JP7245802B2 - V-pulley groove angle measuring instrument - Google Patents

Description

The present invention relates to a groove angle measuring instrument for measuring the angle of a V-shaped groove formed in a pulley.

A V-belt is known as a friction transmission belt that transmits power. There are two types of V-belts: Raw-edge type (raw-edge V-belt), which is a rubber layer with an exposed friction transmission surface (V-shaped side), and Wrapped type, where the friction transmission surface is covered with a cover cloth. (wrapped V-belt). These V-belts are used in power transmission devices such as general industrial machinery, agricultural machinery, and auxiliary machinery in automobile engines, and are also used as variable speed belts in belt-type continuously variable transmissions in motorcycles and the like.

These V-belts have a friction transmission surface (V-shaped side surface) formed at a V angle and are wound under tension between a driving pulley and a driven pulley in which V-shaped grooves are formed. , the V-shaped side surface of the V-belt rotates between the pulleys while being in contact with the V-shaped groove of each pulley.

In the above usage mode, in order to maintain the frictional transmission efficiency and prevent overloading on a part of the V-belt, the V-shaped side surface of the V-belt is placed in the V-shaped groove of each pulley as thoroughly and uniformly as possible. need to contact

Therefore, in the pulley around which the V-belt is wound, the angle of the V-shaped groove formed in the pulley is measured in order to check the change of the V-shaped groove due to the pulley manufacturing process and wear due to use. There is a need to.

In this regard, the conventional method for measuring the angle of a V-shaped groove formed in a pulley is to pour silicone or a low-melting-point alloy (for example, a bismuth-lead-tin-cadmium alloy that melts at 70-80°C) into the groove. , there is a method of taking a mold and measuring the angle from the mold. There is also a method of fitting a plurality of angle gauges into the pulley groove and estimating the angle from the corresponding gauges, or measuring the angle using a commercially available angle gauge (see Patent Documents 1 and 2). Furthermore, there is also a method of using a shape measuring machine that directly measures the groove angle.

JP 2015-215326 A Japanese Utility Model Laid-Open No. 49-148958

However, the method of pouring silicone or a low-melting-point alloy into the groove of the pulley requires time and effort from mold making to angle measurement. In addition, in the method of estimating the angle from the corresponding gauges by fitting a plurality of angle gauges in the pulley groove, there are cases where the angle interval between the gauges is wide and accurate measurement cannot be performed. Also, the method of using a commercially available goniometer may be too large to accurately hit both walls of the V-shaped groove. Also, in the method of using a shape measuring machine that directly measures the groove angle, the shape measuring machine itself is large and is not practical for measuring the groove of a pulley arranged in a small-spaced actual machine.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a compact groove angle measuring instrument capable of easily and accurately measuring the groove angle of a pulley having a V-shaped groove.

In order to solve the above problems, the present invention provides a groove angle measuring instrument for measuring the angle of a V-shaped groove formed in a pulley,
a first plate;
a second plate portion facing the first plate portion;
a fulcrum portion that allows the second plate portion to rotate with respect to the first plate portion;
a first pin and a second pin provided perpendicular to one surface of the first plate;
A third pin and a fourth pin provided perpendicular to one surface of the second plate,
With the first plate portion along one side surface of the groove, the first pin and the second pin are configured such that a first line segment connecting the first pin and the second pin is formed on one side of the groove. are arranged parallel to the sides of the
With the second plate part along the other side surface of the groove, the third pin and the fourth pin are configured such that a second line segment connecting the third pin and the fourth pin is the other side of the groove. are arranged parallel to the sides of the
The first pin, the second pin, the third pin, and the fourth pin are divided into a third line segment connecting the first pin and the third pin, and a line segment connecting the second pin and the fourth pin. It is characterized in that four line segments are arranged in parallel.

