JP2023016428A - Screw gauge - Google Patents

Abstract

To provide a screw gauge capable of realizing a superior core alignment mechanism with a simple structure.SOLUTION: A screw gauge includes: a gauge part 2 having an externally-threaded complete screw 20 on an outer peripheral surface from one end and a bottomed hole 21 on the other end surface; a shaft 1 with a tip part thereof inserted in the bottomed hole 21 of the gauge part 2; and a cylindrical sleeve 3 to be attached to an opening part of the bottomed hole 21. The shaft 1 includes: a ball point part 11 having an external thread shape capable of torque transmission at a tip part thereof; and a shaft part 12 having a maximum outside diameter smaller than a maximum outside diameter of the ball point part. At least on an inner peripheral surface in a vicinity of the bottomed hole 21, an engagement part 21a is formed, in an internal thread shape capable of torque transmission corresponding to the ball point part 11. The sleeve 3 has an inner diameter smaller than the maximum outside diameter of the ball point part 11 and larger than the maximum outside diameter of the shaft part 12 when attached to the opening part of the bottomed hole 21.SELECTED DRAWING: Figure 4

Description

The present disclosure relates to thread gauges for inspecting internally threaded holes.

A thread gauge is used to inspect the formed female threaded hole. A thread gauge for inspecting a female threaded hole has a male threaded gauge part at the tip of the shaft, and the female threaded hole is inspected by whether the gauge part can be properly screwed into the formed female threaded hole. . Screw gauges are divided into standard screw gauges that have a standard accurate gauge part, go-side gauges that have a gauge part made smaller than the standard dimensions, and stop-side gauges that have a gauge part made larger than the standard dimensions. There are types such as limit screw gauges that consist of a pair of gauges.

Inspection with a screw gauge can be done completely manually by the operator, semi-automated by automating only the rotation of the gauge with an electric screwdriver, etc. although it is basically manual work by the operator, or to the female screw hole of the gauge part. A case of full automation in which the positioning is also automated is conceivable. However, it is difficult to position the gauge portion to the female screw hole, and this hinders reduction of the inspection time for 100% inspection of the female screw hole. Improvements are desired in alignment between the gauge portion and the female threaded hole not only in the fully automatic case but also in the manual or semi-automatic case. Moreover, if the alignment is performed smoothly, wear of the gauge can be suppressed. Patent Literature 1 listed below discloses a thread gauge in which a gauge portion provided at the tip of a shaft has an alignment mechanism.

German Utility Model No. 202004018244

In the screw gauge disclosed in Patent Document 1, a hole is formed in the gauge portion along the axial direction, and the tip of the shaft is inserted into the hole. The distal end portion of the shaft and the gauge portion are connected with a pin at the center of the gauge portion in the axial direction. As a result, the gauge portion can swing with respect to the shaft about the pin. Furthermore, by making the inner diameters of both ends of the pin insertion hole formed at the tip of the shaft larger than that of the central portion, the pin itself can swing relative to the shaft to some extent, and the gauge portion can swing freely relative to the shaft. Extended. By making the gauge part swingable with respect to the shaft in this way, an alignment function is realized. Patent Literature 1 also discloses a screw gauge that realizes an alignment function by placing a steel material having a certain degree of flexibility between the gauge portion and the shaft.

However, there is a demand for a screw gauge with a simpler structure and a better alignment function, and an object of the present disclosure is to provide a screw gauge that achieves an excellent alignment mechanism with a simpler structure.

A thread gauge according to the present disclosure is a thread gauge for inspecting a female threaded hole, the gauge having a male-threaded complete thread formed on the outer peripheral surface from one end and a bottomed hole formed on the other end surface. a portion, a shaft whose tip is inserted into the bottomed hole of the gauge portion, and a tubular sleeve attached to the opening of the bottomed hole. The shaft includes a ball point portion having a male shape capable of transmitting torque to the distal end portion, and a shaft portion extending from the ball point portion and having a maximum outer diameter smaller than the maximum outer diameter of the ball point portion. have. An engaging portion having a female shape capable of transmitting torque corresponding to the ball point portion is formed on the inner peripheral surface of the bottomed hole at least in the vicinity of the bottom portion. The sleeve has an inner diameter smaller than the maximum outer diameter of the ball point portion and greater than the maximum outer diameter of the shaft portion when mounted in the opening.

A slit may be formed in the sleeve from one axial end to the other axial end.

Furthermore, a male threaded portion may be formed on the outer peripheral surface of the sleeve, and a female threaded portion may be formed on the inner peripheral surface of the bottomed hole to engage with the male threaded portion.

