奥地利专利AT516056A4 Blank for the production of a denture

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专利摘要:
Blank (1), in particular a dental blank, for producing a dental prosthesis, comprising a bed (2) of a first material (M1), at least one core area (3) of different colors embedded in the bed (2) second material (M2), the core region (3) having a surface (F) directed towards the bed (2), and a surface (F) of the core region (3) facing the bed (2) towards the bed (2) 4), wherein the boundary layer (4) imitates a dentinal boundary between an enamel and a dentin, wherein the blank (1) has at least two separate core areas (3) with separate surfaces (F) directed toward the bed (2). having.
公开号:AT516056A4
申请号:T38/2015
申请日:2015-01-29
公开日:2016-02-15
发明作者:
申请人:Steger Heinrich；
IPC主号:

专利说明:

The invention relates to a blank, in particular a dental blank, for producing a dental prosthesis, comprising a bed of a first material, at least one core area of a second material embedded in the bed and of different colors from the bed, wherein the core area has a surface oriented in the direction of the bed.
Blanks for the manufacture of a dental prosthesis, which are made of different materials (for example, made of different plastics), have been known for some time. For example, there are cylindrical discs which consist of different layers of graduated colors in the axial direction.
As a result, a more natural color gradient can be achieved with dental restorations.
An example of such a variant is disclosed in DE 10 2011 055 393 A1. This document shows the production of a blank for artificial teeth, wherein the blank has a homogeneous color transition and the artificial teeth produced from the blank come close to the appearance of natural teeth. There are no visible dividing lines on which the color transition between two differently colored materials is recognizable. Although the various profiles or structures of the plastic layers may be distributed uniformly or unevenly, they may be wave-shaped, pyramidal, cylindrical or cuboidal, but these, for the production important structures but hardly or not at all recognizable in the finished blank by the homogeneous color transition are.
Similarly, the German Patent DE 197 14 178 C2 describes a method for producing a multicolor shaped body for further processing into a dental restoration, wherein as an essential feature a continuous color gradient is present.
In contrast, the invention further relates to a blank having a bed bounding the bed-facing surface of the core portion
Boundary layer, where the boundary layer simulates a Dentingrenze between an enamel and a dentin. Specifically, the color grading following the dentin nucleus or the dentinal boundary is produced in a certain approximation to reality.
An example of such a blank with a deliberately manufactured, relatively sharp denting limit are the so-called Vitablocs® available on the market. These usually have a size that corresponds to a tooth, so that a single tooth or a denture can be made from this block.
Furthermore, US Pat. No. 4,970,032 is known from the prior art, in which multicolored dental blanks are described, whereby individual teeth are also produced which have different color gradations.
Another document which shows a polychrome dental molding is WO 2008/083358 A1. It is essential here that the different colored zones are arranged concentrically.
Another protective right with a formable blank with different colors is WO 02/09612 A1.
DE 10 2013 203 750 A1 shows a method for producing a tooth replacement part. This involves the provision of reference data on optical properties of different dentin materials and translucent enamel materials of the dental prosthesis. From this setpoint values are determined, whereafter a tooth replacement mold block with the desired interface is selected and provided by material removal.
DE 20 2009 018 724 U1 describes a shaped article of dimensionally stable material and a method for its production. It is quite generally that a second component has a different pigmentation than the first component and the second component is arranged in the first component to form an interface such that the interface represents a spatially curved surface (for example a parabolic boundary line). Using graphics software, the interfaces of the enamel-dentin boundary layers of the maxillary and mandibular teeth are merged, generating the interface shape. This is very time-consuming and has to be determined and generated separately for each individual blank.
A disadvantage of the known from the prior art method is the relatively large effort, especially if several parts of a dentition or more teeth to be produced.
The object of the present invention is therefore to provide a comparison with the prior art improved blank. In particular, this blank should simplify the manufacture of a dental prosthesis and make it faster.
This is achieved by a blank having the features of claim 1. Accordingly, the invention provides that the blank has at least two separate core areas with separate, directed towards the bed surfaces.