According to the above configuration, the groove angle measuring instrument is inserted into the V-shaped groove of the pulley, and while the first plate portion is along one side surface of the groove, By rotating the second plate portion, the second plate portion can be made to follow the other side surface of the groove. As a result, the first line segment connecting the first pin and the second pin is maintained parallel to one side surface of the groove, and the second line segment connecting the third pin and the fourth pin is maintained parallel to the other side surface of the groove. A groove angle measuring device in which a parallel state is maintained, and a third line segment connecting the first pin and the third pin and a fourth line segment connecting the second pin and the fourth pin are maintained in a parallel state. , the distance between the first and third pins, and the distance between the second and fourth pins.
Also, the diameters of the first to fourth pins, the distance between the first and second pins, and the distance between the third and fourth pins are numerical values that are known in advance in terms of design.
Once the above numerical values are known, the angle of the V-shaped groove formed in the pulley can be calculated by calculation using trigonometric functions.
According to this, the instrument for measuring the angle of the V-shaped groove formed in the pulley can be made compact and accurate measurement can be performed.

In addition, the present invention provides the above groove angle measuring instrument,
a first distance between the first pin and the fulcrum portion is the same as a third distance between the third pin and the fulcrum portion;
A second distance between the second pin and the fulcrum is the same as a fourth distance between the fourth pin and the fulcrum.

According to the above configuration, it is easy to design so that the third line segment connecting the first pin and the third pin and the fourth line segment connecting the second pin and the fourth pin are parallel to each other.

In addition, the present invention provides the above groove angle measuring instrument,
It is characterized by comprising a locking mechanism for temporarily locking rotation of the second plate portion with respect to the first plate portion.

According to the above configuration, the groove angle measuring instrument is inserted into the V-shaped groove of the pulley, the first line segment connecting the first pin and the second pin is kept parallel to one side surface of the groove, and The rotation of the second plate portion with respect to the first plate portion can be temporarily stopped (fixed) while the second line segment connecting the third pin and the fourth pin is kept parallel to the other side surface of the groove. can. Thereby, even if the groove angle measuring instrument is removed from the groove, the distance between the first pin and the third pin and the distance between the second pin and the fourth pin can be easily measured while maintaining the above state. can.

In addition, the present invention provides the above groove angle measuring instrument,
The locking mechanism
A screw that is inserted through an arc-shaped elongated hole centered on the fulcrum portion formed in the first plate portion and screwed into a screw hole provided in the second plate portion. there is

According to the above configuration, it is possible to easily temporarily fix the rotation of the second plate portion with respect to the first plate portion simply by screwing the screw into the screw hole.

In addition, the present invention provides the above groove angle measuring instrument,
The first pin, the second pin, the third pin and the fourth pin are characterized in that they are cylindrical.

According to the above configuration, when measuring the distance between the first pin and the third pin and the distance between the second pin and the fourth pin, it is easy to measure with a vernier caliper or the like, and a trigonometric function is used. Calculation of the groove angle is facilitated.

In addition, the present invention provides the above groove angle measuring instrument,
An end portion of the first plate portion that is not inserted into the groove of the pulley has an arc shape centering on the fulcrum portion,
An end portion of the second plate portion, which is not inserted into the groove of the pulley, has an arc shape centering on the fulcrum portion.

According to the above configuration, when the second plate portion is rotated around the fulcrum portion with respect to the first plate portion, the end portion of the first plate portion does not protrude from the end portion of the second plate portion ( The end portion of the second plate portion does not protrude from the end portion of the first plate portion). According to this, when measuring, the end of the first plate portion and the end of the second plate portion are prevented from contacting the hand of the measurer (preventing being caught), and accurate measurement can be performed. becomes possible.

In addition, the present invention provides the above groove angle measuring instrument,
The first plate portion and the second plate portion are characterized in that they have the same shape with their facing surfaces facing in the same direction.

According to the above configuration, manufacturing of the groove angle measuring instrument can be made more efficient, and cost performance can be improved.

In addition, the present invention provides the above groove angle measuring instrument,
The first pin and the second pin are arranged at a position in contact with one side surface of the groove with the first plate part along one side surface of the groove,
The third pin and the fourth pin are arranged at positions contacting the other side surface of the groove while the second plate portion is along the other side surface of the groove. .

According to the above configuration, the first line segment connecting the first pin and the second pin is reliably made parallel to the one side surface of the groove while the first plate portion is along one side surface of the groove. can be placed. Similarly, with the second plate part along the other side surface of the groove, the second line segment connecting the third pin and the fourth pin is reliably arranged so as to be parallel to the other side surface of the groove. can be done.

