• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    A dental instrument 1 for performing an osteotomy comprises a mounting rod 2 and, in the extension thereof, a working portion 3 comprising cutting zones 3A, at least a portion of which is covered by a tungsten carbide coating. enriched with carbon except for a plurality of annular bands 10 distributed along the length of the working portion to indicate the depth of penetration of the tool into a jaw portion.
    公开号:FR3013582A1
    申请号:FR1361613
    申请日:2013-11-25
    公开日:2015-05-29
    发明作者:Pascal Breysse
    申请人:BIOTECH DENTAL;
    IPC主号:
    专利说明:

    [0001] The invention relates to a dental instrument, such as a drill, milling cutter or reamer, whose working surface has a hard and wear-resistant coating. Such an instrument is conventionally elongate in having an operating part intended to be engaged in a rotation apparatus, manual or motorized, and a working part whose working surface, extending from a end, provides the function of drilling or boring. As is known a dental procedure such as an osteotomy, generally involves the formation or enlargement of a channel in the jaw bone, sometimes by means of an instrument rotated at high speed, and such a dental instrument is usually required to have a low coefficient of friction with the bone of the jaw (which is facilitated by the existence of lubrication, sometimes through the instrument), great mechanical hardness providing good wear resistance, good resistance to corrosion, especially to saliva acids, and good thermal conductivity to effectively remove the heat generated during the drilling of a channel, while being biocompatible. To satisfy such a combination of needs, it has been proposed, in particular by the document US Pat. No. 5,299,937, to cover at least the working surface of a dental instrument with a diamond-like hard carbon coating (often using English acronym DLC for Diamond-LikeCarbon); more recently, the document EP-1,128,777 recommended selecting such a hard carbon coating containing between 5% at and 35% and hydrogen.
    [0002] In fact, when using a dental osteotomy instrument, operated by hand or operated by means of a rotating drive motor, it is useful to be able to evaluate as accurately as possible the depth at which the end of the instrument has reached the bone. It is to satisfy this need that it has been proposed, especially in the document EP-1 128 777 cited above, to form on the working surface of the instrument visual depth marks, such as annular bands surrounding the instrument in its working part made so as to form a visual contrast with the rest of the surface of this working part; in practice, these depth strips are formed by removing all or part of the thickness of the diamond-type hard carbon coating locally. In practice these bands are equidistant; in addition, there are instruments on which the strips have a width substantially equal to the distance between them. Such a configuration is satisfactory in many cases, but it has been found that, in certain orientations, during certain interventions, the visual contrast between the depth strips becomes insufficient to allow a reliable evaluation of the depth at which the end of the instrument used has arrived. The subject of the invention is a dental instrument, adapted to osteotomy operations, responding to the various constraints applying to such an instrument, in particular those set out above, while having an improved contrast compared with that afforded by a diamond-like hard carbon coating (DLC). The invention proposes for this purpose a dental instrument adapted to the realization of an osteotomy comprising a mounting rod and, in the extension thereof, a working portion having cutting zones, at least a portion of which is covered by a carbon enriched tungsten carbide coating except for a plurality of annular bands distributed along the length of the working portion to indicate the depth of penetration of the tool into a jaw portion. Surprisingly, it has been found that carbon-enriched tungsten carbide allows better detection of annular bands than DLC although carbon-enriched tungsten carbide is less black than DLC (DLC is a deep black whereas the carbon-enriched tungsten carbide, hereinafter referred to as CETC, is dark gray). In fact, it was initially assumed that, in order to improve the contrast between the annular bands and the coating, it was necessary to increase the difference between the colors between these annular bands and the coating; however, it has been found that this visual contrast can be improved with CETC, despite a lower color difference, due to the fact that the coating is matte whereas the DLC may show reflections in certain lighting configurations. In other words, to improve the detection of the annular bands, it could be more effective to seek to obtain a strong difference in appearance (brightness or gloss) rather than maximizing the color difference; the contrast could be improved from the point of view of color but also and especially from the point of view of brilliance. Advantageously, the coating has a thickness of between 1 and 5 microns, or even between 1 and 3 microns, for example at least approximately equal to 2 microns.
    [0003] According to another advantageous characteristic of the invention, the annular bands are equidistant; in addition, they preferably have a longitudinal dimension equal to their spacing. Regardless of the longitudinal dimension of the strips, their spacing is preferably between 1 and 3 mm, for example 2 mm; by analogy, regardless of the longitudinal dimension of the spacings between the strips (which may vary from one location to another), the longitudinal dimension of the strips is advantageously between 1 and 3 mm, for example equal to 2 mm.
