Classifications

• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61C—DENTISTRY; APPARATUS OR METHODS FOR ORAL OR DENTAL HYGIENE
  • A61C8/00—Means to be fixed to the jaw-bone for consolidating natural teeth or for fixing dental prostheses thereon; Dental implants; Implanting tools
  • A61C8/0089—Implanting tools or instruments
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods
  • A61B17/16—Instruments for performing osteoclasis; Drills or chisels for bones; Trepans
  • A61B17/1662—Instruments for performing osteoclasis; Drills or chisels for bones; Trepans for particular parts of the body
  • A61B17/1673—Instruments for performing osteoclasis; Drills or chisels for bones; Trepans for particular parts of the body for the jaw
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61C—DENTISTRY; APPARATUS OR METHODS FOR ORAL OR DENTAL HYGIENE
  • A61C19/00—Dental auxiliary appliances
  • A61C19/04—Measuring instruments specially adapted for dentistry
  • A61C19/043—Depth measuring of periodontal pockets; Probes therefor
• • A—HUMAN NECESSITIES
  • A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
  • A61B—DIAGNOSIS; SURGERY; IDENTIFICATION
  • A61B17/00—Surgical instruments, devices or methods
  • A61B17/16—Instruments for performing osteoclasis; Drills or chisels for bones; Trepans
  • A61B17/17—Guides or aligning means for drills, mills, pins or wires
  • A61B17/1739—Guides or aligning means for drills, mills, pins or wires specially adapted for particular parts of the body
  • A61B17/176—Guides or aligning means for drills, mills, pins or wires specially adapted for particular parts of the body for the jaw

Definitions

• the present invention relates to a pilot drill, a step drill and a drill set formed therefrom for use in dental implantology.
• the pilot drill is used to produce a blind hole-shaped pilot hole to be inserted into a human jawbone as preparation for its enlargement to a step hole, which is done with one or - with a further enlargement of the step hole - several different step drills.
• the prepared stepped bore is intended for receiving a dental implant, preferably in the form of a screw.
• the prepared borehole can be provided with an internal thread before application or the implant is self-tapping, as a result of which the internal thread is cut when the implant is screwed into the jawbone.
• the present invention relates primarily to dental implants in screw form.
• the healed implant forms the anchor for a superstructure to be built.
• a drill set is shown that consists of a round bur and three twist drills with increasing cross-sections.
• the round bur is used to mark the position on the cortex where the hole is to be made.
• the cortex and cancellous bone are drilled out almost seamlessly with the first twist drill.
• Wieland Dental +technik GmbH & Co. KG, D-75179 Pforzheim, Germany offers a drill sequence for a self-cutting screw implant with 03.3mm and conical neck, consisting of the following drilling instruments: a) an initial drill for precise drilling of the position; b) a drill bit 01.8mm for the preparation of the hole in full depth; c) a step drill 01.8mm / 02.5mm to widen the bore mouth to 02.5mm; d) a drill bit 02.5mm to widen the hole over the entire depth to 02.5mm; and e) a conical drill with a guide 02.5mm to widen the bore mouth.
• Implant Innovation Inc. USA, offers a drill set where, even before the next larger drill is used, the existing hole is widened to the next higher diameter over a short mouth area to ensure that the subsequent drill is well centered. Step drills are used for this. These step drills have a round apical nose with the diameter of the preceding drill, which causes centering in the hole and has no cutting function. This system requires a step drill and the corresponding twist drill for each drilling diameter, so that a larger number of drilling instruments and operations are also required here.
• a drill sequence from FRIADENT GmbH, D-68229 Mannheim, Germany is known.
• the following drills are used for a self-tapping 3-stage screw implant 05.5mm: a) a pre-drill 02.0mm for precise drilling of the position and specification of the axial direction; b) a rose drill 03.4mm to widen the bore mouth to 03.4mm; c) a 3-step milling cutter for the preparation of a 3-step hole 03.4mm; d) a 3-step milling cutter for preparing a 03.8mm hole; e) a 3-step milling cutter for preparing a 04.5mm hole; and f) a 3-step milling cutter for preparing a 05.5mm hole.
