JP5956795B2 - Rotating tool - Google Patents

Description

  The present invention relates to a rotary tool that rotates a nut that is screwed into a threaded portion.

  Patent Document 1 relates to a mounting structure for walls and the like, a panel unit in which a wall and a wall mounting portion are integrated, a rail-like support member that is fixed to a housing and attaches a lower portion of the panel unit, and a housing for the support member The structure provided with the height adjustment mechanism which adjusts the height from is disclosed. In Patent Document 1, the height adjusting mechanism includes an anchor having a threaded portion and a plurality of nuts screwed to the threaded portion, and adjusting the positional relationship between the anchor and the nut, thereby providing a panel for the housing. The height of the unit can be adjusted.

  The nut used as a part of the height adjusting mechanism described above also has a function as a spacer provided between the panel unit and the support member. Therefore, this type of nut is also referred to as a nut spacer. Moreover, since this kind of nut supports the weight of a panel unit, it is preferable that the area of the contact surface with a panel unit and a supporting member is large. Therefore, this type of nut is not limited to a hexagonal nut, and a nut having a wide contact area such as a plate-like square is used.

JP 2008-150821 A

  By the way, when using nuts other than a hexagon nut, the general purpose tool for rotating this nut does not exist at present. Therefore, this type of nut is manually attached to and detached from the support member. However, in general, since the threaded portion of the anchor is long and the number of nuts to be constructed is large, there is a problem that the nuts cannot be efficiently attached and detached.

  The objective of this invention is providing the rotary tool which can attach or detach various nuts efficiently to a thread part.

That is, the rotary tool according to the present invention is a rotary tool that rotates a nut screwed to a screw portion with respect to the screw portion , has a hole portion through which the screw portion is inserted , and rotates around the screw portion. The base and the base are provided, projecting in the direction of the rotation axis at a position away from the hole in the radial direction, contacting the side surface of the nut with the screw part inserted through the hole , and rotating the nut's rotation shaft includes a projecting portion for pressing the side surface of the nut in the circumferential direction of rotation when the center and the rotational force is applied, and a power transmission unit for transmitting the rotational force supplied from an external power source to the base, the hole portion The inner wall is formed with a chevron that has an upward slope and a downward slope along the circumferential direction and that can be engaged with a hexagon nut .

According to the present invention, the power transmission unit transmits the rotational force to the projection through the base from a power source such as an impact driver, and at this time, the projection presses the side surface of the nut, so that the nut is against the screw unit. Rotate. Therefore, it is possible to easily rotate the nut using an external power source. The target nut is not limited to a hexagon nut, and various nuts can be rotated as long as they have side surfaces such as an ellipse or a hexagon. Therefore, various nuts can be efficiently attached to and detached from the screw portion. Moreover, since the rotary tool which concerns on this invention has a hole part which a thread part penetrates, it becomes possible to engage a thread part stably and to rotate a nut in the stable state. Therefore, it is possible to easily attach and detach the nut, and the workability can be further improved.

  In the rotary tool according to the present invention, it is preferable that at least two protrusions are provided symmetrically with respect to the rotation axis. According to the present invention, since the rotational force is transmitted with the two protrusions hooked on the nut, the rotational force can be transmitted to the nut in a stable state. Therefore, the attaching / detaching operation of the nut to the threaded portion can be performed efficiently, and workability can be improved.

  Moreover, the rotary tool which concerns on this invention WHEREIN: It is preferable that a power transmission part is a connector part which can attach or detach a power source. According to this invention, the rotational force of the external power source can be reliably transmitted to the nut via the power transmission portion and the protrusion.

Further, in the rotary tool according to the present invention, the rotary tool includes a socket portion that extends from the base portion in the axial direction of the rotary shaft and has a hollow portion for inserting the screw portion inserted through the hole portion , and the connector portion is provided on the socket portion. It may be provided. According to this invention, the rotary tool can be used in a state where the socket portion is covered with the screw portion. Further, since the connector portion is provided in the socket portion, the entire rotary tool can be attached and detached from the nut and screw portion in a state where an external power source is connected to the connector portion. In other words, the rotary tool can be used integrally with a power source such as an impact driver. Therefore, the nut can be efficiently rotated, and workability can be further improved.

  According to the present invention, various nuts can be efficiently attached to and detached from the screw portion.