    [0004] Objects, features and advantages of the invention emerge from the description which follows, given by way of non-limiting illustrative example, with reference to the accompanying drawing in which Figure 1 is a single dental instrument according to the invention. Usually the dental instrument 1 has an elongate shape, generally cylindrical with a diameter much smaller than its length.
    [0005] In the example considered here, the dental instrument is a drill, but may alternatively be in particular a reamer, a tap, in particular, or any other instrument that may participate in an osteotomy procedure. This drill conventionally comprises a gripping rod 25 intended to be engaged in a tip of a drive device at high rotational speed, and a working portion 3 comprising zones (here cutting edges) 3A. extending longitudinally, advantageously helically; these zones stop here at a slight distance from the end of the working portion, which has a smaller diameter than the portion 10 in which these cutting zones are formed. An annular oversize 4 is here provided between the gripping rod 2 and the working portion 3. According to the invention, at least a portion of the working portion carries a carbon-enriched tungsten carbide coating, or CTEC. Preferably, this coating extends from the end of the working portion to the separation (from the annular extra thickness 4) between this working portion and the gripping rod. In other words, this coating extends over almost the entire length of the working portion. Alternatively, it may extend only over a fraction (in practice at least 50%, preferably at least 75%) of this length. Preferably, this coating covers, in the example shown, not only the outer surface of the working portion but also the interior of the zones set back towards the axis with respect to the cylindrical shape that locally the tool, that is to say in the areas along the cutting edges. Alternatively, all or part of these areas may not be covered by this coating. Although the coating extends over a substantial fraction of the length of the working portion, it is discontinuous due to the presence of annular strips 10 where this coating is not present (or hardly present). The surface of these strips is therefore very slightly recessed relative to the outer surface of the areas where the coating is present, just the thickness of the coating.
    [0006] These strips are here arranged in a regular way, from a certain distance from the end (indeed the extreme portion of the working portion is fully coated). These strips here have a length (that is to say a dimension parallel to the length of the tool) at least approximately equal to their longitudinal spacing, so that each of the edges of these bands is in itself an indicator of depth; these strips here have a length of 2 mm and a gap of 2 mm. As a variant, the longitudinal dimension of the strips may vary from one band to the other, advantageously being between 1 mm and 3 mm (inclusive); likewise the longitudinal dimension of the intervals may vary from one interval to another, advantageously being between 1 mm and 3 mm; they are values allowing a good distinction between the successive bands, while allowing a good detection of the band not to be exceeded in a given application. These strips 10 contrast with the coated portions due to the fact that the material constituting the working portion of the tool has a strong contrast with the CTEC coating. These strips can be obtained by depositing this coating only on the narrow end of the working part and between the light strips 10; however, it is easier to proceed by depositing the coating on all the light and dark areas of the working portion and then selectively removing the coating at the location of the strips 10. The coating may be deposited by any known technique Suitable, for example by vapor deposition (or CVD, acronym for "Chemical Vapor Deposition"). This is a thin layer deposition, for example carried out under a vacuum of the order of 10 -2 bars from a tungsten carbide target, by adding an ionized carbon gas which gives the coating its character enriched in carbon. This coating advantageously has a thickness of between 1 and 5 microns, preferably between 1 and 3 microns, for example substantially equal to 3 microns.
    [0007] The selective removal of this coating, at the location of the future clear strips 10, can be done by chemical, mechanical etching or laser etching. In particular, a laser etching makes it possible to remove the coating not only on the outer surface of the working portion but also inside the grooves along the cutting edges. Surprisingly, it appeared that a dental tool thus coated with CETC led to friction characteristics quite comparable to those of a dental tool coated with hard carbon DLC, while having a better wear resistance. and especially by offering a better visual contrast between the light bands and the dark bands coated. In their attempt to develop a dental tool with a better contrast between the depth indicator strips and the rest of the coating, the inventors initially assumed that a coating at least as dark as the DLC was required, whereas DLC is known to have a deep black color. The inventors have therefore sought to identify another coating also having a very dark color; this led them to focus on a titanium-aluminum nitride alloy AITiN, testing several shades available on the market.
    [0008] It was found that the stripping of the coating at the locations of the strips to be made clear was, depending on the shades tested, effective or not, which led to test the shades difficult to strip without using a tie layer, or with a layer Chrome grip. With a conventional adhesive layer (TiN, typically of a thickness of 0.2 micrometers), it was found that there remained, on the etched areas, a yellow tint resulting from the laser etching burning of this layer. hangs; that is why it was tempted to use a layer of chrome grip, showing a silver tint closer to the shade of the bare dental tool. The coating remained, as a whole, biocompatible, but this silver tint did not allow to have a better contrast than with DLC. In the absence of a bonding layer, the mechanical strength of the coating was insufficient.
