JP4338584B2 - Dental training evaluation program, evaluation body and evaluation device - Google Patents

Description

  The present invention relates to a tooth model shape evaluation program, a tooth model shape evaluation device, a tooth shape measuring instrument, and a tooth model shape for pointing out and forming an objective evaluation of an excessively formed or insufficient part of the shape of a tooth model formed by a student. Regarding the evaluation system.

  Dental students are required to learn techniques for forming teeth into an ideal shape in practical training such as abutment tooth formation, cavity formation, and wax-up. In the process of acquiring the skills for forming teeth, students improve their skills by evaluating the dental models formed by the students with an instructor. When an instructor evaluates a tooth model formed by a student, conventionally, the tooth model formed by the student is visually checked to determine whether or not the shape of the tooth model is appropriate. However, in the method in which the instructor visually evaluates the tooth model, the evaluation is based on the subjective judgment of the instructor, and thus it is difficult to objectively evaluate with a unified judgment. In addition, since it is difficult to make a quantitative judgment with the method of visual evaluation, there is a problem that it is difficult for a student to know which part is insufficient or excessive. Therefore, an evaluation method and apparatus for objectively and quantitatively evaluating the shape of the cavity formed in the tooth model has been proposed (for example, Patent Document 1).

  In the evaluation method according to this proposal, first, the shape of an uncut tooth model, the shape of a tooth model as a model cut by a teacher, and the shape of a tooth model to be evaluated cut by a student are converted into digital data. Find the difference between the uncut tooth model and the model tooth model, and the difference between the uncut tooth model and the tooth model to be evaluated, and superimpose these difference data to determine the excess or deficiency of the overlapped part. Evaluation is performed by converting the score.

However, in the formation of teeth, the required accuracy differs depending on the tooth portion. Therefore, in the method disclosed in Patent Document 1, in order to perform an accurate evaluation, for example, the importance of the overlapping portion and its periphery is set. It is necessary to devise the evaluation method, such as setting and storing in advance, and taking into account the calculation at the time of evaluation. As a result, there has been a problem that processing for evaluation becomes complicated. Further, in order to accurately superimpose the shape data of the tooth model, it is necessary to accurately position the measurement position during measurement of the tooth model, which causes a problem that the measuring instrument becomes complicated.
JP-A-10-97187

  Therefore, in view of the above problems, the present invention provides a tooth model shape evaluation program, a tooth model shape evaluation apparatus, a three-dimensional shape measuring instrument, and a tooth model shape evaluation program that can objectively and quantitatively evaluate a formed tooth shape by simple processing. An object is to provide a dental model shape evaluation system.

  To achieve the above object, the tooth model shape evaluation program according to the present invention is based on tooth model shape data obtained by measuring the quality of the tooth model with a three-dimensional shape measuring instrument. A tooth model shape evaluation program that causes a computer to execute an evaluation process to be evaluated and an output process to output the result of the evaluation process, wherein the evaluation process compares the maximum allowable shape data with the tooth model shape data. The quality of the formation of the tooth model is evaluated by the process of performing the process of comparing the minimum allowable shape data and the tooth model shape data.

  To achieve the above object, the tooth model shape evaluation apparatus according to the present invention is based on tooth model data obtained by measuring the quality of the tooth model with a three-dimensional shape measuring instrument. A tooth model shape evaluation apparatus comprising: an evaluation unit that evaluates and an output unit that outputs the result of the evaluation, wherein the evaluation unit includes a process of comparing maximum allowable shape data and the tooth model shape data; The quality of the tooth model is determined by comparing the minimum allowable shape data with the tooth model shape data.

  In order to achieve the above object, a three-dimensional shape measuring instrument according to the present invention is a state in which a table part that is movable in one direction and a tooth or a tooth model that is provided on the table part and is a measurement object are installed. And a tilting table unit that can tilt, an irradiation unit that irradiates slit-shaped irradiation light toward the measurement range, and a camera that receives and shoots a light cutting line in the measurement range of the irradiation light.

  In order to achieve the above object, a tooth model shape evaluation system according to the present invention is a tooth obtained by measuring the quality of a tooth model with the three-dimensional shape measuring instrument according to the present invention. An evaluation unit that evaluates based on model shape data; and an output unit that outputs a result of the evaluation, wherein the evaluation unit compares the maximum allowable shape data with the tooth model shape data, and the minimum allowable shape The quality of the formation of the tooth model is evaluated by a process of comparing the data and the tooth model shape data.

  According to the tooth model shape evaluation program according to the present invention, the formed tooth shape can be objectively and quantitatively evaluated by a simple process.

  The tooth model shape evaluation program according to the present invention is an evaluation process for evaluating the degree of formation of a tooth model based on tooth model shape data obtained by measuring the tooth model with a three-dimensional shape measuring instrument, and an evaluation process. A tooth model shape evaluation program for causing a computer to execute an output process for outputting the result of the above, wherein the evaluation process includes a process for comparing the maximum allowable shape data and the tooth model shape data, and the minimum allowable shape data and the tooth model shape. The quality of the formation of the tooth model is evaluated by a process of comparing the data.