• the task is based on creating an improved pilot drill.
• Another task is to create an improved tiered borer.
• An additional task is to propose a multi-part, advantageously usable drill set from the pilot and step drills. It can be assumed here that the drilled hole penetrates the cortical bone very precisely at the planning-appropriate location in order to ensure the correct position of the implant and thus of the subsequent denture. The direction of the bore must be precisely aligned in order to optimally absorb the loads that will later affect the dentures.
• the jawbone should be stressed as little as possible.
• the preparation of the bore must be simple and time-saving in just a few simple steps; only a small number of instruments should be required. Finally, it is important to keep the overall costs low.
• a pilot drill is provided to prepare the implant bed for the reception of a dental implant - as a blind hole-shaped step hole to be made in the human jaw bone.
• the pilot drill has a pilot tip with pointed cutting edges at its apical end.
• a pilot guide extends from the pilot tip in the direction of the coronal end of the pilot drill, above which there is a drill neck which has a larger drill diameter than the drill diameter of the pilot guide.
• a drill shaft connects to the drill neck, and the coronal end of the pilot drill has a standardized dental coupling, as is common for dental handpieces on electric drills.
• At least one cutting edge lies on the side of the pilot guide. In the transition from the pilot guide to the drill neck there is a step with at least one step cutting edge.
• At least one spiral groove and an adjoining chamfer extend along the pilot drill.
• the characteristic of the pilot drill is first of all that the tip cutting edges on the pilot tip are sharp and center-cutting and that the bevels extend from the tip cutting edges upwards of the pilot guide.
• the step cutting edges on the step are designed to be cutting, while the guide cutting edges are blunt, that is to say non-cutting.
• the following features represent advantageous embodiments of the invention:
• the drill neck with the chamfer is designed to be weakly cutting.
• the pilot guide has a length in the range of 1.0mm to 4.0mm, e.g. 3.0mm.
• the pilot drill is preferably designed with two cutting edges and thus has two tip cutting edges, bevels, guide cutting edges, spiral grooves, chamfers and step cutting edges.
• the drill neck has at least the length of the insertion depth of the implant to be applied.
• the pilot guide has a diameter in the range of 1.5mm and the drill neck has a diameter in the range of 2.0mm.
• the tip angle between the tip cutting edges is less than 90 °, preferably it is in the range of 80 °.
• the spiral grooves extend continuously from the coronal end of the drill neck to the pilot tip, the spiral grooves on the pilot guide only having a portion of their full cross-section due to the smaller diameter, as is present on the drill neck. Several visible depth markings are attached to the drill neck to check the penetration depth of the pilot drill at equal or unequal intervals.
• the pilot guide with the pilot tip is intended to determine the position of the stepped bore to be produced by introducing a pilot hole approach through the cortex of the jawbone, the approach consisting of a pilot hole guide and a pilot hole tip.
• the step is designed to generate a noticeably increased drilling resistance after the penetrated cortex - with the completion of the pilot drill guide and tip - so that the surgeon can check the direction of the drill at this indication.
• the blunt guide cutting edges enable the direction of the bore to be corrected within a conical correction range without widening the pilot bore guide.
• the size of the drill neck is designed to create the pilot hole at the final depth.
• a step drill For the enlargement of a brought a pilot hole in the form of a blind hole to a step hole or for the further enlargement of an existing step hole to a further enlarged step hole as a receptacle for a dental implant, a step drill is provided.
• the step drill has a step tip that lies at the apical end of the step drill and is provided with point cutting edges.
• a step guide extends from the step tip towards the coronal end of the step drill.
• Above the step guide is a drill neck that has a larger drill diameter than the drill diameter of the step guide.
• a drill shaft is attached to the drill neck, and a standardized dental coupling for adaptation in a dental handpiece of an electric drill is located at the coronal end of the step drill.
• the step drill has at least one guide cutting edge located on the side of the step guide. At the transition from the step guide to the drill neck, a step is formed with at least one step cutting edge. At least one spiral groove and an adjoining chamfer extend over the step drill.
