transmission wheel through a belt; the third driving wheel is in transmission connection with the fifth driving wheel through a belt; the left screw rod and the right screw rod are respectively connected with a group of first sliding block brackets in a rotating mode; the two groups of first sliding block brackets are respectively connected with the mud containing box in a sliding manner; each group of first sliding blocks is fixedly connected with one group of semi-finger molds respectively; the two groups of first sliding block brackets and the half-finger mould are symmetrically distributed; a third rotating shaft is rotatably connected with the support table on one side of the third driving wheel; the warping rod is fixedly connected with the third rotating shaft; the fourth rotating shaft is fixedly connected with one side of the tilting rod; the fifth rotating shaft and the sixth rotating shaft are fixedly connected with the other side of the tilting rod respectively; the fourth rotating shaft is connected with the power assembly; the pressing plate is rotationally connected with the fifth rotating shaft; the U-shaped nicking tool is fixedly connected with the bottom end of the pressing plate; two sides of the pressing plate are respectively connected with a group of limiting rods in a rotating way through rotating shafts; each group of limiting rods is rotatably connected with one group of second sliding block brackets; the two groups of second sliding block supports are respectively connected with the support table in a sliding manner; the transfer block is rotationally connected with the sixth rotating shaft; the switching rod is fixedly connected with the bottom end of the switching block; two groups of third sliding block brackets are respectively connected with the bracket platform in a sliding manner below the switching block; one side of the carrier plate is fixedly connected with the two groups of third sliding block brackets respectively; the other side of the carrier plate is rotationally connected with the transfer rod through a rotating shaft; the arc-shaped blade is fixedly connected with one end of the carrier plate.

More preferably, the power assembly comprises a main motor, a motor rotating shaft, a first straight gear, a second straight gear, an electric slider, a third straight gear, a seventh rotating shaft, a fourth straight gear, a sixth transmission wheel, an eighth rotating shaft, a fifth straight gear, a seventh transmission wheel, a ninth rotating shaft, a second bevel gear, an eighth transmission wheel, a rotating disc, a transmission rod, a tenth rotating shaft, a third bevel gear and a fourth bevel gear; a main motor is fixedly connected with the support platform below the first rotating shaft; the motor rotating shaft is rotatably connected with the support platform; the motor rotating shaft is fixedly connected with the main motor; the first straight gear and the second straight gear are fixedly connected with a motor rotating shaft respectively; on one side of the motor rotating shaft, an electric sliding block is in sliding connection with the support table; the third straight gear is rotationally connected with the electric slide block through a rotating shaft; on one side of the electric sliding block, a seventh rotating shaft and an eighth rotating shaft are respectively in rotating connection with the support platform; the fourth straight gear and the sixth transmission wheel are fixedly connected with the seventh rotating shaft respectively; the fifth straight gear and the seventh transmission wheel are fixedly connected with the eighth rotating shaft respectively; when two sides of the third straight gear are respectively meshed with the first straight gear and the fourth straight gear, the third straight gear and the fourth straight gear rotate; when the two sides of the third straight gear are not meshed with the first straight gear and the fourth straight gear, the third straight gear and the fourth straight gear do not rotate; when the two sides of the third straight gear are respectively meshed with the second straight gear and the fifth straight gear, the third straight gear and the fifth straight gear rotate; when the two sides of the third straight gear are not meshed with the second straight gear and the fifth straight gear, the third straight gear and the fifth straight gear do not rotate; the sixth transmission wheel is in transmission connection with the first transmission wheel through a belt; on the side where the eighth rotating shaft is finished, the ninth rotating shaft is rotatably connected with the support platform; the second bevel gear, the eighth driving wheel and the turntable are fixedly connected with the ninth rotating shaft in sequence; the seventh driving wheel is in transmission connection with the eighth driving wheel through a belt; the transmission rod is in transmission connection with the edge of the rotary disc through the rotating shaft; the transmission rod is in transmission connection with the fourth rotating shaft; on one side of the second bevel gear, a tenth rotating shaft is rotatably connected with the support platform; the third bevel gear and the fourth bevel gear are fixedly connected with the tenth rotating shaft respectively; the second bevel gear is meshed with the third bevel gear; the first bevel gear is meshed with the fourth bevel gear.

