JP2010101700A - Support tool for measuring effective screw diameter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve a problem wherein an effective diameter of a screw axis in a state mounted on a processing machine is difficult to measure heretofore during processing since measurement of the effective diameter of the screw axis needs to produce a specific measurement tool and thus the production of the measurement tool is complicated and expensive and the measurement device becomes large-scale. <P>SOLUTION: The support tool 1 for measuring an effective screw diameter, for supporting two or more pin members 5 when measuring an effective diameter of a screw member 3 of a measured object in a state of sandwiching the screw member 3 by two or more pin members 5 comprises a container part 15 containing the screw member 3, insert holes 12a, 13a inserting two or more pin members 5 penetrating the container part 15 to intersect with the screw member contained in the container part 15, and insert channels 12b, 13b. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention provides an effective screw diameter for holding the plurality of pin members when measuring the effective diameter of the screw member in a state where the screw member to be measured is sandwiched between the plurality of pin members. The present invention relates to a measurement holding jig.

  Conventionally, a three-needle method is known as a method for measuring an effective diameter of a screw member such as a screw or a screw gear. In the three-needle method, one pin member is brought into contact with the thread groove of the screw member to be measured from one side, and two pin members are brought into contact with the other side facing the one side. In this state, the effective diameter of the screw member is measured with a measuring tool such as a micrometer.

  Specifically, for example, as shown in FIGS. 14 and 15, when measuring the effective diameter of the screw member 103, the screw member 103 is hung on the string members 106, 106. The three pin members 105, 105... Are brought into contact with the screw groove 103 a of the screw member 103. Of the three pin members 105, 105, one pin member 105 is disposed on one side of the screw member 103, and the two pin members 105, 105 are disposed on the other side of the screw member 103. Are brought into contact with the thread groove 103a so that the shape connecting the axial centers of the three pin members 105, 105,... Is an isosceles triangle. That is, the two pin members 105 and 105 arranged on the other side of the screw member 103 are in contact with the adjacent screw grooves 103 a and 103 a, and the pin member 105 arranged on one side is the screw member 103. In contact with the screw groove 103 a located between the two pin members 105 on the other side in the axial direction and the pin member 105.

In this way, the measurement by the micrometer or the like is performed with one pin member 105 on one side and the two pin members 105 and 105 on the other side in contact with each other with the screw member 103 interposed therebetween. The effective diameter of the screw member 103 is measured by sandwiching the one pin member 105 on one side and the two pin members 105 on the other side from the outside by the measuring terminals 108a and 108a. .
Moreover, the measurement of the effective diameter of the screw member using the 3-needle method is disclosed in Patent Document 1.

  When measuring the effective diameter of the screw member using the three-needle method as described above, the pin members 105, 105... However, the work efficiency was low. Further, when the pin members 105, 105... Are brought into contact with the screw member 103, the pin members 105, 105... Need to be pressed while following the angle of the screw groove 103a. Are difficult to accurately align with the thread groove 103a, and the measurement accuracy is not so high.

Therefore, in order to solve such a problem, the following configuration has been devised.
For example, in Patent Document 2, an overpin holder provided on an anvil and a spindle of a micrometer, an overpin holding hole formed in the overpin holder, and each overpin holder is connected to the anvil and spindle. An overpin measuring device is disclosed that includes a spring member for always urging to the base side and an overpin that is provided in each of the overpin holding holes and contacts an end of the anvil or spindle.
In the overpin measuring device configured as described above, the gear as the object to be measured is mounted between the overpins, and the spindle is advanced to the anvil side so that each tooth of the gear is not manually held. It can be reliably inserted into the part.