It is the schematic which shows the example of the construction work performed using the rotary tool which concerns on this embodiment. It is a figure for demonstrating the anchor used by the construction work of FIG. It is a perspective view of the anchor used by the construction work of FIG. It is a perspective view of the rotary tool which concerns on 1st Embodiment. It is a bottom view of the rotary tool which concerns on 1st Embodiment. It is a bottom view in the state where the rotary tool concerning a 1st embodiment was attached to the nut. It is a perspective view in the state where the rotary tool concerning a 1st embodiment was attached to the nut. It is a perspective view of the rotary tool which concerns on 2nd Embodiment. It is a perspective view of the rotary tool which concerns on 3rd Embodiment. It is a perspective view which shows the modification of the rotary tool which concerns on this invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, the same code | symbol is used for the same element or the same equivalent element, and the overlapping description is abbreviate | omitted. FIG. 1 is a diagram for explaining an example of construction work using an anchor 100 that is a target using a rotary tool according to the present embodiment, and a lower structure of a wall panel K (see FIG. 2B). Indicates. Specifically, a structure in which the support member 110 that supports the wall panel K is fixed to a housing 120 such as a slab concrete floor is shown. The wall panel K is, for example, an ALC panel. As shown in FIG. 1, the support member 110 is a rail member having an L-shaped cross section that extends in the longitudinal direction and has a horizontal surface and a vertical surface. The support member 110 is provided with holes 111 for each pitch P in the longitudinal direction. The hole 111 is for inserting the screw portion 102 of the anchor 100. The support member 110 and the housing 120 are connected by an anchor 100 having one end embedded in the housing 120 and the other end formed with a screw portion 102. The space S1 between the support member 110 and the housing 120 is filled with mortar and sealing. Thereby, waterproofness and heat insulation are ensured. Further, the value of the pitch P can be set to 50 mm, for example.

  A plurality of nuts are screwed into the screw portion 102. Specifically, as shown in FIGS. 2 and 3, a nut 104 that is a hex nut for fixing to the housing 120, a nut 103 that is a hex nut that supports the lower portion of the support member 110, and an upper portion of the support member 110. Three nuts 101, which are disposed, are screwed into the screw portion 102. The support member 110 and the anchor 100 are fixed by sandwiching the top and bottom of the support member 110 between the nut 101 and the nut 103 in a state where the screw portion 102 is passed through the hole portion 111. A washer 105 is provided between the nut 104 and the housing 120, and a washer 106 is provided between the nut 103 and the support member 110.

  Below, construction work at the time of attachment of wall panel K is explained briefly. First, the embedded portion 107 (see FIG. 3) of the anchor 100 is embedded in the housing 120. At this time, the screw portion 102 protrudes upward from the housing 120. A washer 105, a nut 104, a nut 103, and a washer 106 are inserted or screwed into the screw portion 102. Here, the washer 105 and the nut 104 are positioned at the lower end of the screw portion 102, and the nut 103 is appropriately rotated with respect to the rotation axis A to determine the position of the nut 103 with respect to the screw portion 102. Adjust the position. Then, the nut 101 is screwed into the screw portion 102 protruding upward from the hole portion 111. Thereby, the nut 101 comes to a position opposite to the nut 103 with the support member 110 interposed therebetween. Next, as shown in part (b) of FIG. 2, the wall panel K is placed on the horizontal surface of the support member 110 via the nut 101. And the wall panel K and the support member 110 are fixed by fixing the side surface of the wall panel K using an Inazuma plate, a bolt set, etc. Thereafter, the space S1 is appropriately filled with mortar and sealing, and the construction work of the wall panel K is completed.

  In the construction of the wall panel K, a space S <b> 2 is formed between the wall panel K and the support member 110 by disposing the nut 101 on the support member 110. That is, when the wall panel K is placed on the support member 110, the nut 101 functions as a spacer. Thus, by interposing the nut 101 between the wall panel K and the support member 110 as a spacer, the wall panel K can be stabilized on the support member 110, and cracking of the wall panel K can be prevented. Further, since the nut 101 also has a function of supporting the weight of the wall panel K, it is preferable that the area of the contact surface between the nut 101 and the wall panel K and the support member 110 is wide. For this reason, the nut 101 is not limited to a hexagon nut, and for example, a square nut 101 having a side length L as shown in FIG. 3 is used. Note that a hole 101 a for screwing the screw portion 102 is provided at the center of the nut 101.

