JP2020193827A - Measuring device, base for measuring member, and level fixture - Google Patents

Abstract

To provide a measuring device that is able to hold a pose and is able to find an accurate measurement.SOLUTION: A measuring device 2 comprises a body 3 and a pair of movable vanes 401, 401. The body 3 comprises: a bubble pipe 301 that measures a state of a to-be-measured object 1, such as a horizontal state; and a reference contact portion 3b that comes into contact with the to-be-measured portion 1, which serves as a measurement target of the to-be-measured object 1, so as to determine a pose of the body 3 itself. The movable vanes 401 are pivotally supported by the body 3 so as to be rotatable. The movable vanes 401 each comprise an auxiliary contact portion 4a that comes into contact with the to-be-measured object 1 so as to hold the pose of the body 3.SELECTED DRAWING: Figure 2

Description

The present invention relates to a measuring device, a pedestal for a measuring member, and a spirit level fixture for measuring a predetermined state of an object to be measured, for example, an angle, a length, a vibration, or the like.

Conventionally, in a spirit level for measuring horizontal or vertical, there has been a spirit level with a fixture that can be attached to a measurement target portion for measurement (see, for example, Patent Document 1). In this level with a fixture, the surface that comes into contact with the part to be measured is, for example, a surface to which a removable adhesive is applied. This allows the level to be attached to the part to be measured in a stable state, horizontally or vertically. Was able to be measured.

Utility Model Registration No. 3011098

However, in the spirit level with a fixture, if foreign matter adheres to the removable adhesive coating surface that comes into contact with the part to be measured, the attitude of the spirit level with respect to the part to be measured may be out of order, making accurate measurement difficult. there were.

The present invention has been made to solve the above-mentioned conventional drawbacks, and an object thereof is for a measuring device and a measuring member capable of maintaining a posture and accurately measuring. To provide a pedestal and a spirit level fixture.

The measuring device, the pedestal for measuring members, and the spirit level fitting according to the present invention have the following configurations in order to achieve the above object. That is,
The measuring device according to the invention according to claim 1 is a measuring device for measuring a predetermined state of an object to be measured, and includes a main body and a holding body. Here, the main body includes a measuring unit that measures the state of the object to be measured, and a reference contacting portion that contacts the measured unit to be measured of the object to be measured so as to determine the posture of the main body itself. .. On the other hand, the holding body is provided so as to be displaceable with respect to the main body, and the holding body includes an auxiliary contact portion that comes into contact with the object to be measured so as to hold the posture of the main body.

According to this measuring device, the measuring device is attached to the object to be measured so as to hold the posture of the main body provided with the measuring unit in addition to the reference contacting portion that abuts the measured portion to be measured. It is provided with an auxiliary contact portion for contact. In this way, by providing the auxiliary contact portion, the posture of the main body can be maintained, and by providing this auxiliary contact portion separately from the reference contact portion, foreign matter can be removed from the reference contact portion. It is possible to accurately measure a predetermined state of the object to be measured by eliminating the deviation of the posture of the main body due to the adhesion.

Further, the measuring device according to the invention according to claim 2 is the measuring device according to claim 1, wherein the holding body is displaced with respect to the main body, so that the reference contact portion becomes the measured portion. The auxiliary contact portion moves between a position away from the object to be measured and a position where the auxiliary contact portion is in contact with the object to be measured.

Further, the measuring device according to the invention according to claim 3 is the measuring device according to claim 1 or 2, wherein the auxiliary contact portion has re-adhesiveness and re-peelability to the object to be measured. It consists of an adhesive part that can be adhered.

In addition, the measuring device according to the invention according to claim 4 includes a covering portion that covers the auxiliary contact portion made of the adhesive portion so as not to be exposed to the outside in the measuring device according to claim 3. Here, the covering portion can be moved to a covering position that covers the auxiliary contact portion and a non-covering position that allows the auxiliary contact portion to come into contact with the object to be measured without covering the auxiliary contact portion. Is. As a result, when the measuring device is not used, the auxiliary contact portion can be protected by covering the auxiliary contact portion with the covering portion.

Further, the measuring device according to the invention according to claim 5 is the measuring device according to any one of claims 1 to 3, wherein the holding body is rotated to the main body in order to be displaced with respect to the main body. It is movably supported.

Further, the measuring device according to the invention according to claim 6 is the measuring device according to claim 5, wherein the holding body is located at a position where the reference contact portion is hidden by the rotation and the reference contact portion. Move to the position to expose. As a result, when the measuring device is not used, the reference contact portion can be protected by hiding the reference contact portion with the holding body.

The measuring device according to the invention according to claim 7 is the measuring device according to claim 5 or 6, wherein the holding body is composed of a pair of movable wings rotatably supported by the main body. Due to its rotation, the pair of movable wings approach and separate from each other. Then, the auxiliary contact portion is provided on each of the facing surfaces of the pair of movable wings.