  In the tooth model shape evaluation program according to the present invention, the evaluation process includes forming a tooth model by comparing the maximum allowable shape data and the tooth model shape data, and comparing the minimum allowable shape data and the tooth model shape data. Since the degree of quality is evaluated, it is possible to easily determine the excessive amount and the insufficient amount of the evaluation target tooth model. As a result, the formed tooth shape can be objectively and quantitatively evaluated with a simple process.

  In the tooth model shape evaluation program according to the present invention, the evaluation process includes a cross section of the tooth model shape data in an area surrounded by a contour line in one cross section of the maximum allowable shape data and a contour line in the cross section of the minimum allowable shape data. It is preferable to include processing for determining whether or not an outline line is included.

  In the evaluation process, the determination is performed based on the contour line in one cross section of the maximum allowable tooth model, the minimum allowable tooth model, and the evaluation target tooth model, so that the evaluation target data can be processed as two-dimensional data. As a result, the formed tooth shape can be objectively and quantitatively evaluated with a simple process.

  In the tooth model shape evaluation program according to the present invention, the evaluation processing includes the distance between the contour line in one cross section of the tooth model shape data and the contour line in the cross section of the maximum allowable shape data, and the contour line in the cross section of the tooth model shape data. It is preferable to include a process of further calculating at least one of the distances from the contour line in the cross section of the minimum allowable shape data.

  By calculating the distance between the contour line in one section of the model to be evaluated and the contour line in the section of the maximum allowable tooth model, an excess amount of the tooth model to be evaluated can be obtained. Moreover, the shortage amount of the evaluation target tooth model can be obtained by calculating the distance between the contour line in the cross section of the evaluation target model and the contour line in the cross section of the minimum allowable tooth model.

  In the tooth model shape evaluation program according to the present invention, the output process includes an outline line in one cross section of the maximum allowable shape data, an outline line in the cross section of the minimum allowable shape data, and an outline line in the cross section of the tooth model shape data. It is preferable to include a process of superimposing and displaying on one coordinate system.

  In the output processing, the contour lines in one cross section of the minimum allowable tooth model, the maximum allowable tooth model, and the evaluation target tooth model are displayed superimposed on one coordinate system, so that an excessively formed portion or a shortage is displayed. This makes it easier to visually grasp the part that is being performed.

  In the tooth model shape program according to the present invention, the output process includes a process of enlarging and displaying a part of the maximum allowable shape, the minimum allowable shape, and the tooth model shape superimposed on one coordinate system. It is preferable.

  In the output process, it is difficult to determine whether the degree of formation of the tooth model is good or not by enlarging and displaying a portion of the maximum allowable shape, minimum allowable shape, and tooth model shape superimposed on one coordinate system. It is possible to observe in detail only those parts.

  In the tooth model shape program according to the present invention, the output processing is performed on one coordinate system so that the maximum allowable shape, the minimum allowable shape, and the tooth model shape can be visually grasped simultaneously. It is preferable to include a process of superimposing and displaying the image three-dimensionally.

  In the output process, the maximum allowable shape, the minimum allowable shape, and the tooth model shape are superimposed and displayed in a three-dimensional manner so that each shape can be grasped simultaneously. An excessively formed part or an insufficient part can be easily grasped visually and three-dimensionally.

  In the tooth model shape program according to the present invention, the evaluation process preferably includes a process of calculating a measurement error range from the three-dimensional shape data of the evaluation target tooth model, and the output process preferably includes a process of displaying the error range.

  In the output process, since the error range is displayed, it becomes easier to visually grasp the portion where the quality of the tooth model cannot be evaluated due to the measurement accuracy error.

  The tooth model shape evaluation apparatus according to the present invention includes an evaluation unit that evaluates the quality of the formation of the tooth model based on tooth model shape data obtained by measuring the tooth model with a three-dimensional shape measuring instrument, A tooth model shape evaluation device including an output unit for outputting a result, wherein the evaluation unit compares the maximum allowable shape data with the tooth model shape data, and the minimum allowable shape data and the tooth model shape data. The quality of the formation of the tooth model is determined by the processing to be compared.

  In the tooth model shape evaluation apparatus according to the present invention, the evaluation unit includes a cross section of the tooth model shape data in an area surrounded by a contour line in one cross section of the maximum allowable shape data and a contour line in the cross section of the minimum allowable shape data. It is preferable to determine whether or not an outline line is included.

  In the tooth model shape evaluation apparatus according to the present invention, the evaluation unit includes the distance between the contour line in one section of the tooth model shape data and the contour line in the section of the maximum allowable shape data, and the contour line and the minimum in the section of the tooth model shape data. It is preferable to further calculate at least one of the distances from the outline in the cross section of the allowable shape data.

