GB2568173A - A silicone rubber impression material equipment - Google Patents

Abstract

A silicone rubber impression material equipment, comprising a clamp plate 137; a vertical plate 136 fixedly arranged on the upper end face of the clamp plate; a top cavity (300, fig 3) up and down penetrated through the vertical plate; a motor fixedly set in the lower end wall of the top cavity, wherein the upper end of the motor in the lower end wall of the top cavity is in rotational engagement with the upper end wall of the top cavity; guide rails (301, fig 3) fixedly set on the two end faces of the vertical plate. Sliding plate 138 moves downwards, so that the matrices 117 extend into the third open cavities 134 to dig out the impression materials. Lamp turning equipment may comprise a cushion pad 804, fourth open cavity 806, a transposition motor 803, driving gear 805, a through rod 801, a platform 800 may be arranged on one end face of the through rod, wherein a lamp tube 807 may be fixedly arranged on the platform. A first motor 125 may drive connecting blocks 128, and driving and rotating motors 109 may drive sliding blocks 107 to move so that risers 126 slide into containing cavities 118, and the impression materials in the containing cavities 118 are adhered to end faces. Second motors (406, fig 5) may be operated to enable the connecting blocks 128 to rotate, so that the risers 126 face each other; the first motor drives the connecting sliding blocks to be close to one another to enable the impression materials to be mixed and adhered.

Description

A Silicone Rubber Impression Material Equipment

Field of the Invention

The invention relates to the field of impression, in particular to a silicone rubber impression material equipment.

Background of the Invention

In the traditional impression materials preparation process, two kinds of materials with different types are often mixed for repeated kneading to form a whole, and the whole is embedded into the impression. The existing impression materials preparation process is labor-wasting during kneading, and the labor burden of workers will be increased if large-scale mixing preparation are carried out; but the equipment effectively solves the problem.

Summary of the Invention

The aim of the invention is to provide a silicone rubber impression material equipment, so as to overcome the above disadvantages existing in the prior art.

A silicone rubber impression material equipment of the invention, comprising a clamp plate; a vertical plate fixedly arranged on the upper end face of the clamp plate; a top cavity up and down penetrated through the vertical plate; a motor fixedly set in the lower end wall of the top cavity, wherein the upper end of the motor in the lower end wall of the top cavity is in rotational engagement with the upper end wall of the top cavity; guide rails fixedly set on two end faces of the vertical plate; sliders slidably arranged on outer faces of the guide rails; a sliding plate arranged on one side of the vertical plate, wherein the sliding plate is fixed to the sliders; wherein the sliding plate is in threaded fit connection with the upper end of the motor in the lower end wall of the top cavity; a first open cavity penetrating through the sliding plate from one side to the other side set in the sliding plate; a top block set above the sliding plate; a driving motor fixedly set in the lower end face of the top block, wherein the lower end of the driving motor is in threaded fit connection with the sliding plate and extends downwards; symmetrical connecting rods fixedly set in the lower end face of the top block, wherein the connecting rods slidably penetrate through the sliding plate and extend into first open cavity; a base plate set in lower end faces of the connecting rods, wherein the lower end of the driving motor is in rotational fit connection with the base plate, and symmetrical communicated cavities, each of which has an upward opening, are fixedly set in the base plate, wherein rotating plates extending downwards are rotationally set in the communicated cavities; wherein rotating rods are rotationally set in end faces of the rotating plates; wherein ends of the rotating rods, away from the driving motor, are fixedly connected with connecting boxes, wherein L-shaped blocks are fixedly arranged on lower end faces of the connecting boxes; inner cavities, each of which has a downward opening, are fixedly arranged in the connecting boxes, wherein end walls, away from the rotating rods, of the inner cavities, are fixedly provided with driving and rotating motors, wherein ends, close to the rotating rods, of the driving and rotating motors, are in rotational engagement with end walls of the inner cavities; side rods arranged between the inner cavities; sliding blocks slidably set on outer faces of the side rods, wherein the sliding blocks are in threaded fit connection with outer faces of output shafts of the driving and rotating motors; sliding rods rotationally set in the sliding blocks; rotating handles rotationally set on end faces of the L-shaped blocks, wherein upper end walls of the rotating handles are fixedly provided with sliding cavities, each of which has an upward opening, wherein the sliding cavities are in sliding fit connection with the sliding rods; top columns fixedly arranged on end faces of the rotating handles; annular rails fixedly arranged on end faces of the L-shaped blocks; through slots which are communicated fixedly set in the annular rails, wherein the through slots are in sliding fit connection with the top columns; matrices fixedly arranged on lower end faces of the rotating handles, wherein containing cavities with openings are fixedly arranged in the matrices; wherein a lamp turning equipment is fixedly arranged on the upper end face of the top block.