    [0009] One of the reasons that the insufficient contrast of this AITiN alloy has been attributed is that this material is grayer than black. When it was intended to test a CETC coating, there was initially a negative priori because this material is known not to have mechanical properties as good as DLC; reference can be made to US Pat. No. 5,299,937, which, in connection with the interest of a DLC type coating, takes the example of a tungsten carbide tool; in addition, this material had a priori the same disadvantage as the titanium-aluminum nitride, namely that of having a shade grayer than black. Finally, tungsten carbide was known to often contain cobalt (because of its role as a binder, some percent), which made it a priori incompatible with applications involving biocompatibility. Finally, the hardness of the tungsten carbide is lower than that of the DLC, especially the hydrogenated DLC (1500HV against 2200HV). All this led to the conclusion that this coating was a priori unsuitable for the application in which one sought to obtain a better contrast than with DLC. However, when it has been admitted to actually conduct tests, it has been found that the current tungsten carbide grades do not contain cobalt especially after vacuum deposition (CVD type, see above) and, after adapted the conditions of stripping the coating according to this material, it appeared that in many cases the visual contrast between the stripped strips and the coated areas was better than with DLC; in addition, the CTEC coating appeared to have greater wear resistance than the DLC, which seemed to be in contradiction with the fact that it was less hard than this material. Finally this material appeared to be biocompatible. In fact, it seems that the CTEC coating gives very rarely reflections despite the power of lighting scialyitiques; this coating has indeed a matte appearance. In addition, etching of this coating does not result in any yellowing of the etched surface so that these surfaces are lighter than areas etched with a material such as AITiN. Strictly speaking, such a CTEC coating has, compared to the underlying surface (in practice the surface of a stainless steel), a color difference lower than that obtained with DLC, but the impression of a The best contrast comes from the matte appearance of the coating which keeps the detectability of the light bands in all lighting configurations, which is not the case with the DLC whose appearance is sometimes brilliant to the point of presenting reflections. It should be noted that although it has been proposed to laser-etch the clear strips to be formed on a dental tool with a DLC coating (see, for example, EP-1 128 777), it has appeared that in practice (probably for reasons of technical difficulty or cost) such clear strips are obtained by means of mechanical machining, which is recognized by the fact that the coating remains intact in the grooves along the edges cutting (hence less visibility of light bands); now such machining, if one wants to ensure a total removal of the coating to obtain a good color contrast, necessarily enters the mass of the tool, if only a few tens of microns, with the risk of locally removing the protective layer against corrosion and forming rupture primers leading to risk of breakage of the tool in use, which can be prohibitive; to this is added that the steps generated by such machining generates a risk of detachment of the coating when the dental tool is in use. However, it has been found that, with a CTEC coating, a laser etching makes it possible to effectively remove this coating, including in the grooves along the cutting edges, without degrading the material from the point of view of the resistance to corrosion or the mechanical strength, particularly in flexion. It is within the abilities of those skilled in the art to define operating conditions for such stripping depending on the underlying material, in practice a stainless steel. However, the deposition of a CTEC coating is at a temperature higher than that of the deposition of a DLC (of the order of 400 ° C against the order of 200 ° C) with a technique generally involving more energy than plasma-assisted DLC deposition (PACVD for Plasma Assisted Chemical Vapor Deposition), which suggested that deposition of CTEC would be more difficult to etch than DLC coating. However, it seems that there is, in the application envisaged, a synergy between the foreseeable disadvantages of the CTEC coating, namely that the high deposition temperature of the CTEC coating leads to a better grip of this coating on the surface of the CTEC coating. the tool; it follows that this coating has a better wear resistance than the DLC; at the same time, the fact that CETC is less harsh than the DLC results in it being more easily scoured than the DLC without yellowing or fading of the underlying surface, hence the final combination of properties that in contrast to this predictable, is better with CETC than with DLC. It can be added that the fact that the wear of the CTEC coating is slower than that of the DLC has the advantage of preserving the cutting quality of a tool with the coating of the invention longer compared to a coated tool. of DLC.
    [0010] CETC has a coefficient of friction of 0.15, compared with the value of 0.1 for the DLC, which is not a decisive difference and the CETC coating provides thermal conductivity comparable to that of the DLC. It may be noted that CETC has a metal structure (that of tungsten carbide) whereas a coating such as that advocated in the prior art, that is to say a DLC, has an amorphous structure. It is readily understood that the comments above apply not only to a drill as shown but to other types of dental tools that can be used in osteotomy. 30
    权利要求:
    Claims (6)
    [0001]
    REVENDICATIONS1. Dental instrument for performing an osteotomy comprising a mounting rod (2) and, in the extension thereof, a working portion (3) having cutting zones (3A), at least a portion of which is covered by a coating of carbon-enriched tungsten carbide except for a plurality of annular bands (10) distributed along the length of the working portion to indicate the depth of penetration of the tool into a jaw portion.