  Patent Document 3 discloses an apparatus for measuring the effective diameter of a spiral ball rolling groove formed on the outer peripheral surface of a screw shaft of a ball screw, and includes a fixed handle that is held by a measurer with one hand. A portable device main body, a movable handle that can be operated simultaneously with one hand holding the fixed handle, and a pair of sandwiches that protrude in parallel from the device main body and expand with each other as the movable handle is operated A leg, an elastic member that urges the clamping legs in the direction in which the gap is narrowed, and at least one of the clamping legs provided in the ball rolling groove of the screw shaft when the gap between the pair of clamping legs is narrowed A pair of holding legs, and a display (micro gauge) that displays a distance between the measuring piece provided on one holding leg and the measuring piece provided on the other holding leg. By By clamping the screw shaft, it is possible to easily measure the effective diameter of the screw shaft, the effective diameter measuring apparatus is disclosed of the screw shaft.

Furthermore, Patent Document 4 discloses a main body base having a plate shape and having a long groove, an adapter slidably inserted in the long groove, and a tip that passes through the main body base and rotates toward one end of the adapter. A bar-shaped feed screw that is freely engaged, a feed screw fixture that is attached to the outer side of the main body base and is screwed to the feed screw, and that has an opening and closing mechanism; and the long groove on the main body base A gear comprising: a guide frame mounted on the upper end surface; and an overpin mounting hole that is perforated on the terminal end of the long groove of the main body base and the upper surface of the adapter with a plurality of screw holes each having a different diameter, and an overpin is selectively mounted on each end An overpin diameter measuring jig is disclosed.
In this overpin diameter measuring jig, the overpin corresponding to the tooth profile of the gear to be measured is fixed to the body base and the overpin mounting hole of the adapter, and the gear to be measured is set on the body base to be the overpin. It is comprised so that it may contact between the overpins contacted and measured with a micrometer.
Japanese Utility Model Publication No. 2-135804 JP-A-64-43701 JP 2002-206902 A Japanese Utility Model Publication No. 60-92102

As described above, the object to be measured whose effective diameter is to be measured is a valve actuating valve for adjusting the amount of inflow air by continuously changing the valve lift amount of the intake valve in the engine of the vehicle. There is a screw shaft that is used in the mechanism and becomes a part for converting the rotary motion from the motor into a linear motion.
Since such a screw shaft is required to be machined with high accuracy, when machining the screw shaft, the effective diameter of the screw shaft is measured while being mounted on a processing machine in the middle of machining, Whether or not the desired machining accuracy is satisfied is confirmed, and when the desired machining accuracy is not satisfied, the machining is performed again.
In other words, when measuring the effective diameter of the screw shaft in the middle of machining, the screw shaft in the middle of machining is removed from the processing machine, the measurement is performed, the machine is attached to the processing machine again, and machining is performed. When the shaft is attached to the processing machine again, it is difficult to completely match the phase of the screw shaft before removal and the phase of the screw shaft that has been attached again, ensuring the desired machining accuracy when the screw shaft has been machined. Therefore, when measuring the effective diameter of the screw shaft in the middle of processing, it is necessary to perform the measurement while mounted on the processing machine.

In addition, screw shafts such as those mentioned above are often not special-purpose screws that are not general-purpose, or products that are produced in a variety of small quantities. It is necessary to manufacture a dedicated measuring tool for each specification, and there is a problem that the manufacturing of the measuring tool becomes complicated and the cost increases.
Therefore, when measuring the effective diameter of such a screw shaft, it is preferable if a measuring tool such as a general-purpose micrometer that can be used for other dimension measurements can be used.

However, the measuring device described in the above-mentioned Patent Document 2 has a complicated configuration and is configured by attaching an overpin holder or the like to a micrometer serving as a measuring tool for measuring an effective diameter. This is not preferable because the micrometer is dedicated to the measurement of gear overpins.
In addition, the measuring device described in Patent Document 3 described above has a complicated configuration, and the indicator, which is a measuring tool for measuring the effective diameter, is at a position offset from the clamping leg that clamps the screw shaft. Therefore, it is difficult to measure the effective diameter with high accuracy (because the measuring element of the display and the sandwiching leg are not coaxial). In addition, since the measuring device becomes large, it is difficult to measure the effective diameter of the screw shaft that is mounted on the processing machine during the processing.
Furthermore, since the measuring apparatus described in the above-mentioned Patent Document 4 has a complicated and large-scale configuration, it is difficult to measure the effective diameter of the screw shaft that is mounted on the processing machine during the processing. .