It is possible to provide a compact groove angle measuring instrument capable of easily and accurately measuring the groove angle of a pulley having a V-shaped groove.

1 is a perspective view of a groove angle measuring instrument according to the present embodiment; FIG. It is an explanatory view of a groove angle measuring instrument according to the present embodiment. It is a six-sided view of the groove angle measuring instrument according to the present embodiment. It is explanatory drawing of a 1st board part and a 2nd board part. FIG. 4 is an explanatory diagram of a pulley groove around which a V-belt is wound; FIG. 5 is an explanatory diagram of a method of measuring the groove angle of the pulley groove using a groove angle measuring instrument; FIG. 5 is an explanatory view showing the relative positional relationship between first to fourth pins of the groove angle measuring instrument; FIG. 10 is an explanatory diagram of a groove angle measuring instrument according to another embodiment 1; FIG. 11 is an explanatory diagram of a groove angle measuring instrument according to another embodiment 2; FIG. 11 is an explanatory diagram of a groove angle measuring instrument according to another embodiment 2; FIG. 11 is an explanatory diagram of a groove angle measuring instrument according to another embodiment 2; FIG. 11 is an explanatory diagram of a groove angle measuring instrument according to another embodiment 2;

(embodiment)
Embodiments of the present invention will be described below with reference to the drawings. In this embodiment, the groove angle θ of the V-shaped groove 11 formed in the pulley 10 around which the V-belt having the friction transmission surface (V-shaped side surface) formed at a V angle is wound (see FIG. 5) A groove angle measuring instrument 1 for measuring is described.

(Groove angle measuring instrument 1)
As shown in FIGS. 1 to 4, the groove angle measuring instrument 1 includes a first plate portion 2, a second plate portion 3 facing the first plate portion 2, and a second plate portion 3 facing the first plate portion 2. A rivet 4 (fulcrum) that allows the portion 3 to rotate, a first pin 5 and a second pin 6 that are provided perpendicular to one surface of the first plate portion 2, and the second plate portion 3. A third pin 7 and a fourth pin 8 are provided perpendicularly to one surface, and a lock mechanism 9 for temporarily locking rotation of the second plate portion 3 with respect to the first plate portion 2 .

(First plate portion 2)
As shown in FIG. 4 (a top view of the first plate portion 2), the first plate portion 2 is manufactured by processing a rectangular flat plate (made of metal). A right-angled triangular tip portion 22 is formed along one side surface 11A of the V-shaped groove 11 .

A notch portion 23 is formed in the body portion 21 by obliquely notching the end opposite to the tip portion 22 . A hole 24 into which the rivet 4 is inserted is formed in the body portion 21 at a location slightly closer to the notch portion 23 than the center in the width direction and closer to the tip portion 22 than the center in the longitudinal direction. Further, the body portion 21 is formed with an arcuate long hole 25 centered on the hole 24 (rivet 4: fulcrum portion). The elongated hole 25 is formed to have a size that allows the nominal diameter of the screw 91 of the lock mechanism 9 (to be described later) to slide so that the first plate portion 2 and the second plate portion 3 can rotate relative to each other by at least 10°. ing.

The tip portion 22 is provided with a first pin 5 on the side surface 22A facing one side surface 11A of the groove 11 of the pulley 10 and on the body portion 21 side. A second pin 6 is provided. In the present embodiment, the first pin 5 and the second pin 6 are connected to one side surface 11A of the groove 11 (deep (the side surface 22A of the tip portion 22, the first pin 5, and the second pin 6 are arranged on the tip portion 22 in such a manner that they are in contact with each other at two points in the longitudinal direction). contact state). In addition, the first pin 5 and the second pin 6 do not necessarily have to be arranged so as to contact the one side surface 11A of the groove 11, and the first plate portion 2 is arranged along the one side surface 11A of the groove 11. A first line segment connecting the first pin 5 and the second pin 6 (a line segment corresponding to the center distance b, see FIG. 2) connecting the first pin 5 and the second pin 6 is the groove. 11 (that is, the first pin 5 and the second pin 6 may be arranged apart from the side surface 22A of the distal end portion 22).