More preferably, the squeeze bar has a finger-like irregular oval structure.

More preferably, the interior of the half-finger mould is designed to be hollow in the shape of the half side of the finger.

More preferably, the U-shaped nicking tool is shaped along three sides of the nail where the finger is attached.

More preferably, the arc-shaped blade is designed into an arc shape along the suspended part of the non-connection side of the fingernail and the finger.

Compared with the prior art, the invention has the following advantages: 1. in order to overcome the defects that the manual finger shaping and nail engraving processing steps of the plastic mud are complicated, processing personnel cannot accurately grasp the plastic mud at one time, a plurality of groups of molds are required to carry out shaping processing on the plastic mud, and the manual nail engraving processing speed of the mold is low.

2. The device of the invention is provided with: the electronic control plastic mud conveying cylinder pours plastic mud into the molding assembly, the molding assembly heats the plastic mud and extrudes the plastic mud into a finger-shaped model under the driving of the power assembly, the finger model drops onto the conveyor belt machine part, the conveyor belt machine part conveys the finger model to the lower part of the engraving assembly, then the engraving assembly carries out nail engraving treatment on the finger model, and finally the conveyor belt machine part conveys the finger model engraved with nails into the collecting tray.

3. The invention realizes the sequential heating treatment, the finger shape shaping treatment and the nail engraving treatment of the plasticine, the double-unit synchronous treatment can replace the manual work to improve the working efficiency of the artificial finger production, and the operation is simple, safe and reliable.

Drawings

FIG. 1 is a schematic perspective view of a first embodiment of the present invention;

FIG. 2 is a schematic perspective view of a second embodiment of the present invention;

FIG. 3 is a third perspective view of the present invention;

FIG. 4 is a schematic diagram of a first perspective structure of the molding assembly of the present invention;

FIG. 5 is a schematic diagram of a second perspective structure of the molding assembly of the present invention;

FIG. 6 is a schematic partial perspective view of a molding assembly according to the present invention;

FIG. 7 is a schematic perspective view of an extrusion rod of the present invention;

FIG. 8 is a schematic perspective view of an imprinting assembly of the present invention;

FIG. 9 is a schematic partial perspective view of an imprinting assembly of the present invention;

FIG. 10 is a schematic perspective view of a half-finger mold according to the present invention;

FIG. 11 is a schematic perspective view of a U-shaped nicking tool according to the present invention;

FIG. 12 is a perspective view of a curved blade according to the present invention;

fig. 13 is a perspective view of the power assembly of the present invention.

Wherein the figures include the following reference numerals: 1. a shaping component, 2, an engraving component, 3, a power component, 4, an electric control plastic mud delivery cylinder, 5, a conveyor belt component, 6, a collection disc, 7, a support platform, 8, a control platform, 101, a mud box, 102, a hot air blower regulating component, 103, a heating pipe, 104, a fan, 105, a partition board, 106, a first rotating shaft, 107, a first driving wheel, 108, a rotating ring, 109, an upper push rod, 110, a lower push rod, 111, a double-slider connecting rod, 112, a squeezing block, 113, a squeezing rod, 201, a second rotating shaft, 202, a first bevel gear, 203, a second driving wheel, 204, a third driving wheel, 205, a left screw rod, 206, a right screw rod, 207, a fourth driving wheel, 208, a fifth driving wheel, 209, a first slider support, 210, a half-finger mold, 211, a third rotating shaft, 212, a tilting rod, 213, a fourth rotating shaft, 214, a fifth rotating shaft, 215, a sixth rotating shaft, 216, a pressing plate, 217, The cutting device comprises a U-shaped nicking tool 218, a limiting rod 219, a second sliding block bracket 220, an adapter block 221, an adapter rod 222, a carrier plate 223, a third sliding block bracket 224, an arc-shaped blade 301, a total motor 302, a motor rotating shaft 303, a first straight gear 304, a second straight gear 305, an electric sliding block 306, a third straight gear 307, a seventh rotating shaft 308, a fourth straight gear 309, a sixth transmission wheel 310, an eighth rotating shaft 311, a fifth straight gear 312, a seventh transmission wheel 313, a ninth rotating shaft 314, a second conical gear 315, an eighth transmission wheel 316, a rotary disc 317, a transmission rod 318, a tenth rotating shaft 319, a third conical gear 320 and a fourth conical gear.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Example 1