  Therefore, in the present invention, a screw effective diameter measurement that has a simple configuration and can measure the effective diameter of a screw shaft in a state of being mounted on a processing machine during processing using a general-purpose measuring tool. A holding jig is provided.

A holding jig for measuring an effective screw diameter that solves the above problems has the following characteristics.
That is, as described in claim 1, when the effective diameter of the screw member is measured in a state where the screw member to be measured is sandwiched between the plurality of pin members, the plurality of pin members are held. A holding jig for measuring an effective screw diameter for receiving a housing portion that houses the screw member and a plurality of pin members that penetrate the housing portion so as to intersect the screw member housed in the housing portion An insertion portion.

  According to a second aspect of the present invention, the accommodating portion is configured by a space surrounded by a base member located on one side of the accommodated screw member and side wall members standing from both side end portions of the base member. The insertion portion is configured by an insertion hole or an insertion groove formed in each of the side wall members.

  According to a third aspect of the present invention, the insertion portion is formed in the insertion hole or the insertion groove on one side of the side wall member located on the base member side with respect to the screw member accommodated in the accommodation portion, and in the accommodation portion. It has an insertion hole or an insertion groove on the other side located on the side opposite to the base member relative to the accommodated screw member.

  In addition, as described in claim 4, each side wall member is formed with one of the one side insertion hole or insertion groove and the other side insertion hole or insertion groove, and the one side insertion Two of either the hole or the insertion groove and the other insertion hole or the insertion groove are formed.

According to the present invention, by inserting and holding a plurality of pin members in the insertion portion, the pin members can be brought into contact with each other, and it is not necessary for the operator to hold and hold the pin members by hand. This makes it possible to simplify the measurement work of the effective diameter by using the tool, improve the measurement work efficiency, and easily measure the effective diameter of the screw member mounted on the processing machine during the machining. It has become.
Further, since the pin member can be brought into contact with the screw member along the inclination angle of the screw groove, the alignment of the pin member with respect to the screw groove is stabilized, and the measurement accuracy of the effective diameter of the screw member is improved. Can do.
Furthermore, when measuring the effective diameter of a screw member using a holding jig for measuring the effective diameter of a screw, a general-purpose measuring tool can be used as it is, so even when manufacturing a small variety of products. The effective diameter of the screw member can be measured at low cost and in a short time.

  Next, modes for carrying out the present invention will be described with reference to the accompanying drawings.

The screw effective diameter measuring holding jig 1 shown in FIGS. 1 to 3 includes a base 20 formed in a substantially cylindrical shape and a main body 10 connected to the upper surface of the base 20.
The main body 10 is formed in a flat plate shape, the lower surface of which is connected to the upper surface of the base 20, and a pair of side wall members 12, 13 erected from both ends of the base member 11, have.
The pair of side wall members 12 and 13 are arranged substantially parallel to each other at a predetermined interval, and each of the side wall members 12 and 13 is erected substantially perpendicularly to the base member 11 in the same direction.

In the holding jig 1 for measuring the effective diameter of the screw, the accommodating portion 15 for accommodating the screw member 3 whose effective diameter is to be measured in the space surrounded by the base member 11 and the side wall members 12 and 13. It is configured.
That is, the accommodating portion 15 is a space surrounded by the base member 11 on the lower side in FIG. 2 and the side wall members 12 and 13 on both left and right sides, and at least the measurement is performed between the side wall members 12 and 13. The space | interval more than the outer diameter dimension of the screw member 3 used as object is provided, and the height dimension of each said side wall member 12 * 13 (in the direction substantially orthogonal to the plate | board surface of the base member 11 in each side wall member 12 * 13). The dimension) is at least a dimension equal to or larger than the outer diameter dimension of the screw member 3 to be measured. The upper part of the accommodating part 15 (the direction opposite to the base member 11 side in the standing direction of the side wall members 12 and 13) is open.