Further, the measuring device according to the invention according to claim 8 is the measuring device according to claim 7, wherein the pair of movable wings approach the auxiliary contact portions provided on each of the pair of movable wings. By overlapping with each other, they are covered with movable wings on a side different from the side on which the auxiliary contact portions are provided. As a result, when this measuring device is not used, the auxiliary contact portion can be protected by stacking a pair of movable wings to cover the auxiliary contact portion.

The measuring device according to the invention according to claim 9 is the measuring device according to claim 8, wherein each of the pair of movable wings includes a movable wing main body and the auxiliary contact portion. Here, the auxiliary contact portion is made of an adhesive body having re-adhesiveness and re-peelability on both sides. One surface of the adhesive body is attached to the attachment surface of the movable wing body by adhesive, and the other surface can be attached to the object to be measured. Then, when the pair of movable wings overlap, the other surface of the adhesive body comes into contact with a separation prevention surface provided on the movable wings that covers the other surface. At this time, the area of the attachment surface in contact with the other surface of the adhesive body is smaller than the area of the attachment surface in contact with one surface of the adhesive body. In this way, when the pair of movable wings overlap, the other surface of the adhesive body comes into contact with the separation prevention surface provided on the movable wings that cover the other surface, thereby preventing the pair of movable wings from separating from each other. Will be done. When the pair of movable wings are separated from each other by making the area of the movable wing in contact with the other surface of the adhesive body of the separation prevention surface smaller than the area of the movable wing in contact with one of the adhesive bodies. , One surface of the adhesive remains attached to the mounting surface of the movable wing, and the other surface of the adhesive and the separation prevention surface are separated from each other.

The measuring device according to the invention according to claim 10 is the measuring device according to any one of claims 7 to 9, wherein the main body, one of the pair of movable wings, and the pair of movable wings are used. Both movable wings are provided with an interlocking mechanism that approaches and separates symmetrically with respect to the main body.

Further, the measuring device according to the invention according to claim 11 is the measuring device according to any one of claims 1 to 10, wherein the measuring unit is integrally provided in the main body.

Further, the measuring device according to the invention according to claim 12 is the measuring device according to any one of claims 1 to 10, wherein the main body is a measuring member having the measuring unit and the reference contact portion. It is provided with a base having the above. Here, the base has an installation portion on which the measuring member is installed. Then, the holding body is provided so as to be displaceable with respect to the base in the main body.

Further, the measuring device according to the invention according to claim 13 is the measuring device according to any one of claims 1 to 12, wherein the measuring unit measures at least a horizontal state of the object to be measured. is there.

Further, the pedestal for a measuring member according to the invention according to claim 14 is a pedestal for fastening the measuring member having a measuring unit for measuring the state of the object to be measured to the object to be measured, and the base and the pedestal. Provided with a retainer. Here, the base includes an installation portion on which the measuring member is installed, and a reference contact portion that abuts on the measured portion to be measured of the object to be measured so as to determine the posture of the base itself. On the other hand, the holding body is provided so as to be displaceable with respect to the base, and the holding body includes an auxiliary contact portion that comes into contact with the object to be measured so as to maintain the posture of the base.

According to this measurement member pedestal, the measurement member pedestal holds the posture of the base on which the measurement member is installed, in addition to the reference contact portion that abuts on the measurement target portion of the object to be measured. Is provided with an auxiliary contact portion that contacts the object to be measured. In this way, the posture of the base and the measuring member can be maintained by providing the auxiliary contact portion, and the reference contact portion can be provided separately from the reference contact portion. It is possible to accurately measure a predetermined state of the object to be measured by eliminating the deviation of the posture of the measuring member due to the adhesion of foreign matter to the contact portion.

Further, the spirit level attachment according to the invention according to claim 15 is a spirit level attachment for attaching the spirit level to the object to be measured. Here, the spirit level comes into contact with a measuring unit that measures at least the horizontal state of the object to be measured and a reference contact that abuts the measured unit to be measured of the object to be measured so as to determine the posture of the spirit level itself. It has a part. Therefore, the spirit level fixture includes a mounting body that is mounted and fixed to the spirit level, and a holding body. Then, the holding body is provided so as to be displaceable with respect to the mounting body, and the holding body includes an auxiliary contact portion that contacts the object to be measured so as to hold the posture of the mounting body.

According to this spirit level attachment, the spirit level is provided with a reference contact portion that abuts on the measurement target portion of the object to be measured, and the spirit level attachment is the posture of the attachment body that is attached and fixed to the spirit level. It is provided with an auxiliary contact portion that contacts the object to be measured so as to hold. In this way, by providing the auxiliary contact portion, the posture of the attachment body and the spirit level can be maintained, and by providing this auxiliary contact portion separately from the reference contact portion, the reference contact portion can be maintained. It is possible to accurately measure a predetermined state of the object to be measured by eliminating the deviation of the posture of the spirit level due to the adhesion of foreign matter to the contact portion.

According to the measuring device according to the present invention, by providing the auxiliary contact portion separately from the reference contact portion, not only the posture of the main body provided with the measuring portion can be maintained, but also a predetermined value of the object to be measured can be maintained. The state can be measured accurately.

