KR200377963Y1 - Dental Implant Fixture - Google Patents

Abstract

The present invention relates to a fixture of a dental implant, the fixture of the dental implant according to the present invention, in the fixture of the dental implant embedded in the alveolar bone, having a peak and axially by the bones A body portion having a series of spaced apart circumferentially arranged mountains, the body portion having a peak and including a first uneven portion including a series of mountains arranged circumferentially spaced axially by valleys, The height of the mountains measured from the valley to the peak is greater than the height of the mountains measured from the valley to the peak of the first uneven portion is characterized in that the alternately formed with each other. This increases the adhesion surface with the surrounding bone without increasing the length and diameter of the fixture and distributes the load evenly to the surrounding bone tissue to prevent bone fracture and bone destruction of the surrounding bone more efficiently than before. In addition, by allowing the dentist to select an appropriate procedure according to the condition of the patient, there is provided a fixture of a dental implant that can facilitate the procedure than the prior art.

Description

Dental Implant Fixtures

The present invention relates to a fixture of a dental implant, and more particularly, to a fixture of a dental implant embedded in the alveolar bone for implantation of artificial teeth.

Implants are originally a substitute that recovers when human tissue is lost, but dental implants refer to implanting artificial teeth. It is a cutting-edge procedure that restores the function of teeth by planting a tooth root made of titanium (Titanium), etc., which has no rejection on the human body to replace the root of the lost tooth, and fixing the artificial tooth. In the case of a general prosthesis or denture, the surrounding teeth and bones are damaged over time, but the implants do not damage the surrounding dental tissues, and they have the advantage that they can be used semi-permanently because they have the same function or shape as natural teeth and do not cause tooth decay.

The fixture of such a dental implant is embedded in the upper and lower alveolar bone (hereinafter, referred to as 'alveolar bone') 107 as shown in FIG. 1, which is briefly described, first, fixture (Fixture) 101. The artificial roots are bone-bonded to be completely fixed to the bones like the roots of natural teeth, and after the bones are bonded, an artificial dental support structure (not shown) is connected to the fixture 101 of the implant, When the crown 105 is mounted, the implant artificial tooth is completed. At this time, the fixture 101 of the dental implant passes through the dense bone 107a having a high bone density and is embedded in the spongy bone 107b having a low bone density.

On the other hand, the fixture 101 of the dental implant implanted in the alveolar bone 107, unlike natural teeth coupled to the bone tissue through the periodontal ligament, does not have a physiological movement of the bone by being directly adhered to the bone tissue. . Therefore, the load (low pressure) received from the outside is transmitted to the periphery bones 107a and 107b, and thus, a large stress is generated in the periphery bones 107a and 107b receiving the external load. In particular, the bone density is high and the rigid dense bone 107a has a greater stress due to the characteristics of the material, and as such a large stress is continuously applied to the dense bone 107a, it is pointed out that problems such as bone collapse and bone fracture occur have.

In order to solve this problem, the depth of implantation of the fixture 101 of the implant is increased by lengthening and lengthening the length and diameter of the fixture 101 of the implant in a manner of minimizing the stress of the peripheral bones 107a and 107b. By increasing the adhesion surface between the periphery bone 107a, 107b, it is possible to consider a method of increasing the adhesion efficiency while uniformly dispersing the generated stress. However, such a method cannot increase the length and diameter of the fixture 101 of the implant in a limited space indefinitely, and thus has been pointed out a problem that there is a limit in reality.

Therefore, in consideration of these problems, first, an implant fixture in which the height of peaks measured from the valley to the vertex is 0.2 mm or less (hereinafter referred to as 'micro threads') in its entire length is disclosed internationally. No. WO94 / 07428 is disclosed, but in this case, since the height of the micro thread is low, the drill hole formed by drilling work on the alveolar bone can be properly adhered, and the hole is smaller than the desired diameter. If it is difficult to sell, and if the processing is large, the adhesion rate is significantly reduced, such as a problem that the dentist is difficult to perform the procedure.

Next, pay attention to the fact that the bone density is high and the rigid dense bone has a higher stress due to the characteristics of the material, so that the microjoints are formed on the part of the spongy bone and larger than the part of the dense bone. About 0.3mm to 0.6mm) implant fixtures that form threads (hereinafter referred to as 'macro threads') are disclosed in Korean Patent Application Laid-Open No. 2001-0071941 and Korean Patent Publication No. 2003-0083157 and the like. Disclosed is to reduce the stress generated in the dense bone to prevent bone collapse and bone fracture of the dense bone. However, even in these cases, since the stress generated in the cancellous bone is not properly distributed, it is still difficult to achieve the purpose of preventing bone collapse and bone fracture.