  In the storage portion 15, the screw member 3 is stored along the surface direction of the base member 11 and the side wall members 12 and 13. That is, the screw member 3 is accommodated in the accommodating portion 15 such that the outer peripheral surface thereof faces each surface of the base member 11 and the side wall members 12 and 13.

  Insertion holes 12a and 13a are formed in lower portions of the side wall members 12 and 13 (portions close to the base member 11 in the side wall members 12 and 13), respectively, and upper portions (side wall members 12 and 13 of the side wall members 12 and 13). Insertion grooves 12b and 13b are respectively formed in a portion farther away from the base member 11 than the lower part of FIG.

The insertion holes 12a and 13a are formed in a substantially circular shape, and the inner diameters of the insertion holes 12a and 13a are larger than the outer diameter of the pin member 5 used when measuring the effective diameter of the screw member 3. The insertion holes 12a and 13a are configured so that the pin member 5 can be slidably inserted.
The insertion holes 12a and 13a are formed at positions where one pin member 5 can be simultaneously inserted into the insertion hole 12a and the insertion hole 13a. The inserted pin member 5 penetrates the housing portion 15.
In this example, the insertion holes 12a and 13a are formed in a substantially circular shape. However, for example, the insertion holes 12a and 13a can be formed in an oblong shape that is horizontally long (a direction perpendicular to the standing direction of the side wall members 12 and 13). The pin member 5 may be formed in a shape and size that can be slidably inserted.

The insertion grooves 12b and 13b are formed in a shape in which a part of an oval shape is opened.
In this example, the insertion grooves 12b and 13b are formed in an oblong upper side (the side of the side wall members 12 and 13 on the side of the base member 11) formed in a horizontally long direction (a direction perpendicular to the standing direction of the side wall members 12 and 13). Opening portions 12c and 13c are provided with a substantially central portion on the opposite side) opened upward.
The diameter of the arc in the oval part of the insertion grooves 12b and 13b is formed larger than the outer diameter of the pin member 5, and the oval part of the insertion grooves 12b and 13b slides on the pin member 5. It is configured so that it can be inserted freely. Further, the oval portions of the insertion grooves 12b and 13b are configured so that a plurality of pin members 5 can be inserted.
Further, the insertion grooves 12b and 13b are formed at positions where one pin member 5 can be simultaneously inserted into the insertion groove 12b and the insertion groove 13b. Both the insertion groove 12b and the insertion groove 13b The inserted pin member 5 penetrates the housing portion 15.

Further, the pin member 5 inserted into the insertion holes 12a and 13a and penetrating the accommodating portion 15 and the pin member 5 inserted into the insertion grooves 12b and 13b and penetrating the accommodating portion 15 are accommodated in the accommodating portion 15. It intersects with the screw member 3 to be viewed in plan view.
Further, the insertion holes 12a and 13a and the insertion grooves 12b and 13b constituting the insertion portion are formed at a predetermined interval in the standing direction of the side wall members 12 and 13.

That is, the insertion holes 12a and 13a and the insertion grooves 12b and 13b are spaced apart from each other by a dimension that is approximately the same as the outer diameter of the screw member 3, and are inserted into the insertion holes 12a and 13a. The pin member 5 passes below the screw member 3 accommodated in the accommodating portion 15, and the pin member 5 inserted into the insertion grooves 12 b and 13 b is located above the screw member 3 accommodated in the accommodating portion 15. It is possible to pass through.
Further, the pin member 5 is inserted into the insertion holes 12 a and 13 a and passes below the screw member 3 accommodated in the accommodating portion 15, and inserted into the insertion grooves 12 b and 13 b and accommodated in the accommodating portion 15. The pin member 5 passing above the screw member 3 can be brought into contact with the screw groove 3a of the screw member 3 at positions facing each other with the screw member 3 interposed therebetween.

Further, the base member 11 and the base 20 of the main body 10 are respectively formed with measuring tool insertion holes 11a and 20a that allow the accommodating portion 15 to communicate with the outside.
The measurement tool insertion holes 11a and 20a are formed to have the same diameter and are coaxially arranged, and a measurement terminal 8a (see FIG. 10) of the measurement tool 8 for measuring the effective diameter of the screw member 3 is provided. It can be inserted into the accommodating portion 15 through the measuring instrument insertion holes 11a and 20a.