Alternatively, a projection may extend in the circumferential direction on the outer peripheral surface of the sleeve, and a groove for accommodating the projection may be formed in the inner peripheral surface of the bottomed hole in the circumferential direction. .

Further, the sleeve may be formed with a flange that contacts the other end surface of the gauge portion, and the maximum outer diameter of the flange may be larger than the maximum outer diameter of the gauge portion.

Further, when the maximum outer diameter of the gauge portion is D, the height H from one end surface of the gauge portion to the center of the bottom surface of the bottomed hole is 0.2D≤H≤D/[2(3^). (1/2)].

1 is an overall side view of a thread gauge according to a first embodiment; FIG. It is an exploded side view of the tip portion of the screw gauge (partial cross section). It is a trihedral view of a sleeve in the screw gauge. It is a cross-sectional view of the tip portion of the screw gauge. It is a cross-sectional view of the tip portion of the screw gauge (screwed state to the female thread). It is a cross-sectional view of the tip portion of the screw gauge (contact state with the female screw opening). FIG. 4 is a side view of the thread gauge with its shaft bent (partially in section); FIG. 5 is a view equivalent to FIG. 5 of a screw gauge according to a second embodiment; FIG. 2 equivalent view of the screw gauge according to the third embodiment. FIG. 10 is a trihedral view of the sleeve of the screw gauge according to the third embodiment; FIG. 11 is a trihedral view of the sleeve of the screw gauge according to the fourth embodiment; FIG. 11 is a trihedral view of the sleeve of the screw gauge according to the fifth embodiment;

Embodiments of the thread gauge will be described below with reference to the drawings.

The thread gauge of the embodiment is a thread gauge for inspecting a formed internal thread hole, and is formed in the form of a bit so as to be attached to the chuck portion of an electric screwdriver. Further, the thread gauge of this embodiment is composed of three members, a shaft 1, a gauge portion 2 and a sleeve 3, as shown in FIG. In the first embodiment, the shaft 1, gauge portion 2 and sleeve 3 are all made of metal.

A chuck portion 10 is formed at the base end portion of the shaft 1 . The chuck part 10 has a hexagonal cross section like the driver bit, and a groove for chucking is formed in the circumferential direction. On the other hand, as shown in FIG. 2, the distal end of the shaft 1 has a ball point portion 11 having a male shape capable of transmitting torque. A “torque-transmissible male shape” is a shape having at least one projection projecting in a radial direction perpendicular to the rotation axis of the shaft 1 . When a plurality of protrusions are provided, they are preferably provided evenly in the circumferential direction. For example, the "torque-transmissible male shape" in this embodiment is a convex shape having a regular hexagonal cross section that is used for a normal hexagonal wrench or the like. Therefore, the ball point portion 11 has the same shape as the tip portion of an ordinary ball point hexagon wrench, so that even if the shaft 1 is tilted to some extent, it can be inserted into the mating female hexagon socket, and the shaft The shaft 1 can be rotated even when 1 is tilted.

The chuck portion 10 and the ball point portion 11 are integrally connected by the shaft portion 12 . That is, the shaft portion 12 extends from the ball point portion 11 and is connected to the chuck portion 10 . The shaft portion 12 of this embodiment is a simple round bar. The outer diameter of the shaft portion 12 is constant and at least smaller than the maximum outer diameter of the ball point portion 11 . The cross section of the shaft portion 12 may be, for example, a regular polygon, and may not have a uniform size in the longitudinal direction. In that case, the maximum outer diameter of the shaft portion 12 is at least smaller than the maximum outer diameter of the ball point portion 11 . Although the shaft 1 is made of metal, it is formed thin as described above, so that it can bend, in other words, it can bend.

If the shaft portion 12 is made of metal, its length should be at least five times the maximum outer diameter of the gauge portion 2 in order to achieve the deflection described above. If the length of the shaft portion 12 is too long, it will twist and become difficult to use as a screw gauge. Furthermore, the maximum outer diameter of the shaft portion 12 is set to at least 1/4 or more of the maximum outer diameter of the gauge portion 2, because if it is too thin, it will twist and become difficult to use as a screw gauge.

The gauge portion 2 has a male-threaded complete thread 20 formed on the outer peripheral surface from one end thereof. In this embodiment, as shown in FIG. 2, the complete thread 20 is formed on the entire peripheral surface of the gauge portion 2 from one end to the other end. A bottomed hole 21 is axially bored in the other end surface of the gauge portion 2 in the direction of the rotating shaft of the gauge portion 2 . The bottomed hole 21 has a depth that reaches the tip of the gauge portion 2, that is, the vicinity of one end face. An engaging portion 21 a having a female shape capable of transmitting torque corresponding to the ball point portion 11 is formed on the inner peripheral surface near the bottom of the bottomed hole 21 . The engaging portion 21 a engages with the ball point portion 11 described above to transmit torque from the shaft 1 to the gauge portion 2 .

