CN215778795U - Zirconia artificial tooth processing instrument - Google Patents

Abstract

The utility model relates to the technical field of false tooth processing, and discloses a zirconia false tooth processing instrument. Through placing the board in the setting of sintering shell, place the artificial tooth through a plurality of standing grooves of seting up on placing the board for can sinter many artificial teeth simultaneously, dispel the heat to the artificial tooth after the sintering is accomplished through the radiator unit who sets up, accelerate the cooling rate of artificial tooth, promote machining efficiency.

Description

Zirconia artificial tooth processing instrument

Technical Field

The utility model relates to the technical field of denture processing, in particular to a zirconia denture processing instrument.

Background

The denture is what is commonly called a "denture". Just like "leg prosthesis" and "prosthetic limb" are referred to as "prosthetic limb", a "denture" means that the human being is "obligated" to the utmost. Medical science is a general term for restorations made after partial or complete tooth loss of the upper and lower teeth, and dentures are generally made of zirconia.

The artificial tooth is required to be sintered to improve the hardness and other properties of the artificial tooth in the manufacturing process, the artificial tooth is usually sintered by a sintering instrument, the conventional sintering instrument can only sinter one artificial tooth at a time, and after the conventional artificial tooth is sintered, the artificial tooth is naturally cooled to normal temperature usually, so that the waiting time is long, and the processing efficiency is low.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide a zirconia false tooth processing instrument which is used for sintering a plurality of false teeth simultaneously, accelerating the cooling speed of the false teeth and improving the processing efficiency.

In order to achieve the purpose, the utility model provides the following technical scheme: the utility model provides a zirconia artificial tooth processing instrument, includes the sintering shell, be provided with the door on the sintering shell, sliding connection places the board in the sintering shell, place the board with the door is close to the side fixed connection of sintering shell, place and seted up a plurality of standing grooves on the board, the standing groove all is used for placing the artificial tooth, be provided with radiator unit on the sintering shell, radiator unit is used for dispelling the heat to the artificial tooth.

As a further improvement of the present invention, the inner walls of the two opposite sides of the sintering casing are fixedly connected with slide rails, the length direction of the slide rails is parallel to the width direction of the sintering casing, the placing plate is slidably connected with the slide rails, the inner walls of the two opposite sides of the sintering casing are fixedly connected with two guide tubes, the length direction of the guide tubes is parallel to the width direction of the sintering casing, the guide tubes are slidably connected with guide rods, and one end of each guide rod close to the door is fixedly connected with the door.

As a further improvement of the present invention, the heat dissipation assembly includes a heat dissipation fan, an L-shaped rod is fixedly connected to the top surface of the sintering casing, the heat dissipation fan is fixedly connected to the L-shaped rod, an air outlet of the heat dissipation fan is vertically downward, and when the placing plate is moved out of the sintering casing, the heat dissipation fan is located above the placing plate.

As a further improvement of the present invention, an adsorption part is disposed on the sintered shell, the adsorption part is used for adsorbing the door to the sintered shell, the adsorption part comprises a first magnet, the first magnet is circumferentially disposed on the sintered shell, a second magnet is circumferentially disposed on the door, and the first magnet is matched with the second magnet.

As a further improvement of the utility model, a buffer plate is arranged in the sintering shell, a plurality of compression springs are arranged between the buffer plate and the sintering shell, when the placing plate moves into the sintering shell, the placing plate can be abutted against the buffer plate, and the compression springs are in a compressed state.

As a further improvement of the utility model, the top and the bottom of the sintering shell are both fixedly connected with a plurality of heating pipes, and the heating pipes are arranged in parallel.

As a further improvement of the utility model, an electric cabinet is arranged on the sintering shell, and the electric cabinet is electrically connected with the heating pipe and the cooling fan.

As a further improvement of the utility model, the sintering shell is provided with a heat-insulating layer, the bottom of the sintering shell is provided with a plurality of universal wheels, and the door is provided with a handle.

The utility model has the beneficial effects that: according to the utility model, the placing plate is arranged in the sintering shell, and false teeth are placed in the placing grooves formed in the placing plate, so that a plurality of false teeth can be sintered at the same time; the false tooth after sintering is cooled through the arranged cooling assembly, so that the cooling speed of the false tooth is increased, and the processing efficiency is improved.

