JP6641856B2 - Measurement jig - Google Patents

Description

  The present disclosure relates to a measurement jig for measuring the depth of a bevel groove provided in a rim of an eyeglass frame.

  2. Description of the Related Art Conventionally, a process of forming a bevel on a lens has been performed, and eyeglasses have been manufactured by fitting a bevel formed on the periphery of the lens into a bevel groove provided on a rim of an eyeglass frame (for example, see Patent Document 1). ). The bevel height (the distance in the vertical direction from the bevel shoulder to the top of the bevel) based on the depth of the bevel groove measured using a measuring jig such as a caliper to make the eyeglass frame and the lens fit well. Is set and beveling is performed.

JP 2007-319984 A

  Incidentally, in order to fit the eyeglass frame and the lens well, it is important to accurately measure the depth of the bevel groove. However, conventionally, a bevel groove is estimated by diverting a measuring jig used for another purpose. Further, since the bevel groove is measured by diverting a measuring jig used for other purposes, the depth of the bevel groove cannot be measured accurately. In addition, since a bevel groove is measured by diverting a measuring jig used for another purpose, it is difficult for an unskilled examiner to measure.

  An object of the present disclosure is to provide a measuring jig capable of easily and accurately measuring the depth of a bevel groove in view of a conventional problem.

  In order to solve the above problem, the present disclosure is characterized by including the following configuration.

(1) A measuring jig according to a first aspect of the present disclosure is a measuring jig that measures a depth of a bevel groove provided in a rim of an eyeglass frame, and includes a first inclined portion extending from a first shoulder. A second inclined portion that is different from the first inclined portion and that extends from a second shoulder portion that is different from the first shoulder portion; and the first inclined portion and the second inclined portion. And a plurality of convex portions having a shape that fits into the bevel groove, and the plurality of convex portions are formed from a first hem portion that is a hem portion of the first inclined portion. A first distance to an apex and a second distance from a second skirt, which is a skirt of the second inclined portion, to the apex are different between the plurality of protrusions, and the first shoulder is different. A first inclination angle of the first inclined portion with respect to a portion, and a second inclination angle of the second inclined portion with respect to the second shoulder. Are set at the same angle with respect to each other.
(2) A measurement jig according to a second aspect of the present disclosure is a measurement jig that measures the depth of a convex bevel groove provided on a rim of an eyeglass frame, and includes a first hem of a first shoulder. a surface before extending from a rearward face extending from the second skirt portion of the second shoulder portion is different from the shoulder portion and the face before facing forward of the lenses, and the first shoulder, behind the lens And a plurality of convex portions having a shape that fits into the convex bevel groove, and a plurality of convex portions having a shape that fits into the convex bevel groove . A height distance from one hem portion to the outer peripheral surface, a height of the convex portion being a distance from a second hem portion of the rear surface to the outer peripheral surface , and the first hem portion and the second hem. and the width of the convex portion is a straight line distance connecting the parts, at least one of are different from each other each other between the plurality of protrusions.

1 is a schematic configuration diagram of a measurement jig according to the present disclosure. It is a figure explaining composition of a plurality of 1st convex parts. It is a figure explaining composition of a plurality of 2nd convex parts. It is a figure explaining a bevel groove of a rim of an eyeglass frame. It is a figure explaining the measuring operation at the time of measuring a bevel groove of a rim using a plurality of 1st convex parts. It is a figure explaining the measuring operation at the time of measuring a bevel groove of a rim using a plurality of 2nd convex parts. It is a figure showing an example of a measuring jig in which two measuring jigs were combined. It is a figure which shows an example in which the shoulder part is inclined in the convex part in several 2nd convex part.

  Hereinafter, the measurement jig of the present embodiment will be described. FIG. 1 is a schematic configuration diagram of a measurement jig according to the present disclosure. In FIG. 1, a dotted line portion 10 a is an enlarged view of the dotted line portion 10 of the measuring jig 1. The measuring jig 1 in the present embodiment is used for measuring the depth of a bevel groove provided on a rim of an eyeglass frame. For example, the measuring jig 1 is formed of a metal (for example, aluminum, stainless steel, copper, or the like), a resin (for example, plastic, glass, or the like), or the like.

  In the present embodiment, for example, the measuring jig 1 includes a base 2, a plurality of convexes 3, and a scale 4. For example, the base 2 is provided with a plurality of protrusions 3 and a scale 4. For example, the base 3 and the plurality of protrusions 3 may be integrally formed, or a structure in which the plurality of protrusions 3 are joined to the base 2 may be used. In the present embodiment, the base 2 and the plurality of protrusions 3 are plate-shaped having a uniform thickness. Therefore, the plurality of convex portions 3 are easily fitted into the bevel grooves. Of course, at least one of the base 2 and the plurality of protrusions 3 does not need to have a plate shape.