(Second plate portion 3)
As shown in FIG. 4 (a top view of the second plate portion 3), the second plate portion 3 is manufactured by processing a rectangular flat plate (made of metal) in the same manner as the first plate portion 2. A body portion 31 and a right-angled triangular tip portion 32 along the other side surface 11B of the V-shaped groove 11 of the pulley 10 are formed.

A notch portion 33 is formed in the body portion 31 by obliquely notching the end opposite to the tip portion 32 . A hole 34 into which the rivet 4 is inserted is formed in the body portion 31 at a location slightly closer to the notch portion 33 than the center in the width direction and closer to the tip portion 32 than the center in the longitudinal direction. A circular hole 35 is formed in the body portion 31 at a position corresponding to the elongated hole 25 . A nut 92 (screw hole) is welded at a position corresponding to the hole 35 on the bottom surface side of the body portion 31 .

The distal end portion 32 is provided with a third pin 7 on the side surface 32A facing the other side surface 11B of the groove 11 of the pulley 10 and on the body portion 31 side. A fourth pin 8 is provided. In the present embodiment, the third pin 7 and the fourth pin 8 are connected to the other side surface 11B of the groove 11 (deep (the side surface 32A of the tip portion 32, the third pin 7, and the fourth pin 8 are simultaneously in contact with the other side surface 11B of the groove 11). contact state). It should be noted that the third pin 7 and the fourth pin 8 may not necessarily be arranged in contact with the other side surface 11B of the groove 11. A second line segment connecting the third pin 7 and the fourth pin 8 (a line segment corresponding to the center distance a described later, see FIG. 2) is the groove. 11 (that is, the third pin 7 and the fourth pin 8 may be arranged away from the side surface 32A of the distal end portion 32).

In the present embodiment, the first plate portion 2 and the second plate portion 3 have the same shape with the opposing surface sides facing in the same direction (however, the long hole 25 and the hole 35 shape). As a result, the production of the groove angle measuring instrument 1 can be made more efficient, and the cost performance can be improved.

(Rivet 4: fulcrum)
The rivet 4 (made of metal) is inserted through the hole 24 of the first plate portion 2 and the hole 34 of the second plate portion 3 so that the first plate portion 2 and the second plate portion 3 can rotate relative to each other. It is crimped (fixed) as shown.

(first pin 5, second pin 6, third pin 7, fourth pin 8)
The first pin 5 and the second pin 6 are provided perpendicular to one surface of the first plate portion 2, as shown in FIG. Similarly, the third pin 7 and the fourth pin 8 are provided perpendicular to one surface of the second plate portion 3 . The first pin 5, the second pin 6, the third pin 7, and the fourth pin 8 are cylindrical metal pins and serve as references for distance measurement. 6 has a shape lower in height than the third pin 7 and the fourth pin 8 . Specifically, as shown in the bottom view of FIG. 3, the height of the first pin 5 and the second pin 6 provided on the first plate portion 2 and The heights of the third pin 7 and the fourth pin 8 provided on the second plate portion 3 are set to be the same height. Also, the first pin 5, the second pin 6, the third pin 7 and the fourth pin 8 have the same diameter.

2, the relative positional relationship between the first pin 5, the second pin 6, the third pin 7, and the fourth pin 8 is the center of the first pin 5 and the third pin. A third line segment A connecting the center of pin 7 and a fourth line segment B connecting the center of second pin 6 and the center of fourth pin 8 are arranged parallel to each other.

More specifically, the first pin 5, the second pin 6, the third pin 7 and the fourth pin 8 are defined by a first distance C between the center of the first pin 5 and the center of the rivet 4, The third distance E between the center of the third pin 7 and the center of the rivet 4 is the same, the second distance D between the center of the second pin 6 and the center of the rivet 4 and the fourth pin 8 and the fourth distance F between the center of the rivet 4 and the center of the rivet 4 are the same. By setting such a distance relationship between the first pin 5, the second pin 6, the third pin 7, and the fourth pin 8, a third line segment connecting the first pin 5 and the third pin 7 is formed. A can be easily designed to be parallel to the fourth line segment B connecting the second pin 6 and the fourth pin 8 .