• the characteristic of the step drill is first of all that the tip cutting edges are sharp at the step tip and the bevels extend from the tip cutting edges up to the step guide.
• the step cutting edges on the step are designed to be cutting, while the guide cutting edges are blunt, ie non-cutting.
• the drill neck with the chamfer is designed to cut weakly.
• the step guide has a length in the range of 2.0mm.
• the step drill is preferably of three-edged design and thus has three point cutters, bevels, guide cutters, spiral grooves, chamfers and step cutters.
• the drill neck has at least the length of the insertion depth of the implant to be applied.
• the step guide of various, namely first, second and third step drills has a diameter in the range of 2.0mm, 2.8mm and 3.5mm and the neck of these first, second and third step drills has the associated diameter in the range of 2.8mm, 3.5mm and 4.3mm.
• the tip that spans between the cutting edges angle is greater than 90 °, preferably it is in the range of 120 °.
• the spiral grooves extend continuously from the coronal end of the drill neck to the tip of the step, whereby the spiral grooves on the step guide, due to the smaller diameter, only have a portion of their full cross-section, as is present on the drill neck.
• several visible depth markings are attached to the drill neck at equal or unequal intervals.
• the stepped guide with the stepped tip and the blunt guide cutting edges is designed to center the stepped drill bit when it is being inserted into the pilot hole or stepped hole and to guide it centered along the pilot hole or stepped hole.
• the step with the step cutting edges is intended to widen the pilot hole with the previous diameters to new diameters or to widen the step hole with the previous diameters to the new diameters.
• a drill set for preparing and creating an implant bed for receiving a dental implant in a blind hole-shaped step hole to be made in the human jaw bone, which initially consists of a pilot drill described above for making a pilot hole.
• the drill set also includes at least a first step drill as described above for enlarging the existing pilot hole to form a step hole.
• the drill set is complemented by an optional second step drill described above for the second enlargement of an existing step hole to a further enlarged step hole.
• the drill set can include an optional third step drill described above for the third enlargement of the step hole, which has already been enlarged twice, to form a step hole that has been enlarged for the last time.
• Figure 1A a pilot drill according to the invention
• Figure 1 B the enlarged detail X1 of Figure 1A with the tip of the pilot drill;
• FIG. 2A a first step drill according to the invention with the smallest diameter
• FIG. 2B the enlarged detail X2 from FIG. 2A with the tip of the first step drill
• Figure 3A a second step drill with a medium diameter
• FIG. 3B the enlarged detail X3 from FIG. 3A with the tip of the second step drill
• FIG. 4A a third step drill with the largest diameter
• FIG. 4B the enlarged detail X3 from FIG. 3A with the tip of the third step drill
• Figure 5 a depth gauge for the pilot drill according to Figure 1A;
• FIG. 6 a depth gauge for the first step drill according to FIG. 2A;
• FIG. 7 a depth gauge for the second step drill according to FIG. 3A;
• FIG. 8 a depth gauge for the third step drill according to FIG. 4A;
• FIG. 9 a dental implant known per se for insertion into a bore produced with the first step drill according to FIG. 2A;
• Figures 10 to 13 the basic operational handling of the drill set, starting with the removal aisle situation according to FIG. 10, step 1, until the finished bore is created according to FIG. 11, step 10 (for the smallest implant diameter); Figure 12, step 14 (for the mean implant diameter); Figure 13, step 18 (for the largest implant diameter);
• Step 1 - generating the pilot guide in the cortex with the pilot drill according to FIG. 1A;
• Step 2 optical control of the position of the pilot guide generated;
• Step 3 insertion of the pilot drill into the existing pilot guide and final determination of the direction of the bore;
• Step 4 Create the pilot hole at full depth
• Step 5 Check the drilling depth with the depth gauge according to Figure 5 for the pilot drill; Step 6 - visual inspection of the pilot hole produced;