As described above, in the conventional dental implant fixture, when micro-threads are formed along the entire length of the fixture in order to properly disperse the stress so as to prevent bone collapse and bone fracture, the hole in the alveolar bone is precisely processed. There was a problem that the dentist had difficulty in performing the procedure, and if the micro-thread is formed only at the part that is joined to the dense bone, the stress generated in the spongy bone cannot be properly distributed, which is insufficient to prevent bone collapse and bone fracture. there was. In addition, since only the macro screw thread is formed at the portion to be joined to the cancellous bone, there is a problem that the dentist cannot select an appropriate procedure according to the patient.

On the other hand, in the fixture of a conventional dental implant, the upper end has a tapered shape that gradually increases toward the upper end, which is intended to increase bone adhesion by increasing the contact area or to reach an appropriate position. In order to embed the fixture, more force was required to recognize that the proper position was reached, but in practice, the alveolar bone not only had a micro thread formed at the upper end but also a tapered shape that gradually widened toward the upper end. It requires a lot of power to completely bury the dental implant fixture is not able to completely bury the alveolar bone or had a problem that is quite difficult to implant.

Accordingly, an object of the present invention is to solve the problems of the prior art, to increase the adhesion surface with the surrounding bone without increasing the length and diameter of the fixture and to distribute the load to the surrounding bone tissue more efficiently than before. It is possible to prevent bone fracture and bone fracture of the surrounding bone, and by providing a dental implant fixture that allows the dentist to select an appropriate treatment method according to the patient's condition, which can facilitate the procedure. .

In addition, another object of the present invention is to provide a fixture of a dental implant that can make it easier than before to completely implant the fixture of the implant into the alveolar bone.

The object, according to the present invention, in a fixture of a dental implant embedded in an alveolar bone, comprises a body having a peak and having a series of mountains arranged circumferentially spaced axially by the bones. The body portion has a peak and includes a first uneven portion including a series of mountains arranged circumferentially and axially spaced by the valleys, and the height of the mountains measured from the valley to the peak is measured by the valleys of the first uneven portion. It is achieved by the fixture of the dental implant, characterized in that the second irregularities larger than the height of the mountains measured from the peak to the peak are formed alternately with each other.

Here, the height of the mountains measured from the valleys to the peak of the second uneven portion of the body portion is preferably 0.5mm to 0.05mm larger than the height of the mountains measured from the valleys to the peak of the first uneven portion.

The heights of the mountains measured from the valleys to the peaks of the first uneven portions of the trunk may be 0.02 mm to 0.2 mm, and the heights of the mountains measured from the valleys to the peaks of the second irregularities of the trunk may be 0.25 to 0.6 mm.

Further, at least one of the first uneven portion and the second uneven portion is preferably provided by a thread profile having mountains arranged in the circumferential direction defined by the thread element in the thread side view.

And a tubular portion disposed on the top of the body portion and having a peak and including a series of mountains circumferentially spaced axially by the valleys, wherein the heights of the mountains measured from the valleys to the peaks of the tubular portion are The height of the mountains measured from the valleys to the peaks of the second uneven portion of the trunk portion is preferably lower, and the tubular portion and the trunk portion are configured to exhibit substantially the same lead.

Further, the axial spacing between the peaks of the adjacent mountains in the tubular portion is an axial spacing between the peak of the peak of the first uneven portion of the body portion and the peak of the peak of the second uneven portion adjacent to the mountain of the first uneven portion. Preference is given to substantially the same as.

The tubular portion is provided by a thread profile having mountains arranged in the circumferential direction defined by the threading elements in the thread side view, wherein the screw of the tubular portion may be a double screw.

In addition, the height of the mountains measured from the valley to the peak of the tubular portion may be 0.02mm to 0.2mm.

In addition, the tubular portion is cylindrical, and the outer diameter of the tubular portion is preferably 0.05 mm to 1 mm larger than the outer diameter of the body portion.

In addition, the body portion and the tubular portion may be provided adjacent to.

Hereinafter, with reference to the accompanying drawings will be described in detail for the subject innovation.