Thus, it is possible to produce from a single blank in a simple manner and a plurality of teeth, each having a visible Dentingreze. Characterized in that the core areas and the surfaces directed towards the bed are formed separately and thus spaced from each other, a plurality of teeth together with the dentin core reproducing core area and the enamel-replicating bed can be made from one and the same blank. Advantageous developments will become apparent from the dependent claims.
It is preferably provided that, in addition to the surface directed in the direction of the bed, each core region has a base surface adjoining the surface directed in the direction of the bed and facing away from the bed. It is particularly preferably provided that each base surface is located in a base plane. In particular, it is provided that the base surfaces of all core regions are arranged spaced from each other in the blank. Thus, these base areas do not touch. In principle, although it should not be ruled out that some of the base surfaces touch lightly or at least in some areas, it is preferably provided that the majority of these base surfaces, preferably all base surfaces, do not touch each other in a blank and are thus each formed separately from one another.
In order to achieve the most natural possible form of the dentinal boundary, it is preferably provided that the surface of the core area directed in the direction of the bed is essentially convex. For the production of the blank, there are in principle two different embodiments. According to the first embodiment, it is provided that the base surfaces form an outer surface of the blank. That is, the individual core areas or the base areas of these core areas can be recognized on one side of the surface of the blank due to the difference in color, as they form the surface there.
According to a second embodiment, however, it may alternatively also be provided that a base layer of a material different from the first material adjoins the base surfaces of the core regions in parallel with the base surfaces. In principle, the core region and the base layer can also consist of mutually different materials. This simplifies, above all, the production, since the material of the core region can be poured into already prefabricated recesses in the previously injection-molded bed. Particularly preferred in this regard is provided that the second material forms the material different from the first material, wherein the core regions are formed integrally with the base layer. The base layer thus forms a kind of cover for the core areas embedded in the bed. In other words, it can be said that the bed-facing surface of the base layer is adjacent to the base surfaces of the core regions and to a contact surface of the bed lying in the base plane.
It is possible in principle that the blank consists of three or more different materials. For a simple production, however, it is preferably provided that the blank consists only of the first material and the second material. For imitation of the dentition boundary between an enamel and a dentin or dentin core, it is necessary that the materials used are different colors. This difference in color can be achieved by different methods. It is particularly preferred to provide for the first material and the second material to have mutually different pigmentation and / or to have a different chemical composition and / or to have a mutually different density. The type of Farbfarbigkeit can be decided depending on the application.
The dentition boundary of a dental prosthesis to be produced from a blank is easily recognizable by the eye, especially when the boundary layer extends within a range which has a thickness of less than 0.3 mm, in particular a thickness of between 0.001 and 0.2 mm. The thickness can thus vary within this range, especially depending on the materials used. That is, the more the core region shimmers through the bed (the more "transparent" the material of the bed is), the less sharp and thus thicker the barrier layer can be formed. The more "opaque" and less translucent the material of the bed is, the sharper and less thick the boundary layer can be formed.
The exact formation of the boundary layer depends strongly on the materials used. The materials must be chosen so that there is a good hold between the two materials used during manufacture so that the core area can not be detached from the bed when machining in a milling machine. On the one hand, this can be guaranteed by the fact that the surface of the bed produced first is relatively rough, so that the core area which subsequently hardens adheres well to the bed because of the roughness, preferably by plastic injection molding with the bed. On the other hand - especially when a relatively low surface roughness is given - can also be provided that a mixture of the first material and the second material forms the boundary layer. This means that the first material at least partially fuses with the second material during manufacture and thus there is an intimate connection via the boundary layer then separated from the bed and the core regions. This is preferably achieved by first applying the Bed is injection molded. Subsequently, the core area is sprayed onto the completely or partially cured bed. Both variants create a relatively sharp melt-dentin boundary.