  By the way, when a nut other than a hexagonal nut such as the nut 101 is used, there is no general-purpose tool for rotating the nut. Therefore, the operation of rotating the nut with respect to the screw portion has been performed manually. However, in general, the threaded part is long and the number of nuts to be installed is large, and unlike conventional hex nuts, it may not be able to rotate smoothly. There was a problem of requiring labor for construction work.

  Therefore, in this embodiment, a rotary tool that can efficiently attach and detach the nut 101 to and from the screw portion 102 will be described. Below, the rotary tool which concerns on 1st-3rd embodiment is demonstrated. For convenience of explanation, as shown in FIG. 3, the direction in which the screw portion 102 is provided with respect to the embedded portion 107 will be described as an upward direction, and the opposite direction will be described as a downward direction.

(First embodiment)
The rotary tool 1 according to the first embodiment will be described with reference to FIGS. The rotary tool 1 is a tool used at the time of placing the anchor 100 on the support member 110, for example. 4 is a perspective view of the rotary tool 1, FIG. 5 is a bottom view of the rotary tool 1, FIG. 6 is a bottom view of a state where the nut 101 is rotated using the rotary tool 1, and FIG. The perspective view of the state which rotates is shown, respectively.

  As shown in FIG. 4, the rotary tool 1 includes a flat plate member 2 that is formed in a substantially rectangular parallelepiped shape, two screws 3 that are screwed into the flat plate member 2, and an upper surface of the flat plate member 2. And a power transmission unit 4 formed at the center.

  The flat plate member 2 has a hole portion 2 a through which the screw portion 102 is inserted, and functions as a base portion that rotates around the screw portion 102. As shown in FIG. 5, the flat plate member 2 has a hole 2 a in a substantially central portion. The shape of the hole 2a is, for example, a circular shape penetrating vertically. The diameter of the hole 2 a is larger than the diameter of the screw portion 102. Specifically, the diameter of the hole 2a is slightly larger than the diameter of the screw part 102, and the difference between the inner diameter of the hole 2a and the outer diameter of the screw part 102 is, for example, about 1 mm.

  Further, the flat plate member 2 has two holes 2 c for screwing the screws 3. Each hole 2c is formed to penetrate vertically. The two holes 2 c are symmetrical with respect to the rotation axis A and are provided on the same diagonal line of the flat plate member 2. As shown in FIGS. 5 and 6, the distance between the two holes 2c is L1, and the relationship between the length L of one side of the nut 101 and the distance L1 between the holes 2c is L <L1 ≦ √2L.

  As shown in FIG. 4, the screw 3 includes a screwing portion 3 a that is formed to extend vertically and a washer 3 b. The screwing portion 3a of the screw 3 projects downward from the flat plate member 2 and functions as a protruding portion. Further, the screw 3 is fixed to the flat plate member 2 by inserting and rotating the screwing portion 3a from the upper portion of the hole portion 2c. Further, the washer 3 b is provided to contact the upper surface of the flat plate member 2 when the screw 3 is fixed to the flat plate member 2.

  The power transmission part 4 is formed in the hexagonal column shape provided with the hole 4a penetrated up and down, for example. As the power transmission unit 4, for example, a hexagon nut welded to the upper surface of the flat plate member 2 can be used. The power transmission unit 4 is detachable from a power source such as an impact driver. That is, the power transmission unit 4 functions as a connector unit. The power transmission unit 4 receives a rotational force from the mounted power source, whereby the rotary tool 1 rotates around the rotation axis A. Specifically, for example, a commercially available interface formed in a hexagonal column concave shape of an impact driver is fitted to the power transmission unit 4 to operate the impact driver, whereby the rotary tool 1 rotates with respect to the rotation axis A. The shape of the power transmission unit 4 does not have to be a hexagonal column shape, and may be a different shape as long as it can receive a rotational force from an external power source and transmit the rotational force to the screw 3. Further, for example, the power transmission unit 4 and the flat plate member 2 may be provided with an attachment / detachment mechanism so that the power transmission unit 4 can be attached to and detached from the flat plate member 2.