In a further technical proposal, symmetrical rod cavities which are penetrated from one side to the other side are fixedly set in the sliding plate; a pushing air cylinder is fixedly arranged in the sliding plate, wherein one end face of a push rod of the pushing air cylinder is fixedly provided with a top box, and symmetrical sliding rods are fixedly arranged on the other end face of the top box; wherein the sliding rods are in sliding fit connection with the rod cavities; a second open cavity is set in the top box; a first motor is fixedly arranged in one end wall of the second open cavity, wherein the first motor is in rotational fit connection with the other end wall of the second open cavity; wherein the outer face of one end of the first motor, is in threaded fit connection with symmetrical connecting sliding blocks, wherein second motors are fixedly arranged in end faces of the connecting sliding blocks respectively, wherein ends of the second motors are in a power matching connection with connecting blocks; spring cavities are set in the connecting blocks; slide plates are slidably arranged in the spring cavities, wherein end faces, far away from the center line of the second open cavity, of the slide plates, are fixedly connected with stretching rods, wherein the stretching rods slidably penetrate through the spring cavities and extend outwards; wherein ends, far away from the spring cavities, of the stretching rods, are rotationally provided with rotary rods; symmetrical risers are arranged at the other side of the top box, wherein end faces, close to the central line of the second cavitiy, of the risers, are fixedly provided with vertical blocks respectively, wherein the vertical blocks are in rotational engagement with the rotary rods; wherein end faces, close to the center line of the top box, of the risers, are fixedly provided with connecting plates respectively; wherein each of the connecting plates is in rotational engagement with a respective one of the connecting blocks .

In a further technical proposal, open boxes which are respectively distributed on the two sides are embedded in two sides of the clamp plate; third open cavities, each of which has an upward opening, are set in the open boxes; side plates are fixedly arranged on end faces of the open boxes, wherein rotating blocks are fixedly arranged on upper end faces of the side plates; turning covers are rotationally arranged in the rotating blocks, wherein the turning covers abut against the open boxes; clamping cavities, each of which has an opening to one side, are respectively set in end faces of the turning covers; side blocks are fixedly arranged on the other end faces of the open boxes, wherein connecting top cavities, each of which has an upward opening, are set in the side blocks, wherein sliding elastic cavities are communicated with lower end walls of the connecting top cavities; sliding top blocks are sliadably arranged in the sliding elastic cavities and the connecting top cavities, and the sliding top blocks extend into the clamping cavities and the sliding top blocks are in sliding fit connection with the clamping cavities; whereby openings on the upper ends of the third open cavities are closed when the turning covers are turned over, and the turning covers can be locked tightly by the cooperation between the sliding top blocks and the clamping cavities.

In a further technical proposal, one side face of each of the slide plates is in a resilient fit with one side inner wall of a respective one of the spring cavities.

In a further technical proposal, the distance between the risers and the matrices meets the requirement that the risers extend into the containing cavities and the risers slide in the containing cavities; when the first motor rotates, the first motor can drive the symmetrical stretching rods to move towards two sides respectively.