• Step e optical control of the pilot bore produced (takeover of FIG. 10, step e); Step 7- Insert the first step drill according to FIG. 2A into the existing pilot hole; Step 8 - create the first step hole to the full depth; Step 9 - Check the drilling depth with the depth gauge according to Figure 6 for the first step drill; Step 10 - optical inspection of the first step bore produced;
• Step 10.1 - Option insert the implant with the smallest diameter according to FIG. 9;
• Step 10.2- Option inserted implant with the smallest diameter according to Figure 9;
• Figure 12
• Step 10 visual inspection of the first step bore (takeover of FIG. 11, step 10);
• Step 11 inserting the second step drill according to FIG. 3A into the existing first step hole
• Step 12 - create the second stepped bore to the full depth
• Step 13 Check the drilling depth with the depth gauge according to Figure 7 for the second step drill;
• Step 14 visual inspection of the second stepped bore; Step 14.1 - Option: insert the implant with the medium diameter;
• Step 14.2- inserted implant with the medium diameter
• Step 14 optical control of the second step bore (takeover of Figure 12, step 14);
• Step 15 inserting the third step drill according to FIG. 4A into the existing second step hole;
• Step 16 create the third step hole to full depth
• Step 17 Check the drilling depth with the depth gauge according to Figure 8 for the third step drill
• Step 18 optical control of the third stepped bore produced
• Step 18.1 insert the implant with the largest diameter
• FIG. 14A a representation of all drill cross sections one above the other
• FIG. 14B a representation of all drill cross sections with a description of the matching diameters of guide and neck
• FIG. 14C the tip of the implant with the largest diameter lying in the cross section of the third step drill.
• the pilot drill 1 is used to prepare a blind hole-shaped stepped bore to be inserted into a jaw bone for receiving a dental implant.
• the pilot tip 10 is located at the apical end of the pilot drill 1, with the tip cutting edges 101 arranged thereon, which include the tip angle ⁇ .
• a pilot guide 11 extends from the pilot tip 10 in the direction of the coronal end of the pilot drill 1. Above the pilot guide 11 is the drill neck 12, which has a larger drill diameter b2 than the drill diameter b1 of the pilot guide 11.
• the drill shaft 13 is connected to the drill neck 12 and, at the coronal end of the pilot drill 1, a standardized dental coupling 14 is provided, which is used for receiving in a dental handpiece, as is typical on drilling machines.
• the tip cutting edges 101 on the pilot tip 10 are sharp and center-cutting. From the tip cutting edges 101, cuts 111 extend upward from the pilot guide 11.
• the step cutting edges 125 on the step 124 are designed to be cutting, while the guide cutting edges 112 are blunt, non-cutting.
• the entire drill neck 12 with the chamfer 123 is weak cutting edge.
• the pilot guide 11 has a length 11 in the range from 1.0 mm to 4.0 mm.
• the pilot drill 1 is preferably of double-edged design and thus each has two tip cutting edges 101, bevels 111, guide cutting edges 112, spiral grooves 122, chamfers 123 and step cutting edges 125.
• the drill neck 12 has at least the length of the insertion depth of the implant to be applied, and the pilot guide 11 has this Length 11 by 3.0mm.
• the pilot guide 11 has the diameter b1 in the range of 1.5 mm and the drill neck 12 has the diameter b2 in the range of 2.0 mm.
• the tip angle ⁇ lying between the tip cutting edges 101 is less than 90 °; ⁇ is preferably in the range of 80 °.
• the spiral grooves 122 extend continuously from the coronal end of the drill neck 12 into the pilot tip 10.
• the spiral grooves 122 due to the smaller diameter b1, only have a portion of their full cross section as is present on the drill neck 12.
• several visible depth markings 121 are attached to the drill neck 12 at equal or unequal intervals.
• a step drill 2 serves to enlarge a blind hole-shaped pilot hole in a jawbone to form a step hole or to further enlarge an existing step hole to a further enlarged step hole as a receptacle for a dental implant.
• the step tip 20 lies with the tip cut 201.
• the step guide 21 is located above the step guide 21 which extends is the drill neck 22, which has a larger drill diameter b3, b4, b5 comprising than the drill diameter b2, b3 ', b4 The step guide 21.
• Above the drill neck 22 is the drill shaft 23, to which a standardized dental coupling 24 connects as the coronal end.
• the step guide 21 of the first, second and third step drill 2 has a uniform length 12, 13, 14 in the range of 2.0 mm.
