WO2013079724A1 - Method and device for producing primary and secondary dental parts - Google Patents

Abstract

The invention proposes a method for producing dental prosthesis parts called primary part (7) and secondary part (8), wherein a main body (3) is first of all automatically generated from a blank (2) by material-removal machining performed by means of a programmable machining device, for example by means of a CNC milling machine, which main body (3) has a first end (5), a second end (4), and a circumferential surface that extends between these two ends (4, 5), of which the second end (4) and the circumferential surface correspond exactly to the primary part (7) to be produced, then a receiving part (6) is fitted onto the main body (3) and is automatically held, by means of a programmable handling machine, in such a way that the orientation of the main body or blank in space is precisely defined, with the result that the main body (3) is held by means of the receiving part (6) which encloses the main body (3) and leaves the first end (5) of the main body (3) free, the main body (3) is separated from the rest of the blank (2) at the first end (5) by means of an automatic separating mechanism, the main body (3) is hollowed out automatically from the direction of the first end (5) in order to create the primary part (7), a secondary part (8) is produced that has a recess whose surface is adapted to the outer contour of the primary part (7) and, in the context of a so-called marriage, the secondary part (8) is fitted onto the primary part (7) or the primary part (7) is inserted into the secondary part (8).

Description

 "Method and device for the production of dental primary and secondary parts"

The invention relates to a method for the production of dental primary and secondary parts as well as a device suitable for carrying out the method.

Such a method is known from practice. A blank referred to blank is machined by a milling head such that from this blank, an elongated body is generated with a usually circular cross-section, from which then the primary part of a tooth replacement is to be made in further processing steps. Crowns are considered as dentures, including telescopic and conical crowns and double crowns, but there are also bridges in question. In the manufacture of crowns or bridges usually a primary part is used, which is mounted in the implantation of a patient on a so-called abutment, otherwise referred to as a pen and correspondingly ground down part of a natural tooth of the patient. In the subsequent application in the mouth of the patient, a secondary part is arranged on this primary part, which may be, for example, a crown or bridge.

In the mentioned production of the base body from a blank, connecting webs are always provided on the circumference of the basically circular cross section of the base body. see where the body already made is connected to the rest of the blanks still surrounding it. These connecting webs are required to hold the far completed body so that he, except for this webs, can be edited all around.

Later, the body is cut out of the remaining blank and in the area of the separated connecting webs, the body must be reworked.

The primary part or its base body initially produced is basically elongated and has two opposite ends. The later aligned in the patient's mouth to the jaw end is referred to in the present proposal as the first end and from this first end of the base body is hollowed out so that the then completed primary can be plugged onto a pin or on an implant screw ,

The accuracy of fit between the secondary part and the primary part is essential, as well as the accuracy of fit of the primary part to the associated implant screw or the associated pin: To allow, for example, the easy removal of a bridge, two primary parts must be in absolutely parallel alignment with each other on the associated pins or implant abutments are placed on or can be removed from these. For this reason, it is not possible to produce prefabricated primary parts and secondary parts on a large scale, since these must always be adapted to the individual conditions prescribed for the respective patient in order to ensure the desired parallelism. Even if only a single crown is arranged between two adjacent teeth, the direction in which the crown can be placed on or removed from a pin or on an abutment can be defined by means of a primary part, so that - depending on how the pen or the Abutment is aligned to the adjacent teeth - collisions with the adjacent teeth can be avoided and facilitates the handling of the crown or even made possible.

The above-described procedure for the production of the primary part, the separate production of the secondary part and the subsequent marriage of both elements is relatively expensive.

DE 1 1 2004 000 561 B4 discloses a method for producing a blank made of a ceramic material. From the blank, a dental reconstruction is then produced by cutting, which corresponds in this respect to the above-mentioned secondary part. In the preparation of the dental reconstruction remain on the peripheral surface initially still connecting webs to the rest of the blank, so that this way of manufacturing secondary parts of the above-described production of primary parts is similar. A production of primary parts is not addressed in this document.

