CN213346091U - False tooth processing equipment - Google Patents

Abstract

The utility model provides false tooth processing equipment, which comprises a frame, a material taking mechanism, a processing main shaft, a driving mechanism and a dust collection system; the machine frame is provided with a processing cavity, a protective plate assembly is arranged in the processing cavity, and the protective plate assembly divides the processing cavity into a cutting chamber and a material chamber which are communicated; the driving mechanism is connected with the material taking mechanism and is used for driving the material taking mechanism to move back and forth between the cutting chamber and the material chamber; the material taking mechanism is arranged on the rack and used for transferring the false teeth to be processed in the material chamber to the cutting chamber and transferring the processed false teeth from the cutting chamber to the material chamber; the processing main shaft is used for processing the false tooth to be processed transferred by the material taking mechanism; dust suction ports are formed in the lower end and the rear face of the cutting chamber, and the dust suction system is connected with the dust suction ports. The dust suction port is arranged at the lower end of the cutting chamber, so that the cutting chamber forms downward suction, and falling dust is sucked out from the dust suction port under the dual functions of gravity and dust suction, so that the problem of accumulation of the dust in the cutting chamber is avoided.

Description

False tooth processing equipment

Technical Field

The utility model relates to an artificial tooth processing technology field especially relates to an artificial tooth processing equipment.

Background

In the denture structure processing process, dry cutting processing is required, and the existing denture processing equipment is also generally provided with a cutting chamber, and a dust suction interface is arranged in the cutting chamber; however, in the denture processing equipment, a dust suction port is usually arranged on the side surface of a processing spindle, but the arrangement mode causes the problem that the falling dust cannot be sucked away from a cutting chamber in time during processing, and the dust is accumulated in the cutting chamber. Therefore, how to discharge the dust in time becomes an urgent problem to be solved in the dry cutting process of the denture processing equipment.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model lies in, to prior art's above-mentioned defect, provide an artificial tooth processing equipment, aim at solving among the prior art artificial tooth dry cutting man-hour, the problem of the indoor dust of artificial tooth processing equipment cutting.

The utility model provides a technical scheme that technical problem adopted as follows: a denture manipulation apparatus, comprising: the device comprises a rack, a material taking mechanism, a processing main shaft, a driving mechanism and a dust collection system; the machine frame is provided with a machining cavity, a protection plate assembly is arranged in the machining cavity, and the protection plate assembly divides the machining cavity into a cutting chamber and a material chamber which are communicated; the driving mechanism is connected with the material taking mechanism and is used for driving the material taking mechanism to move back and forth between the cutting chamber and the material chamber; the material taking mechanism is arranged on the rack and used for transferring the false teeth to be processed in the material chamber to the cutting chamber and transferring the processed false teeth from the cutting chamber to the material chamber; the processing main shaft is used for processing the false tooth to be processed transferred by the material taking mechanism; dust absorption openings are formed in the lower end and the rear face of the cutting chamber, and the dust absorption system is connected with the dust absorption openings.

Furthermore, the protection plate assembly is provided with a protection plate capable of ascending and descending, and the protection plate is used for isolating the cutting chamber and the material chamber;

when the protection plate is located at the lower limit position, the protection plate is located at the lowest point, and the material taking mechanism moves between the cutting chamber and the material chamber; when the protection plate is located at the upper limit position, the protection plate is located at the highest point, the protection plate isolates the cutting chamber from the material chamber, and the machining spindle performs cutting machining on the false tooth to be machined in the cutting chamber.

Furthermore, the protection plate assembly is also provided with a protection plate cylinder and a double linear guide rail; the double-linear guide rail is arranged on a side plate of the processing cavity along the vertical direction, and two opposite side edges of the protection plate are connected to the double-linear guide rail in a sliding manner; and a push rod of the protection plate air cylinder is fixed on the protection plate and used for pushing the protection plate to lift along the double linear guide rails.

Further, when the protection plate is in the upper limit position, the protection plate is provided with a space with a top plate of the machine frame, and the space is used for air to enter the cutting chamber.