  For example, in the present embodiment, the plurality of protrusions 3 include a plurality of first protrusions 30 and a plurality of second protrusions 40. For example, the plurality of first protrusions 30 are used for measuring a bevel groove of a spectacle frame having a normal curve (for example, 5 curves or less). For example, the plurality of first protrusions 30 include at least two or more protrusions (for example, protrusions 30a, protrusions 30b, and the like). Note that each of the plurality of first protrusions 30 is a protrusion having the same shape and a different protrusion height H1 (see FIG. 2 described later) between the respective protrusions of the plurality of first protrusions 30. (Details will be described later).

  For example, the plurality of second convex portions 40 are used for measuring a bevel groove of a spectacle frame having a high curve (for example, 6 or more curves). For example, the plurality of second convex portions 40 include at least two or more convex portions (for example, convex portions 40a, convex portions 40b, and the like). For example, each protrusion in the plurality of second protrusions 40 is a protrusion having the same shape but different protrusion height H2 (see FIG. 3 described later) between the protrusions of the plurality of second protrusions 40. (Details will be described later).

  For example, the scale 4 is arranged such that vertical lines (in the vertical direction on the paper surface of FIG. 1) are arranged in the horizontal direction with respect to the base unit 2 at every predetermined measurement unit distance (for example, actual size of 0.2 mm). (Extended line) 4a. For example, the vertical line 4a is displayed below the plurality of first protrusions 30 (downward on the paper surface of FIG. 1). Further, for example, the scale 4 is arranged such that vertical lines (up and down on the paper surface of FIG. 1) are arranged in the horizontal direction with respect to the base unit 2 at every preset measurement unit distance (for example, actual size of 0.2 mm). (A line extending in the direction) 4b. For example, the vertical line 4b is displayed on the upper side near the plurality of second convex portions 40 (upward on the paper surface of FIG. 1). For example, a space is provided below the vertical line 4a and above the vertical line 4b, and a distance value 4c as an actual distance is printed.

  For example, the distance numerical value 4c indicates a numerical value of the convex part heights H1 and H2 (see FIGS. 2 and 3 described later) of each convex part. For example, the numerical value of the distance digit 4c is provided for each convex portion. That is, the examiner reads the numerical values, and thereby, the respective convex portions (each convex portion in the plurality of first convex portions 30 and each convex portion in the plurality of second convex portions 40) provided above or below the numerical values. Can be read. For example, in the present embodiment, the numerical values are displayed in units of 0.2 cm. In other words, in the present embodiment, the protrusion heights H1 and H2 of the protrusions (the protrusions of the plurality of first protrusions 30 and the protrusions of the plurality of second protrusions 40) are equal to the heights of the adjacent protrusions. It is formed so as to differ by 0.2 cm between them. For example, as shown in FIG. 1, the height H1 of the protrusion 30 a of the plurality of first protrusions 30 is 0.2 mm, and the height H1 of the protrusion 30 b of the plurality of first protrusions 30. The projection height H1 is 0.4 mm. Further, for example, as shown in FIG. 1, the height H1 of the protrusion 40 a of the plurality of second protrusions 40 is 0.2 mm, and the height of the protrusion of the plurality of second protrusions 40 is 0.2 mm. The height H1 of the protrusion of 40b is 0.4 mm.

  In the present embodiment, the configuration in which the heights H1 and H2 of the adjacent protrusions are changed in units of 0.2 cm has been described as an example, but the present invention is not limited to this. Any configuration may be used as long as the height of the convex portion is changed between adjacent convex portions. For example, the configuration may be such that the height of adjacent convex portions is changed in units of 0.1 cm, or the configuration may be changed in units of 0.3 cm. Of course, the height between adjacent convex portions may not be changed in a fixed unit. In these cases, for example, the configuration may be such that the height of each of the formed protrusions is printed as a numerical value.

  Hereinafter, the plurality of first protrusions 30 and the plurality of second protrusions 40 will be described in more detail. FIG. 2 is a diagram illustrating a configuration of the plurality of first convex portions 30. In FIG. 2, one of the plurality of first protrusions 30 is shown. For example, the protrusion 30a has a shape that fits into the bevel groove. In the present embodiment, the shape fitting into the bevel groove is, for example, a shape imitating a bevel. Of course, the shape of the convex portion 30a that fits into the bevel groove may not be a shape that imitates the bevel, but may be any shape that fits into the bevel groove.

  For example, the convex portion 30a has a first inclined portion 31, a second inclined portion 32, and a vertex portion (convex vertex portion) 33. For example, the first slope 31 extends from the first shoulder 36. For example, the second slope portion 32 is a slope portion different from the first slope portion 31 and extends from a second shoulder portion 37 which is a shoulder portion different from the first shoulder portion 36. For example, the vertex portion 33 is a portion where the first inclined portion 31 and the second inclined portion 32 intersect. Note that, for example, the apex portion 33 may have a curved shape.

  For example, each protrusion in the plurality of first protrusions 30 is a protrusion having the same shape and different distance from each other in each of the plurality of first protrusions 30. For example, the convex portions having different distances are the distance (first distance) from the first hem 34, which is the hem of the first inclined portion 31, to the vertex 33, and the hem of the second inclined portion 32. The distances (second distances) from the second hem 35 to the apex 33 and the configurations different from each other among the plurality of first protrusions 30 are shown. Hereinafter, the first distance, the second distance, and the protrusion having the same shape will be described in more detail.