Also, the center distance a between the center of the third pin 7 and the center of the fourth pin 8 should be the same as the center distance b between the center of the first pin 5 and the center of the second pin 6. (center distance a=center distance b: see FIG. 7).

(Lock mechanism 9)
The lock mechanism 9 is composed of a screw 91 and a nut 92 with which the screw 91 is screwed. The head of the screw 91 is formed larger than the width of the elongated hole 25 on the bottom side of the body portion 31 . Further, the nominal thread size of the screw 91 is smaller than the width of the elongated hole 25 and the diameter of the hole 35 . As a result, the screw 91 is inserted through the elongated hole 25 of the first plate portion 2 and the hole 35 of the second plate portion 3, and the nut welded to the position corresponding to the hole 35 on the bottom side of the second plate portion 3. 92, the first plate portion 2 and the second plate portion 3 are sandwiched between the head of the screw 91 and the nut 92, and the second plate portion 3 is rotated with respect to the first plate portion 2. can be temporarily fixed.

The lock mechanism 9 may be realized by using the hole 35 of the second plate portion 3 as a screw hole instead of the nut 92 (corresponding to a screw hole). In this case, the rotation of the second plate portion 3 with respect to the first plate portion 2 can be temporarily fixed by screwing the screw 91 into the hole 35 .

Further, as the locking mechanism 9, it is only necessary to temporarily stop the rotation of the second plate portion 3 with respect to the first plate portion 2, and a clip sandwiching the first plate portion 2 and the second plate portion 3 may be employed. Well, it is not limited to screw 91 .

(Method for measuring groove angle of V-shaped groove 11)
Next, a method of measuring the groove angle θ (see FIG. 5) of the V-shaped groove 11 formed on the outer circumference of the pulley 10 using the groove angle measuring instrument 1 will be described.

First, the screw 91 of the lock mechanism 9 is unscrewed from the nut 92 so that the first plate portion 2 and the second plate portion 3 can rotate relative to each other (turnable).

Next, as shown in FIG. 6A, the tip portion 22 of the first plate portion 2 and the tip portion 32 of the second plate portion 3 of the groove angle measuring instrument 1 are inserted into the V-shaped groove 11 of the pulley 10. insert.

Next, the first plate portion 2 is aligned along one side surface 11A of the groove 11, and the first pin 5 and the second pin 6 provided on the first plate portion 2 are attached to one side surface 11A of the groove 11. abut. Similarly, the second plate portion 3 is aligned along the other side surface 11B of the groove 11, and the third pin 7 and the fourth pin 8 provided on the second plate portion 3 are aligned with the other side surface 11B of the groove 11. abut. At this time, the first plate portion 2 and the second plate portion 3 rotate (turn) relative to each other around the rivet 4 .

Here, as shown in FIG. 6(B), the groove angle (36°) of the V-shaped groove 11 of the pulley 10 is equal to the groove angle (36°) of the V-shaped groove 11 of the pulley 10 shown in FIG. 6(A). 34°), the first plate portion 2 and the second plate portion 3 rotate (pivot) relative to each other around the rivet 4, and the angle between the second pin 6 and the fourth pin 8 increases. is shortened, and the screw 91 moves to the right side of the elongated hole 25 . Furthermore, as shown in FIG. 6(C), the groove angle (38°) of the V-shaped groove 11 of the pulley 10 is less than the groove angle (36°) of the V-shaped groove 11 of the pulley 10 shown in FIG. 6(B). °), the first plate portion 2 and the second plate portion 3 are further rotated (rotated) relative to each other around the rivet 4, and the gap between the second pin 6 and the fourth pin 8 is The distance is further shortened, and the screw 91 is further moved to the right side of the slot 25 .

Next, with the first pin 5 and the second pin 6 in contact with one side surface 11A of the groove 11, and the third pin 7 and the fourth pin 8 in contact with the other side surface 11B of the groove 11, Rotation of the second plate portion 3 with respect to the first plate portion 2 is temporarily stopped by screwing the screw 91 into the nut 92 . Thereby, the relative positional relationships among the first pin 5, the second pin 6, the third pin 7, and the fourth pin 8 are held (fixed).