    [0002]
    The dental instrument of claim 1, wherein the coating has a thickness of between 1 and 5 microns.
    [0003]
    The dental instrument of claim 1 or claim 2, wherein the annular bands are equidistant.
    [0004]
    4. Dental instrument according to claim 3, wherein the annular bands have a longitudinal dimension equal to their spacing. 15
    [0005]
    5. Dental instrument according to any one of claims 1 to 4, wherein each spacing between two successive annular bands is between 1 and 3 mm.
    [0006]
    6. Dental instrument according to any one of claims 1 to 5 wherein the longitudinal dimension of each band is advantageously between 1 and 3 mm.
    类似技术:
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    同族专利:
    公开号 | 公开日
    US20150147715A1|2015-05-28|
    CN104644274A|2015-05-27|
    EP2875789B1|2016-11-16|
    FR3013582B1|2016-01-22|
    CA2871866A1|2015-05-25|
    PL2875789T3|2017-06-30|
    KR20150060571A|2015-06-03|
    ES2615893T3|2017-06-08|
    PT2875789T|2017-02-21|
    HUE032490T2|2017-09-28|
    US9668823B2|2017-06-06|
    EP2875789A1|2015-05-27|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US20070101827A1|2005-11-01|2007-05-10|Quan Nancy N|Endodontic Instrument|
    KR20120096839A|2011-02-23|2012-08-31|조선대학교산학협력단|Drill for operating implant|
    US5299937A|1992-07-29|1994-04-05|Si Diamond Technology, Inc.|Dental instruments having diamond-like working surface|
    WO2000027301A1|1998-11-12|2000-05-18|Nobel Biocare Ab|Diamond-like carbon coated dental instrument|
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    CN202776462U|2012-04-15|2013-03-13|孟凡刚|Hand drill with depth limit device|US8753121B2|2006-04-20|2014-06-17|Sonendo, Inc.|Apparatus and methods for treating root canals of teeth|
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    CA3132712A1|2013-02-04|2014-08-07|Sonendo, Inc.|Dental treatment system|
    CA2910809A1|2013-05-01|2014-11-06|Sonendo, Inc.|Apparatus and methods for treating teeth|
    EP3013277A2|2013-06-26|2016-05-04|Sonendo, Inc.|Apparatus and methods for filling teeth and root canals|
    KR101717084B1|2015-08-31|2017-03-20|주식회사 제노스|Drilling driver for placing dental implant|
    EP3593751B1|2016-01-29|2021-12-15|Nobel Biocare Services AG|Dentistry tool|
    US10806544B2|2016-04-04|2020-10-20|Sonendo, Inc.|Systems and methods for removing foreign objects from root canals|
    法律状态:
    2015-10-30| PLFP| Fee payment|Year of fee payment: 3 |
    2016-12-15| PLFP| Fee payment|Year of fee payment: 4 |
    2017-09-08| PLFP| Fee payment|Year of fee payment: 5 |
    优先权:
    申请号 | 申请日 | 专利标题
    FR1361613A|FR3013582B1|2013-11-25|2013-11-25|DENTAL TOOL WITH PENETRATING INDICATOR BANDS|FR1361613A| FR3013582B1|2013-11-25|2013-11-25|DENTAL TOOL WITH PENETRATING INDICATOR BANDS|
    EP14193905.8A| EP2875789B1|2013-11-25|2014-11-19|Dental tool with strips for indicating penetration|
    PT141939058T| PT2875789T|2013-11-25|2014-11-19|Dental tool with strips for indicating penetration|
    PL14193905T| PL2875789T3|2013-11-25|2014-11-19|Dental tool with strips for indicating penetration|
    CA2871866A| CA2871866A1|2013-11-25|2014-11-19|Dentistry tool with penetration indication strips|
    HUE14193905A| HUE032490T2|2013-11-25|2014-11-19|Dental tool with strips for indicating penetration|
    ES14193905.8T| ES2615893T3|2013-11-25|2014-11-19|Dental tool with penetration indicator bands|
    US14/549,881| US9668823B2|2013-11-25|2014-11-21|Dental tool with penetration indicating bands|
    CN201410794667.3A| CN104644274A|2013-11-25|2014-11-24|Dental tool with penetration indicating bands|
    KR1020140164459A| KR20150060571A|2013-11-25|2014-11-24|Dental tool with penetration indicating bands|
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