Drawings

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

FIG. 2 is a schematic top cross-sectional structural view of the present invention;

FIG. 3 is a schematic cross-sectional structural view of the present invention;

fig. 4 is a sectional view schematically showing the door of the present invention in an opened state.

Reference numerals: 1. sintering the shell; 2. a door; 3. placing the plate; 4. a placement groove; 5. a heat dissipating component; 51. a heat radiation fan; 6. a slide rail; 7. a guide tube; 8. a guide bar; 9. an L-shaped rod; 10. a first magnet; 11. a second magnet; 12. a buffer plate; 13. a compression spring; 14. heating a tube; 15. an electric cabinet; 16. a heat-insulating layer; 17. a universal wheel; 18. a handle.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples. In which like parts are designated by like reference numerals. It should be noted that the terms "front," "back," "left," "right," "upper" and "lower" used in the following description refer to directions in the drawings, and the terms "bottom" and "top," "inner" and "outer" refer to directions toward and away from, respectively, the geometric center of a particular component.

Referring to fig. 1 to 4, the zirconia artificial tooth processing instrument of this embodiment, including sintering shell 1, be provided with door 2 on sintering shell 1, sliding connection places board 3 in sintering shell 1, place board 3 and door 2 and be close to the side fixed connection of sintering shell 1, equal fixedly connected with slide rail 6 on the relative both sides inner wall of sintering shell 1, the length direction of slide rail 6 is parallel to each other with the width direction of sintering shell 1, place board 3 and slide rail 6 sliding connection, equal two stand pipes 7 of fixedly connected with on the relative both sides inner wall of sintering shell 1, the length direction of stand pipe 7 is parallel to each other with the width direction of sintering shell 1, sliding connection has guide bar 8 in stand pipe 7, the one end and door 2 fixed connection of guide bar 8 near door 2. Operating personnel removes door 2, and the removal drive through door 2 places board 3 and slides between two slide rails 6, drives guide bar 8 simultaneously and slides in stand pipe 7, places board 3 and guide bar 8 and can remove outside sintering shell 1 or the sintering shell, is convenient for place or take off the artificial tooth on placing board 3.

Place and seted up a plurality of standing grooves 4 on the board 3, standing groove 4 all is used for placing the artificial tooth. False teeth are placed through a plurality of placing grooves 4 formed in the placing plate 3, so that the false teeth can be sintered simultaneously, and the efficiency is improved. The top and the bottom of the sintering shell 1 are both fixedly connected with a plurality of heating pipes 14, and the heating pipes 14 are arranged in parallel. The top and the bottom of the sintering shell 1 are respectively and fixedly connected with three heating pipes 14, so that the sintering speed of the false tooth is high, and the sintering is uniform.

Be provided with the absorption portion on the sintering shell 1, the absorption portion is used for adsorbing door 2 on sintering shell 1 for when door 2 was closed, there was not the gap between door 2 and the sintering shell 1, makes the sintering effect of artificial tooth better. The adsorption part comprises a first magnet 10, the first magnet 10 is circumferentially arranged on the sintering shell 1, and the first magnet 10 is fixedly connected with the sintering shell 1. The circumference is provided with second magnet 11 on the door 2, second magnet 11 and door 2 fixed connection, and first magnet 10 and 11 looks adaptations of second magnet, and first magnet 10 and 11 magnetism of second magnet are opposite, and when door 2 closed, first magnet 10 and 11 mutual absorption of second magnet, do not have the gap between door 2 and the sintering shell 1 for the sintering effect of artificial tooth is better.

Be provided with buffer board 12 in the sintering shell 1, be provided with a plurality of compression spring 13 between buffer board 12 and the sintering shell 1, compression spring 13's quantity sets up to four, and compression spring 13 fixed connection is between buffer board 12 and sintering shell 1, when placing board 3 and move into sintering shell 1, places board 3 and can offset with buffer board 12, and compression spring 13 is in compression state. When door 2 lid closes on sintering shell 1, place board 3 and offset with buffer board 12, and compression spring 13 all is in compression state, produces the supporting role to placing board 3 for it is more stable in sintering shell 1 to place board 3.