Further, according to the pedestal for measuring member according to the present invention, by providing the auxiliary contact portion separately from the reference contact portion, it is possible not only to maintain the posture of the base and thus the measuring member, but also to be measured. It is possible to accurately measure a predetermined state of an object.

Further, according to the spirit level attachment according to the present invention, by providing the auxiliary contact portion separately from the reference contact portion provided in the spirit level, it is possible to maintain the posture of the attachment body and the spirit level. It is possible to accurately measure at least the horizontal state of the object to be measured.

It is a perspective view which applied the measuring apparatus to the piping material of a large diameter of one Embodiment of this invention. Similarly, it is a side view when the reference contact portion is in contact with the measured portion of the large-diameter piping material and the auxiliary contact portion is in contact with the piping material. Similarly, it is a side view when the auxiliary contact portion is at a position away from the piping material in a state where the reference contact portion is in contact with the measured portion of the large-diameter piping material. Similarly, it is a perspective view which applied the measuring device to the piping material of a small diameter. Similarly, it is a side view when the reference contact portion is in contact with the measured portion of the small diameter piping material and the auxiliary contact portion is in contact with the piping material. Similarly, it is a side view when the auxiliary contact portion is at a position away from the piping material in a state where the reference contact portion is in contact with the measured portion of the piping material having a small diameter. Similarly, it is a perspective view of the measuring device seen from diagonally above with a pair of movable wings closed. Similarly, it is a front view of the measuring device in a state where a pair of movable wings are closed. Similarly, it is a cross-sectional view taken along the line AA in FIG. Similarly, it is a cross-sectional view taken along the line BB in FIG. Similarly, it is a perspective view of the measuring device seen from diagonally above with a pair of movable wings open. Similarly, it is a perspective view of the measuring device seen from diagonally below with a pair of movable wings open. Similarly, it is a perspective view of the main body viewed from diagonally above. Similarly, it is a perspective view of the main body viewed from diagonally below. Similarly, it is a vertical sectional view of the main body. Similarly, it is a perspective view of the movable wing seen from diagonally above. Similarly, it is a perspective view of the movable wing seen from the rear side. Similarly, it is a rear view of the movable wing. Similarly, it is a cross-sectional view taken along the line CC in FIG. It is a perspective view when the measuring member is separated from the base of the pedestal for measuring member in the measuring apparatus of another embodiment of this invention. Similarly, in the measuring device, it is a perspective view when the measuring member is installed on the base of the pedestal for the measuring member. It is a perspective view when the spirit level fixture is separated from the spirit level in the measuring device of still another embodiment of this invention. Similarly, in the measuring device, it is a perspective view when the spirit level fixture is attached to the spirit level.

Hereinafter, embodiments for carrying out the measuring device, the pedestal for measuring members, and the spirit level fitting according to the present invention will be described with reference to the drawings.

1 to 19 show an embodiment of the present invention. Reference numeral 1 in the figure indicates an object to be measured. Reference numeral 2 denotes a measuring device for measuring a predetermined state of the object to be measured 1.

The measuring device 2 includes a main body 3 and a holding body 4. Here, the main body 3 is measured so as to determine the posture of the measuring unit 3a for measuring the state of the measured object 1 and the posture of the main body 3 itself (and thus the posture of the measuring unit 3a). A reference contact portion 3b that contacts the portion 1a is provided. Then, the holding body 4 is provided so as to be displaceable with respect to the main body 3, and the holding body 4 hits the object to be measured 1 so as to hold the posture of the main body 3 (and thus the posture of the measuring unit 3a). An auxiliary contact portion 4a that comes into contact is provided. Specifically, the holding body 4 is displaced with respect to the main body 3, so that the auxiliary contact portion 4a is separated from the object to be measured 1 in a state where the reference contact portion 3b is in contact with the measured portion 1a ( (See FIGS. 3 and 6) and the position of contact with the object 1 to be measured (see FIGS. 2 and 5).

Specifically, the auxiliary contact portion 4a is composed of an adhesive portion that has re-adhesiveness and re-peelability and can adhere to the object 1 to be measured. Therefore, the measuring device 2 includes a covering portion 5 that covers the auxiliary contact portion 4a formed of the adhesive portion so as not to be exposed to the outside. The covering portion 5 has a covering position (see FIGS. 7 to 10) that covers the auxiliary contact portion 4a, and the auxiliary contact portion 4a can contact the object to be measured 1 without covering the auxiliary contact portion 4a. It can be moved to the uncovered position (see FIGS. 11 and 12).

Further, the holding body 4 is rotatably supported by the main body 3 so as to be displaced with respect to the main body 3. Then, the holding body 4 moves to a position where the reference contact portion 3b is hidden (see FIGS. 7 to 10) and a position where the reference contact portion 3b is exposed (see FIGS. 11 and 12) due to the rotation thereof. To do.

Specifically, in the illustrated embodiment, the object to be measured 1 is made of a piping material. The object to be measured 1 (piping material) is piped laterally, and the upper portion thereof becomes the measured portion 1a. Then, the measuring unit 3a measures at least a horizontal state (horizontal state and gradient in the illustrated embodiment) as a state of the object to be measured 1 (specifically, the measured unit 1a).