The core areas can have different shapes and sizes. It is preferably provided that the substantially convex surfaces of the core regions are at least partially cylindrical, frusto-conical or parabolic in cross-section. It is also possible for the different convex surfaces of the core regions to have mutually different shapes in one and the same blank.
In order to enable the most efficient possible production of several individual constructions or even larger, multi-unit dental prostheses, it is preferably provided that at least five, preferably at least eight, separate core regions are formed in the blank. It is preferably provided that these at least five core areas are arranged in the form of a grid in the blank. However, it is particularly preferably provided that the at least five core regions are arranged in the blank at least in the form of a tooth-bite. Ideally, at least ten, twelve or fourteen core regions are thus arranged in the form of a tooth-bit, the core regions having different sizes, which are approximated to the dentins of a natural dentition of the shape and size. For a simple clamping of the blank in a processing or milling machine is preferably provided that the blank is disc-shaped. Depending on the design of the machine but other shapes, such as rectangular blanks can be used.
Protection is also desired for a method for producing a blank according to the invention in a plastic injection molding process. In this case, the bed is first injection molded in a first cavity of a mold until it has cured sufficiently. Subsequently, this cured bed is used in a second, larger cavity of a mold, wherein in the remaining cavity between hardened bed and mold, the second material is injected. After hardening of the second material, the two materials adhere to each other, that is, they are joined together by injection molding. This blank can then be milled accordingly in a machining or milling machine.
Further details and advantages of the present invention will be explained in more detail with reference to the description of the figures with reference to the embodiments set forth below. Show:
1a-1c different views of a first embodiment of a blank,
2a-2c different views of a second embodiment of a blank,
FIGS. 3a-3c show different arrangements of the core regions in a blank, and FIGS. 4a, 4b show schematically different embodiments of a boundary layer between the bed and core region.
In Fig. 1a is a plan view of a blank 1 is shown in which a total of nine core portions 3 are formed. These core regions 3 consist of a second material M2. The core regions 3 are embedded in a bed 2 of a first material M1. On the outer surface R of the blank 1 bulges 6 are formed, via which the blank 1 can be clamped in a processing or milling machine, not shown.
In the section i-i shown in FIG. 1b, the configuration of the core regions 3 and of the bed 2 is clearly recognizable, the blank 1 in this case having a plurality of separate core regions 3 with separate surfaces F directed in the direction of the bed 2.
In this embodiment, the surface F is formed completely convex. This surface F, together with the surface of the bed 2 directed toward the core region 3, forms the boundary layer 4. The core region 3 has not only the surface F directed in the direction of the bed 2 but also the base surface B facing away from the bed 2. This base surface B is located in the base plane E. All base surfaces B of the core regions 3 are spaced from each other in the blank 1 and lie in the base plane E. In this first embodiment, the base surface B forms the outer surface R of the blank 1 with.
In Fig. 1c are shown in perspective, the total of nine core areas 3 with their base surfaces B and in the direction of bed 2 facing surfaces F can be seen.
In Fig. 2a is a plan view of a second embodiment of the blank 1 is shown. In this case, a base layer 5 is additionally provided, which consists of a material M different from the first material M1, preferably of the second material M2.
As can be seen from the section ii-ii shown in FIG. 2b, this base layer 5 is formed integrally with the core regions 3. Again, however, lie - as in the first embodiment shown in FIG. 1b - facing away from the bed 2 base surfaces B all on the same base level E. In addition are on this base level E directed towards the base layer 5 contact surfaces K of the bed 2. At these contact surfaces K limits the in the direction of bed 2 directed surfaces L of the base layer 5 at. This means, therefore, that the surface L directed towards the bed 2 of the base layer 5 contacts both the separately and spaced-apart base surfaces B of the core regions 3 and also the contact surfaces K of the bed 2. All of these surfaces L, B and K lie in the base plane E. According to this FIG. 2b, the surface of the base layer 5 facing away from the bed 2 forms the outer surface R of the blank 1 and not the base surfaces B of the core regions 3 as in the first embodiment.