Further, the cutting chamber is provided with a processing jig, and the processing jig is used for fixing the material;

the dust absorption mouth includes main dust absorption mouth and supplementary dust absorption mouth, main dust absorption interface set up in the lower extreme of processing tool, supplementary dust absorption interface set up in processing tool rear end.

Further, an air inlet is formed in the left side face of the rack at the material chamber;

further, the driving mechanism comprises an X-axis driving component, a Y-axis driving component, a first Z-axis driving component and a second Z-axis driving component;

the X-axis driving assembly is used for driving the material taking mechanism and the machining main shaft to move along the X-axis direction;

the Y-axis driving assembly is used for driving the material taking mechanism and the machining main shaft to move along the Y-axis direction;

the first Z-axis driving assembly is used for driving the material taking mechanism to move along the Z-axis direction;

the second Z-axis driving component is used for driving the processing main shaft to move along the Z-axis direction.

Furthermore, the material taking mechanism and the processing main shaft are arranged on the Y-axis driving assembly side by side;

the Y-axis driving component is arranged on the X-axis driving component; the X-axis driving assembly is mounted on the upper end face of the rack.

Furthermore, the X-axis driving assembly and the Y-axis driving assembly are both set to be double linear guide rail assemblies;

the driving mechanism further comprises a frame-shaped mounting seat, and the Y-axis driving component is mounted on the upper end face of the frame-shaped mounting seat;

the lower end face of the frame-shaped mounting seat is mounted on the X-axis driving assembly;

further, the material taking mechanism and the processing main shaft are integrally arranged;

the first Z-axis driving assembly is arranged as a spline lead screw assembly, the material taking mechanism is arranged at the lower end of the spline lead screw assembly and used for taking materials from a material frame of the material chamber and placing the materials on the machining jig of the cutting chamber, and after machining is finished, the materials are taken down from the machining jig of the cutting chamber and placed back on the material frame of the material chamber;

the second Z-axis driving assembly is a screw nut assembly and comprises a Z-axis guide rail and a Z-axis sliding body, a sliding block is arranged on the Z-axis guide rail, and the Z-axis sliding body is arranged on the sliding block of the Z-axis guide rail;

the processing main shaft is fixed on the Z-axis sliding body and is driven by the lead screw nut assembly to move up and down.

Compared with the prior art, the utility model provides false tooth processing equipment, which comprises a frame, a material taking mechanism, a processing main shaft, a driving mechanism and a dust collection system; the machine frame is provided with a processing cavity, a protective plate assembly is arranged in the processing cavity, and the protective plate assembly divides the processing cavity into a cutting chamber and a material chamber which are communicated; the driving mechanism is connected with the material taking mechanism and is used for driving the material taking mechanism to move back and forth between the cutting chamber and the material chamber; the material taking mechanism is arranged on the rack and used for transferring the false teeth to be processed in the material chamber to the cutting chamber and transferring the processed false teeth from the cutting chamber to the material chamber; the processing main shaft is used for processing the false tooth to be processed transferred by the material taking mechanism; dust absorption openings are formed in the lower end and the rear face of the cutting chamber, and the dust absorption system is connected with the dust absorption openings. It can be understood that the utility model provides an artificial tooth processing equipment, cutting room lower extreme and the dust absorption mouth has been seted up at the back for the cutting room forms decurrent suction through setting up the dust absorption mouth in the lower extreme of cutting room, and the dust that drops is under the dual function of gravity and dust absorption, from main dust absorption mouth suction, has avoided the dust in the indoor accumulational problem of cutting. Meanwhile, the dust suction port is arranged behind the cutting chamber, backward suction is formed in the cutting chamber, dust suspended in air in the cutting chamber is sucked out from the dust suction port under the action of the suction force, and the problem that the machine is quickly abraded due to the fact that the suspended dust is lifted to a moving part is solved.