A soft ceramic simulation finger shaping and nail engraving device is shown in figures 1-13 and comprises a shaping component 1, an engraving component 2, a power component 3, an electric control plastic mud conveying cylinder 4, a conveying belt machine part 5, a collecting disc 6, a support table 7 and a control table 8; the shaping component 1 is connected with the marking component 2; the shaping component 1 is connected with the power component 3; the shaping component 1 is connected with a support table 7; the engraving component 2 is connected with the power component 3; the engraving component 2 is connected with the support table 7; the power assembly 3 is connected with the support table 7; the electric control plastic mud conveying cylinder 4 is connected with a support table 7; the conveyor belt part 5 is connected with the bracket table 7; the console 8 is connected with the support table 7.

The working principle is as follows: when the device is used, the device is placed at first, the support table 7 is kept stable, a power supply is connected externally, the device is adjusted and controlled by the control console 8, then the electric control plastic mud conveying cylinder 4 pours the plastic mud into the shaping assembly 1, the shaping assembly 1 heats the plastic mud and extrudes the plastic mud into a finger-shaped model under the driving of the power assembly 3, the finger model falls onto the conveyor belt machine part 5, the conveyor belt machine part 5 conveys the finger model to the lower part of the engraving assembly 2, then the engraving assembly 2 carries out nail engraving treatment on the finger model, and finally the conveyor belt machine part 5 conveys the finger model with engraved nails to the collection disc 6; the invention realizes the sequential heating treatment, the finger shape shaping treatment and the nail engraving treatment of the plasticine, the double-unit synchronous treatment can replace the manual work to improve the working efficiency of the artificial finger production, and the operation is simple, safe and reliable.

The shaping component 1 comprises a mud box 101, a hot air blower regulating and controlling mechanism 102, a heating pipe 103, a fan 104, a partition plate 105, a first rotating shaft 106, a first driving wheel 107, a rotating ring 108, an upper push rod 109, a lower push rod 110, a double-slider connecting rod 111, an extrusion block 112 and an extrusion rod 113; a mud loading box 101 is fixedly connected with the support platform 7 below a discharge plate of the electric control plastic mud conveying cylinder 4; an air heater regulating and controlling part 102 is arranged on one side of the mud box 101; a heating pipe 103 is arranged on the inner side surface of the mud containing box 101; a group of fans 104 are respectively arranged on two sides of the heating pipe 103; the heating pipe 103 and the two groups of fans 104 are respectively connected with the air heater regulating and controlling part 102; a partition plate 105 is fixedly connected to one side of the heating pipe 103 and inside the mud box 101; a first rotating shaft 106 is rotatably connected with the bracket table 7 above one side of the air heater regulating and controlling part 102; the first driving wheel 107 and the rotating ring 108 are fixedly connected with the first rotating shaft 106 respectively; the first driving wheel 107 is connected with the power assembly 3; the upper push rod 109 and the lower push rod 110 are respectively fixedly connected with the side ring surface of the rotating ring 108; the sliding blocks on the two sides of the double-sliding-block connecting rod 111 are respectively connected with the support table 7 in a sliding manner above the mud box 101; an extrusion block 112 is fixedly connected with the middle cross rod part of a double-slider connecting rod 111 above the mud containing box 101; the extrusion block 112 is rotatably connected with the upper push rod 109; the extrusion rod 113 is inserted into the mud containing box 101, and the extrusion rod 113 is connected with the mud containing box 101 in a sliding manner; on the side of the mud tank 101, a squeeze bar 113 is rotatably connected to the lower push rod 110.