In a further technical proposal, the lamp turning equipment comprises a cushion pad, a fourth open cavity fixedly arranged in the cushion pad and a transposition motor fixedly arranged in one end wall of the fourth open cavity; wherein one end of the transposition motor is in power connection with a driving gear, wherein a driven gear is engaged with and set below the driving gear; a through rod is fixedly arranged on one end face of the driven gear, wherein the through rod rotationally penetrates through the other end wall of the fourth open cavity and extends out of the outer space; a platform is fixedly arranged on one end face of the through rod, wherein a lamp tube is fixedly arranged on one end face of the platform.

The benefits of the invention are as follows:

when the device is in the initial state, the driving motor, the motor in the lower end wall of the top cavity, the driving and rotating motors, the pushing air cylinder and the first motor are all out of work, and the slide plates are located in the middle of the spring cavities , and the rotating rods are in the horizontal state, and the rotating plates are in the upright state, and the risers are in the vertical state, so that the above structure is located at the initial position in the initial state, and can be adjusted in subsequent work, thereby effectively improving the work coordination of the equipment.

When the equipment is operated, the sliding top blocks are stirred to move to one side, so that the sliding top blocks are separated from the matching with the clamping cavities; and then the turning covers are turned over, so that the impression materials contained in the third open cavities are exposed; and then the motor in the lower end wall of the top cavity drives the sliding plate to move downwards, so that the matrices extend into the third open cavities; at this time, the driving and rotating motors work to drive the sliding blocks to move towards the direction which is close to the driving and rotating motors, and at this time, the sliding rods slide in the sliding cavities to enable the rotating handles to rotate, and the matrices are enabled to dig out the impression materials in the containing cavities; and then the pushing air cylinder is operated to enable the top box to move forwards, so that the top box and the matrices face to each other; and the second motors are operated to drive the connecting blocks to move to a corresponding position, and at the time the driving and rotating motors drive the sliding blocks to move towards the direction which is close to the driving and rotating motors after the driving and rotating motors work, so that the risers slide into the containing cavities, and the impression materials in the containing cavities are adhered to end faces, close to the matrices, of the risers, and the second motors drive the connecting blocks to be far away from each other after the second motors work again, and the second motors are operated to enable the connecting blocks to rotate, so that the risers face to each other; and then the second motors drive the connecting sliding blocks to be close to one another to enable the impression materials on end faces of the risers to be mixed and adhered after the second motors work; after the mixing and adhesion are completed, the second motors drive the connecting sliding blocks again to be far away from each other, so that workers can take down the impression materials which have been mixed and adhered, so that the repeated mixing and adhersion process of the impression materials can be realized in an automatic mode.

The equipment of the invention is simple in structure and convenient to use, as the equipment adopts an automatic mode, thereby realizing the kneading, mixing and adhesion process of the impression materials, and effectively reducing the labor burden of workers.

Brief Description of the Drawings

For better explain the technical proposal in the present invention embodiments or the prior art, the drawings to be used in the description of the embodiments or the prior art will be briefly described below. Obviously, the drawings in the following description are only some embodiments of the present invention. For those common technicians in this field, other drawings may also be obtained based on these drawings without any creative work.

FIG.1 is the schematic diagram showing an overall structural of a silicone rubber impression material equipment in this invention.

FIG. 2 is the schematic diagram along “A-A” direction in FIG.1.

FIG. 3 is the schematic diagram along “B-B” direction in FIG.1.

FIG. 4 is the enlarged schematic diagram of “C” in FIG.1.

FIG. 5 is the enlarged schematic diagram of “D-D” in FIG.1.

Detailed Description of the Invention

All of the features disclosed in this specification, or all methods or steps in the processes disclosed, may be combined in any manner other than mutually exclusive features and/or steps.

Any feature disclosed in the specification, including any additional claims, abstract and drawings, may be replaced by other equivalents or alternative features with similar purposes, unless otherwise stated. That is, unless specifically stated, each feature is only one example of a series of equivalent or similar features.