Drawings

Fig. 1 is a schematic perspective view of a denture processing apparatus according to the present invention;

fig. 2 is a partially cut-away rear side view of a denture machine provided in the present invention;

fig. 3 is a schematic perspective view of another perspective view of a denture processing apparatus provided in the present invention;

FIG. 4 is an enlarged view of the portion A of FIG. 2 according to the present invention;

fig. 5 is a schematic top view of a denture processing apparatus provided in the present invention;

fig. 6 is a perspective view of the matching relationship between the material taking mechanism, the processing spindle and the driving mechanism in the denture processing device provided by the present invention.

Fig. 7 is a perspective view illustrating a matching relationship between a material-taking mechanism and a first Z-axis driving assembly of the denture processing apparatus according to the present invention;

description of reference numerals:

10. a denture processing device; 11. a frame; 12. a guard plate assembly; 13. a material taking mechanism; 14. processing a main shaft; 15. a drive mechanism; 16. a dust suction port; 17. a dust outlet; 111. a processing cavity; 112. a cutting chamber; 113. a material chamber; 114. an organ shield; 115. a base plate; 116. a rear side plate; 117. spacing; 118. processing a jig; 119. a tool magazine rack; 110. a material rack; 121. a protection plate; 131. a connecting seat; 132. a material taking hand; 133. an inductive sensor; 134. a positioning column; 135. an expansion column; 141. A spindle motor; 142. a main shaft clamping seat; 151. an X-axis drive assembly; 152. a Y-axis drive assembly; 153. a first Z-axis drive assembly; 154. a second Z-axis drive assembly; 155. a frame-shaped mounting seat; 156. a spline lead screw assembly; 157. an X-axis power element; 158. a Y-axis power element; 159. a Z-axis sliding body; 161. an air inlet; 162. an auxiliary dust suction port; 163. the main dust suction port.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention clearer and clearer, the present invention will be described in further detail below with reference to the accompanying drawings and examples. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1, 2 and 3, a first embodiment of the present invention provides a denture processing apparatus 10, comprising: the device comprises a rack 11, a material taking mechanism 13, a processing main shaft 14, a driving mechanism 15 and a dust collection system; the machine frame 11 is provided with a closed machining cavity 111, a protection plate assembly 12 is arranged in the machining cavity 111, the machining cavity 111 is divided into a cutting chamber 112 and a material chamber 113 which are communicated through the protection plate assembly 12, cutting machining is performed in the cutting chamber 112, a material frame 110 and a tool magazine frame 119 are arranged in the material chamber 113, the material frame 110 bears false teeth to be machined, and the tool magazine frame 119 bears tools for machining.

The driving mechanism 15 is connected with the material taking mechanism 13 and the processing spindle 14, is used for driving the material taking mechanism 13 to move back and forth between the cutting chamber 112 and the material chamber 113, and is used for driving the processing spindle 14 to move, and is arranged on the outer end face of the organ protection cover 114 of the rack 11; that is, the driving mechanism 15 is disposed at the upper portion of the organ guard 114 at the upper end of the frame 11; the material taking mechanism 13 is arranged on the frame 11, and the material taking mechanism 13 is used for moving materials, that is, the material taking mechanism 13 is used for moving the denture to be processed in the material chamber 113 to the cutting chamber 112, and moving the denture to be processed in the cutting chamber 112 to the material chamber 113.

The machining spindle 14 is used for machining a denture, and particularly, the machining spindle 14 is used for machining a denture in the cutting chamber 112; further, a dust outlet 17 is formed in the lower end of the cutting chamber 112, a dust suction port 16 is formed in the lower end and the rear of the cutting chamber 112, the dust suction port 16 is communicated with the dust outlet 17, and the dust suction system is communicated with the dust suction port 16;

further, the dust suction port 16 includes a main dust suction port 163 and an auxiliary dust suction port 162, the main dust suction port 163 is disposed at the dust outlet 17, and the auxiliary dust suction port 162 is disposed behind the cutting chamber 112; specifically, the main dust suction port 163 is disposed on the bottom plate 115 at the opposite lower end of the cutting chamber 112, that is, the main dust suction port 163 is disposed at the bottom of the frame 11 and corresponds to the lower end of the processing fixture 118; the auxiliary dust suction port 162 is arranged at the rear end of the processing jig 118; it should be noted that the dust collection system may be a vacuum pump, and after the dust collection port 163 is connected, a negative pressure or a vacuum may be formed in the cutting chamber 112 of the frame 11, which is not described in detail herein.