The “female shape capable of transmitting torque” in this embodiment is a shape having at least one concave portion formed in the radial direction perpendicular to the rotation axis of the gauge portion 2 . The number of recesses is the same as the number of protrusions in the "torque-transmissible male shape" of the ball point portion 11, and when a plurality of recesses are provided, they are preferably provided evenly in the circumferential direction. For example, the "female shape capable of transmitting torque" in this embodiment is a concave shape having a regular hexagonal cross section corresponding to the male shape of the ball point portion 11 described above. Although the circumscribed circle of the regular hexagon of the engaging portion 21a is formed slightly larger than the circumscribed circle of the ball point portion 11, torque transmission is possible.

A cylindrical surface 21b is formed between the engaging portion 21a of the bottomed hole 21 and the opening. A female threaded portion 22A for attaching the sleeve 3 is formed on the cylindrical surface 21b. A circular cross section of the cylindrical surface 21b between the engaging portion 21a and the female screw portion 22A is a circumscribed circle of the regular hexagon of the engaging portion 21a. A circular cross section between the female threaded portion 22A and the opening has an inner diameter slightly larger than the maximum outer diameter of the male threaded portion 32A of the sleeve 3, which will be described later.

The sleeve 3, as shown in FIG. 3, is basically a tubular member having a through hole formed in its axial direction. However, the sleeve 3 has a slit 30, a flange 31 and an externally threaded portion 32A, which will be described below. The outer diameter of the sleeve 3 is equal to or slightly smaller than the inner diameter of the cylindrical surface 21b of the bottomed hole 21 described above. The length of the sleeve 3 is equal to or slightly smaller than the sum of the axial length of the cylindrical surface 21b of the bottomed hole 21 and the thickness of the flange 31, which will be described later. A slit 30 is formed in the sleeve 3 from one axial end to the other axial end. The inside and outside of the sleeve 3 are communicated by the slit 30 . The shaft portion 12 of the shaft 1 is inserted inside the sleeve 3 through this slit 30 . Therefore, the width of slit 30 is equal to or slightly larger than the outer diameter of shaft portion 12 .

From one end of the sleeve 3, a flange 31 abutting on the other end face of the gauge portion 2 described above extends radially outward. Further, as shown in FIG. 3, the flange 31 is formed with a pair of parallel flat surfaces 33 for use when fastening the sleeve 3 to the bottomed hole 21, which will be described later. Plane 33 is parallel to the axial direction of sleeve 3 . As shown in FIG. 5, in this embodiment, the maximum outer diameter of the flange 31 is smaller than the maximum outer diameter of the gauge portion 2 and smaller than the minimum inner diameter of the female threaded hole 40 to be inspected by the screw gauge. A female screw hole 40 shown in FIG. 5 is formed in the workpiece W. As shown in FIG. Note that the sleeve 3 shown in FIG. 5 is shown in a cross section that does not pass through the plane 33 .

A male threaded portion 32A that engages with the female threaded portion 22A of the gauge portion 2 is formed on the outer peripheral surface of the sleeve 3 . However, the male threaded portion 32A is not formed in the portion where the slit 30 is formed. The maximum outer diameter of the male threaded portion 32A is equal to or slightly smaller than the inner diameter of the groove 22 . To attach the sleeve 3 to the opening of the bottomed hole 21 , the male threaded portion 32</b>A and the female threaded portion 22</b>A are screwed together.

The cross-sectional view of FIG. 4 shows the maximum outer diameter portion of the ball point portion 11 . That is, FIG. 4 shows a cross section passing through the vertices of the regular hexagonal cross section of the ball point portion 11 and the cross section passing through the vertices of the regular hexagonal cross section of the engaging portion 21a. The inner diameter of the sleeve 3 attached to the bottomed hole 21 is smaller than the maximum outer diameter of the ball point portion 11 . Therefore, the sleeve 3 is prevented from slipping out of the gauge portion 2 . As shown in FIG. 4, the bottom surface of the bottomed hole 21 of the gauge portion 2 is formed as a curved surface whose center is convex toward the tip of the gauge portion 2, ie, one end face side. The radius of curvature of the bottom surface is larger than the radius of curvature of the tip of the ball point portion 11, and the bottom surface and the tip of the ball point portion 11 are in point contact.