Next, the measurement procedure in the case of measuring the effective diameter of the screw member 3 by the three-needle method using the screw effective diameter measuring holding jig 1 configured as described above will be described.
Note that the screw member 3 to be measured in this description is the screw member 3 being processed, and is the screw member 3 that is mounted on the processing machine and fixed in position.
First, as shown in FIG. 4, the storage portion 15 of the screw effective diameter measurement holding jig 1 is fitted into the screw member 3 to be measured from below, and the screw member 3 is stored in the storage portion 15.

As shown in FIG. 5, after the screw member 3 is housed in the housing portion 15, one pin member 5 is inserted into the insertion holes 12a and 13a, and two pin members 5 are inserted into the insertion grooves 12b and 13b.・ Insert 5
In this case, the pin member 5 is inserted into the insertion holes 12a and 13a, for example, by first inserting the pin member 5 into the insertion hole 12a of the side wall member 12, and then passing the space below the screw member 3 in the storage portion 15. Further, it is performed by inserting into the insertion hole 13 a of the side wall member 13.
The pin members 5 and 5 are inserted into the insertion grooves 12b and 13b, for example, by first inserting the pin members 5 and 5 into the insertion grooves 12b of the side wall member 12, and then the space above the screw member 3 in the storage portion 15. And is inserted into the insertion groove 13 b of the side wall member 13.

As shown in FIG. 6, the pin members 5 and 5 are inserted into the insertion grooves 12b and 13b by inserting the pin members 5 and 5 from above the main body 10 through the openings 12c and 13c of the insertion grooves 12b and 13b. It can also be performed by sequentially inserting into the insertion grooves 12b and 13b.
Thus, by inserting the pin members 5 and 5 into the insertion grooves 12b and 13b through the openings 12c and 13c, the insertion of the pin members 5 and 5 into the insertion grooves 12b and 13b can be simplified. It becomes possible.

As shown in FIGS. 7 to 9, the pin members 5, 5... Inserted into the insertion holes 12 a, 13 a and the insertion grooves 12 b, 13 b can come into contact with the screw grooves 3 a of the screw member 3, respectively. ing.
That is, the pin member 5 inserted into the insertion holes 12a and 13a and penetrating through the storage portion 15 is supported by the inner peripheral surface of the insertion holes 12a and 13a by pressing the holding jig 1 for measuring the effective screw diameter upward. And abuts on the lower screw groove 3 a of the screw member 3.
In this case, the pin member 5 inserted into the insertion holes 12a and 13a abuts along the inclination angle of the lower screw groove 3a.

Further, the pin members 5 and 5 inserted into the insertion grooves 12 b and 13 b and penetrating the storage portion 15 abut on the upper screw groove 3 a in the screw member 3 by their own weight.
In this case, the pin members 5 and 5 inserted into the insertion grooves 12b and 13b abut along the inclination angle of the upper screw groove 3a.

  The pin members 5 and 5 inserted into the insertion grooves 12b and 13b in this way are inserted so as to fit into the adjacent screw grooves 3a on the upper side of the screw member 3, and are inserted into the insertion holes 12a and 13a. The member 5 is inserted so as to be fitted into the screw groove 3a located at the intermediate position of the pin members 5 and 5 inserted into the insertion grooves 12b and 13b on the lower side of the screw member 3.