Then, the groove angle measuring instrument 1 in which the rotation of the second plate portion 3 with respect to the first plate portion 2 is temporarily fixed is removed from the groove 11 of the pulley 10 .

Next, as shown in FIG. 7, in the groove angle measuring instrument 1 taken out, the end distance X _a1 between the end of the first pin 5 and the end of the third pin 7 and the end of the second pin 6 and The end distance _Xb1 between the ends of the fourth pin 8 is measured with a ruler such as a vernier caliper.

Then, the measured both-end distance X _a1 and the both-end distance X _b1 , and the previously measured center distance a between the center of the third pin 7 and the center of the fourth pin 8 (the first pin 5 and the center of the second pin 6 is the same as the center distance a), and the diameter d of the first pin 5 to the fourth pin 8 (the first pin 5 to the fourth pin 8 are all the same diameter), the inclination angle θ ₁ of the side surface 11A of the groove 11 and the inclination angle θ ₂ of the side surface 11B of the groove 11 are obtained by calculation using a trigonometric function, and the groove angle θ (θ = θ ₁ + θ ₂ ) is calculated (see Fig. 5).

Specifically, the distance X a2 between the midpoint C13 between the first pin 5 and _the third pin 7 and the center of the third pin 7 is calculated as (X _a1 -d)/2. .
Similarly, the distance X b2 between the midpoint C24 between the second pin 6 and the fourth pin 8 and the center of the fourth pin ₈ is calculated as (X _b1 -d)/2.
Then, the inclination angle θ ₂ of the side surface 11B of the groove 11 is calculated by the following equation (Equation 1) (see FIG. 7). Similarly, the inclination angle θ ₁ of the side surface 11A of the groove 11 can also be calculated. However, in the present embodiment, since the tilt angle _θ2 and the tilt angle _θ1 have the same value, if the tilt angle _θ2 can be calculated, the tilt angle _θ1 can also be calculated.
From the above, the groove angle θ (θ=2×θ ₂ ) of the groove 11 of the pulley 10 can be calculated (see FIG. 5).

_For example, the _measured values shown in FIG. By substituting and calculating, the inclination angle θ ₂ ≈18.000877 is obtained, and the groove angle θ (θ=2×θ ₂ ) of the groove 11 of the pulley 10 is calculated to be approximately 36.001754°.

By using the groove angle measuring instrument 1 configured as described above, the instrument for measuring the groove angle θ of the V-shaped groove 11 formed in the pulley 10 can be made compact, and the groove angle θ can be accurately measured. Further, since the groove angle measuring instrument 1 is compact, the groove angle measuring instrument 1 can be inserted into the groove 11 of the pulley 10 even when the pulley 10 is incorporated in a device with little space. can be done.

Further, by using the lock mechanism 9, the rotation of the second plate portion 3 with respect to the first plate portion 2 can be temporarily stopped (fixed). Thereby, even if the groove angle measuring instrument 1 is removed from the groove 11, the both-end distance _Xa1 and the both-end distance _Xb1 can be easily measured while maintaining the state.

Further, since the locking mechanism 9 employs the screw 91 , the rotation of the second plate portion 3 with respect to the first plate portion 2 can be easily temporarily fixed simply by screwing the screw 91 into the nut 92 . can.

Also, since the first pin 5, the second pin 6, the third pin 7, and the fourth pin 8 are cylindrical, the distance between the end of the first pin 5 and the end of the third pin 7 is When measuring the both-end distance X _a1 and the both-end distance X _b1 between the end of the second pin 6 and the end of the fourth pin 8, it becomes easier to measure with a vernier caliper or the like, and a trigonometric function is used. , facilitating the calculation of the groove angle. Also, since the first pin 5, the second pin 6, the third pin 7, and the fourth pin 8 have a columnar shape, the first pin 5 and the second pin 6 are located on one side surface 11A of the groove 11. Similarly, the third pin 7 and the fourth pin 8 easily follow the other side surface 11B of the groove 11, so that the both-end distance X _a1 and the both-end distance X _b1 can be accurately measured. .