The center O of the bottom surface of the bottomed hole 21 is positioned within a range of at least 1/2 of the full length of the fully threaded portion 20 on the one end side of the gauge portion 2, that is, on the tip side. /3. In other words, by setting the bottom surface of the bottomed hole 21, that is, the position of the center O of the bottom surface, as close to one end of the gauge portion 2 as possible, the swing center of the gauge portion 2 can be set to the one end side. By setting the swing center of the gauge portion 2 near one end, the alignment function of the gauge portion 2 can be improved.

More preferably, assuming that the maximum outer diameter of the gauge portion 2 is D, the height H from one end surface of the gauge portion 2, that is, from the tip surface to the bottom center O is within the range shown by the following inequality (1). set. In other words, the height H is the center thickness of the bottom wall of the bottomed hole 21 .
0.2D≦H≦D/[2(3̂(1/2)] (1)
Here, as shown in FIG. 4, D/[2(3̂(1/2)] is a 30° line from the circumscribed circle of one end face of the gauge portion 2 toward the central axis of the gauge portion 2. 0.2D is 20% of the maximum outer diameter of the gauge portion 2. The height H of the bottom center O is the height from one end face of the intersection of the line and the central axis when drawn. By setting it within the range represented by the inequality (1), it is possible to further improve the alignment function of the gauge portion 2. Next, this alignment function will be described.

The screw gauge of this embodiment has the above-described configuration, and the ball point portion 11 at the tip of the shaft 1 is loosely fitted in the bottomed hole 21 of the gauge portion 2 . Therefore, the gauge portion 2 is capable of swinging with respect to the shaft 1, and achieves a centering function with respect to the female threaded hole 40 to which it is screwed. Furthermore, since the height H described above is set within the range indicated by the above inequality (1), the swing center of the gauge portion 2 is located on the tip side of the gauge portion 2 . That is, when the gauge portion 2 is screwed into the opening of the female threaded hole 40 , the gauge portion 2 swings about a position near the opening, so that the gauge portion 2 is oriented in the axial direction of the female threaded hole 40 . easier to match.

FIG. 6 shows the state when the gauge portion 2 is screwed into the opening of the female threaded hole 40 . When the gauge portion 2 is screwed into the opening of the female threaded hole 40 , if the axis of the gauge portion 2 does not match the axis of the female threaded hole 40 , a part of the periphery of the distal end of the gauge portion 2 may interfere with the female threaded hole 40 . It contacts the opening edge and does not fully contact the tip peripheral edge on the opposite side. In the state shown in FIG. 6, the full thread 20 of the gauge portion 2 cannot be properly screwed with the thread of the female threaded hole 40. As shown in FIG. However, due to the partial contact between the tip peripheral edge of the gauge portion 2 and the opening edge of the female threaded hole 40 and the contact between the bottom surface of the bottomed hole 21 and the tip of the ball point portion 11, the gauge portion 2 is oscillated. 2 and the axis of the female threaded hole 40 are aligned. That is, the thread gauge and the female threaded hole 40 are aligned.

At this time, as shown in FIG. 6, a triangular relationship is formed as indicated by three arrows on the cross section, so the gauge portion 2 is rapidly swung and aligned. Here, in order for the aligning function to function quickly, the height H of the above-described bottom center O, which is the vertex of the triangle, should be at least 2/1, preferably 1/3, of the length of the complete screw 20. . More preferably, the height H is set within the range of the above inequality (1). If the height H of the center O of the bottom surface exceeds D/[2(3̂(1/2)], the force exerted by the contact between the bottom surface of the bottomed hole 21 and the tip of the ball point portion 11 will reach the gauge It tends to act in the direction opposite to the alignment of the portion 2, and the gauge portion 2 tends to fall in the direction opposite to the alignment.Therefore, the height H is D/[2(3̂(1/2)] More preferably, if the height H of the bottom center O is smaller than 0.2D, the strength of the bottom portion of the bottomed hole 21 may not be ensured.

In the thread gauge of Patent Document 1 described above, the pin connection position of the gauge portion is at the center of the gauge portion in the height direction, and a force that tilts the gauge portion in the opposite direction is likely to occur. On the other hand, in the screw gauge of this embodiment, the ball point portion 11 is arranged sufficiently close to the tip side of the gauge portion 2, so excellent alignment function is realized. In the thread gauge of Patent Document 1, it is necessary to form a hole in the threaded portion, which is important for inspection, on the outer peripheral surface of the gauge portion in order to press-fit a pin for connecting the gauge portion. Therefore, the screw gauge of Patent Document 1 also has aspects that are not preferable as a screw gauge.