  The hole 4a is formed in the upper part of the hole 2a so as to communicate with the hole 2a. The diameter of the hole 4a is slightly larger than the diameter of the screw portion 102, and the difference between the inner diameter of the hole 4a and the outer diameter of the screw portion 102 is, for example, about 1 mm. Therefore, the screw part 102 can be inserted into the hole 4a without being screwed. Moreover, when a hexagon nut is used as the power transmission part 4, for example, a screw groove is formed in the inner peripheral part of the hole 4a as shown in FIG. However, it is not necessary to form a screw groove in the inner peripheral portion of the hole 4a, and the shape of the hole 4a may be any shape as long as the screw portion 102 can be inserted.

  A method of rotating the nut 101 with respect to the screw portion 102 using the rotary tool 1 configured as described above will be described. First, the nut 101 is screwed onto the upper end of the screw portion 102. Then, as shown in FIG. 7, the rotary tool 1 is installed on the nut 101 in a state where the screw portion 102 is inserted into the hole 2 a of the flat plate member 2 and the hole 4 a of the power transmission unit 4. Then, since the relationship between the length L of one side of the nut 101 and the distance L1 between the holes 2c is L <L1 ≦ √2L, as shown in FIG. 6 and FIG. 3a contacts side surface 101s of nut 101 so that nut 101 may be inserted. In this state, when a power source is mounted on the power transmission unit 4 from above and the power source is operated, the rotational force F is supplied to the power transmission unit 4, and the power transmission unit 4 applies the rotational force F to the flat plate member 2. Then, the nut 101 rotates together with the rotary tool 1 around the rotation axis A when the screwing portion 3 a presses the side surface 101 s of the nut 101. At this time, since the diameter of the hole 2a of the flat plate member and the diameter of the hole 4a of the power transmission part 4 are slightly larger than the diameter of the screw part 102, the hole 2a and the hole part 4a slide on the screw part 102. . Thus, the nut 101 can be rotated with respect to the screw portion 102 by using the rotational force F of the external power source.

  As described above, according to the first embodiment, the rotary tool 1 rotates the nut 101 screwed to the screw portion 102 with respect to the screw portion 102, and the hole 2 a that engages the screw portion 102. A flat plate member 2 that rotates around the screw portion 102, and is provided on the flat plate member 2 and protrudes in the direction of the rotation axis at a position away from the hole portion 2a in the rotation radial direction. Is engaged with the side surface 101 s of the nut 101, and when a rotational force F about the rotation axis A of the nut 101 is applied, the threaded portion 3 a that presses the side surface 101 s of the nut 101 in the rotational circumferential direction. And a power transmission unit 4 that transmits a rotational force F supplied from an external power source to the flat plate member 2. Therefore, when the rotational force F is applied to the power transmission unit 4 in a state where the screw portion 102 is inserted into (engaged with) the hole portion 2a, the screwing portion 3a functioning as a projection portion presses the side surface 101s of the nut 101. Therefore, the nut 101 can be rotated with respect to the screw portion 102 by using the rotational force F. Therefore, the nut 101 can be attached and detached efficiently without hurting the hand. In addition, the target nut is not limited to a hexagon nut, and any nut having a side surface such as a square nut 101 or an ellipse or a hexagon may be used, so that various nuts can be rotated. In addition, when the rotational force in the direction opposite to the rotational force F is applied in a state where the screw portion 102 is engaged with the hole portion 2a, the nut 101 can be removed from the screw portion 102.

  In addition, according to the rotary tool 1 according to the first embodiment, two screwing portions 3 a that function as protrusions are provided symmetrically with respect to the rotation axis A. Therefore, since it becomes possible to transmit a rotational force in the state which hooked the two screwing parts 3a on the nut 101, a rotational force can be provided in the stable state. Therefore, it is easy to attach and detach various nuts to and from the screw portion 102, so that workability can be improved and labor during construction can be reduced.

  Moreover, according to the rotary tool 1 which concerns on 1st Embodiment, the hole 2a which penetrates the screw part 102 functions as an engaging part. Therefore, the screw portion 102 can be stably engaged, and the nut 101 can be rotated in a stable state. Therefore, the nut 101 can be attached and detached more easily, and workability can be further improved.

  Moreover, according to the rotary tool 1 which concerns on 1st Embodiment, the power transmission part 4 functions as a connector part which can attach or detach an external power source. Therefore, the rotational force of an impact driver or the like can be reliably transmitted to the nut 101 via the power transmission unit 4. Therefore, the attaching / detaching work of the nut 101 can be easily performed, and the workability can be further improved.

