The present invention relates to a dental file that is used to shape and clean the root canal in dental treatment.
Reamers and files are used as dental root canal cutting instruments that are used to shape and clean the root canal in dental treatment (refer to, for example, Patent Literature 1). The reamer is used to cut the inside of the root canal mainly by being rotated. The file is used to cut the inside of the root canal by, for example, being rotated, and pushed and pulled in the axial direction.
General dental files include those used while holding a gripping portion by hand, and those used by connecting a gripping portion to a dental handpiece. The dental file includes a helical working portion that is tapered toward the distal end, a shaft that is continuous to a rear end of the working portion, and a gripping portion that is continuous to a rear end of the shaft.
The main performance required for such a dental file includes flexibility that allows following the complicated shape of the root canal, cutting ability that allows cutting the root canal appropriately, and fracture resistance that resists breakage during work. As these abilities increase, the root canal can be prepared more easily and more rapidly. As a result, burdens on practitioners and patients can be reduced.
Considering the above circumstances, an object of the present invention is to increase the flexibility, cutting ability, and/or fracture resistance of a dental file.
In order to achieve the above object, according to a feature of the present invention, there is provided a dental file including a working portion formed in a helix shape, wherein a shape of a cross section perpendicular to a longitudinal direction includes one arc-shaped portion, and three first to third linear portions that are continuous sequentially from the arc-shaped portion; a diameter of a virtual circle including the arc-shaped portion is set in such a manner as to decrease from a proximal end portion toward a distal end portion; a connection point between the first and second linear portions, and a connection point between the second and third linear portions are set in such a manner as to be located inside the virtual circle; and an angle that a diameter passing through a connection point between the arc-shaped portion and the first linear portion forms with the first linear portion is set in such a manner as to increase from the proximal end portion toward the distal end portion.
Consequently, if the dental file rotates, for example, in a direction from the arc-shaped portion to the first linear portion, mainly the connection point between the arc-shaped portion and the first linear portion performs cutting while the arc-shaped portion moves along the inner surface of a cut hole, and the angle that the diameter passing through the connection point between the arc-shaped portion and the first linear portion forms with the first linear portion is set in such a manner as to increase from the proximal end portion toward the distal end portion. Therefore, for example, it is possible to improve cutting performance, extraction performance, and flexibility up to the proximal end portion while reducing a cutting force near the distal end.
Moreover, in order to achieve the above object, according to a feature of the present invention, there is provided a dental file including a working portion formed in a helix shape, wherein a shape of a cross section perpendicular to a longitudinal direction includes one arc-shaped portion, and three first to third linear portions that are continuous sequentially from the arc-shaped portion; a diameter of a virtual circle including the arc-shaped portion is set in such a manner as to decrease from a proximal end portion toward a distal end portion; a connection point between the first and second linear portions is set in such a manner as to be located on the virtual circle; and a connection point between the second and third linear portions is set in such a manner as to be located inside the virtual circle.
Consequently, if the dental file rotates, for example, in a direction from the arc-shaped portion to the first linear portion, in addition to the connection point between the arc-shaped portion and the first linear portion, the connection point between the first and second linear portions performs cutting. Therefore, high cutting ability can be easily maintained. On the other hand, the connection point between the first and second linear portions is not diagonal to the connection point between the arc-shaped portion and the first linear portion, which reduces the risk of occurrence of, for example, a sudden stop of rotation due to bite during cutting. As a result, it can be easily configured in such a manner as to resist fracture due to impact.
According to the present invention, it is possible to increase the flexibility, cutting ability, and/or fracture resistance of a dental file.
Embodiments of the present invention are described in detail hereinafter with reference to the drawings. In the following embodiments and modifications, the same reference signs are assigned to constituent elements having similar functions, and descriptions thereof are omitted.
As illustrated in
The working portion 100a of the dental file 100 has a configuration where an envelope surface of an outer surface has a tapered shape of which cross section is reduced in size toward the distal end, and cross sections of a similar shape form a helix. More specifically, the shape of a cross section, which is perpendicular to a longitudinal direction, of the working portion 100a is formed as illustrated in, for example,
In other words, the above cross-sectional shape includes one arc-shaped portion 111 (a land portion), and three first to third linear portions 112 to 114 that are continuous sequentially from the arc-shaped portion 111. It is set in such a manner that the diameter of a virtual circle 101 that includes the arc-shaped portion 111 and is centered on O is reduced from the proximal end portion toward the distal end portion of the working portion 100a.
The linear portions 112 to 114 are neither necessarily nor strictly straight lines. Even if the linear portions 112 to 114 are, for example, curved to some extent, effects described below can still be obtained. For convenience's sake,
A connection point 122 between the first linear portion 112 and the second linear portion 113, and a connection point 123 between the second linear portion 113 and the third linear portion 114 are set in such a manner as to be located inside the virtual circle 101. Moreover, although not particularly limited, for example, the first linear portion 112 and the third linear portion 114 are formed parallel to each other, which allows facilitating a blade groove grinding process, and easily increasing the accuracy of the blade groove grinding process.