Firstly, a regulating and controlling machine member 102 of an air heater respectively drives a heating pipe 103 and a fan 104 to start working, then an electric control plastic mud conveying cylinder 4 pours plastic mud into a mud loading box 101 along a discharging plate, hot air generated by the heating pipe 103 and the fan 104 is transmitted out from a gap of a partition plate 105 and carries out heating treatment on the plastic mud in the mud loading box 101, then a power assembly 3 drives a first driving wheel 107 to rotate, the first driving wheel 107 drives a rotating ring 108 to rotate through a first rotating shaft 106, the rotating ring 108 drives an upper push rod 109 to drive an extrusion block 112 and parts connected with the extrusion block to move downwards, so that the extrusion block 112 compacts the plastic mud in the mud loading box 101, meanwhile, the rotating ring 108 drives a lower push rod 110 to drive the extrusion rod 113 to move outwards from the mud loading box 101, so that the extrusion block 112 cannot press the extrusion rod 113, then the power assembly 3 drives the first driving wheel 107 to rotate reversely, so that the rotating ring 108 drives the upper push rod 109 to drive the extrusion block 112 and the parts connected with the extrusion block 112 to reset upwards, meanwhile, the rotating ring 108 drives the lower push rod 110 to drive the extrusion rod 113 to move towards the mud containing box 101, so that the extrusion rod 113 extrudes the plastic mud in the mud containing box 101 into a mold in the imprinting assembly 2; the assembly is completed with the slush heat treated and extruded into the mold in imprinting assembly 2.

The marking assembly 2 comprises a second rotating shaft 201, a first bevel gear 202, a second transmission wheel 203, a third transmission wheel 204, a left screw rod 205, a right screw rod 206, a fourth transmission wheel 207, a fifth transmission wheel 208, a first slider bracket 209, a half-finger mold 210, a third rotating shaft 211, a tilting rod 212, a fourth rotating shaft 213, a fifth rotating shaft 214, a sixth rotating shaft 215, a pressing plate 216, a U-shaped marking knife 217, a limiting rod 218, a second slider bracket 219, a switching block 220, a switching rod 221, a carrier plate 222, a third slider bracket 223 and an arc-shaped blade 224; the second rotating shaft 201 is rotatably connected with one side of the mud containing box 101 far away from the lower push rod 110; the first bevel gear 202, the second driving wheel 203 and the third driving wheel 204 are fixedly connected with the second rotating shaft 201 respectively; the first bevel gear 202 is connected with the power assembly 3; below the second rotating shaft 201, a left screw rod 205 and a right screw rod 206 are respectively in rotating connection with the second rotating shaft 201; the insection directions of the left screw rod 205 and the right screw rod 206 are opposite; the fourth transmission wheel 207 is fixedly connected with the left screw rod 205; the fifth driving wheel 208 is fixedly connected with the right screw rod 206; the second transmission wheel 203 is in transmission connection with a fourth transmission wheel 207 through a belt; the third driving wheel 204 is in driving connection with a fifth driving wheel 208 through a belt; the left screw rod 205 and the right screw rod 206 are respectively connected with a group of first slider brackets 209 in a screwing way; the two groups of first sliding block brackets 209 are respectively connected with the mud containing box 101 in a sliding manner; each group of first sliding blocks is fixedly connected with one group of half-finger molds 210 respectively; the two groups of first slider brackets 209 and the half-finger mould 210 are symmetrically distributed; on one side of the third driving wheel 204, a third rotating shaft 211 is rotatably connected with the bracket table 7; the tilting rod 212 is fixedly connected with the third rotating shaft 211; the fourth rotating shaft 213 is fixedly connected with one side of the tilting rod 212; the fifth rotating shaft 214 and the sixth rotating shaft 215 are respectively and fixedly connected with the other side of the tilting rod 212; the fourth rotating shaft 213 is connected with the power assembly 3; the pressing plate 216 is rotatably connected to the fifth shaft 214; the U-shaped nicking tool 217 is fixedly connected with the bottom end of the pressing plate 216; two sides of the pressing plate 216 are respectively connected with a group of limiting rods 218 in a rotating manner through rotating shafts; each set of limiting rods 218 is rotatably connected with one set of second slider brackets 219; the two groups of second sliding block brackets 219 are respectively connected with the bracket table 7 in a sliding manner; the transfer block 220 is rotatably connected with the sixth rotating shaft 215; the switching rod 221 is fixedly connected with the bottom end of the switching block 220; below the switching block 220, two sets of third slider supports 223 are respectively connected with the support table 7 in a sliding manner; one side of the carrier plate 222 is fixedly connected with the two groups of third slider supports 223 respectively; the other side of the carrier plate 222 is rotatably connected with the adapter rod 221 through a rotating shaft; the arc-shaped blade 224 is fixedly connected to one end of the carrier plate 222.