The sintering shell 1 is provided with a heat dissipation component 5, and the heat dissipation component 5 is used for dissipating heat of the false tooth. The false tooth after sintering is cooled through the arranged heat dissipation assembly 5, so that the cooling speed of the false tooth is increased, and the processing efficiency is improved. The heat dissipation assembly 5 comprises a heat dissipation fan 51, the top surface of the sintering shell 1 is fixedly connected with an L-shaped rod 9, the heat dissipation fan 51 is fixedly connected to the L-shaped rod 9, an air outlet of the heat dissipation fan 51 is vertically downward, and when the placing plate 3 is moved out of the sintering shell 1, the heat dissipation fan 51 is positioned above the placing plate 3. After the artificial tooth sintering is accomplished, operating personnel outwards stimulates door 2, the removal drive through door 2 places board 3 and slides between two slide rails 6, it slides in stand pipe 7 to drive guide bar 8 simultaneously, place board 3 and guide bar 8 and all move to sintering shell 1 outward, until standing groove 4 exposes in sintering shell 1, radiator fan 51 is located and places board 3 top, stop to stimulate door 2, radiator fan 51 begins work this moment, radiator fan 51's wind dispels the heat to the artificial tooth, operating personnel takes out the artificial tooth from standing groove 4 after the heat dissipation is accomplished.

An electric cabinet 15 is arranged on the sintering shell 1, the electric cabinet 15 is fixedly connected to the sintering shell 1, and the electric cabinet 15 is electrically connected with the heating pipe 14 and the cooling fan 51. The heating pipe 14 and the cooling fan 51 are controlled to work through the electric cabinet 15, so that the heating pipe 14 and the cooling fan 51 are conveniently controlled, and the sintering and cooling efficiency is improved.

Be provided with heat preservation 16 on the sintering shell 1, heat preservation 16 sets up to the pearl cotton, and the pearl is cotton with sintering shell 1 fixed connection, and the heat in the sintering shell 1 reduces outwards giving off when making the sintering through the heat preservation 16 that sets up for sintering speed. A plurality of universal wheels 17 are arranged at the bottom of the sintering shell 1, the number of the universal wheels 17 is four, the universal wheels 17 are fixedly connected with the sintering shell 1, and the sintering shell 1 can be moved to any position to work through the universal wheels 17. The door 2 is provided with a handle 18, the handle 18 is fixedly connected with the door 2, and the handle 18 is convenient for an operator to hold and move the door 2.

The working principle is as follows: when the false teeth are required to be sintered, an operator holds the handle 18 to pull the door 2 outwards, the first magnet 10 on the sintering shell 1 and the second magnet 11 on the door 2 are separated from each other, the placing plate 3 is driven to slide between the two sliding rails 6 through the movement of the door 2, the guide rod 8 is driven to slide in the guide pipe 7, the placing plate 3 and the guide rod 8 both move towards the outside of the sintering shell 1 until the placing groove 4 is exposed out of the sintering shell 1, the door 2 is stopped to be pulled, and the operator places the false teeth in the placing groove 4;

after the placement is finished, an operator pushes the door 2 inwards, the placing plate 3 is driven to slide between the two sliding rails 6 through the movement of the door 2, the guide rod 8 is driven to slide in the guide pipe 7, the placing plate 3 and the guide rod 8 both move towards the sintering shell 1 until a first magnet 10 on the sintering shell 1 and a second magnet 11 on the door 2 are mutually attracted, the door 2 is covered on the sintering shell 1, the placing plate 3 abuts against the buffer plate 12 at the moment, and the compression springs 13 are in a compressed state;

at the moment, the false tooth can be sintered, the heating pipe 14 is controlled to work through the electric cabinet 15, the heating pipe 14 is used for sintering the false tooth, and when the sintering is finished, the heating pipe 14 is controlled to stop working through the electric cabinet 15;