  In the present embodiment, for example, the first distance and the second distance use the height H1 of the convex portion. For example, the convex part height H1 is a distance in a vertical direction (a vertical direction on the paper surface of FIG. 2) from the first hem 34, which is the hem of the first inclined portion 31, to the apex 33. In other words, for example, the convex part height H1 is a distance in the vertical direction (the vertical direction on the paper surface of FIG. 2) from the second hem 35, which is the hem of the second inclined portion 32, to the vertex 33. In the present embodiment, the first distance and the second distance will be described using the height H1 of the convex portion as an example, but the present invention is not limited to this. For example, the first distance and the second distance may be a distance of a straight line connecting the first hem 34 and the apex 33. Further, for example, the first distance and the second distance may be distances in the horizontal direction (left and right directions on the paper surface of FIG. 2) from the first skirt portion 34 to the vertex portion 33.

  In the present embodiment, for example, the projections having the same shape are the first inclination angle (the angle of the skirt portion) α1 of the first inclined portion 31 with respect to the first shoulder portion 36 and the second inclination portion with respect to the second shoulder portion 37. Each of the second inclination angles (the angle of the skirt 35) α2 of the two inclined portions 32 is set at the same angle between the plurality of convex portions. For example, in the plurality of first protrusions 30, the respective protrusions (for example, the protrusions 30a and the protrusions 30b) have the same first inclination angle α1 and the same second inclination angle α2. Are set at the same angle. That is, in the plurality of first protrusions 30, the first inclination angle α1 and the second inclination angle α2 are fixed at a common angle between the respective protrusions.

  For example, in the present embodiment, the protrusions 30a of the plurality of first protrusions 30 have the first inclination angle α1 and the second inclination angle α2 formed at the same angle. In other words, the convex portion 30a has a straight line of the convex portion height H1 (specifically, a perpendicular line lowered from the vertex 33 to a straight line connecting the first shoulder portion 36 and the second shoulder portion 37) as a center line. The left and right convex portions have the same shape (a left-right symmetric shape). In the present embodiment, for example, the first inclination angle α1 and the second inclination angle α2 are set to 145 °. Of course, the first inclination angle α1 and the second inclination angle α2 are set to arbitrary angles (for example, 100 °, 90 °, etc.). It is preferable that the first inclination angle α1 and the second inclination angle α2 are set such that the convex portion 30a is smaller than the bevel groove in a normal curved eyeglass frame.

  As described above, in the convex portions having the same shape, any one of the horizontal distance, the vertical distance (convex portion height H1), and the linear distance (the distance of the straight line connecting the first skirt portion 34 and the vertex portion 33) is used. Are different, the other two distances also have different configurations. For example, when the height H1 of the protrusions of the same shape is changed, the horizontal distance and the linear distance are also changed. For this reason, each of the plurality of first protrusions 30 has the same shape between the respective protrusions, and the protrusions have different heights H1.

  FIG. 3 is a diagram illustrating a configuration of the plurality of second convex portions 40. In FIG. 3, one of the plurality of second protrusions 40 is shown. For example, the protrusion 40a has a shape that fits into the bevel groove. In the present embodiment, the shape fitting into the bevel groove is, for example, a shape imitating a bevel. Of course, the shape of the convex portion 40a that fits into the bevel groove need not be a shape that imitates the bevel, but may be any shape that fits into the bevel groove.

  For example, the convex portion 40a has a first inclined portion 41, a second inclined portion 42, and an apex (a convex apex) 43. For example, the first slope 41 extends from the first shoulder 46. For example, the second slope portion 42 is a slope portion different from the first slope portion 41 and extends from a second shoulder portion 47 which is a shoulder portion different from the first shoulder portion 46. For example, the vertex 43 is a portion where the first inclined portion 41 and the second inclined portion 42 intersect. Note that, for example, the apex portion 43 may have a curved shape.

  For example, each protrusion in the plurality of second protrusions 40 is a protrusion having the same shape and different distance from each other in each of the plurality of second protrusions 40. For example, the convex portions having different distances are a distance (first distance) from the first skirt portion 44, which is the skirt portion of the first inclined portion 41, to the apex portion 43, and a skirt portion of the second inclined portion 42. The distance (second distance) from the second skirt 45 to the apex 43 and the different configurations between the respective convex portions of the plurality of second convex portions 40 are shown. Hereinafter, the first distance, the second distance, and the protrusion having the same shape will be described in more detail.

  In the present embodiment, for example, the first distance and the second distance use the height H2 of the convex portion. For example, the convex part height H2 is a distance in the vertical direction (the vertical direction on the paper surface of FIG. 3) from the first skirt part 44, which is the skirt part of the first inclined part 41, to the apex part 43. In other words, for example, the convex part height H2 is a distance in the vertical direction (the vertical direction on the paper surface of FIG. 3) from the second hem 45, which is the hem of the second inclined part 42, to the vertex 43. In the present embodiment, the first distance and the second distance will be described using the height H2 of the convex portion as an example, but the present invention is not limited to this. For example, the first distance and the second distance may be linear distances connecting the first skirt portion 44 and the vertex portion 43. In this case, the first distance and the second distance are different from each other. Further, for example, the first distance and the second distance may be distances in the horizontal direction (left and right directions on the paper surface of FIG. 2) from the first skirt portion 44 to the vertex portion 43. In this case, the first distance and the second distance are different from each other.