• the step drill 2 is preferably of three-edged design and thus each has three point cutting edges 201, bevels 211, guide cutting edges 212, spiral grooves 222, chamfers 223 and step cutting edges 225.
• the drill neck 22 has at least the length of the insertion depth of the implant to be applied.
• the step guide 21 on the first step drill 2 has the diameter b2 "in the range of 2.0 mm, while the associated drill neck 22 has the diameter b3 in the range of 2.8 mm.
• the step guide 21 on the second step drill 2 has the diameter b3 'in the range of 2.8 mm, the drill neck 22 having the diameter b4 in the range of 3.5 mm Finally, the step guide 21 on the third step drill 2 has the diameter b4 'in the range of 3.5 mm and its drill neck 22 has the diameter b5 in the range of 4.3 mm.
• the point angle ⁇ lying between the tip cutting edges 201 is greater than 90 °, preferably ⁇ lies in the range of 120 °.
• the spiral grooves 222 extend continuously from the coronal end of the drill neck 22 to the step tip 20.
• the spiral grooves 222 only take up a portion of their full cross-section, such as it is present on the drill neck 22. Again to control the drilling depth during the drilling process, several visible depth markings 221 are attached to the drill neck 22 at equal or unequal intervals.
• the depth gauge 3 according to FIG. 5 for the pilot drill 1 has apically the guide 31 with the diameter t1, the length k1 and the tip 30 lying at the bottom.
• the neck 32 with the depth markings 321 adjoins the guide 31.
• the neck 32 is followed by a holding area 33 with the transition 331 to the head 332.
• the diameter t1 of the guide 31 is the same or slightly smaller than the diameter b1 of the pilot guide 11 of the pilot drill 1.
• the length k1 of the guide 31 is preferably slightly larger than the length 11 of the pilot guide 11 of the pilot drill 1 designed.
• the diameter t2 of the neck 32 of the depth gauge 3 is also dimensioned equal to or slightly smaller than the diameter b2 of the drill neck 12 of the pilot drill 1.
• the diameter and length ratios allow the depth gauge 3 to be easily inserted into a borehole for measuring the depth, and the effective depth of the borehole generated can be reliably determined by determining the sinking depth at the depth markings 321.
• the depth gauge 3 according to FIG. 6 for the first step drill 2 has on its guide 31 the diameter t2 ⁇ which is the same or slightly smaller than the diameter b2 'on the step guide 21 of the first step drill 2.
• the length k2 of the guide 31 is preferably minimally greater than the length 12 of the step guide 21 of this step drill 2.
• the diameter t3 of the neck 32 is also the same or slightly smaller than the diameter b3 of the drill neck 22 of the first step drill 2.
• the depth gauge 3 according to FIG. 7 for the second step drill 2 has on its guide 31 the diameter t3 'which is the same or slightly smaller than the diameter b3' on the step guide 21 of the second step drill 2.
• the length k3 of the guide 31 is minimally greater than the length 13 of the step guide 21 of this step drill 2.
• the diameter t4 of the neck 32 is also the same or slightly smaller than the diameter fo4 of the drill neck 22 of the second step drill 2.
• the depth gauge 3 according to FIG. 8 is designed analogously for the third step drill 2.
• the guide 31 has the diameter t4 ′, which corresponds to the diameter b4 ′′ on the step guide 21 of the third step drill 2.
• the length k4 of the guide 31 corresponds to the length 14 of this third step drill 2
• the diameter t5 on the neck 32 corresponds to the diameter b5 on the drill neck 22 of the third step drill 2.
• FIG. 9 The implant 4 is of a shape known per se and begins apically with the tip 41, which is first followed by a shaft 42 and a neck 43 as the coronal end.
• a threading geometry 44 extends from the tip 41 into the shaft 42, which is provided with an external thread 421 and has the core diameter i3. Stronger implants 4 have the core diameter i4 or i5 (see FIGS. 12 and 13).