  A tooth shape measuring device according to the present invention includes a table portion that is movable in one direction, an inclined table portion that is provided on the table portion and can be tilted in a state where a tooth or a tooth model that is a measurement object is installed, An irradiation unit that irradiates slit-shaped irradiation light toward the measurement range, and a camera that receives and shoots a light cutting line in the measurement range of the irradiation light.

  The tooth shape measuring instrument according to the present invention is provided with an inclined table portion that can be tilted in a state in which a tooth or a tooth model as a measurement object is installed on a table portion that is movable in one direction. By adjusting the position by moving the part in one direction, the position where the measurement object is measured can be easily determined. Further, since the tilt table can be tilted in a state where the tooth or tooth model as the measurement object is installed, the invisible region of the camera on the measurement object can be eliminated.

  In the tooth shape measuring instrument according to the present invention, it is preferable that the inclined table portion is inclined in a direction of at least one axis.

  In the tooth shape measuring instrument according to the present invention, it is preferable that the inclined table portion can be inclined at an inclination angle of 10 ° to 45 °.

  In the tooth shape measuring instrument according to the present invention, it is preferable that the inclined table portion is inclined at an inclination angle of at least three stages per direction.

  In the tooth shape measuring instrument according to the present invention, it is preferable that a fixture for fixing a jaw or a tooth model on which a tooth or a tooth model is mounted is provided on the inclined table portion.

  Since the jaw model for mounting the teeth or the tooth model on the inclined table is fixed, the relative position between the table portion and the tooth or the tooth model as the measured object is fixed. Therefore, by positioning the table portion, it is possible to position the tooth or tooth model that is the measurement object.

  The tooth model shape evaluation system according to the present invention evaluates the quality of the formation of the tooth model based on the tooth model shape data obtained by measuring the tooth model with the three-dimensional shape measuring device according to the present invention. And an output unit for outputting the result of the evaluation, the evaluation unit includes a process for comparing the maximum allowable shape data and the tooth model shape data, and a process for comparing the minimum allowable shape data and the tooth model shape data. To evaluate the quality of the formation of the tooth model.

  Since the tooth model shape evaluation system according to the present invention includes the tooth shape measuring instrument according to the present invention, it is possible to easily position the tooth model that is the object to be measured. Therefore, the maximum allowable tooth model, the minimum allowable tooth model, and the evaluation target tooth model are measured at the same position on the tooth shape measuring instrument. As a result, the processing when the evaluation unit compares the three-dimensional shape data of the maximum allowable tooth model, the minimum allowable tooth model, and the evaluation target tooth model is simplified. As a result, the formed tooth shape can be objectively and quantitatively evaluated with a simple process.

  In the tooth model shape evaluation system according to the present invention, the evaluation unit includes a section of the tooth model shape data in an area surrounded by the contour line in one section of the maximum allowable shape data and the contour line in the section of the minimum allowable shape data. It is preferable to determine whether or not an outline line is included.

  In the tooth model shape evaluation system according to the present invention, the evaluation unit includes the distance between the contour line in one section of the tooth model shape data and the contour line in the section of the maximum allowable shape data, and the contour line and the minimum in the section of the tooth model shape data. It is preferable to further calculate at least one of the distances from the outline in the cross section of the allowable shape data.

  Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

(Embodiment 1)
The first embodiment is a tooth model shape evaluation system that evaluates the quality of the formation of a tooth model. FIG. 1 is a functional block diagram illustrating an example of a configuration of a tooth model shape evaluation system according to the first embodiment. As shown in FIG. 1, the tooth model shape evaluation system 1 according to the present embodiment includes a tooth shape measuring device 2, a storage unit 4, an evaluation unit 5, and an output unit 8. The tooth shape measuring instrument 2 measures the shape of a tooth model that is a measured object. The shape of the tooth model measured by the tooth model measuring device 2 is stored in the storage unit 4 as three-dimensional data. Based on the shape data stored in the storage unit 4, the evaluation unit 5 evaluates the quality of the formation degree of the tooth model. The evaluation result is stored in the storage unit 4 and output to the output unit 8 as necessary.

  FIG. 2 is a diagram illustrating an example of a hardware configuration of the tooth model shape evaluation system 1. As shown in FIG. 2, the tooth model shape evaluation system 1 is constructed, for example, by connecting a tooth shape measuring instrument 2 to a personal computer 10 (hereinafter referred to as a personal computer) via an interface board 11. In this case, the functions of the evaluation unit 5 and the output unit 8 are realized by the CPU of the personal computer executing a predetermined program. A hard disk of a personal computer can be used as the storage unit 4. A display device including a personal computer display can be used as the output unit 8.

  By installing a program for realizing the functions of the evaluation unit 5 and the output unit 8 on an arbitrary personal computer, for example, from a storage medium such as a CD-ROM or by downloading via a communication line, the tooth model shape The evaluation system 1 can be constructed.