Referring to FIG.1 to FIG.5, a silicone rubber impression material equipment of the invention, comprising a clamp plate 137; a vertical plate 136 fixedly arranged on the upper end face of the clamp plate 137; a top cavity 300 up and down penetrated through the vertical plate 136; a motor fixedly set in the lower end wall of the top cavity 300, wherein the upper end of the motor in the lower end wall of the top cavity 300 is in rotational engagement with the upper end wall of the top cavity 300; guide rails 301 fixedly set on two end faces of the vertical plate 136; sliders 302 slidably arranged on outer faces of the guide rails 301; a sliding plate 138 arranged on one side of the vertical plate 136, wherein the sliding plate 138 is fixed to the sliders 302; wherein the sliding plate 138 is in threaded fit connection with the upper end of the motor in the lower end wall of the top cavity 300; a first open cavity 119 penetrating through the sliding plate 138 from one side to the other side set in the sliding plate 138; a top block 100 set above the sliding plate 138; a driving motor 101 fixedly set in the lower end face of the top block 100, wherein the lower end of the driving motor 101 is in threaded fit connection with the sliding plate 138 and extends downwards; symmetrical connecting rods 102 fixedly set in the lower end face of the top block 100, wherein the connecting rods 102 slidably penetrate through the sliding plate 138 and extend into the first open cavity 119; a base plate 103 set in lower end faces of the connecting rods 102, wherein the lower end of the driving motor 101 is in rotational fit connection with the base plate 103, and symmetrical communicated cavities 500, each of which has an upward opening, are fixedly set in the base plate 103, wherein rotating plates 104 extending downwards are rotationally set in the communicated cavities 500; wherein rotating rods 105 are rotationally set in end faces of the rotating plates 104; wherein ends of the rotating rods 105, away from the driving motor 101, are fixedly connected with connecting boxes 108, wherein L-shaped blocks 140 are fixedly arranged on lower end faces of the connecting boxes 108; inner cavities 106, each of which has a downward opening, are fixedly arranged in the connecting boxes 108, wherein end walls, away from the rotating rods 105, of the inner cavities 106, are fixedly provided with driving and rotating motors 109, wherein ends, close to the rotating rods 105, of the driving and rotating motors 109, are in rotational engagement with end walls of the inner cavities 106; side rods 110 arranged between the inner cavities 106; sliding blocks 107 slidably set on outer faces of the side rods 110, wherein the sliding blocks 107 are in threaded fit connection with outer faces of output shafts of the driving and rotating motors 109; sliding rods 112 rotationally set in the sliding blocks 107; rotating handles 116 rotationally set on end faces of the L-shaped blocks 140, wherein upper end walls of the rotating handles 116 are fixedly provided with sliding cavities 115, each of which has an upward opening, wherein the sliding cavities 115 are in sliding fit connection with the sliding rods 112; top columns 111 fixedly arranged on end faces of the rotating handles 116; annular rails 113 fixedly arranged on end faces of the L-shaped blocks 140; through slots 114 which are communicated fixedly set in the annular rails 113, wherein the through slots 114 are in sliding fit connection with the top columns 111; matrices 117 fixedly arranged on lower end faces of the rotating handles 116, wherein containing cavities 118 with openings are fixedly arranged in the matrices 117; wherein a lamp turning equipment is fixedly arranged on the upper end face of the top block 100.