• the rounding 411 at the is of particular importance in relation to the hole to be made in the jawbone Implant tip 41 and the cone 412 with the cone cutting area 441 and the thread cutting area 442. With this geometry, when the screw is screwed into a hole prepared accordingly in the jaw bone, the bone chips produced thereby provide a precise fit for the implant 4, without larger cavities and without excessive bone compression.
• the handling with the pilot drill 1 and the associated depth gauge 3 is now explained.
• the oral situation is shown schematically with the jawbone 5, i.e. without the gingiva. It is assumed that the pilot drill 1 is used in the handpiece of a conventional dental drill.
• the cortex 51 under which the cancellous bone 52 lies, is pierced with the pilot tip 10 at the intended position in the jawbone 5.
• the pilot drill 1 is oriented in the bore direction R.
• the surgeon feels increased resistance as soon as step 124 touches the cortex, which he uses as a sign to interrupt the drilling process and transfer it to the second step.
• Step.? A visual check of the position of the pilot bore 61, which has been introduced into the jawbone 5 to a certain extent, with the pilot bore tip 610 and the pilot bore guide 611 which penetrates the hard cortex 51 is carried out. In particular, it is checked whether the direction of bore R corresponds to the planning.
• the pilot guide 11 with the pilot tip 10 are therefore intended to determine the position of the stepped bore 62, 63, 64 to be produced further by introducing a shoulder of a pilot bore 61 through the cortex 51.
• the pilot drill 1 which is still at a standstill, is again placed in the started pilot bore 61.
• the planned drilling direction R is determined in relation to the surrounding mouth situation and the further drilling process is started, which defines the definitive drilling direction R.
• the blunt guide cutting edges 112 make this correction possible without widening the pilot bore guide 611.
• Step ⁇ The associated depth gauge 3 with the diameter t2 on the neck 32 is inserted into the pilot bore 61 and by determining the sinking depth by reading off the depth markings 321, the pilot bore 61 produced is checked for its exact depth.
• the pilot bore 81 produced with the pilot bore tip 810 lying at the bottom of the bore, the pilot bore guide 611 adjoining it and the pilot bore neck 612 which rises coronally and which opens at the cortex 51 is checked optically.
• first step drill 2 This is followed by handling with the first step drill 2 and the corresponding depth gauge 3. It is assumed that the first step drill 2 and possibly the second and third step drill 2 used subsequently are used in a dental handpiece.
• the pilot bore 61 produced was checked optically (as a takeover of
• the step guide 21 with the drill diameter b2 ' is inserted into the pilot hole 61 and checked for correct alignment.
• the drilling process is started and a first stepped bore 62 to the full
• Drilled out depth Optimal centering in the pilot bore 61 is ensured by the step guide 21 provided on the step drill 2, the guide cutting edges 212 of which are blunt, and the laterally non-cutting neck 22. A lateral drift of the hole is excluded in principle.
• the step drill 2 has excellent centering properties.
• the step 224 with the step cutting edges 225 causes the pilot bore 61 with the diameters d1 / d2 to be widened to the diameter d2 / d3.
• the associated depth gauge 3 with the diameter t3 on the neck 32 for the first step drill 2 is inserted into the first step hole 62 generated in order to check the drilling depth reached.
• Optical control of the first step bore 62 produced which is composed of the step tip 620 lying on the bottom of the hole, the subsequent step guide 621 and the step neck 622 ascending coronally and ending in the cortex 51.
• the implant 4 with the smallest core diameter i3 lies in situ in the first
• Stepped bore 62 Stepped bore 62.
• the first stepped bore 62 produced was checked optically (as a takeover of step 10 from FIG. 11).
• Step . First 1 From the second step drill 2 - with the diameter b4 on the drill neck 22 - the step guide 21 with the drill diameter b3 'is inserted into the existing first step bore 62 and checked for correct alignment.
• Step . First 2
• the drilling process was started and a second stepped bore 63 was drilled to the full depth.
• the step 224 with the step cutting edges 225 causes the first step bore 62 with the diameters d2 / d3 in the resulting second step bore 63 to be widened to the diameter d3 / d4.
• the corresponding depth gauge 3 with the diameter t4 on the neck 32 for the second step drill 2 is inserted into the second step hole 63 produced in order to check the drilling depth reached.