  Here, the tooth shape measuring instrument 2 will be described in detail. FIG. 3 is a schematic diagram showing the structure of the tooth shape measuring instrument 2 in the present embodiment. As shown in FIG. 3, the tooth shape measuring instrument 2 includes a table unit 24 that can move only in the X-axis direction, an inclined table unit 23 provided on the table unit 24, and a measurement range on the inclined table 23. Toward, it has the irradiation part 22 which irradiates slit-shaped irradiation light, and the camera 21 which light-receives and image | photographs the optical cutting line in the measurement range of irradiation light.

  As the table unit 24, a mechanism of a precision positioning table used for calibration of a general measuring instrument can be used. Thereby, the table part 24 can move to the position designated by the user in the X-axis direction. For example, it can be moved at intervals of 5 μm or can be repeated.

  As shown in FIG. 4, the tooth model 27 that is the object to be measured is fixed to the tilt table 23 while being attached to the jaw model 26. On the lower surface of the jaw model 26, a fixture provided on the tilting table, that is, a hole in which the protrusion 28 fits closely is provided, and the jaw model 26 is inclined so that the protrusion 28 fits in the hole of the jaw model 26. Fix by placing on the table 23. Thereby, the jaw model 26 can always be arrange | positioned in the same position on the inclination table 23. FIG.

  The method of fixing the jaw model 26 to the tilt table 23 is not limited to this. In addition, for example, a concave portion corresponding to the lower shape of the jaw model 26 may be formed on the inclined table 23, and the jaw model 26 may be fixed by fitting into the concave portion.

  As shown in FIG. 3, the slit light is irradiated from the irradiation unit 22 onto the tooth model fixed to the inclined table 23. Irradiation of the slit light can be performed, for example, by reflecting the semiconductor laser light with a rotating polygon mirror. The slit light irradiated on the tooth model is reflected by the surface, received by the camera 21, and photographed. Based on the image taken by the camera 21, the three-dimensional coordinate value of the tooth model can be obtained by using the principle of triangulation by the light cutting method. For example, coordinate data of 640 points can be obtained from one slit light. The table portion 24 is moved in the X-axis direction, for example, at a pitch of 0.1 mm, and the slit light at each position is received by the camera 21 and photographed, whereby three-dimensional coordinates of the surface of the tooth model are obtained.

  Here, as shown in FIG. 5A, the shape of the tooth model 27 may be smaller at the lower part than the upper part, and the lower part of such a tooth model 27 is invisible to the invisible region of the camera 21. Become. Therefore, in the conventional tooth shape measuring instrument, by providing a plurality of cameras, the invisible area can be eliminated, or the inspected area can be eliminated by attaching the object to be measured to the rotatable shaft and rotating the image. Was. However, when a plurality of cameras are provided, it is necessary to adjust the optical axes of the respective cameras, and there is a problem that the cost for manufacturing the device increases. In addition, the method of attaching the measured object on the rotating shaft has a problem that the positioning process of the measured object becomes complicated.

  In the tooth shape measuring instrument in the present embodiment, the tooth model 27 that is the object to be measured is fixed via the jaw model 26 on the tilt table 23 that can change the angle. As shown, the tooth model 27 is also inclined by increasing the angle of the inclination table 23. Therefore, the invisible region of the camera 21 can be eliminated. Furthermore, since the tooth model 27 is always disposed at the same position on the tilt table 23, the positioning process is simplified.

  In actual measurement, for example, the state in which the tilt table 23 is not tilted (state 1), the state in which the X axis is tilted by + 30 ° (state 2), and the state in which the X axis is tilted by −30 ° Shape measurement is performed in (State 3), a state inclined by + 30 ° with the Y axis as the rotation axis (State 4), and a state inclined by −30 ° with the Y axis as the rotation axis (State 5). The shape measurement is performed by moving the table unit 24 in the X-axis direction so that the slit light is scanned with respect to the tooth model 27. The three-dimensional coordinate data measured in a state where the tilt table 23 is tilted (states 2 to 5) is subjected to coordinate conversion processing corresponding to the tilt. For example, the data obtained in the state 2 is converted by rotating by −30 ° using the X axis as the rotation axis. For example, affine transformation or the like can be used for this transformation. When the three-dimensional coordinate data measured in state 2 to 5 and coordinate-transformed three-dimensional coordinate data measured in state 1 are combined, three-dimensional coordinate data representing all exposed surfaces of tooth model 27 are obtained. can get. In addition, if the shape data measured and coordinate-transformed in states 2 to 5 overlaps with the shape data obtained in state 1, it is possible to save memory and improve processing speed by deleting the data. It is. The tilt angle of the tilt table 23 is not limited to ± 30 °. Further, the number of states in which the measurement is performed while being inclined is not limited to the above specific example. According to the shape of the tooth model 27, an appropriate inclination angle and rotation axis can be selected.