Helpfully, symmetrical rod cavities 403 which are penetrated from one side to the other side fixedly set in the sliding plate 138; a pushing air cylinder 400 fixedly arranged in the sliding plate 138, wherein one end face of a push rod of the pushing air cylinder 400 is fixedly provided with a top box 130, and symmetrical sliding rods 401 are fixedly arranged on the other end face of the top box 130; wherein the sliding rods 401 are in sliding fit connection with the rod cavities 403; a second open cavity 404 set in the top box 130; a first motor 125 fixedly arranged in one end wall of the second open cavity 404, wherein the first motor 125 is in rotational fit connection with the other end wall of the second open cavity 404; wherein the outer face of one end of the first motor 125 is in threaded fit connection with symmetrical connecting sliding blocks 405, wherein second motors 406 are fixedly arranged in end faces of the connecting sliding blocks 405 respectively, wherein ends of the second motors 406 are in a power matching connection with connecting blocks 128; spring cavities 120 set in the connecting blocks 128; slide plates 121 slidably arranged in the spring cavities 120, wherein end faces, far away from the center line of the second open cavity 404, of the slide plates 121, are fixedly connected with stretching rods 122, wherein the stretching rods 122 slidably penetrate through the spring cavities 120 and extend outwards; wherein ends, far away from the spring cavities 120, of the stretching rods 122, are rotationally provided with rotary rods 123; symmetrical risers 126 arranged at the other side of the top box 130, wherein end faces, close to the central line of the second open cavity 404, of the risers 126, are fixedly provided with vertical blocks 124 respectively, wherein the vertical blocks 124 are in rotational engagement with the rotary rods 123; wherein end faces, close to the center line of the top box 130, of the risers 126, are fixedly provided with connecting plates 127 respectively; wherein each of the connecting plates 127 is in rotational engagement with a respective one of the connecting blocks 128.

Helpfully, open boxes 135 which are respectively distributed on the two sides embedded in two sides of the clamp plate 137; third open cavities 134, each of which has an upward opening, are set in the open boxes 135; side plates 133 fixedly arranged on end faces of the open boxes 135, wherein rotating blocks 132 are fixedly arranged on upper end faces of the side plates 133; turning covers 131 rotationally arranged in the rotating blocks 132, wherein the turning covers 131 abut against the open boxes 135; clamping cavities 204, each of which has opening to one side, are respectively set in end faces of the turning covers 131; side blocks 200 fixedly arranged on the other end faces of the open boxes 135, wherein connecting top cavities 202, each of which has an upward opening, are set in the side blocks 200, wherein sliding elastic cavities 201 are communicated with lower end walls of the connecting top cavities 202; sliding top blocks 203 sliadably arranged in the sliding elastic cavities 201 and the connecting top cavities 202, and the sliding top blocks 203 extend into the clamping cavities 204 and the sliding top blocks 203 are in sliding fit connection with the clamping cavities 204.

Helpfully, one side face of each of the slide plates 121 is in resilient fit with one side inner wall of a respective one of the spring cavities 120.

Helpfully, the distance between the risers 126 and the matrices 117 meets the requirement that the risers 126 extend into the containing cavities 118 and the risers 126 slide in the containing cavities 118; when the first motor 125 rotates, the first motor 125 can drive the symmetrical stretching rods 122 to move towards two sides respectively.

Helpfully, the lamp turning equipment, comprising a cushion pad 804; a fourth open cavity 806 fixedly arranged in the cushion pad 804; a transposition motor 803 fixedly arranged in one end wall of the fourth open cavity 806, wherein one end of the transposition motor 803 is in power connection with a driving gear 805, wherein a driven gear 802 is engaged with and set below the driving gear 805; a through rod 801 fixedly arranged on one end face of the driven gear 802, wherein the through rod 801 rotationally penetrates through the other end wall of the fourth open cavity 806 and extends out of the outer space; a platform 800 fixedly arranged on one end face of the through rod 801,wherein a lamp tube 807 is fixedly arranged on one end face of the platform 800.

When the equipment is in the initial state, the driving motor 101, the motor in the lower end wall of the top cavity 300, the driving and rotating motors 109, the pushing air cylinder 400 and the first motor 125 is all out of work, and the slide plates 121 are located in the middle of the spring cavities 120, and the rotating rods 105 are in the horizontal state, and the rotating plates 104 are in the upright state, and the risers 126 are in the vertical state.