The main body 3 includes a main body case 3c, a support 3d, and a bubble tube 301 serving as the measuring unit 3a. The main body case 3c is formed in a horizontally long shape having an inverted U-shaped cross section extending horizontally. That is, the main body case 3c has a top wall 3e and a side wall 3f so as to form an inverted U-shaped cross section, and further has an end wall 3g so as to close both ends in the extending lateral direction (horizontal direction). doing. Therefore, the lower end surface of the main body case 3c (in the illustrated embodiment, the lower end surface of the end wall 3g and the side wall 3f) becomes the reference contact portion 3b, and the reference contact portion 3b is the side wall 3f, 3f. It consists of a tapered surface that inclines so that the width becomes narrower toward the center of the space. Then, a window 3h is opened in the top wall 3e of the main body case 3c, and the bubble tube 301 is exposed from the window 3h. Further, both end walls 3g and 3g of the main body case 3c are provided with a pair of shaft holes 3i for axially supporting the movable wings 401, which will be described later, so as to correspond to the pair of movable wings 401 and 401.

The support 3d supports the bubble tube 301 from below, and is attached to the inside of the main body case 3c by a fixing tool 3j such as a screw. In this way, the bubble tube 301 (measurement unit 3a) is attached so as to be sandwiched between the support 3d and the peripheral edge of the window 3h of the main body case 3c, and the bubble tube 301 (measurement unit 3a) is integrally provided with the main body 3. Will be done. In the illustrated embodiment, the bubble tube 301 has three marked lines 3k and 3k on each side, and depending on the position of the bubble with respect to the marked line 3k, the bubble tube 301 and thus the reference contact portion 3b are in contact with each other. It can be determined whether the device to be measured 1a in contact is in a horizontal state, has a 1/100 gradient, or has a 2/100 gradient, for example.

The holding body 4 is composed of a pair of movable wings 401 and 401 rotatably supported by the main body 3, and the pair of movable wings 401 and 401 are brought close to each other and separated from each other by the rotation. Therefore, the auxiliary contact portion 4a is provided on each of the facing surfaces of the pair of movable blades 401 and 401. The auxiliary contact portions 4a provided on each of the pair of movable wings 401 and 401 are on the side where the auxiliary contact portions 4a are provided on each other when the pair of movable wings 401 and 401 are close to each other and overlap each other. It is covered with a movable wing 401 on a different side from the above. Therefore, these movable wings 401 and 401 serve as the covering portion 5, and the movable wings 401 and 401 are close to each other and overlap each other, separated from the covering position covering the auxiliary contact portion 4a, and separated from the auxiliary contact portion. The auxiliary contact portion 4a can move to an uncovered position where it can contact the object 1 to be measured without covering the 4a. Then, when the auxiliary contact portions 4a of the pair of movable wings 401 and 401 come into contact with the object to be measured 1, the pair of movable wings 401 and 401 hold the object 1 to be measured (specifically, the piping material) on both sides. It is located so as to sandwich it from.

Specifically, each of the pair of movable wings 401 and 401 serving as the holding body 4 includes a movable wing main body 4b and the auxiliary contact portion 4a. The auxiliary contact portion 4a is made of a pressure-sensitive adhesive 402 (a plate-shaped pressure-sensitive adhesive in the illustrated embodiment) having re-adhesiveness and re-peelability on both sides, and has cushioning properties. One surface of the adhesive body 402 is attached to the attachment surface 4c of the movable wing main body 4b by adhesive, and the other surface can be attached to the object to be measured 1. Further, when the pair of movable wings 401 and 401 overlap, the other surface of the adhesive body 402 comes into contact with the separation prevention surface 4d provided on the movable wing 401 that covers the other surface. At this time, the area of the mounting surface 4c and the separation prevention surface 4d in contact with the other surface of the adhesive body 402 of the separation prevention surface 4d is smaller than the area of the attachment surface 4c in contact with one surface of the adhesive body 402. It is provided so as to be.

More specifically, each movable wing body 4b includes a wing portion 4e formed in a horizontally long plate shape, and an arm portion 4f extending upward from both end portions in the lateral direction (horizontal direction) of the wing portion 4e. have. A shaft portion 4g is provided at the tip portion of the arm portion 4f, and by inserting the shaft portion 4g into the shaft hole 3i of the main body 3, the movable wing main body 4b (movable wing 401) becomes the main body. It is rotatably supported by 3.

Therefore, the mounting surface 4c and the separation prevention surface 4d are provided on each of the opposite inner surfaces of the wing portions 4e and 4e. Here, the mounting surface 4c is widely provided so as to be in contact with the entire one surface of the adhesive body 402, and the separation prevention surface 4d is narrowly provided so as to be in contact with a part of the other surface of the adhesive body 402. In the illustrated embodiment, the mounting surface 4c is provided so as to be slightly recessed on the inner surface of the wing portion 4e. In the separation prevention surface 4d, a recess 4h is provided on the inner surface of the wing portion 4e, and the tip surface of the rib formed in the recess 4h is the separation prevention surface 4d. Then, when the pair of movable wings 401 and 401 are close to each other and overlap each other, the adhesive body 402 is housed in the wing portion 4e (that is, in the movable wing main body 4b).