  Next, a mechanism for tilting the tilt table 23 will be described. FIG. 6 is a conceptual diagram showing a structure that supports the tilt table 23. The tilt table 23 is supported above the base 203 by a support 201 and four expansion / contraction units 202a, 202b, 202c, and 202d. The expansion / contraction units 202a, 202b, 202c, and 202d can expand and contract in the Z-axis direction. The support 201 and the tilt table 23 are connected by a table joint 204. Thereby, the inclination table 23 can be inclined about the X axis and the Y axis as rotation axes. When the expansion / contraction units 202a and 202b are extended and the expansion / contraction units 202c and 202d are contracted, the inclination table 23 is inclined with the X axis as the rotation axis. When the expansion / contraction units 202a and 202d are extended and the expansion / contraction units 202b and 202c are contracted, the inclination table 23 is inclined with the Y axis as the rotation axis. Each expansion / contraction unit 202a, 202b, 202c, 202d is expanded / contracted by driving units 205a, 205b, 205c, 205d having a geared motor. In addition, the structure of the inclination table 23 is not limited to the structure shown in FIG.

  FIG. 7 is a conceptual diagram showing the structure of the expansion / contraction unit 202. The telescopic unit mainly includes a unit base 210, a movable member 212 that is movable in the vertical direction, and a guard motor 213 that moves the movable member 212 in the vertical direction. The lower end of the unit base 210 is connected to the base 203 via a universal joint 211a. The upper end of the movable member 212 is connected to the inclined table 23 via the universal joint 211b. The movable member 212 is provided with a long hole 212e in the vertical direction, and the slide guide 214 is fixed to the unit base 210 through the hole 212e. As a result, the movable member 212 is movable in the vertical direction. A groove 212f is provided on a side surface of the movable member 212, and a gear 213g attached to the rotating shaft of the guard motor 213 is engaged with the groove 212f. Thereby, when the guard motor 213 is driven, the movable member 212 moves in the vertical direction. Stoppers 215 are provided above and below the movable member 212, and the movable member 212 is configured to move up and down within a certain range. An eccentric fastener 216 is passed through the hole 215 h of the stopper 215. Thereby, the position of the stopper can be adjusted. Two convex portions 212h are provided on the side surface of the movable member 212. When the detent lever 217 provided on the unit base 210 is hooked on these convex portions 212h, the movable member 212 has L, M, and H. It is designed to be stable and stationary at three positions. Thereby, the inclination table 23 can be inclined in three steps per direction. Moreover, it is preferable that the inclination table 23 can incline at an inclination angle of 10 ° to 45 °. In addition, the structure which expands / contracts an expansion-contraction unit is not restricted to the structure shown in FIG. In addition, the telescopic unit shown in FIG. 7 is configured to be stably stationary at three positions, but is not limited to three stages.

  Next, operation | movement of the tooth model shape evaluation system in this Embodiment is demonstrated, referring FIG. 1 and FIG. FIG. 8 is a flowchart showing the operation of the tooth model shape evaluation system 1 according to the present embodiment.

  First, as shown in FIG. 8, in step 101, the tooth shape measuring instrument 2 measures the shape of the maximum allowable tooth model and stores the measurement result in the storage unit 4 as maximum allowable shape data. Here, the maximum allowable shape is the maximum shape that can be accepted in the degree of formation of the tooth model. For example, the maximum allowable shape data can be obtained by creating a maximum allowable tooth model and measuring the maximum allowable tooth model. Therefore, for example, if a tooth model formed by a student has a portion that protrudes from the maximum allowable shape, the formation of the portion is evaluated as inappropriate.

  In step 102, the tooth shape measuring device 2 measures the shape of the minimum allowable tooth model, and stores the measurement result in the storage unit 4 as minimum allowable shape data. Here, the minimum allowable shape is the minimum shape that can be accepted in the degree of formation of the tooth model. For example, the instructor creates a minimum allowable tooth model and measures this to obtain minimum allowable shape data. Therefore, for example, in a tooth model formed by a student, if there is a portion formed inward from the minimum allowable shape, it is evaluated that the formation of that portion is inappropriate.

  In this embodiment, the maximum allowable shape data and the minimum allowable shape data are obtained by creating the maximum allowable tooth model and the minimum allowable tooth model and measuring the shape, but actually creating the model. Alternatively, the maximum allowable shape data and the minimum allowable shape data may be set by numerical input or the like. For example, in the preparation of an abutment tooth, it is important to determine the margin form, axial taper, and occlusal clearance, but enter the minimum and maximum allowable values for these formations numerically. By doing so, the minimum allowable shape data and the maximum allowable shape data can be set.

  In step 103, the tooth shape measuring device 2 measures the shape of the tooth model to be evaluated formed by the student, and stores the measurement result in the storage unit 4 as evaluation target tooth model data.