When the equipment is operated, the sliding top blocks 203 are stirred to move to one side, so that the sliding top blocks 203 are separated from the matching with the clamping cavities 204; and then the turning covers 131 are turned over, so that the impression materials contained in the third open cavities 134 are exposed; and then the motor in the lower end wall of the top cavity 300 drives the sliding plate 138 to move downwards, so that the matrices 117 extend into the third open cavities 134; at this time, the driving and rotating motors 109 work to drive the sliding blocks 107 to move towards the direction which is close to the driving and rotating motors 109, and at this time, the sliding rods 112 slide in the sliding cavities 115 to enable the rotating handles 116 to rotate, and the matrices 117 is enabled to dig out the impression materials in the containing cavities 118; and then the pushing air cylinder 400 is operated to enable the top box 130 to move forwards, so that the top box 130 and the matrices 117 face to each other; and the first motor 125 is operated to drive the connecting blocks 128 to move to a corresponding position, and at the time the driving and rotating motors 109 drive the sliding blocks 107 to move towards the direction which is close to the driving and rotating motors 109 after the driving and rotating motors 109 work, so that the risers 126 slide into the containing cavities 118, and the impression materials in the containing cavities 118 are adhered to end faces, close to the matrices 117, of the risers 126, and the first motor 125 drives the connecting blocks 128 to be far away from each other after the first motor 125 works again, and the second motors 406 are operated to enable the connecting blocks 128 to rotate, so that the risers 126 face to each other; and then the first motor 125 drives the connecting sliding blocks 405 to be close to one another to enable the impression materials on end faces of the risers 126 to be mixed and adhered after the first motor 125 works; after the mixing and adhesion are completed, the first motor 125 drives the connecting sliding blocks 405 again to be far away from each other, so that workers can take down the impression materials which have been mixed and adhered.

The benefits of the invention are as follows: when the device is in the initial state, the driving motor, the motor in the lower end wall of the top cavity, the driving and rotating motors, the pushing air cylinder and the first motor is all out of work, and the slide plates are located in the middle of the spring cavities, and the rotating rods are in the horizontal state, and the rotating plates are in the upright state, and the risers are in the vertical state, so that the above structure is located at the initial position in the initial state, and can be adjusted in subsequent work, thereby effectively improving the work coordination of the equipment.

When the equipment is operated, the sliding top blocks are stirred to move to one side, so that the sliding top blocks are separated from the matching with the clamping cavities; and then the turning covers are turned over, so that the impression materials contained in the third open cavities are exposed; and then the motor in the lower end wall of the top cavity drives the sliding plate to move downwards, so that the matrices extend into the third open cavities; at this time, the driving and rotating motors work to drive the sliding blocks to move towards the direction which is close to the driving and rotating motors, and at this time, the sliding rods slide in the sliding cavities to enable the rotating handles to rotate, and the matrices are enabled to dig out the impression materials in the containing cavities; and then the pushing air cylinder is operated to enable the top box to move forwards, so that the top box and the matrices face to each other; and the second motors are operated to drive the connecting blocks to move to a corresponding position, and at the time the driving and rotating motors drive the sliding blocks to move towards the direction which is close to the driving and rotating motors after the driving and rotating motors work, so that the risers slide into the containing cavities, and the impression materials in the containing cavities are adhered to end faces, close to the matrices, of the risers, and the second motors drive the connecting blocks to be far away from each other after the second motors work again, and the second motors are operated to enable the connecting blocks to rotate, so that the risers face to each other; and then the second motors drive the connecting sliding blocks to be close to one another to enable the impression materials on end faces of the risers to be mixed and adhered after the second motors work; after the mixing and adhesion are completed, thesecond motors drive the connecting sliding blocks again to be far away from each other, so that workers can take down the impression materials which have been mixed and adhered, so that the repeated mixing and adhersion process of the impression materials can be realized in an automatic mode.

The equipment of the invention is simple in structure and convenient to use, as the equipment adopts an automatic mode, thereby realizing the kneading, mixing and adhesion process of the impression materials, and effectively reducing the labor burden of workers.