  In the present embodiment, for example, the protrusions having the same shape include a first inclination angle (an angle of the skirt 44) α3 of the first inclined portion 41 with respect to the first shoulder 46 and a second inclination with respect to the second shoulder 47. Each of the second inclination angles (the angle of the skirt 45) α4 of the two inclined portions 42 is set at the same angle between the plurality of convex portions. For example, in the plurality of second convex portions 40, each convex portion (for example, convex portion 40a, convex portion 40b) has the same first inclination angle α3 and the same second inclination angle α4. Are set at the same angle. That is, in the plurality of second protrusions 40, the first inclination angle α1 and the second inclination angle α2 are fixed at a common angle between the respective protrusions.

  For example, in the present embodiment, the projections 40a of the plurality of second projections 40 are formed such that the first inclination angle α3 and the second inclination angle α4 are different. In other words, the convex portion 40a has a shape (asymmetric shape left and right) in which the right and left convex portions have different shapes with the straight line having the convex portion height H2 (a perpendicular line at the vertex of the convex portion) as the center line. For this reason, the convex portion 40a has an inclined shape. That is, the shape is such that the apex 43 of the convex portion 40a approaches one inclined portion side (in the present embodiment, the second inclined portion 42 side). Thereby, for example, the distance of the straight line connecting the first skirt portion 44 and the vertex portion 43 is different between the first distance and the second distance. Further, for example, the distance in the horizontal direction from the first skirt portion 44 to the vertex portion 43 is different from each other in the first distance and the second distance.

  In the present embodiment, for example, the first inclination angle α3 is set to 150 °. In the present embodiment, for example, the second inclination angle α4 is set to 135 °. Of course, the first inclination angle α3 and the second inclination angle α4 are set to arbitrary angles (for example, 100 °, 90 °, etc.). It is preferable that the first inclination angle α3 and the second inclination angle α4 are set so that the convex portion 40a is smaller than the bevel groove in the normal curved eyeglass frame.

  As described above, in the protrusions having the same shape, one of the horizontal distance, the vertical distance (convex portion height H2), and the linear distance (the distance of the straight line connecting the first skirt portion 44 and the vertex portion 43) Are different, the other two distances also have different configurations. For example, when the height H2 of the protrusions of the same shape is changed, the distance in the horizontal direction and the straight line distance are also changed. For this reason, each of the plurality of second protrusions 40 has the same shape between the protrusions, and has a different protrusion height H2.

  FIG. 4 is a diagram illustrating the bevel groove of the rim of the spectacle frame. Hereinafter, measurement of the spectacle frame F using the measurement jig 1 will be described. For example, the spectacle frame F shown in FIG. 4 is a view of the high-curve spectacle frame F viewed from above (above the spectacle frame F). Note that, in the present embodiment, a description will be given by taking the left part of the eyeglass frame as an example. Of course, the following description has the same configuration for the right portion of the eyeglass frame. For example, the spectacle frame F includes a rim L and a bridge B. In FIG. 4, the configuration of the spectacle frame F is simplified for convenience.

  For example, in a high-curve spectacle frame F, the shape of the bevel groove of the rim L may differ depending on the part of the spectacle frame F. For example, in the spectacle frame F, the rim of the portion where the rim is inclined (for example, the ear portion L1 and the nose portion L2 of the spectacle frame F) and the portion where the rim is not inclined (for example, the top and bottom of the spectacle frame F) The shape of the bevel groove of the rim differs from that of the rim of the portion L3). In FIG. 4, a dotted line portion La is an enlarged view of a cross section of the rim 50 of the top and bottom portion L3 (the portion where the rim is not inclined) of the eyeglass frame F. In FIG. 4, dotted line portions Lb are rims of an ear portion (a portion where the rim of the spectacle frame F is inclined) L1 and a nose portion (a portion where the rim of the spectacle frame F is inclined) L2 of the spectacle frame F. 60 shows an enlarged view of a cross section of FIG. In the present embodiment, the rim of the ear portion L1 and the rim of the nose portion L2 are described as rims 60 having the same bevel groove.

  For example, the rim 50 has a first inclined portion 51, a second inclined portion 52, an apex (a bevel groove apex) 53, a first shoulder 54, and a second shoulder 55. For example, the first inclination angle of the first inclined portion 51 with respect to the first shoulder portion 54 and the second inclination angle of the second inclined portion 52 with respect to the second shoulder portion 55 are set to the same angle. That is, the rim 50 has the same shape (a symmetrical shape) in the left and right bevel grooves with the vertical line at the apex portion 53 as the center line. For this reason, the shape of the bevel groove of the rim 50 and the shape of each of the plurality of first protrusions 30 are formed in the same shape. Thereby, the plurality of first protrusions 30 can be fitted into the bevel groove of the rim 50. In addition, it is considered that the shape of the bevel groove of the rim in the spectacle frame having a normal curve (for example, a low curve) is similar to the shape of the rim in the spectacle frame F where the rim is not inclined. For this reason, in the measurement of the bevel groove of the rim of the spectacle frame having the normal curve, the plurality of first convex portions 30 can be used.