2 is a perspective view of a fixture of a dental implant according to an embodiment of the present invention, Figure 3 is a cross-sectional view according to III-III of Figure 2, Figure 4 is a plan view of the fixture of the dental implant of Figure 2 5 is a bottom view of the fixture of the dental implant of FIG. 2. As shown in these figures, the fixture 1 of a dental implant according to one embodiment of the present invention has a torso having a peak and having a series of mountains arranged circumferentially axially spaced by bones. The part 10 and the tubular part 20 arrange | positioned at the upper part of the trunk part 10 are provided. The trunk portion 10 includes a first uneven portion 13 having a peak and including a series of mountains circumferentially disposed axially by the valleys, and the height h2 of the mountains measured from the valley to the peak. The second concave-convex portion 15 larger than the height of the mountains (h ₁ ) measured from the valley to the peak of the first concave-convex portion 13 is alternately formed. That is, the first uneven portion 13 and the second uneven portion 15 having different heights h ₁ and h ₂ measured from valleys to peaks are alternately formed along the circumferential direction. .

Fixture (1) of the dental implant according to an embodiment of the present invention is embedded in the alveolar bone, it is bone-bonded to be completely fixed to the alveolar bone like the roots of natural teeth, and after the bone adhesion artificial artificial support structure (abutment) (Not shown) is connected to the artificial dental implant (not shown) to complete the implant artificial tooth. At this time, the fixture 1 of the dental implant (1), generally at least a portion of the body portion 10 is in contact with the sponge bone of low bone density of the alveolar bone and the tubular portion 20 to the high density bone of the alveolar bone It is buried to come into contact with the bone. And the dental implant fixture 1 is usually made of pure titanium or titanium alloys or other metals, metal alloys or ceramics that are free of human body rejection.

The trunk portion 10 has an alternating recess portion 11 and a lower end portion 17 disposed below the alternating recess portion 11. The alternately uneven portion 11 has a peak as described above, and includes a first uneven portion 13 including a series of mountains circumferentially spaced axially by the valleys, and mountains measured from the valleys to the peaks. has a height (h ₂₎ of the first height of the mountains been measured from the bone to the peak (h ₁₎ the larger the second concave-convex portion 15 than the concave and convex portion 13 are formed in a mutually alternating (交番) enemy. Here, the height h ₁ of the mountains measured from the valley of the first uneven portion 13 of the trunk portion 10 to the peak may be selected from 0.02 mm to 0.2 mm, and the second unevenness of the trunk portion 10 may be selected. The height h _{2 of the} mountains measured from the valley of the section 15 to the peak may be selected from 0.25 to 0.6 mm. The height h ₂ of the mountains measured from the valleys of the second uneven portions 15 of the trunk portion 10 to the peaks is the height h _{1 of the} mountains measured from the valleys of the first uneven portions 13 to the peaks thereof. ) 0.5 mm to 0.05 mm larger, preferably 0.3 mm to 0.15 mm larger. Further, the first concave-convex portion 13 and the second concave-convex portion 15 may be provided by a thread profile having mountains arranged in the circumferential direction defined by the thread element in the thread side view. That is, the first concave-convex portion 13 and the second concave-convex portion 15 are screws having different heights of the threads, and thus, the alternate concave-convex portions 11 of the trunk portion 10 alternate with each other. Iii) If the tubular portion 20 to be described later is a double screw as a multi-threaded arrangement, the first concave-convex portion 13 and the second concave-convex portion 15 of the alternate concave-convex portion 11 are one line. As a result, the alternately uneven portion 11 is a double screw in which screws having different heights of threads are alternately arranged.

As the trunk portion 10 is arranged such that screws having different heights of threads are alternately arranged, that is, a screw having a low thread height is formed in the trunk portion 10 and thus the trunk portion 10 is formed in the trunk portion 10. Increasing the adhesion surface of spongy bone tissue of adjacent alveolar bone and distributing the load evenly to spongy bone tissue of adjacent alveolar bone, resulting in avoiding large stress concentration, thus preventing bone collapse and bone fracture more efficiently than before. . In addition, since both the first concave-convex portion 13 and the second concave-convex portion 15 are formed in the torso 10, the dentist can select an appropriate treatment method according to the condition of the patient.

In addition, the lower end portion 17 disposed below the alternating recess portion 11 has a truncated conical shape in which the width of the fixture 1 becomes narrower toward the lower portion so as to be easily inserted into the hole of the alveolar bone. In addition, the three uneven parts 11 and the lower part 17 have three self-tapping grooves symmetrically disposed with respect to the central axis for self-tapping when the fixture 1 of the dental implant is inserted into the hole of the alveolar bone ( 18a, 18b, 18c).