Further, since the gauge portion 2 as a thread gauge is formed with a complete thread 20 over the entire length, a tapered portion for facilitating screwing, that is, an incomplete thread with an imperfect thread is not formed at the tip. This is because if an incomplete thread is formed, the thread cannot be inspected accurately. For this reason, just by pushing the gauge portion 2, the alignment function of the tapered portion at the tip of a normal screw cannot be exhibited. be. Moreover, such an alignment mechanism reduces the wear of the gauge portion 2 .

At this time, according to the screw gauge of this embodiment, as shown in FIG. The gauge portion 2 can be more accurately aligned. That is, in FIG. 6, alignment is performed by matching the direction of the axis, but the position of the gauge portion 2 and the position of the female screw hole 40 are aligned in the in-plane direction in which the opening of the female screw hole 40 is formed. Alignment can also be performed by aligning by deflection.

When the gauge portion 2 is brought into contact with the female threaded hole 40, a force acts to move the center of the gauge portion 2 toward the center of the female threaded hole 40 in parallel with the alignment shown in FIG. This force is generated by the partial contact between the edge of the tip of the gauge portion 2 and the opening edge of the female threaded hole 40 and the swinging movement of the gauge portion 2 shown in FIG. As a result, the shaft portion 12 is bent, and the alignment shown in FIG. 7 is also performed. In particular, the deflection of the shaft portion 12 shown in FIG. 7 is caused by the force acting on the ball point portion 11 provided at the tip of the shaft portion 12 via the gauge portion 2. Therefore, the shaft portion 12 is easily deflected, Improve alignment function. In the screw gauge of this embodiment, the alignment by swinging the gauge portion 2 with respect to the shaft 1 shown in FIG. 6 and the alignment by the deflection of the shaft portion 12 shown in FIG. Improves core function.

The assembly of the thread gauge described above will be briefly described. First, the sleeve 3 is attached to the shaft portion 12 of the shaft 1 . At this time, the shaft portion 12 can be inserted into the sleeve 3 through the slit 30 of the sleeve 3 . After that, while the sleeve 3 is positioned near the ball point portion 11, the pair of flat surfaces 33 of the sleeve 3 are used to insert the male threaded portion 32A of the sleeve 3 into the female threaded portion 22A of the bottomed hole 21 using a tool. screw together. At this time, when the portion of the flange 31 where the flat surface 33 is not formed contacts the opening edge of the bottomed hole 21, an axial force acts between the male threaded portion 32A and the female threaded portion 22A. A fastening force is generated with the hole 21 . When the full thread 20 of the gauge part 2 wears out and needs to be replaced, the gauge part 2 can be easily replaced by unscrewing the sleeve 3 and the gauge part 2 in the thread gauge of this embodiment. be able to.

In this embodiment, by forming a pair of flat surfaces 33 on the flange 31, a fastening torque required for fastening the sleeve 3 to the bottomed hole 21 is generated by a tool. However, the outer shape of the flange 31 may be made into another shape such as a regular hexagon so that fastening torque can be generated. Alternatively, a tool that generates fastening torque using the slit 30 without forming the flat surface 33 on the flange 31 may be manufactured.

Next, a thread gauge of a second embodiment will be described with reference to FIG. The sleeve 3 shown in FIG. 8 is also shown in a cross-section not passing through the plane 33, as in FIG. In the first embodiment described above, the maximum outer diameter of the flange 31 of the sleeve 3 is formed smaller than the minimum inner diameter of the maximum outer diameter of the gauge portion 2, as shown in FIG. That is, the maximum outer diameter of the flange 31 was smaller than the maximum outer diameter of the internal thread 40 to be inspected, and as shown in FIG. On the other hand, in this embodiment, the maximum outer diameter of the flange 31 is formed larger than the maximum outer diameter of the gauge portion 2, as shown in FIG. That is, the maximum outer diameter of the flange 31 is larger than the maximum outer diameter of the internal threaded hole 40 to be inspected, and the flange 31 functions as a stopper for the internal threaded hole 40 . The maximum outer diameter of the female thread refers to the outer diameter of the root portion of the thread groove. Since the configuration other than the flange 31 is the same as the configuration of the first embodiment described above, redundant description thereof will be omitted.