Assume that the rotation direction in which debris on the working portion 100a is delivered toward the proximal end during normal use of the dental file 100 is a main rotation direction R. In other words, specifically, if the helix of the dental file 100 is, for example, right handed, assume that a counterclockwise direction is the main rotation direction R as viewed from the distal end. When a rotation is performed in such a direction R, a connection point 121 between the arc-shaped portion 111 and the first linear portion 112 performs a cutting action with the rotation of the dental file 100. The rotation direction of the dental file 100 is not limited to the direction R, and, for example, a mode including a reverse rotation, or a mode that changes the rotation directions alternately may be used.
Moreover, angles A11 and A12 that a diameter of the virtual circle 101 passing through the connection point 121 between the arc-shaped portion 111 and the first linear portion 112 forms with the first linear portion 112 are set in such a manner that the angle at the distal end portion (for example, A11) is larger than the angle at the proximal end portion (for example, A12). The absolute magnitudes of the angles A11 and A12 are not particularly limited, but are set within a range of, for example, 10° to 40°.
The above angles A11 and A12 can be set by, for example, setting a distance from the center O of the virtual circle 101 to the first linear portion 112 relative to the diameter of the virtual circle 101 (the ratio of the distance) in such a manner that a distance L11 at the distal end portion is longer than a distance L21 at the proximal end portion.
Moreover, in fact, the settings can also be made by specifying the ratios of the distance L21 and a distance L22 between the first linear portion 112 and the third linear portion 114 to the diameter of the virtual circle 101 although not equivalent to the above settings. In other words, for example, especially if the cross-sectional shape of the dental file 100 is symmetric about a straight line passing through the center O of the virtual circle 101, and the first linear portion 112 and the third linear portion 114 are formed parallel, the ratios of the distances L21 and L22 between the first linear portion 112 and the third linear portion 114 to the diameter of the virtual circle 101 may be set in such a manner as to increase from the proximal end portion toward the distal end portion of the dental file 100. Moreover, central angles A21 and A22 of the arc-shaped portion 111 may be set in such a manner as to increase from the proximal end portion toward the distal end portion of the dental file 100.
Consequently, it is easy to exert effects at a stage where it is desired to slightly reduce the cutting force near the distal end (such as an early stage of root canal preparation), and in improvement in followability, for example, in a root canal that is curved near the root apex. Moreover, the cutting performance and the extraction performance improve up to a shank portion, and the flexibility also improves up to the shank portion. As a result, compatibility between the cutting ability and the operability can also be encouraged. Furthermore, a portion around the distal end is what is called “resilient”, which also facilitates improving rotation transmission ability.
An angular relationship similar to the above angles A11 and A12 at the distal end portion and at the proximal end portion of the dental file 100 can also be set by forming the shape of a cross section at the proximal end portion as illustrated in
In other words, an angle that a perpendicular from the center O of the arc-shaped portion 111 to the first linear portion 112 forms with a perpendicular from the center O to the third linear portion 114 (an angle subtended on the arc-shaped portion 111 side) is set in such a manner that an angle A31 at the distal end portion is smaller than an angle A33 at the proximal end portion. Consequently, the angles A11 and A13 that a diameter of the virtual circle 101 passing through a connection point 121 between the arc-shaped portion 111 and the first linear portion 112 forms with the first linear portion 112 can be set in such a manner that the angle at the distal end portion (for example, A11) is larger than the angle at the proximal end portion (for example, A13).
Consequently, again, not only can the cutting performance be obtained at an appropriate level at a stage where it is desired to slightly reduce the cutting force near the distal end (such as an early stage of root canal preparation) but also it becomes easy to exert an effect at a finishing stage and in cases where the cutting force is required along the entire length. Moreover, it is possible to increase the cutting force toward a shank portion while having the high ability to follow the shape of a curved root canal. Moreover, the cutting performance and the extraction performance improve up to the shank portion, and the flexibility also improves up to the shank portion. As a result, compatibility between the cutting ability and the operability can also be encouraged.
A cross-sectional shape according to a third embodiment is formed as illustrated in, for example,
A connection point 122 between the first linear portion 112 and the second linear portion 113 is set in such a manner as to be located on the virtual circle 101. Furthermore, a connection point 123 between the second linear portion 113 and the third linear portion 114 is set in such a manner as to be located inside the virtual circle 101. Moreover, although not particularly limited, for example, the first linear portion 112 and the third linear portion 114 are formed perpendicular to a chord 103 of the arc-shaped portion 111 and parallel to each other, which allows facilitating a blade groove grinding process, and easily increasing the accuracy of the blade groove grinding process.
Assume that the rotation direction in which debris on the working portion 100a is delivered toward the proximal end during normal use of the dental file 100 is a main rotation direction R. In other words, specifically, if the helix of the dental file 100 is, for example, right handed, assume that a counterclockwise direction is the main rotation direction R as viewed from the distal end. Two connection points 121 and 122 that are located on the virtual circle 101 as described above are provided and perform cutting when a rotation is performed in such a direction R. As a result, high cutting ability can be easily maintained.