  For example, the rim 60 has a first inclined portion 61, a second inclined portion 62, an apex (a bevel groove apex) 63, a first shoulder 64, and a second shoulder 65. The first inclined angle of the first inclined portion 61 with respect to the first shoulder portion 64 and the second inclined angle of the second inclined portion 62 with respect to the second shoulder portion 65 are formed at different angles. For example, the rim 60 has a shape in which the shapes of the left and right bevel grooves are different from each other (asymmetric shape in the left and right directions) with the vertical line at the vertex 63 as the center line. Thus, the bevel groove in the rim 60 has an inclined shape. In other words, the rim 60 has a shape in which the apex portion 63 approaches one inclined portion side (in the present embodiment, the second inclined portion 62 side). Therefore, the shape of the bevel groove of the rim 60 and the shape of each of the plurality of second protrusions 40 are formed in the same shape (inclined shape). Therefore, the plurality of second protrusions 40 can be fitted into the bevel groove of the rim 60.

  FIG. 5 is a diagram illustrating a measurement operation when measuring the bevel groove of the rim 50 using the plurality of first protrusions 30. The examiner fits any one of the plurality of first protrusions 30 of the measurement jig 1 into the bevel groove of the rim 50. The examiner checks the convex portion that fits properly into the bevel groove while changing the convex portion that fits into the bevel groove of the rim 50.

  FIG. 5A is a diagram illustrating a case where a protrusion having a height H1 smaller than the bevel groove of the rim 50 in the plurality of first protrusions 30 is fitted into the bevel groove of the rim 50. It is. As shown in FIG. 5A, for example, of the plurality of first protrusions 30, a protrusion having a protrusion height H1 smaller than the bevel groove of the rim 50 is fitted into the bevel groove of the rim 50. In this case, the apex portion 33 of the convex portion does not abut on the apex portion (bevel groove apex portion) 53 of the rim 50. Therefore, for example, a space S1 is generated between the bevel groove of the rim 50 and the projection. In this case, for example, when the examiner operates to move the measuring jig 1 in the horizontal direction (horizontal direction on the paper surface of FIG. 5), the measuring jig 1 moves in the horizontal direction with respect to the bevel groove of the rim 50. I do. For this reason, when the examiner moves the measuring jig 1 in the horizontal direction, the convex portion height H1 of the convex portion fitted in the plurality of first convex portions 30 is determined by the bevel groove of the rim 50. It can be determined that it is smaller than the depth. In this case, the examiner selects a convex portion larger than the fitted convex portion from the plurality of first convex portions 30 and fits the selected convex portion into the bevel groove.

  FIG. 5B is a diagram illustrating a case where a protrusion having a height H1 larger than the bevel groove of the rim 50 among the plurality of first protrusions 30 is fitted into the bevel groove of the rim 50. It is. As shown in FIG. 5B, for example, among the plurality of first protrusions 30, a protrusion having a protrusion height H1 larger than the bevel groove of the rim 50 is fitted into the bevel groove of the rim 50. In this case, before the convex portion fits into the bevel groove of the rim 50, the vertex 33 of the convex portion comes into contact with the vertex portion (vertical portion of the bevel groove) 53 of the rim 50. Therefore, for example, a space S2 is generated between the first shoulder 54 and the second shoulder 55 of the rim 50 and the projection, and the measuring jig 1 is in a floating state. In this case, for example, when the examiner confirms the fitting of the measuring jig 1, it is possible to confirm a state in which the convex portion is floating with respect to the bevel groove of the rim 50. For this reason, when the examiner can confirm the state in which the convex portion is floating with respect to the bevel groove of the rim 50, the examiner checks the convex portion fitted in the plurality of first convex portions 30. It can be determined that the convex portion height H1 is larger than the depth of the bevel groove of the rim 50. In this case, the examiner selects a protrusion smaller than the fitted protrusion from the plurality of first protrusions 30 and fits the selected protrusion into the bevel groove.

  FIG. 5C is a diagram illustrating a case where a protrusion selected from the plurality of first protrusions 30 is properly fitted into the bevel groove of the rim 50. As shown in FIG. 5C, for example, when a convex portion selected from the plurality of first convex portions 30 is fitted into the bevel groove of the rim 50, the apex portion 33 of the convex portion becomes the rim 50. When abutment is made on the apex portion (apex portion of the bevel groove) 53, a space is hardly generated. In this case, for example, when the examiner confirms the fitting of the measuring jig 1, the lifting of the convex portion with respect to the bevel groove of the rim 50 is not confirmed. Further, for example, even if the examiner operates to move the measuring jig 1 in the horizontal direction, the measuring jig 1 does not move in the horizontal direction with respect to the bevel groove of the rim 50. For this reason, the examiner can determine that the protrusion selected from the plurality of first protrusions 30 is properly fitted into the bevel groove of the rim 50. In this case, the examiner reads the distance value 4c corresponding to the convex portion. Thereby, the bevel groove can be measured.