After the extrusion rod 113 extrudes the plastic mud in the mud storage box 101 into the two sets of half-finger molds 210, the plastic mud is extruded into a finger-shaped mold, the power assembly 3 drives the first bevel gear 202 to rotate, the first bevel gear 202 drives the second transmission wheel 203 and the third transmission wheel 204 to rotate through the second rotating shaft 201, the second transmission wheel 203 and the third transmission wheel 204 respectively drive the fourth transmission wheel 207 and the fifth transmission wheel 208 through the belt and drive the fourth transmission wheel and the fifth transmission wheel 208 to rotate, the fourth transmission wheel 207 and the fifth transmission wheel 208 respectively drive the left screw rod 205 and the right screw rod 206 to rotate, because the insection directions of the left screw rod 205 and the right screw rod 206 are opposite, the first slider bracket 209 respectively connected with the left screw rod 205 and the right screw rod 206 drives the half-finger molds 210 connected with the first slider bracket 209 to move towards two sides, and the finger molds 210 in the two sets of half-finger molds 210 fall onto the conveying belt part of the conveying belt 5 after the half-finger molds 210 are opened, the finger model is conveyed to the lower part of the pressing plate 216 by the conveyor belt of the conveyor belt mechanism 5, then the power assembly 3 drives the fourth rotating shaft 213 to move upwards, the fourth rotating shaft 213 drives the warping rod 212 to rotate around the axis of the third rotating shaft 211, the warping rod 212 drives the pressing plate 216 to drive the U-shaped graver 217 to move downwards through the fifth rotating shaft 214, meanwhile, the pressing plate 216 drives the limiting rod 218 and the second slider bracket 219 connected with the limiting rod to move towards the fourth rotating shaft 213 through the rotating shaft, when the limiting rod 218 is blocked by the bracket table 7 along with the second slider bracket 219 and cannot move, the limiting rod 218 drives one side of the pressing plate 216 to rotate upwards around the fifth rotating shaft 214 through the rotating shaft, so that the U-shaped graver 217 below the pressing plate 216 is pressed on the finger model in a horizontal state, meanwhile, the warping rod 212 drives the transfer block 220 to move downwards through the sixth rotating shaft 215, and the transfer block 220 drives the support plate 222 and the connected components to move towards the fourth rotating shaft 213 through the transfer rod 221, the arc-shaped blade 224 is used for extruding one end of the finger model on one side of the U-shaped nicking tool 217; the assembly completes the nail imprint process on the finger model.

The power assembly 3 comprises a general motor 301, a motor rotating shaft 302, a first straight gear 303, a second straight gear 304, an electric slider 305, a third straight gear 306, a seventh rotating shaft 307, a fourth straight gear 308, a sixth driving wheel 309, an eighth rotating shaft 310, a fifth straight gear 311, a seventh driving wheel 312, a ninth rotating shaft 313, a second bevel gear 314, an eighth driving wheel 315, a rotating disc 316, a driving rod 317, a tenth rotating shaft 318, a third bevel gear 319 and a fourth bevel gear 320; a main motor 301 is fixedly connected with the support table 7 below the first rotating shaft 106; the motor rotating shaft 302 is rotatably connected with the support table 7; the motor rotating shaft 302 is fixedly connected with the main motor 301; the first straight gear 303 and the second straight gear 304 are respectively and fixedly connected with the motor rotating shaft 302; on one side of the motor rotating shaft 302, an electric sliding block 305 is in sliding connection with the support table 7; the third spur gear 306 is rotationally connected with the electric slider 305 through a rotating shaft; on one side of the electric slider 305, a seventh rotating shaft 307 and an eighth rotating shaft 310 are respectively connected with the support table 7 in a rotating manner; the fourth spur gear 308 and the sixth transmission wheel 309 are fixedly connected with the seventh rotating shaft 307 respectively; the fifth spur gear 311 and the seventh transmission wheel 312 are fixedly connected with the eighth rotating shaft 310 respectively; when both sides of the third spur gear 306 are respectively engaged with the first spur gear 303 and the fourth spur gear 308, the third spur gear 306 and the fourth spur gear 308 rotate; when both sides of the third spur gear 306 are not engaged with the first spur gear 303 and the fourth spur gear 308, the third spur gear 306 and the fourth spur gear 308 do not rotate; when both sides of the third spur gear 306 are engaged with the second spur gear 304 and the fifth spur gear 311, respectively, the third spur gear 306 and the fifth spur gear 311 rotate; when both sides of the third spur gear 306 are not engaged with the second spur gear 304 and the fifth spur gear 311, the third spur gear 306 and the fifth spur gear 311 do not rotate; the sixth driving wheel 309 is in driving connection with the first driving wheel 107 through a belt; on the side where the eighth rotating shaft 310 is finished, the ninth rotating shaft 313 is rotatably connected with the support table 7; the second bevel gear 314, the eighth driving wheel 315 and the turntable 316 are fixedly connected with a ninth rotating shaft 313 in sequence; the seventh driving wheel 312 is in transmission connection with the eighth driving wheel 315 through a belt; the transmission rod 317 is in transmission connection with the edge of the turntable 316 through a rotating shaft; the transmission rod 317 is in transmission connection with the fourth rotating shaft 213; on the side of the second bevel gear 314, a tenth rotating shaft 318 is rotatably connected with the support table 7; the third bevel gear 319 and the fourth bevel gear 320 are respectively fixedly connected with the tenth rotating shaft 318; second bevel gear 314 is engaged with third bevel gear 319; the first bevel gear 202 meshes with the fourth bevel gear 320.