It can be understood that the denture processing device 10 provided in the present invention, by providing the main suction port 163 at the lower end of the cutting chamber 112, allows the cutting chamber 112 to form a downward suction force, and the falling dust is sucked out from the main suction port 163 under the dual actions of gravity and dust suction, thereby avoiding the problem of dust accumulation in the cutting chamber 112. The auxiliary dust suction port 162 is arranged behind the cutting chamber 112, and backward suction is formed in the cutting chamber 112, so that dust suspended in air in the cutting chamber 112 is sucked out from the auxiliary dust suction port 162 under the action of the suction force, and the problem that the machine is quickly abraded due to the fact that the suspended dust is lifted to moving parts is solved.

Referring further to fig. 4, in some embodiments, the shielding plate assembly 12 is provided with a shielding plate 121 capable of ascending and descending, and the shielding plate 121 is used for isolating the cutting chamber 112 and the material chamber 113; the protection plate 121 has a certain lifting stroke, namely, an upper limit position and a lower limit position, and is moved and switched between the upper limit position and the lower limit position; when the protection plate 121 is at the lower limit position, the protection plate 121 is at the lowest point, and the material taking mechanism 13 moves between the cutting chamber 112 and the material chamber 113; when the protection plate 121 is at the upper limit position, the protection plate 121 is at the highest point, the protection plate 121 isolates the cutting chamber 112 from the material chamber 113, and the machining spindle 14 performs cutting machining on the denture to be machined in the cutting chamber 112.

As can be understood, the protective plate 121 is arranged, so that dust can be effectively prevented from entering the material chamber 113, and the dust is prevented from polluting materials and cutters; meanwhile, the space of the cutting chamber 112 is reduced, and the dust collection effect of the equipment is further effectively improved.

In some preferred embodiments, the fender assembly 12 is further provided with a fender cylinder and a dual linear guide; the double linear guide rails are vertically arranged on a base of the protection component 12, and two side edges of the protection plate 121 are connected to the double linear guide rails; the push rod of the protection plate cylinder is fixed on the protection plate 121 and used for pushing the protection plate 121 to lift along the double-linear guide rail; the guard plate cylinder and the double linear guide are used for switching the guard plate 121 between the upper limit outer and lower limit positions. It is understood that, when the cutting chamber 112 performs the denture cutting process, the air cylinder pushes the protection plate 121 to rise to the upper limit position, and when the denture cutting process is completed, the air cylinder pushes the protection plate 121 to return to the lower limit position, so that the material taking mechanism 13 and the processing spindle 14 reciprocate between the cutting chamber 112 and the material chamber 113.

In other preferred embodiments, when the protection plate 121 is in the upper limit position, the protection plate 121 is provided with a space 117 from the top plate 114 of the machine frame 11, the space 117 being used for air to enter the cutting chamber 112. The size of the gap 117 is 1-3 cm; the space 117 is only used for gas to enter the cutting chamber 112, and meanwhile, the gas enters the cutting chamber 112 from the material chamber 113 during cutting by reserving the space 117, so that dust is prevented from entering the material chamber 113.

Further, an air inlet 161 is formed in the side surface of the frame 11 at the position of the material chamber 113; specifically, an air inlet 161 is formed in the left side surface of the frame 11 at the material chamber 113. It will be appreciated that when a dental prosthesis is being manufactured, the gas enters the material chamber 113 from the gas inlet 161 and then enters the cutting chamber 112 via the partition 117 and exits the cutting chamber 112 with the dust via the suction system.