The above is only the specific embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any changes or substitutions without creative efforts shall fall within the protection scope of the present invention. Therefore, the claimed protection extent of the invention shall be determined with reference to the appended claims.

Claims (6)

Claims

1. A silicone rubber impression material equipment, comprising:

a clamp plate;

a vertical plate fixedly arranged on the upper end face of the clamp plate;

a top cavity up and down penetrated through the vertical plate;

a motor fixedly set in the lower end wall of the top cavity, wherein the upper end of the motor in the lower end wall of the top cavity is in rotational engagement with the upper end wall of the top cavity;

guide rails fixedly set on two end faces of the vertical plate;

sliders slidably arranged on outer faces of the guide rails;

a sliding plate arranged on one side of the vertical plate, wherein the sliding plate is fixed to the sliders;

wherein the sliding plate is in threaded fit connection with the upper end of the motor in the lower end wall of the top cavity;

a first open cavity penetrating through the sliding plate from one side to the other side set in the sliding plate;

a top block set above the sliding plate; a driving motor fixedly set in the lower end face of the top block, wherein the lower end of the driving motor is in threaded fit connection with the sliding plate and extends downwards;

symmetrical connecting rods fixedly set in the lower end face of the top block, wherein the connecting rods slidably penetrate through the sliding plate and extend into the first open cavity;

a base plate set in lower end faces of the connecting rods, wherein the lower end of the driving motor is in rotational fit connection with the base plate;

symmetrical communicated cavities, each of which has an upward opening, are fixedly set in the base plate, wherein rotating plates extending downwards are rotationally set in the communicated cavities;

wherein rotating rods are rotationally set in end faces of the rotating plates;

wherein ends of the rotating rods, away from the driving motor, are fixedly connected with connecting boxes, wherein L-shaped blocks are fixedly arranged on lower end faces of the connecting boxes;

inner cavities, each of which has a downward opening, are fixedly arranged in the connecting boxes, wherein end walls, away from the rotating rods, of the inner cavities, are fixedly provided with driving and rotating motors, wherein ends, close to the rotating rods, of the driving and rotating motors, are in rotational engagement with end walls of the inner cavities;

side rods arranged between the inner cavities;

sliding blocks slidably set on outer faces of the side rods, wherein the sliding blocks are in threaded fit connection with outer faces of output shafts of the driving and rotating motors;

sliding rods rotationally set in the sliding blocks;

rotating handles rotationally set on end faces of the L-shaped blocks, wherein upper end walls of the rotating handles are fixedly provided with sliding cavities, each of which has an upward opening, wherein the sliding cavities are in sliding fit connection with the sliding rods;

top columns fixedly arranged on end faces of the rotating handles;

annular rails fixedly arranged on end faces of the L-shaped blocks;

through slots which are communicated fixedly set in the annular rails, wherein the through slots are in sliding fit connection with the top columns; matrices fixedly arranged on lower end faces of the rotating handles, wherein containing cavities with openings are fixedly arranged in the matrices;

wherein a lamp turning equipment is fixedly arranged on the upper end face of the top block;

whereby when the driving motor rotates, the base plate can be driven to move up and down in the opening cavity, so that the connecting boxes can be driven to move up and down, so that the matrices can be driven to move up and down; meanwhile, the sliders can be driven to move towards two sides through the rotation of the driving and rotating motors, so as to drive the matrices to move towards two sides.

2. The silicone rubber impression material equipment of claim 1, wherein symmetrical rod cavities which are penetrated from one side to the other side are fixedly set in the sliding plate;

a pushing air cylinder is fixedly arranged in the sliding plate, wherein one end face of a push rod of the pushing air cylinder is fixedly provided with a top box, and symmetrical sliding rods are fixedly arranged on the other end face of the top box;

wherein the sliding rods are in sliding fit connection with the rod cavities;

a second open cavity is set in the top box ;

a first motor is fixedly arranged in one end wall of the second open cavity, wherein the first motor is in rotational fit connection with the other end wall of the second open cavity;