Then, when the pair of movable wings 401 and 401 are brought close to each other and overlap each other and the main body 3 is located between the arms 4f and 4f of the movable wings 401 (holding body 4), the reference contact portion 3b becomes. It is hidden by the wing portion 4e of the movable wing 401 (specifically, the upper surface of the wing portion 4e). Then, when the pair of movable wings 401 and 401 are separated from each other, the reference contact portion 3b is exposed. In this way, the movable wing 401 (holding body 4) moves to a position where the reference contact portion 3b is hidden and a position where the reference contact portion 3b is exposed by its rotation.

Further, in the measuring device 2, both movable wings 401 and 401 are symmetrical with respect to the main body 3 between the main body 3, one of the pair of movable wings 401 and 401, and the other of the pair of movable wings 401 and 401. It is provided with an interlocking mechanism 6 that approaches and separates from. In the illustrated embodiment, the interlocking mechanism 6 has a shaft hole 3i and a shaft portion 4g for rotatably supporting the movable wing 401 to the main body 3, and a movable wing main body 4b (centered on the shaft portion 4g). It is composed of a gear portion 6a provided integrally with the movable wing 401). Therefore, the gear portions 6a and 6a of the two movable wings 401 and 401 mesh with each other and rotate about the shaft hole 3i, respectively, so that the two movable wings 401 and 401 are symmetrically approached and separated from each other with respect to the main body 3. To do.

By the way, FIGS. 1 to 3 show a case where the object to be measured 1 is a piping material having a large diameter, and FIGS. 1 and 2 show a state in which the reference contact portion 3b is in contact with the measurement portion 1a. , The auxiliary contact portion 4a is in contact with the object to be measured 1. In FIG. 3, the auxiliary contact portion 4a is from the object to be measured 1 with the reference contact portion 3b in contact with the object to be measured 1a. It is in a distant position. 4 to 6 show a case where the object 1 to be measured is a piping material having a small diameter, and FIGS. 4 and 5 show a state in which the reference contact portion 3b is in contact with the measurement portion 1a. The auxiliary contact portion 4a is in contact with the object to be measured 1, and FIG. 6 shows that the auxiliary contact portion 4a is separated from the object to be measured 1 while the reference contact portion 3b is in contact with the object to be measured 1a. Is in the right position. As described above, in the measuring device 2, the holding body 4 is composed of a pair of movable wings 401 and 401, and the pair of movable wings 401 and 401 are separated from each other at an arbitrary angle. It can be applied to piping materials with multiple types of diameters.

Next, the operation and effect of the measuring device 2 having the above configuration will be described. The measuring device 2 holds the posture of the main body 3 provided with the measuring unit 3a in addition to the reference contacting portion 3b that abuts on the measured unit 1a to be measured by the measuring object 1. It is provided with an auxiliary contact portion 4a that comes into contact with 1. By providing the auxiliary contact portion 4a in this way, the posture of the main body 3 (that is, the posture of the measurement unit 3a) can be maintained, and the auxiliary contact portion 4a can be used as the reference contact portion 3b. By providing it separately from the above, it is possible to eliminate the deviation of the posture of the main body 3 due to the adhesion of foreign matter such as dust to the reference contact portion 3b, and to accurately measure the predetermined state of the object to be measured 1. That is, according to the measuring device 2, by providing the auxiliary contact portion 4a separately from the reference contact portion 3b, it is possible not only to maintain the posture of the main body 3 provided with the measuring unit 3a but also to measure. The predetermined state of the object 1 can be accurately measured.

Further, since the auxiliary contact portion 4a is composed of an adhesive portion (adhesive body 402 in the illustrated embodiment) that can adhere to the object to be measured 1, the measuring device may be shaken during gradient adjustment or for other reasons. It is possible to prevent the 2 from deviating from or falling from the object to be measured 1.

Further, the measuring device 2 includes a covering portion 5 (movable wing 401 in the illustrated embodiment) that covers the auxiliary contact portion 4a composed of the adhesive portion (specifically, the adhesive body 402) so as not to be exposed to the outside. ing. Therefore, when the measuring device 2 is not used, the auxiliary contact portion 4a can be protected from foreign matter such as dust and dirt by covering the auxiliary contact portion 4a with the covering portion 5.

Further, the holding body 4 (movable wing 401 in the illustrated embodiment) moves to a position where the reference contact portion 3b is hidden and a position where the reference contact portion 3b is exposed by rotation. Therefore, when the measuring device 2 is not used, the reference contact portion 3b can be protected by hiding the reference contact portion 3b with the holding body 4.