In Fig. 2c by the dashed representation again the base layer 5 can be seen, in addition, one looks practically from above on the surface of the
Base layer L, which contacts the contact surface K of the bed 2 and the base surfaces B of the core regions 3 in the base plane E.
From FIGS. 3 a to 3 c it can be seen that the core regions 3 in the blank 1 can be arranged differently. These shapes can be defined in advance, ie before the production of the blanks 1. These core areas 3 are surrounded by the bed 2. The individual core regions 3 or their surfaces F can have fine structures as they are customary in nature. In FIG. 3 a, a total of twenty-five, essentially identical core regions are arranged in the form of a grid in the blank 1. According to FIGS. 3b and 3c, fourteen, in some cases differently sized, core regions 3 are arranged in the shape of a bite. In FIGS. 3 a to 3 c, all core regions 3 are formed in a substantially frusto-conical shape. Of course, the core areas 3 may also have different shapes.
FIG. 4 a shows a schematic section through part of the blank 1. Specifically, a section in the region of the boundary layer 4 is shown schematically here. In this case, the surface roughness of the first material M1 of the bed 2 is relatively large, which is indicated schematically by the relatively high waves. With this relatively large surface roughness (having a surface roughness Ra between 10 and 15 μm, preferably 12.5 μm), the core region 3 can intimately bond to the bed 2 without hardly merging the materials M1 and M2. Thus, the boundary layer 4 is not a self-contained layer but is formed by the abutting or adhering surfaces of the bed 2 and the core regions 3. This boundary layer 4 is within a range of thickness D less than 0.1 mm for better illustration only. In many cases, the exact thickness D of this range can not be determined unambiguously. In principle, it is also possible for this purpose, that even with a polished surface having a Ra of less than 0.01 μm, sufficient adhesion is provided in the region of the boundary layer 4. This depends mainly on the specific applications.
On the other hand, as shown in Fig. 4b, a first material M1 having a smaller surface roughness was used for the bed 2. When injecting the second material M2 for the core regions 3, the materials M1 and M2 at least partially fuse together, whereby the boundary layer 4 is formed of a mixture MX between the first material M1 and second material M2. This results in an intimate connection between the bed 2 and the core regions 3. In this embodiment, the boundary layer extends in a region with a thickness D of less than 0.05 mm. Since this thickness D is not always exactly determinable, this distance is also the better illustration. For the production of the blanks 1 (blocks), a multi-component injection molding method is preferably used. So it is best possible that you can accommodate several different colors and shapes in a blank 1. Theoretically, the manufacturing process works with all thermoplastics, which have sufficient adhesion to each other in the mating used. In principle, however, thermosets can also be used. However, thermoplastics such as polymethyimethacrylate (PMMA), polycarbonates (PC), acrylonitrile-butadiene-styrene (ABS), polyethylenes (PE), polypropylene (PP), polyetheretherketone (PEEK), polyamide (PA), etc. are preferably used. This results in a blank 1 of at least two different components (materials M1 and M2), which have a different color or pigmentation. The core region 3 can also consist of a completely different chemical material and not only have a different pigmentation. So it would also be possible to use two-component silicone. It is also possible to press such a blank 1 from ceramic materials (eg zirconium). The size of the individual core regions 3 should be substantially similar to the natural size of the dentin found in natural teeth.
The processing of a blank 1 according to the invention can take place via a suitable program or software. In this case, a virtual tooth or virtual teeth is placed over the core areas 3 via this software. As soon as this virtual configuration of the tooth is suitably positioned, the corresponding teeth are milled out of the blank 1 via the processing machine. The teeth can be executed as single teeth or be milled out continuously. Depending on which work is concerned (individual work or multi-unit work), the Rohlingl can be constructed differently. Preferably, the blank 1 is designed to be able to produce several individual works.
LIST OF REFERENCES: 1 blank 2 bed 3 core areas 4 boundary layer 5 base layer 6 bulges M1 first material M2 second material F surface (bed direction) B base surface E base plane R outer surface M material other than M1 L surface of base layer K contact surface D thickness MX mixture
Innsbruck, 27th January 2015