wherein the outer face of one end of the first motor is in threaded fit connection with symmetrical connecting sliding blocks, wherein second motors are fixedly arranged in end faces of the connecting sliding blocks respectively, wherein ends of the second motors are in a power matching connection with connecting blocks;

spring cavities are set in the connecting blocks;

slide plates are slidably arranged in the spring cavities, wherein end faces, far away from the center line of the second open cavity, of the slide plates, are fixedly connected with stretching rods, wherein the stretching rods slidably penetrate through the spring cavities and extend outwards;

wherein ends, far away from the spring cavities, of the stretching rods, are rotationally provided with rotary rods;

symmetrical risers are arranged at the other side of the top box, wherein end faces, close to the central line of the second open cavity, of the risers, are fixedly provided with vertical blocks respectively, wherein the vertical blocks are in rotational engagement with the rotary rods;

wherein end faces, close to the center line of the top box, of the risers, are fixedly provided with connecting plates respectively;

wherein each of the connecting plates is in rotational engagement with a respective one of the connecting blocks;

whereby after the second motors are operated, the connecting blocks are rotated, so that risers face to each other, and the second motors drive the connecting sliding blocks to be close to each other to enable the impression materials on the end faces of the risers to be mixed and adhered after the second motors are operated; after the mixing and adhesion are completed, the second motors drive the connecting sliding blocks to be far away from each other, and the impression is completed at the moment.

3. The silicone rubber impression material equipment of claim 1, wherein open boxes which are respectively distributed on two sides are embedded in two sides of the clamp plate;

third open cavities, each of which has an upward opening, are set in the open boxes;

side plates are fixedly arranged on end faces of the open boxes, wherein rotating blocks are fixedly arranged on upper end faces of the side plates;

turning covers are rotationally arranged in the rotating blocks, wherein the turning covers abut against the open boxes;

clamping cavities, each of which has an opening to one side, are respectively set in end faces of the turning covers;

side blocks are fixedly arranged on the other end faces of the open boxes, wherein connecting top cavities, each of which has an upward opening, are set in the side blocks, wherein sliding elastic cavities are communicated with lower end walls of the connecting top cavities;

sliding top blocks are sliadably arranged in the sliding elastic cavities and the connecting top cavities, and the sliding top blocks extend into the clamping cavities and the sliding top blocks are in sliding fit connection with the clamping cavities;

whereby openings on the upper ends of the third open cavities are closed when the turning covers are turned over, and the turning covers can be locked tightly by the cooperation between the sliding top blocks and the clamping cavities.

4. The silicone rubber impression material equipment of claim 2, wherein one side face of each of the slide plates is in a resilient fit with one side inner wall of a respective one of the spring cavities;

whereby when the slide plate are not subjected to a thrust to one side, the slide plates can move in the spring cavities which are far away from the cavity.

5. The silicone rubber impression material equipment of claim 2, wherein the distance between the risers and the matrices meets the requirement that the risers extend into the containing cavities and the risers slide in the containing cavities;

whereby when the first motor rotates, the first motor can drive the symmetrical stretching rods to move towards two sides respectively.

6. The silicone rubber impression material equipment of claim 1, wherein the lamp turning equipment comprises a cushion pad, a fourth open cavity fixedly arranged in the cushion pad and a transposition motor fixedly arranged in one end wall of the fourth open cavity;

wherein one end of the transposition motor is in power connection with a driving gear, wherein a driven gear is engaged with and set below the driving gear;

a through rod is fixedly arranged on one end face of the driven gear, wherein the through rod rotationally penetrates through the other end wall of the fourth open cavity and extends out of the outer space;

a platform is fixedly arranged on one end face of the through rod, wherein a lamp tube is fixedly arranged on one end face of the platform;

whereby when the transposition motor rotates, the driving gear can be driven to rotate, so that the through rod is driven to rotate through the driven gear, so that the lamp tube can be driven to rotate through the platform, and the lamp tube which is rotating can increase the illumination range.