Here, consider a case where the gauge portion 2 is screwed into the female threaded hole 40 using a machine capable of detecting the number of revolutions. In the inspection of the female screw hole 40, the depth of the female screw hole 40 may also be inspected, and if such a machine is used, it is possible to detect whether the female screw hole 40 is normally formed to the desired depth from the number of revolutions and the screw pitch. . On the other hand, it is difficult to detect the screwing depth when the inspection is performed manually or semi-automatically. Therefore, if the flange 31 is formed as a stopper as in this embodiment and the stopper can be screwed into contact with the opening edge of the female screw hole 40, it can be determined that the female screw hole 40 is normally formed to the desired depth. It becomes possible. On the other hand, if the screw gauge of the first embodiment is used together with a machine that can detect the number of revolutions, it is also possible to inspect the deep internal thread hole 40 . The above-described other effects brought about by the first embodiment are also brought about by this embodiment.

Next, a thread gauge of a third embodiment will be described with reference to FIGS. 9 and 10. FIG. In the first and second embodiments, the sleeve 3 is attached to the bottomed hole 21 by means of the male threaded portion 32A and the female threaded portion 22A. In the present embodiment, the projection 32 is formed instead of the male threaded portion 32A, and the groove 22 is formed instead of the female threaded portion 22A to engage the sleeve 3 with the bottomed hole 21. As shown in FIG. Also in this embodiment, the sleeve 3 is made of metal. Since other configurations are the same as those of the first embodiment described above, redundant description thereof will be omitted.

In this embodiment, between the engaging portion 21a and the opening of the bottomed hole 21, a cylindrical surface 21b is formed, the cross section of which is the circumscribed circle of the regular hexagon of the engaging portion 21a. A groove 22 for retaining the sleeve 3 is formed on the cylindrical surface 21b along the entire circumference in the circumferential direction. A protrusion 32 that engages with the groove 22 extends along the entire circumference of the outer peripheral surface of the sleeve 3 . However, the protrusion 32 is not formed in the portion where the slit 30 is formed. The outer diameter of projection 32 is equal to or slightly smaller than the inner diameter of groove 22 . The protrusion 32 has a convex cross-sectional shape that is the same as the concave cross-sectional shape of the groove 22, but is slightly smaller. It is prevented from slipping out of the part 2.

Attachment of the sleeve 3 to the opening of the bottomed hole 21 will be described. First, the sleeve 3 is attached to the shaft portion 12 of the shaft 1 as in the first embodiment. After that, while the sleeve 3 is positioned near the ball point portion 11, an external force is applied to the sleeve 3 to elastically deform the protrusion 32 so that the outer diameter of the protrusion 32 becomes equal to or less than the inner diameter of the cylindrical surface 21b of the bottomed hole 21. , insert the sleeve 3 into the bottomed hole 21 . When the applied external force is released, the sleeve 3 returns to its original shape due to its elastic restoring force, and the projection 32 is housed in the groove 22. - 特許庁In the present embodiment as well, when the full thread 20 of the gauge portion 2 wears out and needs to be replaced, the gauge portion 2 can be easily replaced by performing the above steps in reverse order. According to this embodiment, it is possible to prevent the sleeve 3 from coming off by simply processing the protrusions 32 and the grooves 22 without the need for complicated threading of the male threaded portion 32A and the female threaded portion 22A of the first embodiment. The above-described other effects brought about by the first embodiment are also brought about by this embodiment.

Next, a thread gauge of a fourth embodiment will be described with reference to FIG. In this embodiment, the sleeve 3 is fixed to the gauge portion 2 by press-fitting the sleeve 3 into the bottomed hole 21 . Also in this embodiment, the sleeve 3 is made of metal. Since the sleeve 3 is press-fitted into the bottomed hole 21 , no protrusion 32 is formed on the outer peripheral surface of the sleeve 3 . Further, the outer diameter of the sleeve 3 is slightly larger than the inner diameter of the cylindrical surface 21b of the bottomed hole 21 as an interference so that the sleeve 3 is fixed after press-fitting. Although not shown, it is not necessary to form the internal thread portion 22A or the groove 22 on the cylindrical surface 21b. Since other configurations are the same as those of the first embodiment described above, redundant description thereof will be omitted.

The method of assembling the thread gauge is substantially the same as that of the thread gauge of the first embodiment, but the sleeve 3 can be attached to the opening of the bottomed hole 21 simply by press-fitting. After press-fitting, the width of the slit 30 is expected to be slightly narrowed, but since the shaft portion 12 is already positioned inside the sleeve 3, there is no problem. In this embodiment, although a slight stress is applied to the gauge portion 2 after press-fitting, the attachment of the sleeve 3 to the gauge portion 2 is facilitated. In addition, it is possible to prevent the sleeve 3 from slipping off without machining the male threaded portion 32A and the female threaded portion 22A of the first embodiment or the protrusion 32 and the groove 22 of the third embodiment. The above-described other effects brought about by the first embodiment are also brought about by this embodiment.