• Optical control of the generated second stepped bore 63 which, analogously to the first stepped bore 62, is composed of the stepped tip 630 lying on the bottom of the bore, the following stepped guide 631 and the stepped neck 632 rising in the coronal direction. Sch ⁇ tt.14.1.
• An implant 4 with the mean core diameter i4 can be inserted in the second step bore 63 which is now present.
• the implant 4 with the average core diameter i4 lies in situ in the second stepped bore 62.
• the generated second stepped bore 63 was checked optically (as a takeover of step 14 from FIG. 12).
• Step . First 5 From the third step drill 2 - with the diameter b5 on the drill neck 22 - the step guide 21 with the drill diameter b4 'is inserted into the existing second step bore 83 and again checked for correct bore direction R.
• the drilling process was carried out and a third stepped bore 64 was drilled to full depth.
• the step 224 with the step cutting edges 225 caused the second step bore 63 with the diameters d3 / d4 in the resulting third step bore 64 to be widened to the diameter d4 / d5.
• Optical control of the third stepped bore 64 produced which is composed of the stepped tip 640, the stepped guide 641 and the stepped neck 642 analogously to the previous stepped holes 62, 63.
• the implant 4 with the largest core diameter i5 lies in situ in the third stepped bore 64.
• FIGS. 14A and 14B In this schematic representation, all of the drill cross sections 61, 62, 63, 64 lie one above the other, as they are made in the jawbone 5 before the insertion of an implant 4 with the largest diameter i5 in the sequence of the previously described working cycles. It can be seen that around the pilot hole 61 - with the pilot hole tip 610, the pilot hole guide 611 and the pilot hole neck 612 - all further step holes 62, 63, 64 made afterwards - with the corresponding step tips 620, 630, 640, the associated step guides 621, 631, 641 and step necks 622,632,642 - are centered and have the same drilling depth.
• the diameter b2 on the drill neck 12 of the pilot drill 1 is at least almost identical to the diameter b2 'on the step guide 21 of the first step drill 2.
• at least almost identical diameters also result in the resulting bores, namely the pilot drill neck 612 and the first step guide 621, which both are labeled d2.
• the bore diameter d1 was produced by the pilot guide 11 of the pilot drill 1 with the bore diameter b1.
• the bore diameters d3 and d4 originate from the at least almost identical diameters b3 on the drill neck 12 of the first step drill 2 and the diameter b3 'on the step guide 21 of the second step drill 2 or of the diameters b4 on the drill neck 12 of the second step drill 2 and the diameter b4 'on the step guide 21 of the third step drill 2.
• This facilitates the insertion and penetration of the outside non-cutting step guide 21 with the blunt guide cutting edges 212 into the pilot neck 612 of the pilot bore 61 or into the step neck 622, 622 of the first or second step bore 62, 63.
• FIG. 14C shows in principle how the tip 41 of the implant 4 with the largest diameter i5 lies in the cross section of the third stepped bore 64 with diameter d5.
• the rounding 411 from the implant tip 41 fits well into the step tip 640 of the third step bore 64.
• the cross section of the step guide 641 of the local step bore 64 is minimally smaller than the cross section of the cone 412 of the implant tip 41.
• it has a cutting edge geometry 44 with a cone cutting area 441. As a result, particles are cut off from the bone 5 in the region of the cone 412 and the bore cross section is expanded accordingly.

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• Health & Medical Sciences (AREA)
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• 2004
  • 2004-01-19 DE DE202004000723U patent/DE202004000723U1/de not_active Expired - Lifetime
  • 2004-01-27 WO PCT/CH2004/000042 patent/WO2004080325A1/de not_active Ceased
  • 2004-01-27 ES ES04705368.1T patent/ES2609387T3/es not_active Expired - Lifetime
  • 2004-01-27 EP EP04705368.1A patent/EP1601302B1/de not_active Expired - Lifetime
  • 2004-01-27 US US10/549,266 patent/US20060210949A1/en not_active Abandoned
  • 2004-01-27 JP JP2006504140A patent/JP4495147B2/ja not_active Expired - Lifetime

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