  FIG. 6 is a diagram illustrating a measurement operation when measuring the bevel groove of the rim 60 by using the plurality of second protrusions 40. The examiner fits any one of the plurality of second protrusions 40 of the measurement jig 1 into the bevel groove of the rim 60. The examiner checks the convex portion that fits properly into the bevel groove while changing the convex portion that fits into the bevel groove of the rim 60.

  FIG. 6A is a diagram illustrating a case in which a convex portion having a height H2 smaller than that of the bevel groove of the rim 60 among the plurality of second convex portions 40 is fitted into the bevel groove of the rim 60. It is. As shown in FIG. 6A, for example, of the plurality of second protrusions 40, a protrusion having a protrusion height H2 smaller than the bevel groove of the rim 60 is fitted into the bevel groove of the rim 60. In this case, the apex portion 43 of the projection does not abut on the apex portion (bevel groove apex) 63 of the rim 60. Therefore, for example, a space S3 is generated between the bevel groove of the rim 60 and the projection. In this case, for example, when the examiner operates to move the measuring jig 1 in the horizontal direction (horizontal direction on the paper surface of FIG. 5), the measuring jig 1 moves in the horizontal direction with respect to the bevel groove of the rim 60. I do. For this reason, when the examiner moves the measuring jig 1 in the horizontal direction, the convex part height H2 of the convex part fitted in the plurality of second convex parts 40 is determined by the bevel groove of the rim 60. It can be determined that it is smaller than the depth. In this case, the examiner selects a convex portion larger than the fitted convex portion from the plurality of second convex portions 40 and fits the selected convex portion into the bevel groove.

  FIG. 6B is a diagram illustrating a case where a convex portion having a convex portion height H2 larger than the bevel groove of the rim 60 among the plurality of second convex portions 40 is fitted into the bevel groove of the rim 60. It is. As shown in FIG. 6B, for example, of the plurality of second protrusions 40, a protrusion having a protrusion height H2 larger than the bevel groove of the rim 60 is fitted into the bevel groove of the rim 60. In this case, before the convex portion fits into the bevel groove of the rim 60, the vertex 43 of the convex portion comes into contact with the vertex portion (vertical portion of the bevel groove) 63 of the rim 60. Therefore, for example, a space S4 is generated between the first shoulder 64 and the second shoulder 65 of the rim 60 and the projection, and the measurement jig 1 is in a floating state. In this case, for example, when the examiner confirms the fitting of the measuring jig 1, it is possible to confirm a state in which the convex portion is floating with respect to the bevel groove of the rim 60. For this reason, when the examiner can confirm the state where the convex portion is floating with respect to the bevel groove of the rim 60, the convex portion fitted in the plurality of second convex portions 40 is determined. It can be determined that the convex portion height H2 is larger than the depth of the bevel groove of the rim 60. In this case, the examiner selects a convex portion smaller than the fitted convex portion from the plurality of second convex portions 40 and fits the selected convex portion into the bevel groove.

FIG. 6C is a diagram illustrating a case where a protrusion selected from the plurality of second protrusions 40 is appropriately fitted into the bevel groove of the rim 60. As shown in FIG. 6C, for example, when a convex portion selected from the plurality of second convex portions 40 is fitted into the bevel groove of the rim 60, the vertex 43 of the convex portion becomes the rim 60. When abutment is made on the apex portion (apex portion of the bevel groove) 63, a space is hardly generated. In this case, for example, when the examiner confirms the fitting of the measuring jig 1, the floating of the convex portion with respect to the bevel groove of the rim 60 is not confirmed. Further, for example, even if the examiner operates to move the measuring jig 1 in the horizontal direction, the measuring jig 1 does not move in the horizontal direction with respect to the bevel groove of the rim 60. For this reason, the examiner can determine that the protrusion selected from the plurality of second protrusions 40 is properly fitted into the bevel groove of the rim 60. In this case, the examiner reads the distance value 4c corresponding to the convex portion. Thereby, the bevel groove can be measured.
As described above, in the present embodiment, the measuring jig 1 has a plurality of convex portions having different convex portion heights. This makes it possible to easily and accurately measure the depth of the bevel groove.

  In the present embodiment, for example, the measurement jig 1 includes a plurality of convex portions for normal curve measurement (for example, a plurality of convex portions having the same shape on the left and right with respect to a vertical line at the vertex of the convex portion as a center line). 1st convex part 30 grade | etc.). As a result, it is possible to satisfactorily fit the convex portion into the bevel groove with respect to the rim of the spectacle frame having the normal curve, and it is possible to easily and accurately measure the depth of the bevel groove with respect to the spectacle frame having the normal curve.