Next, a thread gauge of a fifth embodiment will be described with reference to FIG. In this embodiment, the sleeve 3 is made of resin and is fixed to the gauge portion 2 by press-fitting the sleeve 3 into the bottomed hole 21 . Since the sleeve 3 is made of resin, its elastic deformation amount is larger than that of metal. Therefore, even if the width of the slit 30 is narrowed, the shaft portion 12 can be arranged inside the slit 30 by elastically deforming so as to widen the width of the slit 30 . Moreover, the width of the slit 30 is set to a width that closes after being press-fitted into the bottomed hole 21 . That is, the outer diameter of the sleeve 3 is larger than the inner diameter of the cylindrical surface 21b of the bottomed hole 21 before press-fitting. More specifically, when the sleeve 3 is elastically deformed until the slit 30 is closed, the tightening margin is such that the outer diameter of the sleeve 3 after elastic deformation is slightly larger than the inner diameter of the cylindrical surface 21b of the bottomed hole 21. , a sleeve 3 is formed. Also in this embodiment, it is not necessary to form the internal thread portion 22A or the groove 22 on the cylindrical surface 21b. Since other configurations are the same as those of the first embodiment described above, redundant description thereof will be omitted.

The method of assembling the thread gauge is substantially the same as that of the thread gauge of the first embodiment, but when the sleeve 3 is attached to the shaft portion 12 as described above, the slit 30 is widened. In addition, the sleeve 3 can be attached to the opening of the bottomed hole 21 simply by press-fitting. After press-fitting, the slit 30 is closed, and the above-described interference effectively functions to fix the sleeve 3 to the opening of the bottomed hole 21 . This embodiment also facilitates attachment of the sleeve 3 to the gauge portion 2 . The above-described other effects brought about by the first embodiment are also brought about by this embodiment.

The thread gauge according to the above embodiment is attached to the gauge part 2 having the bottomed hole 21 formed therein, the shaft 1 having the ball point part at the tip thereof inserted into the bottomed hole 21, and the opening of the bottomed hole 21. A cylindrical sleeve 3 is provided. Torque can be transmitted from the shaft 1 to the gauge portion 2 by the ball point portion 11 having a male shape capable of transmitting torque and the engaging portion 21a of the bottomed hole 21 correspondingly having a female shape capable of transmitting torque. , and the gauge portion 2 can swing with respect to the shaft 1 . The sleeve 3 has an inner diameter smaller than the maximum outer diameter of the ball point portion 11 and larger than the maximum outer diameter of the shaft portion 12 when attached to the opening of the bottomed hole 21 . Therefore, an alignment mechanism in which the gauge portion 2 swings on the basis of the tip of the shaft 1 and the bottom of the bottomed hole 21 can be realized with a simple structure.

Moreover, since the gauge portion 2 swings with reference to the tip of the shaft 1 and the bottom portion of the bottomed hole 21, an excellent alignment mechanism can be realized. At this time, since the ball point portion 11 is loosely fitted in the bottomed hole 21, the gauge portion 2 can swing with respect to the shaft 1 without resistance, and alignment can be performed smoothly. Furthermore, the maximum outer diameter of the shaft portion 12 is made smaller than the maximum outer diameter of the ball point portion 11, so that the shaft portion 12 can bend. Therefore, since an alignment function by bending of the shaft portion 12 is added to the alignment function by swinging of the gauge portion 2 described above, a more excellent alignment mechanism can be realized.

Further, since the slit 30 is formed in the sleeve 3 , the sleeve 3 can be easily attached to the shaft portion 12 . That is, the thread gauge can be constructed with a simpler structure.

Here, in the first and second embodiments, while the slit 30 is formed, the male threaded portion 32A is formed on the outer peripheral surface of the sleeve 3, and the male threaded portion 32A is formed on the inner peripheral surface of the bottomed hole 21. 22 A of internal thread parts screwed together are formed. Therefore, it is possible to reliably prevent the sleeve 3 from coming off the bottomed hole 21 .

Alternatively, in the third embodiment, while the slits 30 are formed, the protrusions 32 are extended in the circumferential direction on the outer peripheral surface of the sleeve 3, and the protrusions 32 are accommodated on the inner peripheral surface of the bottomed hole 21. A groove 22 is formed in the circumferential direction. Therefore, a structure for reliably preventing the sleeve 3 from coming off from the bottomed hole 21 can also be realized with a simple structure.