The diameters of the oval portions of the insertion holes 12a and 13a and the insertion grooves 12b and 13b, and the interval between the insertion holes 12a and 13a and the insertion grooves 12b and 13b are determined by the pins inserted into the insertion holes 12a and 13a. Both the pin member 5 and 5 inserted into the member 5 and the insertion grooves 12b and 13b can contact the screw groove 3a of the screw member 3, and the pin member 5 and the insertion groove inserted into the insertion holes 12a and 13a. Even when the pin members 5 and 5 inserted into 12b and 13b are positioned at the farthest positions in the insertion holes 12a and 13a and the oval portions of the insertion grooves 12b and 13b, they are inserted into the insertion holes 12a and 13a. The distance between the inserted pin member 5 and the pin members 5 and 5 inserted into the insertion grooves 12b and 13b is set so as not to exceed the maximum outer diameter of the screw member 3. To have.
That is, with the screw member 3 stored in the storage portion 15, the pin members 5, 5... Inserted into the insertion holes 12a and 13a and the insertion grooves 12b and 13b and fitted in the screw grooves 3a are as follows. Thus, the screw member 3 does not move beyond the thread of the screw member 3 and remains in the initial desired position where it is inserted into the insertion holes 12a and 13a and the insertion grooves 12b and 13b.

  As described above, after inserting the pin members 5... Into the insertion holes 12 a and 13 a and the insertion grooves 12 b and 13 b and fitting them into the screw grooves 3 a of the screw member 3 housed in the housing portion 15. As shown in FIGS. 10 to 12, the effective diameter of the screw member 3 is measured using a measuring tool 8 having a pair of measuring terminals 8 a and 8 a.

Specifically, one measurement terminal 8a of the measuring instrument 8 is inserted into the accommodating portion 15 through the measuring instrument insertion holes 11a and 20a, and is inserted into the inserting holes 12a and 13a and penetrates the accommodating portion 15. The other measurement terminal 8a is inserted into the housing part 15 from above the opened housing part 15 and is inserted into the insertion grooves 12b and 13b and penetrates the housing part 15. The pin member 5 inserted into the insertion holes 12a and 13a and the pin members 5 and 5 inserted into the insertion grooves 12b and 13b by the pair of measurement terminals 8a and 8a. By pinching from the outside, the distance between the pin member 5 on the insertion hole 12a / 13a side and the pin member 5/5 on the insertion groove 12b / 13b side is measured.
The effective diameter of the screw member 3 is calculated by the following equation 1 based on the distance between the pin members 5 measured in this way, the diameter of the pin member 5, and the screw pitch and thread angle of the screw member 3. .

As described above, the effective diameter of the screw member 3 can be measured by the three-needle method using the holding jig 1 for measuring the effective screw diameter, but the three pin members 5. When abutting against the member 3, the pin members 5, 5... Are inserted into the insertion holes 12a, 13a and the insertion grooves 12b, 13b and held by the holding jig 1 for measuring the effective screw diameter. 3, and it is not necessary for the operator to hold and hold the pin members 5, 5 by hand, and the pin members 5, 5. Therefore, the measurement work of the effective diameter while sandwiching can be simplified, and the measurement work efficiency can be improved.
Further, the holding jig 1 for measuring the effective diameter of the screw is composed of a housing part 15 for housing the screw member 3 and an insertion part for inserting the pin members 5. Therefore, the effective diameter of the screw member 3 mounted on the processing machine can be easily measured during the processing.

Further, the pin member 5 inserted into the insertion holes 12a and 13a and the pin members 5 and 5 inserted into the insertion grooves 12b and 13b abut against the screw member 3 along the inclination angle of the screw groove 3a. It is possible to stabilize the alignment of the members 5, 5... With respect to the screw grooves, and to improve the measurement accuracy of the effective diameter of the screw member 3.
Furthermore, when measuring the effective diameter of the screw member 3 using the holding jig 1 for measuring the effective diameter of the screw, there is no need to perform special processing or the like on the measuring tool 8 for measuring the effective diameter. Therefore, the effective diameter of the screw member 3 can be measured at a low cost and in a short time even when manufacturing a small variety of products.

Further, in the holding jig 1 for measuring the effective screw diameter of the present example, the insertion grooves 12b and 13b for inserting the plurality of pin members 5 and 5 are formed on the upper portions of the side wall members 12 and 13, The insertion grooves 12b and 13b can be configured as insertion holes.
That is, as shown in FIG. 13, the screw effective diameter measuring holding jig 51 includes a base member 61 formed in a flat plate shape, and a pair of side wall members 62 and 63 erected from both end portions of the base member 61. The space surrounded by the base member 61 and the side wall members 62 and 63 is configured as an accommodating portion 65 for accommodating the screw member 3 to be measured for an effective diameter, and the side wall member 62 and The insertion holes 62a and 63a and the insertion holes 62b and 63b for inserting the pin member 5 and the pin members 5 and 5 may be formed in the lower part and the upper part of 63, respectively.