Further, the first pin 5 and the second pin 6 are arranged at positions contacting one side surface 11A of the groove 11 with the first plate portion 2 along one side surface 11A of the groove 11. The pin 7 and the fourth pin 8 are arranged at positions contacting the other side surface 11B of the groove 11 with the second plate portion 3 along the other side surface 11B of the groove 11 . According to this configuration, the first line segment connecting the first pin 5 and the second pin 6 is formed along one side surface 11A of the groove 11 while the first plate portion 2 is aligned along one side surface 11A of the groove 11. 11A can be reliably arranged. Similarly, with the second plate portion 3 along the other side surface 11B of the groove 11, the second line segment connecting the third pin 7 and the fourth pin 8 is made parallel to the other side surface 11B of the groove 11. can be reliably arranged so that

(Other embodiment 1)
In the groove angle measuring instrument 1 of the above embodiment, the end portion of the first plate portion 2 on the side not inserted into the groove 11 of the pulley 10 and the end portion of the second plate portion 3 on the side not inserted into the groove 11 of the pulley 10 Both ends are straight. However, like the groove angle measuring instrument 101 shown in FIG. 8, the end portion 126 of the first plate portion 102 on the side not inserted into the groove 11 of the pulley 10 has an arc shape centered on the rivet 104 (fulcrum portion). , and the end portion 136 of the second plate portion 103 on the side not inserted into the groove 11 of the pulley 10 may also have an arc shape centered on the rivet 104 .

According to the above configuration, when the second plate portion 103 is rotated around the rivet 104 (fulcrum portion) with respect to the first plate portion 102, the end portion 126 of the first plate portion 102 moves toward the second plate portion. 103 (the end 136 of the second plate portion 103 does not protrude from the end 126 of the first plate portion 102). According to this, when measuring the groove angle .theta. Accurate measurement can be performed by preventing tampering (preventing catching).

(Other embodiment 2)
Further, in the groove angle measuring instrument 1 of the above-described embodiment, the body portion 21 of the first plate portion 2 (above the hole 24) and the body portion 31 of the second plate portion 3 (above the hole 34) have , may be processed to make it easier to put a finger on.

For example, as shown in the groove angle measuring instrument 201 of FIG. At least a part of the upper thickness direction side surfaces 236 and 237 of the portion 231 may be subjected to a large number of fine groove processing or knurl processing. As a result, the user can easily measure the side surfaces 226 and 227 of the first plate portion 202 and the side surfaces 236 and 237 of the second plate portion 203 on which a large number of fine grooves or knurls have been applied. When measuring the groove angle θ of the V-shaped groove 11 formed on the outer periphery of the pulley 10 by placing a finger on the surface of the pulley 10, slippage can be prevented (anti-slip effect).

Further, for example, as shown in the groove angle measuring instrument 301 of FIG. A protruding portion 336 may be provided on the side surface in the thickness direction on the upper end side of 331 . Further, at least a portion of the ridges 326 and 336 may be subjected to a large number of micro-grooving or knurling. As a result, when the user measures the groove angle θ of the V-shaped groove 11 formed on the outer circumference of the pulley 10 by placing a finger on the ridges 326 and 336 of the groove angle measuring instrument 301, In addition, it can be made less slippery (anti-slip effect). Furthermore, by putting two fingers of one hand on the protruding streaks 326 and 336 respectively, the first plate portion 302 and the second plate portion 303 can be easily rotated relative to each other. (It can facilitate closing and opening the groove angle measuring instrument 301 with one hand).

Further, for example, as shown in the groove angle measuring instrument 401 of FIG. ) may be provided, and a notch 436 (which may be a triangle shape, a concave shape, or a U shape) may be provided on the side surface in the thickness direction of the upper end side of the main body portion 431 of the second plate portion 403 . . Further, at least a portion of the notch 426 and notch 436 may be subjected to multiple micro-grooving or knurling. As a result, the user puts two fingers of one hand on the notch 426 and notch 436 of the groove angle measuring instrument 401, respectively, so that the first plate portion 402 and the second plate portion 403 are moved relative to each other. It can be made easier to rotate (make it easier to close and open the groove angle measuring instrument 401 with one hand).