In the second embodiment, the sleeve 3 is formed with a flange 31 that contacts the other end surface of the gauge portion 2, that is, the opening portion of the bottomed hole 21. It is made larger than the maximum outer diameter. Therefore, since the flange 31 functions as a stopper for the female screw hole 40 to be inspected, the depth of the female screw hole 40 can also be inspected during manual or semi-automatic inspection.

Furthermore, in the above-described embodiment, the height H of the center O of the bottom surface of the bottomed hole 21 is set within the range of the inequality (1), so that the above-described alignment function can be reliably realized.

The thread gauge of the present disclosure is not limited to the embodiments described above. For example, the "torque-transmissible male shape and male shape and female shape" in the above-described embodiment were regular hexagonal convex and concave shapes. However, the "torqueable male and female shapes" may be other torquable shapes such as hex lobes or pentalobes. It is also possible to form the ball point portion 11 in a shape such as a hexalobed shape or a pentalobed shape.

Also, in the above embodiment, the thread gauge is formed in the form of a bit, but it may be formed in a form intended only for manual use instead of being formed in the form of a bit. Also, even when formed in the form of a bit, the form of the chuck part 10 is not limited to the form shown in FIG. 1, and may be formed in other forms. Furthermore, according to the screw gauge of the present disclosure, when the internal screw hole 40 is inspected fully automatically using a robot arm, the alignment function is improved, so it is easy to cope with full automation.

Further, in the above-described embodiment, the shaft 1 is formed as an integrated body, but the shaft portion 12 and the ball point portion 11 are formed as an integrated body, and the shaft portion 12 is joined to the chuck portion 10 by screwing or the like. It's okay. In this case, since the shaft portion 12 can be inserted through the sleeve 3 before the shaft portion 12 is joined to the chuck portion 10, it is not necessary to provide the slit 30 for passing the shaft portion 12 through the sleeve 3. However, in the case of the third embodiment in which the protrusion 32 and the groove 22 are engaged with each other, it is necessary to form a slit for attaching the sleeve 3 to the opening of the bottomed hole 21 .

Further, in the above embodiment, the sleeve 3 is prevented from coming off from the gauge portion 2 by screwing the male threaded portion 32A and the female threaded portion 22A, engaging the protrusion 32 with the groove 22, or press-fitting the sleeve 3. However, it may be fixed to the opening of the bottomed hole 21 of the sleeve 3 by bonding the sleeve 3 and the cylindrical surface 21b.

1 Shaft 2 Gauge portion 3 Sleeve 11 Ball point portion 12 Shaft portion 21 Bottomed hole 21a Engagement portion 22A Female threaded portion 22 Groove 30 Slit 31 Flange 32A Male threaded portion 32 Projection 40 Female threaded hole O Bottom center (of bottomed hole 21)

Claims (6)

A thread gauge for inspecting an internally threaded hole, comprising:
a gauge portion having a male-threaded complete thread formed on the outer peripheral surface from one end and a bottomed hole formed on the other end surface;
a shaft having a tip portion inserted into the bottomed hole of the gauge portion;
a cylindrical sleeve attached to the opening of the bottomed hole,
The shaft includes a ball point portion having a male shape capable of transmitting torque to the distal end portion, and a shaft portion extending from the ball point portion and having a maximum outer diameter smaller than the maximum outer diameter of the ball point portion. has
An engaging portion having a female shape capable of transmitting torque corresponding to the ball point portion is formed on the inner peripheral surface of the bottomed hole at least in the vicinity of the bottom portion,
The screw gauge, wherein the sleeve has an inner diameter smaller than the maximum outer diameter of the ball point portion and greater than the maximum outer diameter of the shaft portion when mounted in the opening. 2. The screw gauge according to claim 1, wherein the sleeve is formed with a slit from one axial end to the other axial end. A male threaded portion is formed on the outer peripheral surface of the sleeve, and
3. The screw gauge according to claim 2, wherein a female threaded portion that is screwed with said male threaded portion is formed on an inner peripheral surface of said bottomed hole. A protrusion extends in the circumferential direction on the outer peripheral surface of the sleeve, and
3. The screw gauge according to claim 2, wherein a groove for accommodating said protrusion is formed in the inner peripheral surface of said bottomed hole in the circumferential direction. The sleeve is formed with a flange that abuts on the other end surface of the gauge portion,
The thread gauge according to any one of claims 1 to 4, wherein the maximum outer diameter of the flange is larger than the maximum outer diameter of the gauge portion. When the maximum outer diameter of the gauge portion is D, the height H from one end surface of the gauge portion to the center of the bottom surface of the bottomed hole is 0.2D≤H≤D/[2(3^(1 /2)].

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