  Further, for example, in the case of a high-curve eyeglass frame, the bevel grooves of the rim at the nose side portion and the ear side portion of the eyeglass frame are often inclined. For example, in the present embodiment, the measuring jig 1 includes a plurality of convex portions for measuring a high curve (for example, a plurality of convex portions having left and right asymmetric shapes with right and left asymmetrical shapes with a vertical line at a vertex portion of the convex portion as a center line). 2nd convex part 40 grade | etc.). For this reason, it is possible to satisfactorily fit the convex portion even on a rim in which the bevel groove is inclined, and it is possible to easily and accurately measure the depth of the bevel groove even in a high-curve eyeglass frame.

  Also, for example, in the present embodiment, by having a convex portion for measuring the depth of the bevel groove with respect to the rim of the normal curve eyeglass frame and the depth of the bevel groove with respect to the rim of the high curve eyeglass frame, respectively. The depth of the bevel groove can be easily and accurately measured for various types of spectacle frames.

  The configuration of the measuring jig 1 in the present embodiment includes a plurality of first convex portions 30 used for measuring a normally curved spectacle frame and a plurality of first convex portions 30 used for measuring a high curved spectacle frame. The configuration including both the two convex portions 40 has been described as an example, but the configuration is not limited to this. The measuring jig 1 may have a configuration including at least one of the plurality of first protrusions 30 and the plurality of second protrusions 40.

  In the present embodiment, the measuring jig may be a measuring jig configured to combine two or more measuring jigs 1 described in the present disclosure. For example, a measurement jig in which two measurement jigs are combined will be described. FIG. 7 is a diagram illustrating an example of a measurement jig in which two measurement jigs are combined. In this case, for example, the measurement jig 100 has a connection moving unit 70 that connects the two measurement jigs 1a and 1b. For example, the connection moving unit 70 has a slider mechanism. For example, the connection moving means 70 moves one of the two measuring jigs 1a and 1b relative to the other measuring jig in a direction in which the width W between the two measuring jigs is changed. It is possible (see the arrow portion of the connection moving means 70 in FIG. 7). The configuration for changing the width W is not changed by movement in the vertical direction (vertical direction on the paper surface of FIG. 7). Any configuration may be used as long as the width between the two measurement jigs in any direction is changed by moving in the direction. Note that the connection moving means is not limited to the slider mechanism. The connection moving means 70 may be configured such that one of the two measuring jigs 1a and 1b moves in the direction in which the width between the two measuring jigs is changed with respect to the other measuring jig. I just need. For example, as the plurality of protrusions 110 of the measurement jig 100, at least one of the plurality of first protrusions 30 and the plurality of second protrusions 40 may be applied. When both the plurality of first protrusions 30 and the plurality of second protrusions 40 are applied to the measurement jig 100, one of the plurality of protrusions is connected to the upper end side of the measurement jig (the left side on the paper in FIG. 7). ) (The positions of the plurality of protrusions 110), and the other plurality of protrusions may be provided on the lower end side of the measurement jig (right side on the paper surface of FIG. 7). The examiner changes the width between the two measuring jigs 1a and 1b in a state where the measuring jig 100 is inserted into the frame of the spectacle frame, and adjusts the rims at both ends of the spectacle frame (for example, the ear rim and the nose). A plurality of bevel grooves are measured simultaneously by making contact with the bevel grooves of the side rim. As described above, since the distance between the two measurement jigs can be changed, the width W between the two measurement jigs is changed while the measurement jig is inserted into the frame of the spectacle frame, and Can be brought into contact with the bevel grooves of the rims at both ends (for example, the ear rim and the nose rim). This eliminates the need for the examiner to bring the measuring jig into contact with the bevel groove for measurement, and inserts the measuring jig into the eyeglass frame and changes the width between the measuring jigs with a simple operation. The measurement jig can be brought into contact with the bevel groove. That is, the measurement of the bevel groove can be performed more easily.

  Note that a configuration may be adopted in which at least one of the first shoulder 46 and the second shoulder 47 of the plurality of second protrusions 40 is inclined. FIG. 8 is a diagram illustrating an example in which the shoulders of the plurality of second protrusions 40 are inclined. FIG. 8 shows a case where, for example, both the first shoulder 46 and the second shoulder 47 are inclined. For example, in the first shoulder 46a, the first shoulder 46 is inclined from the skirt 44 toward the center of the measuring jig 1. Further, for example, in the second shoulder portion 47a, the first shoulder portion 47 is inclined from the skirt portion 45 toward the outside of the measurement jig 1. As described above, the protrusions of the plurality of second protrusions 40 are configured such that the shoulders are inclined, so that the rim (a straight line connecting the first shoulder and the second shoulder of the rim) and the protrusions are formed. (The straight line connecting the first hem and the second hem) is brought into contact in a parallel state, so that the depth of the bevel groove can be accurately measured.