On the other hand, the tubular portion 20 disposed on the upper portion of the body portion 10 has a peak and has an uneven portion 21 including a series of mountains arranged in the circumferential direction axially spaced by the valleys, and the fine portion ( 21 has an upper end 23 disposed above it. The height h ₃ of the mountains measured from the valley of the uneven portion 21 of the tubular portion 20 to the peak is the height of the mountains measured from the valley of the second uneven portion 15 of the trunk portion 10 to the peak ( h ₂ ), which is approximately similar to the height h _{1 of the} mountains measured from the valley of the first uneven portion 13 of the trunk portion 10 to the peak, ie, from the valley of the tubular portion 20 to the peak. The height h ₃ of the measured mountains may be selected from 0.02 mm to 0.2 mm, but is equal to the height h _{1 of the} mountains measured from the valleys of the first uneven portion 13 of the trunk portion 10 to the peak. It is preferable not to be provided. And the tubular portion 20 and the torso 10 are configured to exhibit substantially the same pitch, more precisely, substantially the same lead, and also between peaks of adjacent mountains in the tubular portion 20. The axial spacing d ₂ is the peak of the peak of the first uneven portion 13 of the trunk portion 10 and the peak of the peak of the second uneven portion 15 adjacent to the peak of the first uneven portion 13. It is preferred to be constructed substantially the same as the axial gap d ₁ in between. For example, when the body portion 10 is a two-threaded screw, that is, a double screw composed of the first uneven portion 13 and the second uneven portion 15, each of which is a single line screw, the tubular portion 20 is an uneven portion. The first uneven portion 13, which is a double screw disposed between the second uneven portion 15 and the second uneven portion 15, in which 21 is a two-line screw or a double screw, and the trunk portion 10 is a single-line screw. If formed as a tubular portion 20 may be composed of three screws, that is, three-line screws.

The tubular portion 20 is provided by a threaded profile having mountains arranged in the circumferential direction defined by the threaded elements of the threaded side view, in this embodiment the screw of the tubular portion 20 is a double screw or triple screw, Of course, it can be four screws. Angles formed between adjacent threads in the tubular portion 20 and the trunk portion 10 may be all configured the same, and the threads of the tubular portion 20 and the trunk portion 10 may be configured to be separated from each other. The fine concave portion 21 of the tubular portion 20 is smaller than the threaded portion of the second concave-convex portion 15 of the trunk portion 10, and thus is harder, so that the load can be more evenly distributed to the surrounding bone tissue, particularly the dense bone. .

Further, the tubular portion 20 is cylindrical, and the outer diameter of the tubular portion 20 is configured to be 0.05 mm to 1 mm larger than the outer diameter of the trunk portion 10, preferably 0.2 mm to 0.3 mm larger. That is, the difference h ₄ between the outer diameter of the tubular portion 20 and the outer diameter of the trunk portion 10 is preferably configured to be 0.2 mm to 0.3 mm. In order to achieve various effects such as bone adhesion enhancement, the conventional implant fixture 1 has a tubular portion 20 that is mostly conical, and due to the shape of the conical shape, a lot of load is required at the end of the feeding. As described above, there is a problem that the tubular portion 20 of the fixture 1 of the sea implant is not completely embedded in the dense bone of the alveolar bone. Therefore, in the present invention, by having the tubular portion 20 in a cylindrical shape, it is possible to complete the laying out more easily than conventionally. Instead, the outer diameter of the tubular portion 20 is configured to be larger than the outer diameter of the trunk portion 10 so as to widen the bone adhesion area to the dense bone of the alveolar bone.

An inner hole 30 is formed inside the fixture 1 of the implant that does not penetrate along the length but extends from the top to the center region of the body 10. The inner hole 30 receives an artificial dental support structure for supporting the artificial dental crown. The inner hole 30 has an upper conical tubular portion 31, a lower conical tubular portion 35 on which female threads are formed, and an intermediate portion 33 therebetween. The artificial dental support structure (abutment) has a truncated conical shape in which a male screw is formed so as to be screwed into a portion in which the female thread of the lower conical tube portion 35 is detachably fixed to the inner hole 30.

The length of the fixture 1 of the implant may range from 8 mm to 19 mm depending on the clinical situation and may have 3.5 mm or 4.0 mm as the outer diameter of the torso 10.

By such a configuration, the fixture (1) of the dental implant according to the present invention is bone-bonded so as to be completely fixed to the bone like the root of natural teeth, at least a portion of the body portion 10 to the sponge bone low bone density of the alveolar bone The tubular part 20 is contacted and bone-bonded so as to contact the high density bone of the alveolar bone, and connects an artificial crown support structure (not shown) to the fixture 1 of the implant after the bone adhesion. When the artificial dental crown is mounted on it, the implant artificial tooth is completed.

In the above-described embodiment, the first concave-convex portion 13 is formed between the second concave-convex portion 15 by one line screw, but the first concave-convex portion 13 is formed by the two-line screw between the second concave-convex portion 15. Of course, in the above-described embodiment with respect to the same pitch, the fine concave portion 21 of the tubular portion 20 is a double screw, but the fine concave portion of the tubular portion 20 21) can be composed of triple screws.