  Here, the tooth model will be described. FIG. 9 is a side view of the tooth model 27. 9A is an uncut tooth model 27a, FIG. 9B is an example of a maximum allowable tooth model 27b in an abutment tooth formation practice, FIG. 9C is an example of a minimum allowable tooth model 27c, FIG. 9D shows an example of a tooth model 27d formed by a student. When the tooth model 27 is set on the jaw model 26 (see FIG. 4), the upper portion u is exposed, and the lower portion s is fitted into the hole of the jaw model. When the student cuts the tooth model, etc., as shown in FIG. 10, cutting is performed with the jaw model 26 fitted with the tooth model 27 set on the training head phantom 29. Therefore, in the tooth model 27 shown in FIG. 9, the upper part u is the object of formation such as cutting, and the lower part s is not the object of formation. The maximum allowable tooth model 27b, the minimum allowable tooth model 27c, and the evaluation target tooth model 27d have the same shape in the lower part s. Therefore, as shown in FIG. 4, when the tooth model 27 is fitted to the jaw model 26 and set on the tilt table 23, any of the maximum allowable tooth model 27b, the minimum allowable tooth model 27c, or the evaluation target tooth model 27d is set. However, it is always set at the same position with respect to the table unit 24. As a result, the shape data obtained by these measurements can be accurately superimposed and compared.

  In steps 101, 102, and 103, the maximum allowable shape data, the minimum allowable shape data, and the evaluation target tooth shape data are stored in the storage unit 4 as a set of points on three-dimensional coordinates. The three-dimensional coordinates at this time can be, for example, an orthogonal coordinate system in which a plane parallel to the bottom surface of the tooth model 27 is an ab plane and an axis perpendicular to the bottom surface is a c-axis. In this case, the X-axis direction and the Y-axis direction in FIG. 3 can be taken as the a-axis and the b-axis.

  In step 104, the evaluation unit 5 performs processing for reading and comparing the maximum allowable shape data and the tooth model shape data stored in the storage unit 4. In the comparison processing, for example, as shown in FIG. 11A, the outline line in one plane (hereinafter referred to as an evaluation section) of the planes (bc plane) perpendicular to the a axis in the maximum allowable shape data. The data indicating j and the data indicating the contour line k in the evaluation cross section from the evaluation target tooth model shape data are extracted, and the contour line k of the evaluation target tooth model shape data is located inside the contour line j of the maximum allowable shape data. Determine if it exists. As a determination method, for example, it is possible to determine by comparing the c coordinate values of the contour lines j and k of the maximum allowable shape and the tooth model shape with respect to each b coordinate in the evaluation cross section. As a result of the determination, if there is a portion where the contour line k of the evaluation target tooth model shape data exists outside the contour line j of the maximum allowable shape data, a process of deducting the evaluation points is performed (step 106).

  In step 105, the evaluation unit 5 reads out and compares the minimum allowable shape data and the evaluation target tooth model shape data stored in the storage unit 4. In the comparison process, for example, as shown in FIG. 11B, whether or not the contour line k of the evaluation target tooth model extracted in step 104 exists outside the contour line m in the evaluation section of the minimum allowable shape data. Determine whether. The determination method is the same as in step 104. As a result of the determination, if there is a place where the contour line k of the evaluation target tooth model shape data exists inside the contour line m of the minimum allowable shape data, a process of deducting the evaluation points is performed (step 106).

  According to the present embodiment, evaluation is performed by comparing the evaluation target tooth model shape with the maximum allowable shape and the minimum allowable shape. Therefore, accurate evaluation can be performed by appropriately setting the maximum allowable shape and the minimum allowable shape. Can be performed. For example, in places where a high degree of accuracy is required, such as a margin position in abutment tooth formation, the evaluation accuracy can be adjusted by narrowing the difference between the maximum allowable shape and the minimum allowable shape. it can. As a result, evaluation can be performed with simple processing.

  Note that the determination processing in step 104 and step 105 can be performed simultaneously. That is, as shown in FIG. 11C, the c coordinate of the contour line k of the evaluation target tooth model is between the c coordinate of the contour line m of the minimum allowable shape and the c coordinate of the contour line j of the maximum allowable shape. Whether or not it exists can be determined for each b coordinate in the evaluation section. Thereby, it can be determined whether or not the contour line of the evaluation target tooth model is included in the area surrounded by the contour line of the maximum allowable shape data and the contour line of the minimum allowable shape data. If it is determined that it is not included, a deduction process is performed (step 106).

  In Steps 104 and 105, evaluation is performed using a cross section perpendicular to the a axis (bc cross section) as an evaluation cross section, but the evaluation cross section is not limited to a cross section perpendicular to the a axis.