EP 0 455 845 A1 discloses a blank body for producing a tooth restoration fitting. From the rod-shaped blank body, the base body is machined out so that its vertical axis, that is, the axis passing through the first and the second end of the base body, extends transversely to the longitudinal axis of the rod-shaped blank body. In addition, a holder is machined from the rod-shaped blank body, which adjoins the peripheral surface of the base body laterally and with uniform material, so that the base body can be machined at its two ends. Subsequently, the holder is separated from the base body. The subsequent reworking of the location where the holder adjoins the peripheral surface of the tooth restoration fitting body is just as necessary as the post-processing of the body of a Pri märteils at the first end in the aforementioned prior art. The tooth restoration fitting body is tooth-shaped, ie it corresponds to the secondary part of the prior art known from practice. A production of primary parts is not addressed in this document.

From EP 0 064 601 A2 a method for the production of dental prostheses is known in which primary and secondary parts are produced by casting in the lost wax process. The excavation at the first end of the body is created by spark erosion.

WO 97/30654 relates to an implantable dental prosthesis, an abutment therefor, as well as a method for the production of abutments. The proposed primary part is optionally mounted on an abutment instead of a pin of a natural tooth.

The invention has for its object to improve a generic method to the extent that this can be carried out as economically as possible and within a short time, the production of the combination of secondary and primary part, as well as to provide a device for carrying out the method.

This object is achieved by a method having the features of claim 1 and a device having the features of claim 13.

In other words, the invention proposes to carry out the milling process differently during the production of the main body, namely to produce both the circumference peripheral surface and the second end of the main body opposite the first end directly with the desired contour, ie the contour corresponding to the later primary part already corresponds, so that Therefore, these surfaces of the body must not be reworked later. Only at the first end so the body is still connected to the rest of the blank, for example, the already mentioned above blank.

Subsequently, the base body is held by means of a receiving part, which comprises the base body, similar to that of the wedding between the secondary part and primary part is known, so that the first end is now accessible for further processing by this holder of the body. In favor of a rational and fast workflow as possible can be advantageously provided that this receiving part is moved by a programmable handling machine and thus automatically moved through the room, placed on the body and is also held, so that by means of this programmable handling machine first the receiving part is placed on the base body.

In any case, the base body or the blank from which the base body has been worked out can be released after it has been connected to the receiving part and the receiving part is held by a programmable handling machine, since the held in the receiving part body now by means of the handling machine and means held by this handling machine receiving part in turn is held.

Since the first end of the main body is now freely accessible, then the main body can be separated by means of an automatic separator at the first end of the rest of the blank. The automatic separator is programmable in space with respect to its mobility, so that it automatically moves to the appropriate location on the blank, where the body is to be separated from the rest of the blank. Also the speed of a typically rotating one Tool, z. Example, a milling head or a cutting disc, can preferably be controlled automatically, so that depending on the processing progress, with which the cutting tool is moved by the material of the blank, the tool speed and the feed speed of the separator can be controlled automatically by means of a suitable machine control ,

As the last processing step, the main body is now hollowed out, so that now has become the primary part of the main body. This excavation is carried out automatically by means of a programmable processing machine, for example by means of a CNC-controlled milling machine, so that, for example, a cavity designated as a bore can be precisely introduced into the basic body at a predetermined angle. The course of this bore ensures the alignment of the primary part on a pin or abutment, and thus the subsequent parallelism with which a secondary part can be lifted off this primary part and a second primary part located in the patient's mouth, or ensures the direction in which a crown between two adjacent teeth can be lifted off the primary part.

The automatic handling and processing of the blank, of the base body created therefrom, as well as of the receiving part to be applied to the main body in the sense of the most economical and precise production possible, are preferably carried out by means of an electronic system or machine control. The outer and inner contours of the primary part can be determined, for example, computer-aided, so that corresponding CAD data is available. This CAD data can be processed either directly or by means of a suitable interface of the plant or machine control, so that in this way the individual handling and processing tools can be precisely guided in space to the desired outer and inner contours of the Primary part too produce. The handling and / or the processing tools can be program-controlled at the end of a freely movable in space multi-axially movable robot arm, or be moved on a so-called carriage or a portal along a predetermined trajectory.

In particular, since the same CAD data can be used for the production of the receiving or secondary part, it is also possible to achieve a shaping of the receiving or secondary part which is precisely adapted to the shape of the primary part. In particular, the same CAD data can be transmitted almost simultaneously to two processing centers, so that the receiving part can already be made during the production of the primary part. It is not necessary to first make the primary part and only then, in adaptation to its outer contour, to produce the receiving part.