The power assembly 3 drives the shaping assembly 1 to perform shaping work, firstly, the main motor 301 drives the first spur gear 303 and the second spur gear 304 to rotate through the motor rotating shaft 302, then the electric slider 305 drives the third spur gear 306 to move through the rotating shaft, so that the first spur gear 303 is meshed with the third spur gear 306 and drives the third spur gear to rotate, the third spur gear 306 is meshed with the fourth spur gear 308, the sixth transmission wheel 309 is driven to rotate through the seventh rotating shaft 307, and the sixth transmission wheel 309 drives the first transmission wheel 107 through a belt and drives the sixth transmission wheel to rotate, so that the shaping assembly 1 performs shaping work; in addition, the power assembly 3 drives the engraving assembly 2 to perform nail engraving work, firstly, the electric slide block 305 drives the third spur gear 306 to move through the rotating shaft, so that the second spur gear 304 is meshed with the third spur gear 306 and drives the third spur gear 306 to rotate, the third spur gear 306 is meshed with the fifth spur gear 311 and drives the seventh transmission wheel 312 to rotate through the eighth rotating shaft 310, the seventh transmission wheel 312 drives the eighth transmission wheel 315 through the belt to drive the ninth rotating shaft 313 to rotate, the ninth rotating shaft 313 respectively drives the second bevel gear 314 and the rotating disc 316 to rotate, the second bevel gear 314 is meshed with the third bevel gear 319 and drives the fourth bevel gear 320 to rotate through the tenth rotating shaft 318, the fourth bevel gear 320 is meshed with the first bevel gear 202 and drives the fourth bevel gear 202 to rotate, when the two groups of half finger molds 210 are respectively opened towards two sides, the rotating disc 316 rotates upwards through the rotating shaft transmission rod 317, the transmission rod 317 drives the fourth rotating shaft 213 to move upwards, so that the U-shaped engraving knife 217 is pressed on the mold in a horizontal state, simultaneously, the arc-shaped blade 224 extrudes one end of the finger model; the component completes the operation of driving the shaping component 1 to carry out shaping work and completes the operation of driving the engraving component 2 to carry out nail engraving work.

The squeeze bar 113 has a finger-like irregular oval structure.

The squeeze bar 113 can be brought into close proximity with the inner surface of the mold half 210 as it enters the interior of the mold half 210.

The inside of the half-finger mold 210 is a half-side hollow design of the finger.

The shaping treatment of the finger shape can be completed on the plasticine.

The U-shaped nicking tool 217 is shaped along three sides of the nail at the connection with the finger.

The upper surface of one side of the plasticine can be pressed into a U-shaped nail-shaped groove.

The arc-shaped blade 224 is designed to be arc-shaped along the hanging part of the non-connecting side of the fingernail and the finger.

Can extrude the arc-shaped groove at the suspension part at the non-connection side of the fingernail and the finger from one end of the plasticine.