In other preferred embodiments, the cutting chamber 112 is provided with a processing fixture 118, the processing fixture 118 is used for fixing the material, and the main dust suction port 163 is disposed at a lower end of the processing fixture 118. It should be noted that the height of the auxiliary dust suction port 162 is not higher than the height of the processing jig 118 in the cutting chamber 112, so as to effectively avoid the problem that dust in the air of the cutting chamber 112 flows to the moving parts above the machine frame along with the air.

In other embodiments, the drive mechanism 15 includes an X-axis drive assembly 151, a Y-axis drive assembly 152, a first Z-axis drive assembly 153, and a second Z-axis drive assembly 154; the X-axis driving assembly 151 is used for driving the material taking mechanism 13 and the processing spindle 14 to move along the X-axis direction; the Y-axis driving assembly 152 is used for driving the material taking mechanism 13 and the processing spindle 14 to move along the Y-axis direction; the first Z-axis driving component 153 is configured to drive the material taking mechanism 13 to move along the Z-axis direction; the second Z-axis driving assembly 154 is used for driving the processing spindle 14 to move along the Z-axis direction.

It should be noted that the material taking operation and the machining operation are not performed synchronously in the denture cutting process; it is to be appreciated that the denture processing apparatus 10 provided in the present invention is constructed by sharing the X-axis drive assembly 151 and the Y-axis drive assembly 152 with the material extracting mechanism 13 and the processing spindle 14; compared with the prior art that the material taking mechanism 13 and the machining main shaft 14 are separately provided with the three-axis driving mechanism 15, the structure complexity of the denture machining equipment 10 is obviously reduced, the number of parts and the device cost are effectively reduced, and the stability of the denture machining equipment 10 is obviously improved.

Further, the material taking mechanism 13 and the processing spindle 14 are mounted on the Y-axis driving assembly 152 side by side; the Y-axis driving assembly 152 is mounted on the X-axis driving assembly 151; the X-axis driving assembly 151 is mounted to an upper end of the frame 11.

Referring to fig. 5, in some embodiments, the X-axis driving assembly 151 and the Y-axis driving assembly 152 are both configured as a dual linear guide assembly; the double-linear guide rail mechanism comprises linear guide rails which are parallel to each other and a sliding block which is connected to the linear guide rails in a sliding manner; further, the driving mechanism 15 further includes a frame-shaped mounting seat 155, and the Y-axis driving assembly 152 is mounted on an upper end surface of the frame-shaped mounting seat 155; the lower end surface of the frame-shaped mounting seat 155 is mounted on the X-axis driving assembly 151; the material taking mechanism 13 and the processing spindle 14 are mounted on the frame-shaped mounting seat 155. That is, the X-axis driving assembly 151 drives the Y-axis driving assembly 152, the material taking mechanism 13 and the processing spindle 14 to move along the X-axis direction by driving the frame-shaped mounting seat 155; further, through setting up the frame type mounting bracket, and then the realization will extracting mechanism 13 and processing main shaft 14 install side by side in proper order on Y axle drive assembly 152.

Further, the X-axis driving assembly 151 further includes an X-axis power element 157, the X-axis power element 157 is set as a motor nut lead screw assembly, and the motor nut lead screw assembly includes an X-axis motor, an X-axis lead screw nut, and an X-axis lead screw; the X-axis motor drives the X-axis screw rod to rotate, and the X-axis screw rod nut is fixedly connected to the sliding block or the frame-shaped mounting seat 155.

Correspondingly, the Y-axis driving assembly 152 further comprises a Y-axis power element 158, the Y-axis power element 158 is a motor nut lead screw assembly, and the motor nut lead screw assembly comprises a Y-axis motor, a Y-axis lead screw nut and a Y-axis lead screw; the Y-axis motor drives the Y-axis screw rod to rotate, and the Y-axis screw rod nut is fixedly connected with the sliding block or the material taking mechanism 13 and the mounting seat of the machining main shaft 14.