Further, for example, as shown in the groove angle measuring instrument 501 of FIG. Holes 536 may be provided in the corners. By attaching metal fittings such as finger pins and plates to the holes 526 and 536 , the user can easily remove metal fittings such as pins and plates attached to the holes 526 and 536 of the groove angle measuring instrument 501 . In addition, by placing two fingers of one hand on each of them, the first plate portion 502 and the second plate portion 503 can be easily rotated relative to each other (the groove angle measuring instrument 501 can be closed and opened with one hand). can be made easier).

In addition, in the groove angle measuring instruments 201, 301, 401, 501 of the second embodiment, when the first plate portions 202, 302, 402, 502 and the second plate portions 203, 303, 403, 503 are overlapped, In addition, a part of the side surface in the thickness direction on the upper end side of the first plate parts 202, 302, 402, 502 and a part of the side surface in the thickness direction on the upper end side of the second plate parts 203, 303, 403, 503 are , are designed to overlap in the same plane. Further, in the groove angle measuring instruments 201, 301, 401, and 501, the same numbers are given to the members common to the groove angle measuring instrument 1 (rivet 4, second pin 6, third pin 7, fourth pin 7). pin 8, locking mechanism 9, etc.).

REFERENCE SIGNS LIST 1 groove angle measuring instrument 2 first plate portion 3 second plate portion 4 rivet 5 first pin 6 second pin 7 third pin 8 fourth pin 9 locking mechanism 10 pulley 11 groove

Claims (8)

A groove angle measuring instrument for measuring the angle of a V-shaped groove formed in a pulley,
a first plate;
a second plate portion facing the first plate portion;
a fulcrum portion that allows the second plate portion to rotate with respect to the first plate portion;
a first pin and a second pin provided perpendicular to one surface of the first plate;
A third pin and a fourth pin provided perpendicular to one surface of the second plate,
With the first plate portion along one side surface of the groove, the first pin and the second pin are configured such that a first line segment connecting the first pin and the second pin is formed on one side of the groove. are arranged parallel to the sides of the
With the second plate part along the other side surface of the groove, the third pin and the fourth pin are configured such that a second line segment connecting the third pin and the fourth pin is the other side of the groove. are arranged parallel to the sides of the
The first pin, the second pin, the third pin, and the fourth pin are divided into a third line segment connecting the first pin and the third pin, and a line segment connecting the second pin and the fourth pin. A groove angle measuring instrument, characterized in that four line segments are arranged so as to be parallel to each other. a first distance between the first pin and the fulcrum portion is the same as a third distance between the third pin and the fulcrum portion;
2. The groove angle measurement of claim 1, wherein a second distance between said second pin and said fulcrum and a fourth distance between said fourth pin and said fulcrum are the same. instrument. 3. The groove angle measuring instrument according to claim 1, further comprising a lock mechanism for temporarily fixing rotation of said second plate portion with respect to said first plate portion. The locking mechanism is
A screw that is inserted through an arc-shaped elongated hole centered on the fulcrum portion formed in the first plate portion and screwed into a screw hole provided in the second plate portion. 4. The groove angle measuring instrument according to claim 3, wherein: The groove angle measuring instrument according to any one of claims 1 to 4, wherein the first pin, the second pin, the third pin and the fourth pin are cylindrical. An end portion of the first plate portion that is not inserted into the groove of the pulley has an arc shape centering on the fulcrum portion,
6. The apparatus according to any one of claims 1 to 5, wherein the end portion of the second plate portion that is not inserted into the groove of the pulley has an arc shape centering on the fulcrum portion. Groove angle measuring instrument. The first plate portion and the second plate portion are characterized in that they have the same shape with their facing sides facing in the same direction. groove angle measuring instrument. The first pin and the second pin are arranged at a position in contact with one side surface of the groove with the first plate part along one side surface of the groove,
The third pin and the fourth pin are arranged at a position contacting the other side surface of the groove with the second plate portion along the other side surface of the groove. The groove angle measuring instrument according to any one of claims 1 to 7.

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