Alternatively, a method sequence may be provided, in which first the base body is hollowed out at its first end and only subsequently separated from the remainder of the blank. For example, during excavation, material removal progress may be radially from the center out, leaving an increasingly thinner edge around the progressively larger cavity. The main body remains connected via this edge with the rest of the blank and is separated when the milling head removes this edge.

In this procedure, no tool change is required, as would be the case if, for example, a separate cutting tool to be used in addition to the milling tool. The processing system can therefore be designed simpler and less expensive, since it neither has to have two separate processing arms, each with its own tool, nor must it be configured to allow an automatic change of tools on one and the same processing arm. In addition, time savings can be achieved. the otherwise associated with the approach of the respective tool to the workpiece and with a possible change of the tool.

The processing system can be equipped in this procedure, for example, with a single tool in the form of, for example, a milling head, this milling head serves to create from the blank, the outer surface of the body, to create the cavity in the body, as well as the main body from the rest of the blank separate.

The proposed, largely automatic machining of the blank and the body allows a fast and thus economical production of the primary part. The fact that the holder of the blank and the base automatically, namely mechanically, is always ensured that the orientation of the body or blank is precisely defined in space, so that accordingly the correct position, the hollowing of the body can be done. The mechanical handling and processing of the blank and the base body also ensures that this work can be carried out within a very short time and thus particularly economically.

Advantageously, it can be provided that as a receiving part, by means of which the not yet completely finished body is held before it is hollowed out, the secondary part is used, which has been previously made. This preparation can preferably also be done automatically, similar to that described for the production of the primary part, so that this automatic production of the secondary part and its orientation in space is known precisely and accordingly the secondary part can be precisely guided to the body. The so-called wedding takes place when the secondary part is used as the receiving part, ie even before the final completion of the primary part, namely when the primary part has not yet been hollowed out. Because the finished secondary part is already used as the receiving part for holding the basic body, an additional handling step is unnecessary. On the one hand, this has an advantageous effect on the cycle times with which the manufacture of dental prosthesis parts can take place. In addition, a potential source of error is minimized by any saved handling or transfer of a component from one to another handling or processing device, which could lead to misalignments of the component to be processed or handled, so that thereby the precision and quality of the prepared dental prosthesis parts is improved.

Alternatively it can be provided that the receiving part is not prefabricated before it is placed on the body, but is created directly on the body. For example, a potting compound can be poured around the main body. It solidifies and lies exactly to the body.

For example, two-component plastics can be used as potting compound. Their solidification or curing time can be adjusted so that this process takes no longer than when the receiving part is milled out of a block of material.

Advantageously, it can be provided that a rod-shaped blank is used instead of the aforementioned cuboid blanks. Since the main body or primary parts anyway have a substantially circular cross section, less material must be removed from the blank to complete the primary part, so that the processing time can be shortened and also the collection and processing of the machining chips is simplified and facilitated. Since the amount of such machining chips is reduced, in particular when processing high-quality and, accordingly, reprocessable ma- materials, eg As gold alloys, the reduction of the associated effort ensures improved efficiency in the production of dental prostheses.

When using a plurality of rod-shaped blanks with different sizes around the above advantage of using rod-shaped blanks can be further enhanced: From this plurality of different sized rod-shaped blanks each of the blank can be selected whose circumferential dimensions are as similar as possible to those of the primary part to be produced, so that In this way, the required material removal from the blank can be minimized.

It can advantageously be provided that a plurality of rod-shaped blanks with the different sizes are held in a common holder. The automatic processing machine, for example, a CNC-controlled milling machine can be controlled so that already processed blanks are not approached again for processing, but that is stored in the plant control of this machine, which blank to which extent at which position of the common holder still for Processing are available, so that accordingly the respective suitable blank for the next processing, ie for the production of the next primary part, is approached. The distances between the blanks on the common holder to each other are so large that the processing by means of the processing machine is easily possible.

Alternatively to the arrangement of a plurality of blanks on a common holder can be provided that a plurality of rod-shaped blanks are mounted individually with the different sized circumferential dimensions. Due to the automated mechanical production of the primary part, it is possible to provide a system control which, depending on the known dimensions of the primary part to be produced, has the best suited suitable blank or stock with the most suitable blanks selects, so that a holding device can automatically start this camp, detects the suitable blank from this camp and brings into the processing position in which the material-removing machining of the blank for the production of the body. This can be done in a similar manner as is known, for example, from automatic plotters, in which crayons with different stroke widths or different colors are automatically detected or changed.