In the above-described embodiment, the first uneven part 13, the second uneven part 15, and the uneven part 21 of the tubular part 20 are screws. The peaks and valleys of the uneven portion 13, the second uneven portion 15, and the uneven portion 21 of the tubular portion 20 form beads along the circumferential direction or form various grooves. Of course, it can be prepared by.

In addition, in the above-described embodiment, although the fixture 1 of the implant is composed of the trunk portion 10 and the tubular portion 20, the fixture 1 of the implant 1 includes the first uneven portion 13 and the first. Naturally, the two uneven parts 15 may be composed of only the body parts 10 alternately formed.

As described above, according to the present invention, even without increasing the length and diameter of the fixture, the adhesion surface with the surrounding bone is increased and the load is evenly distributed to the surrounding bone tissue so that the bone decay of the surrounding bone is more efficient than before. There is provided a fixture of a dental implant that can prevent bone fracture and allow the dentist to select an appropriate treatment method according to the patient's condition to facilitate the procedure.

Further, by configuring the tubular portion joined to the dense bone of the alveolar bone to have a cylindrical shape, there is provided a dental implant fixture which makes it easier to conventionally embed the fixture of the implant in the alveolar bone.

1 is a front view of a fixture of a dental implant according to a conventional embodiment,

2 is a perspective view of a fixture of a dental implant according to an embodiment of the present invention,

3 is a cross-sectional view taken along line III-III of FIG. 2;

4 is a plan view of the fixture of the dental implant of FIG.

5 is a bottom view of the fixture of the dental implant of FIG. 2.

* Explanation of symbols for main parts of the drawings

     1: Fixture of dental implant 10: Torso

    11: shift uneven portion 13: first uneven portion

    15: the second uneven portion 17: the lower portion

    18a, 18b, 18c: Self Tapping Groove 20: Tubular Section

    21: fine iron portion 23: the upper portion

    30: inner hole 31: upper conical tube portion

    33: middle part 35: lower conical tube part

Claims (10)

In the fixture of the dental implant embedded in the alveolar bone, A body having a peak and having a series of mountains arranged circumferentially spaced axially by the valleys, The body portion has a peak and includes a first uneven portion including a series of mountains circumferentially spaced axially by the valleys, and the height of the mountains measured from the valley to the peak is peaked from the valley of the first uneven portion. Fixture of a dental implant, characterized in that the second concave-convex portions larger than the height of the mountains measured up to each other are formed alternately. The method of claim 1, The height of the mountains measured from the valleys to the peak of the second uneven portion of the body portion is 0.5mm to 0.05mm larger than the height of the mountains measured from the valleys to the peak of the first uneven portion. The method of claim 2, The height of the mountains measured from the bone to the peak of the first uneven portion of the body portion is 0.02mm to 0.2mm, the height of the mountains measured from the bone to the peak of the second uneven portion of the body portion is 0.25 to 0.6mm Implant fixtures. The method of claim 1, At least one of the first concave portion and the second concave portion is provided with a thread profile having threads arranged in the circumferential direction defined by the thread element of the thread side view. Chew. The method of claim 1, A tubular portion disposed on top of the body portion, the tubular portion having a peak and comprising a series of mountains axially spaced axially by valleys; The height of the mountains measured from the valley to the peak of the tubular portion is lower than the height of the mountains measured from the valley to the peak of the second uneven portion of the trunk portion, and the tubular portion and the trunk portion are configured to exhibit substantially the same lead. Fixture of dental implant, characterized in that. The method of claim 5, The axial spacing between peaks of adjacent mountains in the tubular portion is substantially equal to the axial spacing between the peak of the peak of the first uneven portion of the trunk portion and the peak of the peak of the second uneven portion adjacent to the peak of the first uneven portion. Dental implant fixtures, characterized in that the same. The method of claim 5, The tubular portion is provided by a threaded profile having mountains arranged in the circumferential direction defined by the threaded elements of the threaded side view, wherein the screw of the tubular portion is a double screw fixture of a dental implant. The method of claim 5, The height of the mountains measured from the valley to the peak of the tubular portion is a fixture of the dental implant, characterized in that 0.02mm to 0.2mm. The method of claim 5, The tubular portion is cylindrical, the fixture of the dental implant, characterized in that the outer diameter of the tubular portion is 0.05mm to 1mm larger than the outer diameter of the body portion. The method of claim 5, Fixation of the dental implant, characterized in that the body portion and the tubular portion is provided adjacent.