权利要求:
Claims (17)
[1]
1. blank (1), in particular dental blank, for the production of a dental prosthesis, with - a bed (2) of a first material (M1), - at least one embedded in the bed (2) from the bed (2) of different colors formed core area (3) of a second material (M2), the core region (3) having a surface (F) directed towards the bed (2), and a surface (B) facing the bed (2) ( F) of the core region (3) delimiting boundary layer (4), wherein the boundary layer (4) simulates a Dentingrenze between an enamel and a dentin, characterized in that the blank (1) at least two separate core regions (3) with separate, in the direction Bed (2) has directed surfaces (F).
[2]
Blank according to claim 1, characterized in that each core region (3) has a base surface (B) adjoining the surface (F) directed towards the bed (2) and facing away from the bed (2), each base surface (B) being lying in a base plane (E) and wherein the base surfaces (B) of all core regions (3) spaced from each other in the blank (1) are arranged.
[3]
3. blank according to claim 1 or 2, characterized in that in the direction of the bed (2) directed surface (F) of the core region (3) is formed substantially convex.
[4]
4. blank according to claim 2 or 3, characterized in that the base surfaces (B) an outer surface (R) of the blank (1) along.
[5]
5. blank according to claim 2 or 3, characterized in that on the base surfaces (B) of the core regions (3) parallel to the base surfaces (B) aligned base layer (5) of a material different from the first material (M1) (M) followed.
[6]
6. blank according to claim 5, characterized in that the second material (M2) of the first material (M1) different material (M), wherein the core regions (3) with the base layer (5) are integrally formed.
[7]
7. blank according to claim 5 or 6, characterized in that in the direction of the bed (2) directed surface (L) of the base layer (5) to the base surfaces (B) of the core regions (3) and one in the base plane (E) lying contact surface (K) of the bed (2) adjacent.
[8]
8. blank according to one of claims 1 to 7, characterized in that the blank (1) consists only of the first material (M1) and the second material (M2).
[9]
9. blank according to one of claims 1 to 8, characterized in that the first material (M1) and the second material (M2) have mutually different pigmentation and / or are chemically different and / or have a mutually different density.
[10]
10. Blank according to one of claims 1 to 9, characterized in that the boundary layer (4) extends within a range of a thickness (D) of less than 0.3 mm, in particular a thickness (D) between 0.001 and 0.2 mm, has.
[11]
11. Blank according to one of claims 1 to 10, characterized in that a mixture (MX) of first material (M1) and second material (M2) forms the boundary layer (4).
[12]
12. blank according to one of claims 1 to 11, characterized in that the - the core region (3) forming - second material (M2) in the region of the boundary layer (4) on - the bed (2) forming - first material (M1) liable.
[13]
13. Blank according to one of claims 1 to 12, characterized in that the substantially convex surfaces (F) of the core regions (3) are at least partially cylindrical, frusto-conical or parabolic in cross-section.
[14]
14. Blank according to one of claims 1 to 13, characterized in that at least five, preferably at least eight, separate core regions (3) in the blank (1) are formed.
[15]
15. Blank according to claim 14, characterized in that the at least five core regions (3) are arranged in the form of a grid or tooth-teeth in the blank (1).
[16]
16. Blank according to one of claims 1 to 15, characterized in that the blank (1) is disc-shaped.
[17]
17. A method for producing a blank (1) according to any one of claims 1 to 16 in a plastic injection molding process. Innsbruck, 27th January 2015

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引用文献:

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法律状态:
2020-09-15| MM01| Lapse because of not paying annual fees|Effective date: 20200129 |

优先权:

申请号 | 申请日 | 专利标题

ATA38/2015A|AT516056B1|2015-01-29|2015-01-29|Blank for the production of a denture|ATA38/2015A| AT516056B1|2015-01-29|2015-01-29|Blank for the production of a denture|

ES16000130.1T| ES2639240T3|2015-01-29|2016-01-20|Gross piece to produce a dental prosthesis|

EP16000130.1A| EP3053541B1|2015-01-29|2016-01-20|Blank for the manufacture of a dental prosthesis|

US15/008,963| US10265145B2|2015-01-29|2016-01-28|Blank for the production of a tooth prosthesis|

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