As an alternative to a rod-shaped blank or a blank, a disk-shaped blank or blank can be used, which is referred to in this case as Ronde. The diameter of the blank is dimensioned so large that several bodies can be worked out of the blank. It is provided that the still to be produced base body or primary parts are within the Ronde that the free second ends of an upper side of the Ronde are adjacent, while the first ends are provided near the bottom of the Ronde.

The areas of the blank provided for producing the main body or primary parts are referred to as processing stations, so that, depending on the size and arrangement of the processing stations, it is possible to create quite different numbers of primary parts from two identically sized blanks. The division of the blank in such processing stations may be provided purely mentally or be deposited in a plant control of the machining tool so that the machining tool gradually anfährt the individual still unprocessed processing stations Ronde, there mills a base body of the blank material, and then this area the blank is stored in the system control as edited. The subdivision of the blank into several processing stations, however, can be done not only mentally, but also physically: At the bottom of Ronde can be provided at each processing station a hole, so that there the material to be removed during excavation of the body, already at the factory the volume of the hole is reduced. Thus, the number and size of the processing stations can be predetermined by the factory and the size of the holes.

When using blanks can be advantageously provided to define such a blank by means of a clamping ring on a holding device, so that the blank is fixed and can be edited. A receiving part, which is applied to the carved out of the blank basic body can also be worked out of a Ronde by milling, with a complementary to the main body of the first Ronde shape. This second Ronde can also be held by means of a clamping ring, namely advantageous to the clamping ring of the first Ronde, so that subsequently the first Ronde can be solved by the holding device and both blanks can be handled together, z. B. to hollow out the body.

As a further alternative to a cylindrical rod-shaped or to a disc-shaped blank or blank, a blank may be present as a finished workpiece, which approximates the shape of a primary part already ex factory, and in which only a fine or post-processing of the outer surface must be made and the cavity must be generated. The volume of the material still to be removed can be kept very low by such teilfertigarbeiten workpieces, so that thereby the required processing time can be kept low and in a relatively short time a variety of primary parts can be produced economically. Advantageously, a base body is produced from the blank, which does not have an exactly circular cross-sectional peripheral contour, but a deviating outer contour. For example, in the form of a teardrop shape, a lens shape or a polygon, or in which the peripheral contour of the body cross-section have one or more ribs. In this case, the secondary part has a complementary to this peripheral contour recess so that the secondary part can be placed on the main body or on the primary part and the primary part is held against rotation in the secondary part. In particular, when the secondary part is placed as a receiving part on the not yet hollowed body, this rotation between body and secondary ensures that in a subsequent excavation of the body z. B. by means of a drill, milling cutter or the like of the base body can be kept defined and can be reliably ruled out that the main body rotates in the secondary part.

To carry out the proposed method can advantageously be used a device having a blank holding the first holding means and a base body of the blank generating processing machine which generates the body materialabtragend, for example by a router, a laser device, a water jet cutter or the like. Furthermore, the device has a second holding device which holds the secondary part and a separating device which separates the main body at the first end of the remaining blank when the main body in

Recording part is held. Furthermore, the device has a processing machine, which hollow out the base body, namely from its first end, and finally the device has a programmable controller, which is designed to control the aforementioned elements of the overall device. Advantageously, the device described can also be developed in such a way that it is designed for the production of the secondary part and has a material-removing processing machine suitable for this purpose. In this way, in turn, a transfer step is avoided, thus improving the precision in the production of the dental prosthesis, since on one and the same device both the main body and the primary part as well as the secondary part are produced, so that in the transfer of the individual primary and Abutments and their marriage as high degree of accuracy in the positioning of these individual parts can be ensured.

An economically advantageous embodiment of the device may be advantageous in that the same processing machine is provided for producing the base body and for creating its cavity, for example the same milling machine. As a result, not only the required space requirement of the proposed device is reduced, but also reduces the technical complexity of the device, so that this can ultimately be produced and operated more economically.

The proposal according to the method will be explained in more detail below with reference to the purely schematic representations. It shows

1 shows several rod-shaped blanks with different sizes, which are held in a common holder,

3 shows a bridge with two secondary and primary parts, FIG. 4 shows the processing of a blank into a base body and a primary part in several steps, FIG. 5 shows an embodiment of a blank-shaped blank, FIG. 6 a blank blank in section and partly broken away,

 7 shows a first clamping ring for receiving a blank-shaped blank for primary parts,

8 shows a second clamping ring for receiving a blank-shaped blank for secondary parts, and

 Fig. 9 is a view of the two clamping rings, with two held therein ronde-shaped blanks.