Referring further to fig. 6 and 7, in other preferred embodiments, the material taking mechanism 13 and the processing spindle 14 are integrally formed; the first Z-axis driving assembly 153 is arranged as a spline screw rod assembly 156, the material taking mechanism 13 is arranged at the lower end of the spline screw rod assembly 156, and is used for taking down materials from the material rack 110 of the material chamber 113 and placing the materials on the processing jig 118 of the cutting chamber 112, and after the processing is finished, taking down the materials from the processing jig 118 of the cutting chamber 112 and placing the materials back on the material rack 110 of the material chamber 113; the second Z-axis driving assembly 151 is a screw nut assembly and comprises a Z-axis guide rail and a Z-axis sliding body 159, a sliding block is arranged on the Z-axis guide rail, and the Z-axis sliding body 159 is arranged on the sliding block of the Z-axis guide rail; the machining spindle 14 is fixed to the Z-axis slide 159 and is driven by a lead screw nut assembly to move up and down.

It can be understood that, by integrally providing the material taking mechanism 13 and the processing spindle 14, a guarantee is provided for the material taking mechanism 13 and the processing spindle 14 to share the X-axis driving assembly 151 and the Y-axis driving assembly 152.

In other preferred embodiments, in some preferred implementations, the material taking mechanism 13 includes a connecting seat 131 and a material taking hand 132, and the connecting seat 131 is used for mounting the material taking hand 132 on the first Z-axis driving assembly 153.

Further, the material taking hand 132 comprises an induction sensor 133, an expansion column 135 and a positioning column 134 which are arranged on the connecting seat 131 along the Z-axis direction. It will be appreciated that the inductive sensor 133 can sense whether material is being taken or dropped, by effectively holding the material by the simultaneous expansion column 135; through setting up reference column 134, and then the effectual material precision and the efficiency of getting of having promoted feeding agencies 13, the upper end of reference column 134 is provided with the trachea and connects 136, the reference column 114 below leaves the mouth of blowing, clears up the dust on the material through blowing before getting the material.

Compared with the prior art, the utility model provides false tooth processing equipment, which comprises a frame provided with a closed processing cavity; the cutting chamber and the material chamber are arranged in the processing cavity of the rack, and the protection plate assembly is used for isolating the cutting chamber from the material chamber; the material taking mechanism is used for moving and taking materials; a processing spindle for processing the denture; the driving mechanism is arranged on the outer end face of the top plate of the rack and is used for driving the material taking mechanism and the machining main shaft to move; and set up in cutting room lower extreme and back have seted up the dust absorption mouth, the dust absorption mouth intercommunication dust collecting system is through setting up main dust absorption interface in the lower extreme of cutting room for the cutting room forms decurrent suction, and the dust that drops is under the dual function of gravity and dust absorption, from main dust absorption mouth suction, has avoided the accumulational problem of dust in the cutting room. The auxiliary dust collection interface is arranged behind the cutting chamber, backward suction is formed in the cutting chamber, dust suspended in air in the cutting chamber is sucked out from the auxiliary dust collection interface under the action of the suction force, the problem that the machine is quickly abraded due to the fact that the suspended dust is lifted to a moving part is avoided, and the service life of the false tooth machining equipment is prolonged.

It is to be understood that the invention is not limited to the above-described embodiments, and that modifications and variations may be made by those skilled in the art in light of the above teachings, and all such modifications and variations are intended to be included within the scope of the invention as defined in the appended claims.

Claims (10)

1. A denture manipulation apparatus, comprising:

the device comprises a rack, a material taking mechanism, a processing main shaft, a driving mechanism and a dust collection system;

the machine frame is provided with a machining cavity, a protection plate assembly is arranged in the machining cavity, and the protection plate assembly divides the machining cavity into a cutting chamber and a material chamber which are communicated;

the driving mechanism is connected with the material taking mechanism and the processing main shaft and is used for driving the material taking mechanism to move back and forth between the cutting chamber and the material chamber;

the material taking mechanism is arranged on the rack and used for transferring the false teeth to be processed in the material chamber to the cutting chamber and transferring the processed false teeth from the cutting chamber to the material chamber;

the processing main shaft is used for processing the false tooth to be processed transferred by the material taking mechanism;

dust absorption openings are formed in the lower end and the rear face of the cutting chamber, and the dust absorption system is connected with the dust absorption openings.