Further, when the pair of movable wings 401 and 401 overlap, the other surface of the adhesive body 402 comes into contact with the separation prevention surface 4d provided on the movable wings 401 covering the other surface, whereby the pair of movable wings Separation of 401 and 401 from each other is prevented. The area of the movable wing 401 in contact with the other surface of the adhesive body 402 of the attachment surface 4c is smaller than the area of the movable wing 401 in contact with the other surface of the adhesive body 402, so that the pair of movable wings 401 , 401 are separated from each other, one surface of the adhesive body 402 remains attached to the mounting surface 4c of the movable wing 401, and the other surface of the adhesive body 402 and the separation prevention surface 4d are separated from each other.

The present invention is not limited to the above-described embodiment, and various other modifications can be made. For example, as shown in FIGS. 20 and 21, the main body 3 may include a measuring member 3m having a measuring unit 3a and a base 3n having a reference contacting portion 3b. Here, the base 3n has an installation portion 3p on which the measuring member 3m is installed. Then, the holding body 4 is provided so as to be displaceable with respect to the base 3n in the main body 3.

In this way, in the measuring device 2, the main body 3 is provided separately from the measuring member 3m and the base 3n, and the base 3n in the main body 3 and the holding body 4 form a pedestal 7 for the measuring member. It is formed. That is, the pedestal 7 for the measuring member is a pedestal for fastening the measuring member 3m having the measuring unit 3a for measuring the state of the object to be measured 1 to the object to be measured 1, and the base 3n and the holding body 4 are attached to each other. Be prepared. Here, the base 3n determines the posture of the base 3n itself (that is, the posture of the main body 3 and the posture of the measurement unit 3a) with the installation portion 3p on which the measuring member 3m is installed. It is provided with a reference contact portion 3b that abuts the measured portion 1a to be measured. Then, the holding body 4 is provided so as to be displaceable with respect to the base 3n (that is, displaceable with respect to the main body 3), and the holding body 4 is in the posture of the base 3n (that is, the main body 3). An auxiliary contact portion 4a (not shown) that abuts the object to be measured 1 so as to hold the posture, and thus the posture of the measurement unit 3a (measurement member 3m), is provided.

In the illustrated embodiment, similarly to the above-described embodiment, the measuring unit 3a includes a bubble tube 301 for measuring at least the horizontal state of the object 1 to be measured (specifically, the piping material). The measuring member 3m has a body 3q formed in a horizontally long rectangular parallelepiped shape, and a bubble tube 301 is fitted in a recess 3r provided at the upper center position of the body 3q. The base 3n is formed in a horizontally long rectangular parallelepiped shape, the upper surface thereof serves as the installation portion 3p, and the lower surface thereof serves as the reference contact portion 3b. Here, in installing the measuring member 3m on the mounting portion 3p of the base 3n, for example, a double-sided adhesive tape or a magnet is used, or a claw or the like that engages with the measuring member 3m is provided on the base 3n. Or something. Further, shaft holes (not shown) are provided at both left and right ends of the base 3n as in the main body 3 in the above-described embodiment. Then, the holding body 4 is composed of a pair of movable wings 401 and 401 and is pivotally supported in the shaft hole provided in the base 3n, as in the above-described embodiment. That is, each of the pair of movable wings 401 and 401 is provided with a shaft portion to be inserted into the shaft hole, and for example, as in the above-described embodiment, the auxiliary contact portion 4a (not shown). ) Is composed of an adhesive body (adhesive portion), and a mounting surface or a separation prevention surface is provided for the adhesive body.

The measuring member pedestal 7 holds the posture of the base 3n on which the measuring member 3m is installed, in addition to the reference contacting portion 3b that abuts the measured object 1a to be measured. An auxiliary contact portion 4a that comes into contact with the object to be measured 1 is provided. By providing the auxiliary contact portion 4a in this way, the posture of the base 3n and eventually the measuring member 3m (that is, the posture of the measuring unit 3a) can be maintained, and the auxiliary contact portion 4a can be held. By providing the reference contact portion 3b separately from the reference contact portion 3b, it is possible to eliminate the deviation of the posture of the measuring member 3m due to the adhesion of foreign matter such as dust to the reference contact portion 3b, and to accurately obtain the predetermined state of the object to be measured 1. Can be measured. That is, according to the measurement member pedestal 7, by providing the auxiliary contact portion 4a separately from the reference contact portion 3b, it is possible not only to maintain the posture of the base 3n and thus the measurement member 3m. The predetermined state of the object to be measured 1 can be accurately measured.

Further, as shown in FIGS. 22 and 23, the main body 3 may include a spirit level 3s and a mounting body 3t. Here, the spirit level 3s includes a measuring unit 3a for measuring the state of the object 1 to be measured (specifically, a measuring unit for measuring at least a horizontal state, and in the illustrated embodiment, a bubble tube 301) and a level. A reference contact portion 3b that abuts on the measured portion 1a to be measured of the measured object 1 is provided so as to determine the posture of the instrument 3s itself (and thus the posture of the measuring unit 3a). Then, the attachment body 3t is attached and fixed to the spirit level 3s. Therefore, the holding body 4 is provided so as to be displaceable with respect to the mounting body 3t in the main body 3.