  In the present embodiment, as the measuring jig 1, the convex portion is simultaneously fitted into the front inclined portion (one inclined portion) and the rear inclined portion (the other inclined portion) of the bevel groove, and the measurement is performed. The configuration has been described by way of example, but is not limited to this. For example, a measuring jig for separately measuring the front inclined portion and the rear inclined portion of the bevel groove may be used. For example, on one side of the measuring jig (for example, on the side of the plurality of first convex portions 30), a plurality of convex portions for measuring the front inclined portion of the bevel groove (for example, the front side of the bevel groove) are formed. On one side (for example, the side of the plurality of second convex portions 40), a plurality of convex portions for measuring the rear inclined portion (for example, the rear surface side of the bevel groove) of the bevel groove may be formed. . In this case, for example, in a plurality of convex portions for measuring the front inclined portion of the bevel groove, the first inclined portion and the second inclined portion of each convex portion have a vertical shape (for example, the inclination angle of the inclined portion with respect to the shoulder is 90 °). Further, for example, in a plurality of convex portions for measuring the rear inclined portion of the bevel groove, the first inclined portion and the second inclined portion of each convex portion have a vertical shape (for example, the inclination angle of the inclined portion with respect to the shoulder is 90 °).

  Note that, in the present embodiment, the bevel shape having the first inclined portion, the second inclined portion, and the apex portion has been described as an example of the shape of the convex portion; however, the shape is not limited to this. A measuring jig for measuring the depth of the bevel groove provided on the rim of the spectacle frame may be a plurality of protrusions having a shape that fits into the bevel groove. In this case, the plurality of protrusions include the height of the protrusion (height of the protrusion) and the width of the protrusion (e.g., a distance between straight lines connecting the first skirt and the second skirt). At least one of the protrusions may have a different shape between the plurality of protrusions. More specifically, a convex bevel (sometimes referred to as a "T bevel") having a front surface facing the front of the lens, a rear surface facing the rear of the lens, and an outer surface facing the outer periphery of the lens. May be formed.

  In the present embodiment, a measuring jig for measuring a bevel groove has been described as an example, but the present invention is not limited to this. The technology of the present disclosure can be applied to a measuring jig for measuring a groove. For example, any configuration may be used as long as a protrusion having a shape imitating a groove to be measured is provided.

  The configuration of the measurement jig 1 in the present embodiment may be provided in another device. For example, it may be provided in a spectacle frame shape measuring device (tracer), a spectacle lens processing device (lens edger), or the like. By being provided in these devices, the depth information of the bevel groove can be promptly input to the device, and the setting of each device can be performed smoothly. Further, since the setting of each device can be performed using the measurement result obtained by measuring the bevel groove accurately, spectacles can be produced satisfactorily.

DESCRIPTION OF SYMBOLS 1 Measurement jig 1a Measurement jig 1b Measurement jig 2 Base part 3 Plural convex parts 4 Scale 30 Plural first convex parts 30a Convex part
40 plural second convex parts 40a convex part 70 connection moving means 100 measuring jig 110 plural plural convex parts

Claims (5)

A measuring jig for measuring the depth of a bevel groove provided on a rim of an eyeglass frame,
A first slope extending from the first shoulder, a second slope different from the first slope, and a second slope extending from a second shoulder that is different from the first shoulder; A plurality of convex portions having a first inclined portion and a vertex portion at which the second inclined portion intersects, and having a shape fitted into the bevel groove;
The plurality of protrusions are a first distance from a first hem, which is a hem of the first inclined portion, to the vertex, and a second distance from a second hem, which is a hem of the second inclined portion. A second distance to the convex portion is different from each other between the plurality of convex portions;
A first inclination angle of the first inclined portion with respect to the first shoulder portion and a second inclination angle of the second inclined portion with respect to the second shoulder portion are set at the same angle between the plurality of convex portions. A measuring jig characterized by being performed. The measuring jig according to claim 1,
Wherein the plurality of convex portions, measurement jig in which the first inclination angle of each convex portion and the second tilt angle, characterized in that it comprises a plurality of convex portions are the same angle. The measuring jig according to claim 1 or 2,
Wherein the plurality of convex portions, measurement jig in which the first inclination angle of each convex portion and the second tilt angle, characterized in that it comprises a plurality of convex portions are different angles. It is a measurement jig which has two measurement jigs of Claims 1-3,
A connection moving unit that connects two measurement jigs, wherein one of the two measurement jigs is different from the other measurement jig in a width between the two measurement jigs. A measuring jig provided with a connection moving means capable of moving in a direction to be measured. A measuring jig for measuring the depth of a convex bevel groove provided on a rim of an eyeglass frame,
A surface before extending from the first skirt portion of the first shoulder portion, and a face before facing forward of the lenses, extending from the second skirt portion of the second shoulder portion is different from the shoulder portion and the first shoulder portion A rear surface, a rear surface facing the rear of the lens, and an outer peripheral surface facing the outer peripheral side of the lens, comprising a plurality of convex portions having a shape fitted into the convex bevel groove,
The plurality of protrusions are a height distance from a first skirt of the front surface to the outer peripheral surface, and a height of the protrusion which is a distance from a second skirt of the rear surface to the outer peripheral surface. And at least one of a width of the convex portion, which is a distance of a straight line connecting the first hem portion and the second hem portion, is different between the plurality of convex portions. .

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