  As described above, when the insertion holes 62a, 63a and the insertion holes 62b, 63b are formed in the side wall members 62, 63, the pin members 5, 5,. Can be held by the screw effective diameter measuring holding jig 51 and brought into contact with the screw member 3, and the effective diameter of the screw member 3 mounted on the processing machine can be easily set during processing. Therefore, it is possible to improve the measurement work efficiency.

It is a side view which shows the holding jig for a screw effective diameter measurement. It is a front view which shows the holding jig for screw effective diameter measurement. It is a top view which shows the holding jig for a screw effective diameter measurement. It is a perspective view which shows a mode that a screw member is accommodated in the accommodating part of the holding jig for a screw effective diameter measurement. It is a perspective view which shows a mode that a pin member is inserted in an insertion hole and an insertion groove in the state which accommodated the screw member in the accommodating part. It is a perspective view which shows a mode that insertion of the pin member to an insertion groove is performed by inserting a pin member into the insertion groove from the upper part of a main body through the opening part of an insertion groove. It is a side view showing the state where the pin member inserted in the insertion hole and the insertion groove is in contact with the screw groove of the screw member. It is a front sectional view showing the state where the pin member inserted into the insertion hole and the insertion groove is in contact with the screw groove of the screw member. It is a top view which shows the state which the pin member inserted in the insertion hole and the insertion groove is contact | abutting to the screw groove of a screw member. It is a perspective view which shows a mode that the effective diameter of a screw member is measured with a measuring tool using the holding jig for a screw effective diameter measurement. It is a side view which shows a mode that the effective diameter of a screw member is measured with a measuring tool using the holding jig for effective screw diameter measurement. It is front sectional drawing which shows a mode that the effective diameter of a screw member is measured with a measuring tool using the holding jig for effective screw diameter measurement. It is a perspective view which shows another Example of the holding jig for a screw effective diameter measurement. It is a perspective view which shows the mode of a measurement of the effective diameter of the screw member using the conventional 3 needle | hook method. It is a side view which shows the mode of the measurement of the effective diameter of the screw member using the conventional 3 needle method.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Screw effective diameter measurement holding jig 3 Screw member 5 Pin member 10 Main body 11 Base member 11a Measuring tool insertion hole 12/13 Side wall member 12a / 13a Insertion hole 12b / 13b Insertion groove 15 Housing part 20 Base

Claims (4)

When measuring the effective diameter of the screw member in a state where the screw member to be measured is sandwiched between the plurality of pin members, a holding screw for measuring the effective diameter of the screw for holding the plurality of pin members. Tools,
An accommodating portion for accommodating the screw member;
An insertion portion into which a plurality of pin members penetrating the housing portion are inserted so as to intersect the screw member housed in the housing portion;
A holding jig for measuring the effective diameter of a screw. The accommodating portion is configured by a space surrounded by a base member located on one side of a screw member to be accommodated and side wall members standing from both side end portions of the base member,
The insertion portion is configured by an insertion hole or an insertion groove formed in each of the side wall members,
The holding jig for measuring an effective screw diameter according to claim 1. The insertion portion includes an insertion hole or an insertion groove on one side of each side wall member that is positioned closer to the base member than the screw member housed in the housing portion, and an anti-base than the screw member housed in the housing portion. Having an insertion hole or insertion groove on the other side located on the member side,
The holding jig for measuring an effective screw diameter according to claim 2. Each of the side wall members is formed with one of the insertion hole or insertion groove on the one side and the insertion hole or insertion groove on the other side, and the insertion hole or insertion groove on the one side and the other side. Either one of the insertion hole or the insertion groove is formed,
The holding jig for measuring an effective screw diameter according to claim 3.

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