In this way, in the measuring device 2, the main body 3 is provided separately from the spirit level 3s and the mounting body 3t, and the spirit level mounting tool 8 is provided by the mounting body 3t and the holding body 4 in the main body 3. It is formed. That is, the spirit level mounting tool 8 is a mounting tool for mounting the spirit level 3s on the object to be measured 1, and is mounted and fixed to the spirit level 3s (specifically, the mounting body 3t is detachably mounted and fixed). And the holding body 4. Therefore, the holding body 4 is provided so as to be displaceable with respect to the mounting body 3t (that is, displaceable with respect to the main body 3), and the holding body 4 is provided with the posture of the mounting body 3t (that is, the main body 3). An auxiliary contact portion 4a (not shown) that abuts the object to be measured 1 so as to hold the posture, and thus the posture of the measurement unit 3a (level 3s), is provided.

In the illustrated embodiment, the spirit level 3s has a horizontally long rectangular parallelepiped body 3u, and the bubble tube 301 is fitted in a recess 3v provided at the upper center position of the body 3u. Then, the lower surface of the body 3u becomes the reference contact portion 3b. A pair of spirit levels 8 are provided for the spirit level 3s, and each spirit level 8 is attached to the left and right ends of the spirit level 3s. Here, the mounting body 3t is formed in a U shape. Therefore, the attachment body 3t is attached to the body 3u (that is, the spirit level 3s) by sandwiching the body 3u of the spirit level 3s so as to straddle the body 3u. In this mounting body 3t, bearing portions 3w are formed so as to protrude from both U-shaped tips, and shaft holes (not shown) are provided on both sides of the bearing portions 3w. Similar to the above-described embodiment, the holding body 4 is composed of a pair of movable wings 401 and 401, and is pivotally supported by the shaft hole provided in the mounting body 3t (specifically, the bearing portion 3w). That is, each of the pair of movable wings 401 and 401 is provided with a shaft portion to be inserted into the shaft hole, and for example, as in the above-described embodiment, the auxiliary contact portion 4a (not shown). ) Consists of an adhesive body (adhesive part).

In the spirit level attachment 8, the spirit level 3s includes a reference contact portion 3b that abuts on the measurement target portion 1a of the object 1 to be measured, and the spirit level attachment 8 includes the spirit level 3s. An auxiliary contact portion 4a that comes into contact with the object to be measured 1 is provided so as to maintain the posture of the attachment body 3t that is attached and fixed to the object. By providing the auxiliary contact portion 4a in this way, the posture of the mounting body 3t and eventually the spirit level 3s (that is, the posture of the measuring unit 3a) can be maintained, and the auxiliary contact portion 4a can be held. By providing the reference contact portion 3b separately from the reference contact portion 3b, it is possible to eliminate the deviation of the posture of the spirit level 3s due to the adhesion of foreign matter such as dust to the reference contact portion 3b, and to accurately obtain the predetermined state of the object 1 to be measured. Can be measured. That is, according to the spirit level attachment 8, the auxiliary contact portion 4a is provided separately from the reference contact portion 3b provided in the spirit level 3s to maintain the posture of the attachment body 3t and thus the spirit level 3s. Not only can this be done, but at least the horizontal state of the object 1 to be measured can be accurately measured.

Further, the measuring unit 3a measures at least a horizontal state as the state of the object 1 to be measured, but in general, it may measure an angle such as horizontal, vertical, or 45 degrees, and as a measuring means thereof. Is not limited to the bubble tube 301, and may be one using a laser or the like. Further, the measuring unit 3a may measure not only the angle but also the length, vibration, temperature and the like.

Further, the object to be measured 1 is not limited to the piping material, and may be a bar material, a plate material, or other material.

Further, the measuring device 2 includes an interlocking mechanism 6 in which both movable wings 401 and 401 are symmetrically approached and separated from each other with respect to the main body 3, but the interlocking mechanism 6 may not be provided. This also applies to the pedestal 7 for measuring members and the spirit level attachment 8, and both movable wings 401 and 401 are provided with an interlocking mechanism 6 that is symmetrically approached and separated from the base 3n or the attachment 3t. It may or may not be provided.

Further, even if the holding body 4 does not consist of a pair of movable wings 401 and 401, one becomes a movable wing 401 as the holding body 4, and the other is a fixed wing fixed to the main body 3 instead of the movable wing 401. You may become.

Further, the holding body 4 may be slidably supported by the main body 3 without being rotatably supported by the main body 3. For example, the holding body 4 provided with the auxiliary contact portion 4a at the tip slides in the direction of projecting from the main body 3 so as to come into contact with the object to be measured 1, or refrains from the direction opposite to the projecting direction so as to move away from the object to be measured 1. You may slide in the direction.

Further, the movable wing 401 also functions as a covering portion 5, but the covering portion 5 may be provided separately from the movable wing 401. Further, the covering portion 5 may not be provided.

Further, the auxiliary contact portion 4a is composed of an adhesive portion (adhesive body 402 in the illustrated embodiment) that can be adhered to the object to be measured 1, but the auxiliary contact portion 4a is held without sticking. The body 4 may sandwich the object 1 to be measured.