2. The denture processing apparatus according to claim 1,

the protection plate assembly is provided with a protection plate capable of ascending and descending, and the protection plate is used for isolating the cutting chamber and the material chamber;

when the protection plate is located at the lower limit position, the protection plate is located at the lowest point, and the material taking mechanism moves between the cutting chamber and the material chamber;

when the protection plate is located at the upper limit position, the protection plate is located at the highest point, the protection plate isolates the cutting chamber from the material chamber, and the machining spindle performs cutting machining on the false tooth to be machined in the cutting chamber.

3. The denture processing apparatus according to claim 2,

the protection plate assembly is also provided with a protection plate cylinder and a double linear guide rail;

the double-linear guide rail is arranged on a side plate of the processing cavity along the vertical direction, and two opposite side edges of the protection plate are connected to the double-linear guide rail in a sliding manner;

and a push rod of the protection plate air cylinder is fixed on the protection plate and used for pushing the protection plate to lift along the double linear guide rails.

4. The denture processing apparatus according to claim 2,

when the guard plate is in the upper limit position, the guard plate is provided with a space with the top plate of the frame, the space is used for air to enter the cutting chamber.

5. The denture processing apparatus according to claim 2,

the cutting chamber is provided with a processing jig which is used for fixing the material;

the dust absorption mouth includes main dust absorption mouth and supplementary dust absorption mouth, main dust absorption interface set up in the lower extreme of processing tool, supplementary dust absorption interface set up in processing tool rear end.

6. The denture processing apparatus according to claim 2,

an air inlet is formed in the left side face of the rack at the material chamber.

7. The denture processing apparatus according to any one of claims 1 to 6,

the driving mechanism comprises an X-axis driving assembly, a Y-axis driving assembly, a first Z-axis driving assembly and a second Z-axis driving assembly;

the X-axis driving assembly is used for driving the material taking mechanism and the machining main shaft to move along the X-axis direction;

the Y-axis driving assembly is used for driving the material taking mechanism and the machining main shaft to move along the Y-axis direction;

the first Z-axis driving assembly is used for driving the material taking mechanism to move along the Z-axis direction;

the second Z-axis driving component is used for driving the processing main shaft to move along the Z-axis direction.

8. The denture processing apparatus according to claim 7,

the material taking mechanism and the processing main shaft are arranged on the Y-axis driving assembly side by side;

the Y-axis driving component is arranged on the X-axis driving component;

the X-axis driving assembly is installed at the upper end of the rack.

9. The denture processing apparatus according to claim 8,

the X-axis driving assembly and the Y-axis driving assembly are both set to be double linear guide rail assemblies;

the driving mechanism further comprises a frame-shaped mounting seat, and the Y-axis driving component is mounted on the upper end face of the frame-shaped mounting seat;

the lower end face of the frame-shaped mounting seat is mounted on the X-axis driving assembly;

the material taking mechanism and the processing main shaft are arranged on the frame-shaped mounting seat.

10. The denture processing apparatus according to any one of claims 8 or 9,

the material taking mechanism and the processing main shaft are integrally arranged;

the first Z-axis driving assembly is arranged as a spline lead screw assembly, the material taking mechanism is arranged at the lower end of the spline lead screw assembly and used for taking materials from a material frame of the material chamber and placing the materials on the machining jig of the cutting chamber, and after machining is finished, the materials are taken down from the machining jig of the cutting chamber and placed back on the material frame of the material chamber;

the second Z-axis driving assembly is a screw nut assembly and comprises a Z-axis guide rail and a Z-axis sliding body, a sliding block is arranged on the Z-axis guide rail, and the Z-axis sliding body is arranged on the sliding block of the Z-axis guide rail;

the processing main shaft is fixed on the Z-axis sliding body and is driven by the lead screw nut assembly to move up and down.

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