In Fig. 1, a holder 1 is shown, the three differently shaped blanks 2 carries. Each of the blanks 2 is designed in each case as a cylindrical rod, wherein the three blanks 2 have three different diameters. Alternatively to the arrangement in a common holder 1, the blanks 2 can be present separately and detected by a first holding device and retrieved from a warehouse and brought into a processing position and held there, in which they are accessible to a programmable processing machine.

That this unprocessed, cylindrical blank 2 is brought into the machining position, as shown in FIG. 4 represents a first processing step I in the manufacture of a primary part.

From the cylindrical blank 2, a base body is produced, as can be seen from FIG. 2 and identified there with 3. The main body 3 is shown in the drawings for better visual distinction from the remaining, still connected to the main body 3, cylindrical portion of the blank 2 as a truncated cone. It has a first end 5, which adjoins de unprocessed portion of the blank 2, as well as an opposite free, second end 4. The main body 3 represents the material-processed portion of the same blank 2.

The blank 2 is held in the region of its unprocessed portion, namely by means of the mentioned first holding device. The main body 3 can be machined out of the blank 2, wherein both the frusto-conical peripheral surface and the free, second end 4 are finished, that is to say receive the surface design which is to have the finished primary part.

4 shows a second processing step II in the production of a primary part. It is shown in FIG. 4 that the base body 3 may have a cross-sectional peripheral contour deviating from the circular circular By way of example, a rib 12 is shown which extends over the height of the main body 3.

In Fig. 2 it is shown that on the base body 3, a receiving part 6 is placed. The receiving part 6 is held by means of an electronically controlled second holding device and brought to the main body 3 and placed on the base body 3. Subsequently, the first holding device, which has first held the blank 2, release the blank 2, since the processed portion of the blank 2, namely the base body 3, is now held together with the receiving part 6 of the second holding device.

The placement of the receiving part 6, as shown in FIG. 4, represents a third processing step III in the manufacture of a primary part. The receiving part 6 according to FIG. 4 has a cross-sectional inner contour deviating from the circular circumference, which is complementary to the cross-sectional peripheral contour of the main body 3, so that the base body 3 is held against rotation in the receiving part 6.

Next, the main body 3 can be separated from the rest of the blank 2, namely at the first end 5. This is shown in FIG. 4 as the fourth processing step IV. A separator, for. B. in the form of pliers, a cutting disc, a Saw or the like separates the main body 3 from the rest of the blank 2 in the direction of the arrow.

The first end 5 is now free for editing. In Fig. 4 is shown as a fifth processing step V that in the direction of

Arrow the body 3 can be eroded. The main body 3 of FIG. 2 is retained in the receiving part 6 in a force-locking manner solely on account of the friction forces, while in the exemplary embodiment of FIG. 4 the rib 12 creates an additional, positive rotation safeguard. The cavity can preferably be produced by means of the same processing machine which has previously produced the outer surfaces of the base body 3. As a result, a primary part 7 is created, as shown in step VI of FIG. 4 or can also be seen in FIG. 3 or 2. The shape, size and location of the excavation depends on the individual circumstances, eg. B. whether the primary part 7 is provided for a crown or bridge, and how are the physiological conditions of the patient to be cared.

The apparent in Figs. 2 and 4 receiving parts 6 are shown purely schematically. As a receiving part 6, an already completed secondary part can preferably be used, as can be seen from FIG. 3 and identified there with 8.

In Fig. 3, a bridge 1 1 is shown, wherein two primary parts 7 are used, the cavities cooperate with a respective tooth pin and are aligned so that two parallel lines of movement when placed on or when removing from the two tooth pins result.

Fig. 5 shows a blank 2, which is designed as a so-called Ronde 9, so as a cylindrical, flat disc whose

Material thickness is so large that from the Ronde 9 Pri- 7 can be made. In Ronde 9 four differently sized, each circularly marked processing stations 10 are indicated, which are within the blank 2.

6 shows a section through a part of the blank 9 in the region of a processing station 10. From the material of the blank 9, a base body 3 has been worked out in the region of the processing station 10, so that the outer contour of the base body 3 is already exposed, namely the second, free end 4 and the peripheral surface, and so that around the base 3 around the material thickness of the blank 9 is significantly reduced. The first end 5 of the base body 3 is provided at a distance above the side of the blank 9 shown in FIG. 6 below.