Further, in the spirit level attachment 8, the attachment body 3t is attached to the left and right end sides of the spirit level 3s, but may be attached to both left and right end surfaces of the spirit level 3s. Then, when attaching the attachment body 3t to the spirit level 3s, it may be attached using a fixing tool such as a screw or a set screw, or may be attached by sticking.

1 Measured object 1a Measured part 2 Measuring device 3 Main body 3a Measuring part 3b Reference contact part 3m Measuring member 3n Base 3p Installation part 3s Level 3t Mounting body 4 Holding body 401 Movable wing 402 Adhesive body 4a Auxiliary contact part 4b Movable wing body 4c Mounting surface 4d Separation prevention surface 5 Covering part 6 Interlocking mechanism 7 Measuring member pedestal 8 Level mounting tool

Claims (15)

A measuring device for measuring a predetermined state of an object to be measured.
Equipped with a main body and a holding body,
The main body includes a measuring unit that measures the state of the object to be measured, and a reference contact portion that contacts the measured unit to be measured of the object to be measured so as to determine the posture of the main body itself.
The holding body is provided so as to be displaceable with respect to the main body, and the holding body is provided with an auxiliary contact portion that comes into contact with the object to be measured so as to hold the posture of the main body. The holding body is displaced with respect to the main body so that the reference contact portion is in contact with the measured portion, and the auxiliary contact portion is separated from the measured object and the measured portion is measured. The measuring device according to claim 1, wherein the measuring device moves between the position where the object comes into contact with the object. The measuring device according to claim 1 or 2, wherein the auxiliary contact portion is an adhesive portion that has re-adhesiveness and re-peelability and can adhere to the object to be measured. A covering portion for covering the auxiliary contact portion formed of the adhesive portion so as not to be exposed to the outside is provided.
The covering portion can be moved to a covering position that covers the auxiliary contact portion and a non-covering position that allows the auxiliary contact portion to come into contact with the object to be measured without covering the auxiliary contact portion. The measuring device according to claim 3. The measuring device according to any one of claims 1 to 3, wherein the holding body is rotatably supported by the main body so as to be displaced with respect to the main body. The measuring device according to claim 5, wherein the holding body moves to a position where the reference contact portion is hidden and a position where the reference contact portion is exposed by the rotation. The holding body is composed of a pair of movable wings rotatably supported by the main body, and the rotation causes the pair of movable wings to approach and separate from each other.
The measuring device according to claim 5 or 6, wherein the auxiliary contact portion is provided on each of the facing surfaces of the pair of movable wings. The auxiliary contact portions provided on each of the pair of movable wings are movable wings on a side different from the side on which the auxiliary contact portions are provided because the pair of movable wings approach each other and overlap each other. The measuring device according to claim 7, which is covered. Each of the pair of movable wings includes a movable wing body and the auxiliary contact portion.
The auxiliary contact portion is made of an adhesive body having re-adhesiveness and re-peelability on both sides.
One surface of the adhesive body is attached to the attachment surface of the movable wing body by adhesive, and the other surface can be attached to the object to be measured.
When the pair of movable wings overlap, the other surface of the adhesive body comes into contact with a separation prevention surface provided on the movable wings that covers the other surface.
The measuring device according to claim 8, wherein the area of the attachment surface in contact with the other surface of the adhesive body is smaller than the area of the attachment surface in contact with one surface of the adhesive body. Claims 7 to 9 include an interlocking mechanism in which both movable wings are symmetrically approached and separated from each other with respect to the main body, between the main body, one of the pair of movable wings, and the other of the pair of movable wings. The measuring device according to any one of the above items. The measuring device according to any one of claims 1 to 10, wherein the measuring unit is integrally provided on the main body. The main body includes a measuring member having the measuring portion and a base having the reference contact portion.
The base has an installation portion on which the measuring member is installed.
The measuring device according to any one of claims 1 to 10, wherein the holding body is provided so as to be displaceable with respect to the base in the main body. The measuring device according to any one of claims 1 to 12, wherein the measuring unit measures at least a horizontal state of the object to be measured. A pedestal for a measuring member for fastening a measuring member having a measuring unit for measuring the state of the object to be measured to the object to be measured.
With a base and a retainer,
The base includes an installation portion on which the measuring member is installed and a reference contact portion that abuts on the measured portion to be measured of the object to be measured so as to determine the posture of the base itself.
The holding body is provided so as to be displaceable with respect to the base, and the holding body is provided with an auxiliary contact portion that comes into contact with the object to be measured so as to hold the posture of the base. Pedestal. A spirit level fixture for attaching a spirit level to an object to be measured.
The level has a measuring unit that measures at least the horizontal state of the object to be measured and a reference contacting portion that contacts the measured unit to be measured so as to determine the posture of the spirit level itself. Prepare,
The spirit level fitting includes a mounting body that is mounted and fixed to the spirit level, and a holding body.
The holding body is provided so as to be displaceable with respect to the mounting body, and the holding body includes an auxiliary contact portion that contacts the object to be measured so as to hold the posture of the mounting body. Fixture.

Images