The technical principle of the embodiment of the present invention is described above in conjunction with the specific embodiments. The description is only intended to explain the principles of embodiments of the invention and should not be taken in any way as limiting the scope of the embodiments of the invention. Based on the explanations herein, those skilled in the art will be able to conceive of other embodiments of the present invention without inventive step, and these embodiments will fall within the scope of the present invention.

Claims (7)

1. The utility model provides a soft pottery emulation is pointed moulding and nail seal carving device, including catch tray, pallet and control cabinet, its characterized in that: the automatic molding machine also comprises a molding component, an imprinting component, a power component, an electric control plastic mud conveying cylinder and a conveyor belt part; the shaping component is connected with the imprinting component; the shaping component is connected with the power component; the shaping component is connected with the support platform; the engraving assembly is connected with the power assembly; the engraving component is connected with the support platform; the power assembly is connected with the support platform; the electric control plastic mud conveying cylinder is connected with the support platform; the conveyor belt part is connected with the support table; the console is connected with the support table;

the shaping component comprises a mud box, a hot air blower regulating and controlling part, a heating pipe, a fan, a partition plate, a first rotating shaft, a first driving wheel, a rotating ring, an upper push rod, a lower push rod, a double-slider connecting rod, an extrusion block and an extrusion rod; a mud loading box is fixedly connected with a support platform below a discharge plate of the electric control plastic mud conveying cylinder; one side of the mud box is provided with an air heater regulating and controlling part; the inner side surface of the mud box is provided with a heating pipe; a group of fans are respectively arranged on two sides of the heating pipe; the heating pipe and the two groups of fans are respectively connected with the air heater regulating and controlling part; a partition plate is fixedly connected inside the mud containing box on one side of the heating pipe; the first rotating shaft is rotatably connected with the support platform above one side of the air heater regulating and controlling part; the first driving wheel and the rotating ring are fixedly connected with the first rotating shaft respectively; the first driving wheel is connected with the power assembly; the upper push rod and the lower push rod are respectively fixedly connected with the side ring surface of the rotating ring; the sliding blocks on two sides of the double-sliding-block connecting rod are respectively connected with the support platform in a sliding manner above the mud box; the extrusion block is fixedly connected with the middle cross rod part of the double-slider connecting rod above the mud containing box; the extrusion block is rotationally connected with the upper push rod; the extrusion rod is inserted into the mud containing box in a penetrating way, and the extrusion rod is connected with the mud containing box in a sliding way; on one side of the mud box, the extrusion rod is rotationally connected with the lower push rod.

2. The device for modeling a finger and engraving a nail as recited in claim 1, further comprising: the engraving and printing assembly comprises a second rotating shaft, a first bevel gear, a second driving wheel, a third driving wheel, a left screw rod, a right screw rod, a fourth driving wheel, a fifth driving wheel, a first sliding block support, a half-finger mold, a third rotating shaft, a warping rod, a fourth rotating shaft, a fifth rotating shaft, a sixth rotating shaft, a pressing plate, a U-shaped engraving knife, a limiting rod, a second sliding block support, a transfer block, a transfer rod, a support plate, a third sliding block support and an arc-shaped blade; the second rotating shaft is rotatably connected with one side of the mud containing box far away from the lower push rod; the first bevel gear, the second driving wheel and the third driving wheel are fixedly connected with the second rotating shaft respectively; the first bevel gear is connected with the power assembly; the left screw rod and the right screw rod are respectively in rotary connection with the second rotating shaft below the second rotating shaft; the insection directions of the left screw rod and the right screw rod are opposite; the fourth driving wheel is fixedly connected with the left screw rod; the fifth driving wheel is fixedly connected with the right screw rod; the second transmission wheel is in transmission connection with the fourth transmission wheel through a belt; the third driving wheel is in transmission connection with the fifth driving wheel through a belt; the left screw rod and the right screw rod are respectively connected with a group of first sliding block brackets in a rotating mode; the two groups of first sliding block brackets are respectively connected with the mud containing box in a sliding manner; each group of first sliding blocks is fixedly connected with one group of semi-finger molds respectively; the two groups of first sliding block brackets and the half-finger mould are symmetrically distributed; a third rotating shaft is rotatably connected with the support table on one side of the third driving wheel; the warping rod is fixedly connected with the third rotating shaft; the fourth rotating shaft is fixedly connected with one side of the tilting rod; the fifth rotating shaft and the sixth rotating shaft are fixedly connected with the other side of the tilting rod respectively; the fourth rotating shaft is connected with the power assembly; the pressing plate is rotationally connected with the fifth rotating shaft; the U-shaped nicking tool is fixedly connected with the bottom end of the pressing plate; two sides of the pressing plate are respectively connected with a group of limiting rods in a rotating way through rotating shafts; each group of limiting rods is rotatably connected with one group of second sliding block brackets; the two groups of second sliding block supports are respectively connected with the support table in a sliding manner; the transfer block is rotationally connected with the sixth rotating shaft; the switching rod is fixedly connected with the bottom end of the switching block; two groups of third sliding block brackets are respectively connected with the bracket platform in a sliding manner below the switching block; one side of the carrier plate is fixedly connected with the two groups of third sliding block brackets respectively; the other side of the carrier plate is rotationally connected with the switching rod through a rotating shaft; the arc-shaped blade is fixedly connected with one end of the carrier plate.