In Fig. 6, the running through the blank 9 sectional area is shown hatched, with solid lines. A hatching with broken lines indicates the area of the main body 3, which is removed when hollowing the base body 3, so that then a hollow, approximately cup-shaped primary part 7 is created. To illustrate this, the inner contour of the primary part is also shown in Fig. 6. It runs along a line marked 22.

Each of the four processing stations 10 has a bore 23, wherein according to the orientation of the blank 9 in Fig. 6, the side of the blank 9, which has the bore 23 is referred to as the bottom of the blank 9. The bore 23 of the processing station 10 shown in FIG. 6 extends from the underside of the blank 9 into the base body 3 and serves as a contact surface on which a milling head can be attached in order to further hollow out the base body 3.

Since four differently sized processing stations 10 are provided, which are to serve to create differently sized base body 3, and the holes 23 may have different diameters in order to keep the time as short as possible, which is required to hollow out the body by means of the mentioned milling head. A larger processing station 10 can accordingly have a bore 23 with a larger diameter than a smaller processing station 10. However, the bore 23 is also so small that the cavity not only with a right angle, but optionally also with an oblique to the bottom of the Ronde. 9 extending central axis can be generated, depending on the physiological conditions in the patient, z. B. in adaptation to the respective orientation of a pin or abutment, whereupon the primary part 7 is to be mounted.

After hollowing remains a comparatively thin-walled primary part 7, wherein during the same milling operation, the base body 3 is not only hollowed out, but also separated from the rest of the blank 9. The first end 5 of the primary part is provided where the base body 3 connects to the reduced material thickness of the blank 9.

Fig. 7 shows a first clamping ring 14, which serves to define a blank 9 on a holding device, which is indicated schematically in Fig. 9 with 15. The holding device 15 has a plurality of retaining bolts 16, which are configured mushroom-shaped or in longitudinal section approximately T-shaped. Each retaining bolt 16 of the holding device 15 is a keyhole holder 17 on the first

Clamping ring 14 assigned. The blank 9 is held between the holding device 15 and the first clamping ring 14, wherein the first clamping ring 14 is first placed on the retaining pin 16 and then rotated about its central axis until the keyhole 17 engage behind the heads of the retaining pin 16, so that the first clamping ring 14 is fixed in the manner of a bayonet lock on the holding device 15. The free, remote from the holding device 15 surface of the blank 9 can now be edited so that one or more body 3 can be generated. The first round plate 9 serves to produce primary parts 7. A second round plate 18 is shown in FIG. 9. It serves for the production of receiving parts 6, and their directed to the first Ronde 9 surface is the contouring or topography of the first Ronde 9 complementarily adapted so that a receiving part of the second Ronde 18 can be placed on a main body of the first Ronde 9. This is the case in the arrangement of the two blanks 9 and 18 shown in Fig. 9.

The second Ronde 18 is held by means of a second clamping ring 19 in its first Ronde 9 adjacent position. The second clamping ring 19 is designed substantially like the first clamping ring 14 and also has keyhole 17. Instead of the retaining bolts 16 which are provided on the holding device 15, blanket pins 20 serve to fix the second clamping ring 19. The blanking bolts 20 are attached to the first clamping ring 14, namely screwed into threaded holes 21.

After the two blanks 9 and 18 have been processed and joined together according to FIG. 9, the so-called package consisting of the two blanks 9 and 18 and the two clamping rings 14 and 19 can be released from the retaining bolts 16 of the holding device 15 in that the entire package is rotated in the reverse direction until the heads of the retaining bolts 16 can be guided through the larger sections of the keyhole receptacles 17 and thereby the package is withdrawn from the retaining bolts 16 in its axial direction. The handling of the package is preferably carried out fully automatically by means of a handling robot.

After the package has been released from the holding device 15, the surface of the first blank 9 shown in Fig. 6 below is exposed, so that one or more body 3 can now be hollowed out. When the connection of a basic body 3 along its first end 5 to the other first ten Ronde 9 is separated, this base body 3 remains securely in the associated receiving part 6, which is formed by the second Ronde 18. In this case, either after this separation process, the main body 3 can be further hollowed out and created in this way, the primary part 7, or with the remaining first Ronde 9 first still connected base body 3 is hollowed out, and only at the end of this processing operation is the connection with the other first round plate 9 separated so that now the primary part 7 is present.