after the artificial tooth sintering is completed, an operator holds the handle 18 to pull the door 2 outwards, the first magnet 10 on the sintering shell 1 and the second magnet 11 on the door 2 are separated from each other, the placing plate 3 is driven to slide between the two sliding rails 6 through the movement of the door 2, the guide rod 8 is driven to slide in the guide pipe 7 simultaneously, the placing plate 3 and the guide rod 8 both move outwards to the sintering shell 1 until the placing groove 4 is exposed out of the sintering shell 1, the door 2 stops being pulled, the heat dissipation fan 51 is controlled to start working through the electric cabinet 15 at the moment, the wind of the heat dissipation fan 51 dissipates heat to the artificial tooth, and the operator takes out the artificial tooth from the placing groove 4 after the heat dissipation is completed.

The above is only a preferred embodiment of the present invention, and the protection scope of the present invention is not limited to the above-mentioned embodiments, and all technical solutions belonging to the idea of the present invention belong to the protection scope of the present invention. It should be noted that modifications and embellishments within the scope of the utility model may occur to those skilled in the art without departing from the principle of the utility model, and are considered to be within the scope of the utility model.

Claims (8)

1. A zirconia artificial tooth processing instrument is characterized in that: including sintering shell (1), be provided with door (2) on sintering shell (1), sliding connection places board (3) in sintering shell (1), place board (3) with door (2) are close to the side fixed connection of sintering shell (1), place and seted up a plurality of standing grooves (4) on board (3), standing groove (4) all are used for placing the artificial tooth, be provided with radiator unit (5) on sintering shell (1), radiator unit (5) are used for dispelling the heat to the artificial tooth.

2. The zirconia dental prosthesis machining apparatus according to claim 1, wherein: equal fixedly connected with slide rail (6) on the relative both sides inner wall of sintering shell (1), the length direction of slide rail (6) with the width direction of sintering shell (1) is parallel to each other, place board (3) with slide rail (6) sliding connection, equal two stand pipes (7) of fixedly connected with on the relative both sides inner wall of sintering shell (1), the length direction of stand pipe (7) with the width direction of sintering shell (1) is parallel to each other, sliding connection has guide bar (8) in stand pipe (7), guide bar (8) are close to the one end of door (2) with door (2) fixed connection.

3. The zirconia dental prosthesis machining apparatus according to claim 2, wherein: the heat dissipation assembly (5) comprises a heat dissipation fan (51), an L-shaped rod (9) is fixedly connected to the top surface of the sintering shell (1), the heat dissipation fan (51) is fixedly connected to the L-shaped rod (9), an air outlet of the heat dissipation fan (51) is vertically downward, and when the placing plate (3) is moved out of the sintering shell (1), the heat dissipation fan (51) is located above the placing plate (3).

4. The zirconia dental prosthesis machining apparatus according to claim 1, wherein: be provided with the adsorption part on sintering shell (1), the adsorption part be used for with door (2) adsorbs on sintering shell (1), the adsorption part includes first magnet (10), first magnet (10) circumference sets up on sintering shell (1), circumference is provided with second magnet (11) on door (2), first magnet (10) with second magnet (11) looks adaptation.

5. The zirconia dental prosthesis machining apparatus according to claim 2, wherein: be provided with buffer board (12) in sintering shell (1), buffer board (12) with be provided with a plurality of compression spring (13) between sintering shell (1), work as place board (3) and move into when sintering shell (1), place board (3) can with buffer board (12) offset, just compression spring (13) are in compression state.

6. The zirconia dental prosthesis machining apparatus according to claim 3, wherein: the top and the bottom of the sintering shell (1) are both fixedly connected with a plurality of heating pipes (14), and the heating pipes (14) are arranged in parallel.

7. The zirconia dental prosthesis machining apparatus according to claim 6, wherein: an electric cabinet (15) is arranged on the sintering shell (1), and the electric cabinet (15) is electrically connected with the heating pipe (14) and the cooling fan (51).

8. The zirconia dental prosthesis machining apparatus according to claim 1, wherein: the door is characterized in that a heat insulation layer (16) is arranged on the sintering shell (1), a plurality of universal wheels (17) are arranged at the bottom of the sintering shell (1), and a handle (18) is arranged on the door (2).

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