  In step 106, the evaluation unit 5 performs a process of calculating an evaluation score. When the contour line k in the evaluation section of the evaluation target tooth model exists outside the contour line j in the evaluation section of the maximum allowable shape, the contour line k of the evaluation target tooth model shape data and the contour line j of the maximum allowable shape data And the number of points to be deducted may be determined according to the distance. For example, as the distance between the contour line k of the evaluation target tooth model and the contour line j of the maximum allowable shape data increases, the number of points to be deducted can be increased. Similarly, when the contour line k in the evaluation section of the evaluation target tooth model exists inside the contour line m in the evaluation section of the minimum allowable shape, the contour line k of the evaluation target tooth model shape data and the minimum allowable shape data The distance from the outline m can be calculated, and the number of points to be deducted can be calculated according to the distance.

  Further, an ideal shape may be set between the maximum allowable shape and the minimum allowable shape. It is also possible to calculate the distance between the contour line in the evaluation section of the ideal shape and the contour line of the evaluation target tooth shape, and determine the number of points according to the distance. In this case, the maximum allowable shape or the minimum allowable shape may be an ideal shape.

  The processing in step 104 and step 105 is repeatedly performed using a plurality of planes perpendicular to the a axis (bc plane) as evaluation sections. Thus, the overall shape of the evaluation target tooth model 27d can be evaluated. When evaluating only a part of the evaluation target tooth model 27d, it is only necessary to perform a cross section of a necessary portion.

  In the present embodiment, a plane (bc plane) perpendicular to the a-axis is used as the evaluation cross section, but the evaluation cross section is not limited to this. For example, depending on the content of the practice, a cross section in which a feature of the degree of formation of the tooth model is noticeable can be set as the evaluation cross section.

  Further, the evaluation unit 5 may calculate the measurement error range of the evaluation target tooth model shape data at the time of performing the evaluation in Step 104 and Step 105, and may perform the evaluation by taking this into consideration. The measurement error occurs, for example, because the sensitivity of the CCD pixel of the camera 21 is slightly different depending on the location, or the intensity of the slit light is different depending on the location. In addition, when the distance is obtained from the image captured by the camera 21 using the light cutting method, an error may also occur by using an approximate expression.

  The method for obtaining the error range is obtained, for example, by measuring the radius of the hemispherical object to be measured at a plurality of points on the surface of the hemisphere, obtaining the average value, and comparing the average value with each measured value as a true value. be able to. The measurement error range can be, for example, a range of Z coordinate ± 100 μm of measurement data.

  In step 107, the output unit 8 displays the evaluation result. The output unit 8 displays the maximum allowable shape, the minimum allowable shape, and the evaluation target tooth model shape in a three-dimensional manner such that the respective shapes can be visually recognized at the same time. FIG. 12 is a diagram illustrating a display example in the case where the maximum allowable shape and the minimum allowable shape are superimposed and displayed so that they can be visually grasped simultaneously. In the display example shown in FIG. 12, the minimum allowable shape is displayed with, for example, a colored surface, and the maximum allowable shape is displayed below the maximum allowable shape because the surface is displayed as a set of points. The minimum allowable shape is also visible. The tooth model shape to be evaluated can be displayed as a set of points or a transparent surface, superimposed on the display of the maximum allowable shape and the minimum allowable shape. As a result, the excess portion and the lack portion of the evaluation target tooth model can be easily grasped visually. In FIG. 12, the number of points representing the surface of the minimum allowable shape is reduced in order to make the drawing easier to see. In actual display, for example, by displaying all the points corresponding to each three-dimensional coordinate of the minimum allowable shape, the surface shape can be more easily grasped by increasing the number of points. .

  Further, as shown in FIG. 13A, the contour lines j, m, and k in the evaluation section of the maximum allowable tooth shape, the minimum allowable tooth shape, and the evaluation target tooth shape can be superimposed and displayed on one screen. . When displaying, the area outside the outline line j of the maximum allowable tooth shape, the area surrounded by the outline line j of the maximum allowable tooth shape and the outline line m of the minimum allowable tooth shape, the inside of the outline line m of the minimum allowable tooth shape These areas can also be displayed in different colors. Thereby, it becomes easy to visually grasp the excess portion and the lack portion of the evaluation tooth model in the evaluation section. It is preferable that the user can select the cross section to be displayed.

  In the above-described three-dimensional display and cross-sectional display, it is preferable to enlarge and display a part of the maximum allowable shape, the minimum allowable shape, and the tooth model shape that are superimposed. The user may be allowed to specify the area to be enlarged. As a result, for example, as shown in FIG. 13B, it is easy to observe a portion n that requires a fine determination, such as a margin width p in abutment tooth formation. In the display of FIG. 13B, the positions of the left ends of the contour lines j, k, and m are vertically aligned, but in the actual display, they are not necessarily aligned.

  Further, the measurement error range may be displayed with a color, for example, in the display of the tooth model shape. Thereby, it becomes easy to visually grasp a portion that is difficult to determine due to an error.

  In the present embodiment, the tooth model shape evaluation system in the abutment tooth formation training has been mainly described, but the present invention is not limited to this. That is, for example, in the practice of forming a cavity, wax-up, and other tooth models, a tooth model shape evaluation system for evaluating a tooth model is also included in the present invention.