Claims

Process for the preparation of dental technical, as a primary part (7) and secondary part (8) designated dental prosthesis parts, wherein

^■ first a basic body (3) by means of a programmable processing machine - such as by means of a CNC-controlled milling machine - is automatically generated from a blank (2) by material-removing machining,

 which base body (3) has a first end (5) and a second end (4), and a peripheral surface extending between these two ends (4, 5),

 and whose second end (4) and the peripheral surface correspond exactly to the primary part (7) to be produced,

^■ then a receiving part (6) is applied to the base body (3) and held automatically by means of a programmable handling machine, such that the orientation of the basic body or blank is precisely defined in space,

 such that the base body (3) is held by means of the receiving part (6), which comprises the base body (3) and thereby leaves free the first end (5) of the base body (3),

^■ the base body (3) by means of an automatic separating device at the first end (5) of the other blank (2) is separated,

^■ the base body (3) from the first end (5) is automatically forth hollowed out to create the primary part (7),

Is prepared ^■ a secondary part (8) having a recess whose surface to the outer contour of the primary part (7) is adapted ^■ and in the context of a so-called wedding, the secondary part (8) placed on the primary part (7) or the primary part (7) is inserted into the secondary part (8).

Method according to claim 1,

characterized,

that the secondary part (8) is used as receiving part (6), such that the wedding already takes place when the primary part (7) is not yet completed.

Method according to claim 1,

characterized,

that a casting compound is used as the receiving part (6), which is poured around the base body and then solidifies.

Method according to one of the preceding claims, characterized

that a rod-shaped blank (2) is used.

Method according to claim 4,

characterized,

that of a plurality of rod-shaped blanks (2) with different sized circumferences that blank (2) is selected for the material-removing machining whose circumference is at least greater than the circumference of the primary part to be produced (7).

Method according to claim 5,

characterized,

that a plurality of rod-shaped blanks (2) with different sizes are held in a common holder,

wherein the distances of the blanks (2) to each other are so large that they allow the automatic material-removing machining of a blank (2). Method according to claim 5,

 characterized,

 that a plurality of rod-shaped blanks (2) are stored individually with differently sized enclosures,

 and that a holding device automatically anfährt this camp, detects the selected blank (2) and brings in the processing position in which the material-removing machining takes place.

Method according to one of claims 1 to 3,

 characterized,

 in that a disk-shaped blank (2) designated as blank (9) is used.

Method according to claim 8,

 characterized,

 the blank (9) has a plurality of processing stations (10) for producing a plurality of base bodies (3),

 and that the programmable processing machine for producing a new primary part automatically an unprocessed processing station (10) anfährt on which then the material-removing processing. 10. The method according to any one of the preceding claims, characterized

 a basic body (3) is produced from the blank (2), which has a cross-sectional peripheral contour deviating from the circular circumference,

 and in that in the secondary part (8) a complementary recess is created,

 such that after the wedding, the primary part (7) is held against rotation in the secondary part (8).

1 1. Method according to one of the preceding claims, characterized that the main body (3) is first hollowed out automatically from the first end (5)

and during this processing remains connected to the rest of the blank (2),

and only after that at the first end (5) is separated from the remainder of the blank (2) to provide the primary part (7).

Method according to one of claims 1 to 10,

characterized,

the base body (3), when it is automatically hollowed out from the first end (5), is first separated from the remaining blank (2),

and only then further hollowed out to create the primary part (7).

Device for producing dental primary and secondary dental prosthesis parts (7, 8) according to one of the preceding claims,

with a first holding device holding the blank (2),

a processing machine producing the base body (3) in a material-removing manner,

a second holding device holding the secondary part (8),

a separating device separating the base body (3) at the first end (5) from the remainder of the blank (2), a processing machine hollowing out the base body (3),

and with a programmable controller for controlling the processing machine, the second holding device and the separating device

Device according to claim 13,

characterized,

that the device also has a second, the secondary part (8) having producing, material-removing processing machine.

Apparatus according to claim 13 or 14,

characterized,

in that the same processing machine is provided for producing and hollowing out the base body (3).

Device according to one of claims 13 to 15,

characterized,

the processing machine provided for generating and / or hollowing out the base body (3) also forms the separating device separating the base body (3) at the first end (5) from the remaining blank (2).