On the other hand, the connection point 122 is located at a position that is offset from a diameter passing through the connection point 121, and the connection point 123 that is diagonal to the connection point 121 is inside the virtual circle 101, which reduces the risk of occurrence of, for example, a sudden stop of rotation (lock) due to bite during cutting. Therefore, it can also be configured to resist fracture due to impact resulting from lock. The rotation direction of the dental file 100 is not limited to the direction R, and a mode including a reverse rotation, or a mode where the rotation directions change alternately may be used.
Moreover, the connection point 123 between the second linear portion 113 and the third linear portion 114 is provided as described above. Consequently, it is possible to easily set the length of the arc-shaped portion 111 not too long due to the third linear portion 114 while setting angles A21 and A22 that a diameter passing through the connection point 122 between the first linear portion 112 and the second linear portion 113 forms with the second linear portion 113 large to some extent. Hence, the arc-shaped portion 111 is set not too long while the angles A21 and A22 are set large to some extent to resist impact fracture due to a screw-in effect or lock. As a result, the occurrence of fatigue fracture can be easily reduced by, for example, increasing the followability and the flexibility.
Moreover, the connection point 121 between the arc-shaped portion 111 and the first linear portion 112 is set in such a manner as to be located upstream of the connection point 122 between the first linear portion 112 and the second linear portion 113 in the main rotation direction R of the dental file. Moreover, in a case of the above relationship between the cross-sectional shape and the main rotation direction, the arc-shaped portion 111, and the first to third linear portions 112 to 114 are formed in such a manner as to appear sequentially on a side portion of the working portion 100a from the distal end portion to the proximal end portion of the dental file 100. In a case of such a relationship between the cross-sectional shape and the rotation direction, cutting is performed by the connection point 121 at a downstream end of the arc-shaped portion 111 in the main rotation direction R first, and then by the connection point 122 located on the virtual circle 101 with the rotation of the dental file 100. As a result, high cutting ability can be easily maintained.
Moreover, although not particularly limited, for example, angles A11 and A12 that the diameter of the virtual circle 101 passing through the connection point 121 between the arc-shaped portion 111 and the first linear portion 112 forms with the first linear portion 112 are set equal to angels A21 and A22 that the diameter of the virtual circle 101 passing through the connection point 122 between the first linear portion 112 and the second linear portion 113 forms with the second linear portion 113. More specifically, the angles are set to, for example, equal to or greater than 10° and equal to or less than 40°, preferably, for example, approximately 30°. The cutting ability can be easily set at an appropriate level within such an angle range under normal circumstances.
It is also possible to specify the dimension of each portion instead of the above settings of angles. In other words, for example, the distances from the center O of the virtual circle 101 to the first to third linear portions 112 to 114 may be set equal to each other. Alternatively, the linear portions 112 to 114 may be designed to touch the same inscribed circle 102. Such a shape can be easily formed by equalizing the amounts of cut from the circumference of the virtual circle 101 to the linear portions 112 to 114. For example, grinding can be easily performed by use of a common routine with a predetermined amount of cut in a program that operates a grinding machine.
The above cross-sectional shape may be formed in a similar figure along all or part of the working portion 100a in the longitudinal direction. However, a varying shape may be formed as illustrated in
In this manner, the dental file 100 is set in such a manner to have a cross-sectional shape that changes along the longitudinal direction. Consequently, it is possible to set a relatively large cutting force near the proximal end portion while reducing the cutting force to a relatively small force near the distal end portion. Hence, it can facilitate increasing the cutting force toward the proximal end portion while securing flexibility near the distal end portion and high ability to follow the shape of a curved root canal also if the dental file 100 is used at early and finishing stages of root canal preparation and in cases where the cutting force is required along the entire length. Moreover, especially the angles A11 and A12 that the diameter passing through the connection point 121 forms with the first linear portion 112 are set in such a manner as to decrease from the distal end portion toward the proximal end portion. Consequently, the proportion of what is called a pocket to the virtual circle 101 increases, which can facilitate removing debris from the distal end portion to the proximal end portion. The ratio of the cross-sectional area (the second moment of area) to the cross-sectional shape of the virtual circle 101 decreases, which can facilitate further improving flexibility.
In the above cross-sectional shape of the dental file 100, the distances from the center O of the virtual circle 101 to two or more of the first to third linear portions 112 to 114 may be set equal to each other. Alternatively, the linear portions 112 to 114 may be designed to touch the same inscribed circle having the same center as the center O of the virtual circle 101. Such a shape can be easily formed by equalizing the amounts of cut from the circumference of the virtual circle 101 to the linear portions 112 to 114. For example, grinding can be easily performed by use of a common routine with a predetermined amount of cut in a program that operates a grinding machine.
Number | Date | Country | Kind |
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2019-188038 | Oct 2019 | JP | national |
2019-188041 | Oct 2019 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2020/036923 | 9/29/2020 | WO |