  The present invention relates to a tooth model shape evaluation program, a tooth model shape evaluation device, a three-dimensional shape measuring instrument, and a tooth model shape evaluation system useful for objectively and quantitatively evaluating a formed tooth shape by simple processing. Is available as

4 is a functional block diagram illustrating an example of a configuration of a tooth model shape evaluation system in Embodiment 1. FIG. It is a figure which shows an example of the hardware constitutions of the tooth model shape evaluation system. 3 is a schematic view showing the structure of a tooth shape measuring device 2. FIG. It is a perspective view of a jaw model and a tilting table. (A) is a figure for demonstrating the invisible area | region of a camera. (B) is a figure for demonstrating the mechanism which eliminates the invisible area | region of a camera by inclining a to-be-measured body. 3 is a conceptual diagram showing a structure for supporting an inclined table 23. FIG. FIG. 4 is a conceptual diagram showing the structure of an extendable unit 202. It is a flowchart which shows operation | movement of the tooth model shape evaluation system 1. FIG. (A) is a side view of an uncut tooth model. (B) is a side view of the maximum allowable tooth model. (C) is a side view of the minimum allowable tooth model. (D) is a side view of a dental model formed by a student. It is a figure which shows the state which set the jaw model which fitted the tooth model to the head phantom for training. (A) is a figure which shows the outline of the maximum permissible shape and the evaluation object tooth model shape. (B) is a figure which shows the outline of the minimum tolerance | permissible shape and an evaluation object tooth model shape. (C) is a figure which shows the outline of a maximum permissible shape, a minimum permissible shape, and an evaluation object tooth model shape. It is a figure which shows the example of a display in the case of displaying the maximum permissible shape and the minimum permissible shape. (A) is a figure which shows the example of a display in the case of displaying the maximum permissible shape in an evaluation cross section, the minimum permissible shape, and the outline of an evaluation object tooth model shape. (B) is the figure which expanded a part of example of a display shown to (a).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Tooth model shape evaluation system 2 Tooth shape measuring device 4 Memory | storage part 5 Evaluation part 8 Output part 10 Personal computer 11 Interface board 21 Camera 22 Irradiation part 23 Inclination table 24 Table part 26 Jaw model 27 Tooth model 28 Protrusion 29 Head for training phantom

Claims (5)

Evaluation process for evaluating the quality of the formation of the tooth model based on the tooth model shape data obtained by measuring the tooth model with a three-dimensional shape measuring instrument,
A tooth model shape evaluation program for causing a computer to execute an output process for outputting the result of the evaluation process,
The evaluation process evaluates the quality of the formation of the tooth model by a process of comparing the maximum allowable shape data and the tooth model shape data and a process of comparing the minimum allowable shape data and the tooth model shape data. ,
In the output process, the maximum allowable shape indicated by the maximum allowable shape data, the tooth model shape indicated by the tooth model shape data, and the minimum allowable shape indicated by the minimum allowable shape data are superimposed on one coordinate system. A tooth model shape evaluation program further including a process of displaying .   The evaluation process includes an outline line in one section of the maximum allowable shape data and an outline line in the cross section of the tooth model shape data in an area surrounded by the outline line in the cross section of the minimum allowable shape data. The tooth model shape evaluation program according to claim 1, comprising a process for determining whether or not the tooth model is being used. The tooth model according to claim 1 or 2, wherein the maximum allowable shape data and the minimum allowable data include values representing a maximum allowable amount and a minimum allowable amount of a margin form, an axial surface taper, and an occlusal surface clearance formation degree. Shape evaluation program. A table part that can be moved in one direction, an inclined table part that is provided on the table part and can be tilted in a state where a tooth or a tooth model as a measurement object is installed, and slit-shaped irradiation light in the measurement range A three-dimensional shape measuring instrument having an irradiating unit for irradiating and a camera for receiving and photographing a light cutting line in the measurement range of the irradiation light ;
An evaluation unit that evaluates whether the degree of formation of the tooth model is good or not based on tooth model shape data obtained by measuring the tooth model with the three-dimensional shape measuring instrument,
An output unit for outputting the result of the evaluation,
The evaluation unit evaluates the quality of the formation of the tooth model by a process of comparing the maximum allowable shape data and the tooth model shape data and a process of comparing the minimum allowable shape data and the tooth model shape data. ,
The output unit further superimposes the maximum allowable shape indicated by the maximum allowable shape data, the tooth model shape indicated by the tooth model shape data, and the minimum allowable shape indicated by the minimum allowable shape data, so that one coordinate system Teeth model shape evaluation system displayed above .   The evaluation unit includes an outline line in one cross section of the maximum allowable shape data and an outline line in the cross section of the tooth model shape data in an area surrounded by the outline line in the cross section of the minimum allowable shape data. The tooth model shape evaluation system according to claim 4, wherein it is determined whether or not the tooth model is formed.

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