3. The device for modeling a finger and engraving a nail as recited in claim 2, further comprising: the power assembly comprises a main motor, a motor rotating shaft, a first straight gear, a second straight gear, an electric slider, a third straight gear, a seventh rotating shaft, a fourth straight gear, a sixth transmission wheel, an eighth rotating shaft, a fifth straight gear, a seventh transmission wheel, a ninth rotating shaft, a second bevel gear, an eighth transmission wheel, a rotary table, a transmission rod, a tenth rotating shaft, a third bevel gear and a fourth bevel gear; a main motor is fixedly connected with the support platform below the first rotating shaft; the motor rotating shaft is rotatably connected with the support platform; the motor rotating shaft is fixedly connected with the main motor; the first straight gear and the second straight gear are fixedly connected with a motor rotating shaft respectively; on one side of the motor rotating shaft, an electric sliding block is in sliding connection with the support table; the third straight gear is rotationally connected with the electric slide block through a rotating shaft; on one side of the electric sliding block, a seventh rotating shaft and an eighth rotating shaft are respectively in rotating connection with the support platform; the fourth straight gear and the sixth transmission wheel are fixedly connected with the seventh rotating shaft respectively; the fifth straight gear and the seventh driving wheel are respectively and fixedly connected with the eighth rotating shaft; when two sides of the third straight gear are respectively meshed with the first straight gear and the fourth straight gear, the third straight gear and the fourth straight gear rotate; when the two sides of the third straight gear are not meshed with the first straight gear and the fourth straight gear, the third straight gear and the fourth straight gear do not rotate; when the two sides of the third straight gear are respectively meshed with the second straight gear and the fifth straight gear, the third straight gear and the fifth straight gear rotate; when the two sides of the third straight gear are not meshed with the second straight gear and the fifth straight gear, the third straight gear and the fifth straight gear do not rotate; the sixth transmission wheel is in transmission connection with the first transmission wheel through a belt; on the side where the eighth rotating shaft is finished, the ninth rotating shaft is rotatably connected with the support platform; the second bevel gear, the eighth driving wheel and the turntable are fixedly connected with the ninth rotating shaft in sequence; the seventh driving wheel is in transmission connection with the eighth driving wheel through a belt; the transmission rod is in transmission connection with the edge of the rotary disc through the rotating shaft; the transmission rod is in transmission connection with the fourth rotating shaft; on one side of the second bevel gear, a tenth rotating shaft is rotatably connected with the support platform; the third bevel gear and the fourth bevel gear are fixedly connected with the tenth rotating shaft respectively; the second bevel gear is meshed with the third bevel gear; the first bevel gear is meshed with the fourth bevel gear.

4. The device for modeling a finger and engraving a nail as recited in claim 3, further comprising: the extrusion rod is in a finger-shaped irregular oval structure.

5. The device for modeling a simulated finger and engraving nails as recited in claim 4, wherein: the inside of the half-finger mould is in a hollow design of the half-side shape of the finger.

6. The device for modeling a finger and engraving a nail as recited in claim 5, further comprising: the U-shaped graver is designed in the shape of the joint of the finger and the nail along three sides of the nail.

7. The device for modeling a finger and engraving a nail as recited in claim 6, further comprising: the arc-shaped blade is designed into an arc shape along the suspension part at the non-connection side of the nail and the finger.

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