  Moreover, according to the rotary tool 1 which concerns on 1st Embodiment, the power transmission part 4 is a hexagon nut fixed to the base. Therefore, an impact driver etc. can be easily connected to the power transmission part 4 only by inserting the interface for turning the existing hexagon nuts, such as a hexagonal column-shaped recessed part, in a connector part.

  Further, according to the rotary tool 1 according to the first embodiment, the screw 3 is detachable from the flat plate member 2. Therefore, for example, when the screw 3 is broken, it can be replaced with a new screw 3.

(Second Embodiment)
Next, a second embodiment of the present invention will be described with reference to FIG. FIG. 8 is a perspective view of the rotary tool 21 according to the second embodiment. In the second embodiment, the rotary tool 21 is formed in a substantially rectangular parallelepiped shape, and has a flat plate member 22 having a hole portion 22a that opens up and down, and four protrusions 23 that protrude downward from the flat plate member 22. A substantially cylindrical socket portion 25 that extends upward from the upper surface of the flat plate member 22 and a power transmission portion 26 provided at the upper end portion of the socket portion 25 are configured.

  Similar to the flat plate member 2 of the first embodiment, the flat plate member 22 has a hole portion 22 a that engages the screw portion 102 and functions as a base portion that rotates around the screw portion 102. On the inner wall of the hole 22a, for example, 12 mountain-shaped portions having an upward slope and a downward slope are formed along the circumferential direction. Therefore, a hexagonal nut such as a nut 103 or a nut 104 can be engaged with the inner wall of the hole 22a. The rotary tool 21 according to the second embodiment is configured so that the nut 103 and the nut 104 are also located with respect to the screw portion 102. It can be rotated.

  Four protrusions 23 are provided symmetrically with respect to the rotation axis A. The protruding portion 23 is formed to protrude downward from the lower surface of the flat plate member 22. The protrusion 23 is formed in a columnar shape, for example. Further, the distance between the two protrusions 23 located on the same diagonal line of the flat plate member 22 is L1 as in the distance between the hole portions 2a of the first embodiment. The relationship between the length L of one side of the nut 101 and the distance L1 between the two protrusions 23 located on the same diagonal of the flat plate member 22 is L <L1 ≦ √2L.

  The socket part 25 is formed in a cylindrical shape extending in the axial direction of the rotation axis A. The lower end portion of the socket portion 25 is welded to, for example, the upper surface of the flat plate member 22. The hollow portion of the socket portion 25 communicates with the hole portion 22a, and the diameter of the hollow portion of the socket portion 25 is larger than the diameter of the screw portion 102. Therefore, the screw portion 102 can be inserted into the hollow portion of the socket portion 25 and the hole portion 22a.

  Similar to the power transmission unit 4 of the first embodiment, the power transmission unit 26 has a shape in which a power source such as an impact driver can be attached and detached. That is, the power transmission unit 26 functions as a connector unit. The power transmission unit 26 receives a rotational force from the mounted power source, and thereby rotates the rotary tool 21 around the rotation axis A. Specifically, for example, the rotary tool 21 rotates around the rotation axis A by fitting an interface formed in a cylindrical concave shape of the impact driver into the power transmission unit 26 and operating the impact driver. The power transmission unit 26 may be integrally formed with the socket unit 25 or may be detachable from the socket unit 25.

  A method of rotating the nut 101 with respect to the screw portion 102 using the rotary tool 21 configured as described above will be briefly described. First, the nut 101 is screwed onto the upper end of the screw portion 102. Then, the flat plate member 22 and the socket portion 25 are put on the screw portion 102. Then, since the relationship between the length L of one side of the nut 101 and the distance L1 between the two protrusions 23 located on the same diagonal line is L <L1 ≦ √2, each protrusion 23 is It contacts the side surface 101s of the nut 101 so as to sandwich the 101. In this state, when a power source is attached to the power transmission unit 26 and the power source is operated, the rotational force F is transmitted around the rotation axis A to the flat plate member 22 via the power transmission unit 26, and the four protrusions. 23 presses the side surface 101 s of the nut 101, and the nut 101 rotates around the rotation axis A together with the rotary tool 21. Thus, the nut 101 can be rotated with respect to the screw portion 102.

  Further, a method for rotating the nut 103 with respect to the screw portion 102 using the rotary tool 21 will be described. First, the nut 103 is screwed onto the upper end of the screw portion 102. Then, the socket portion 25 is covered with the screw portion 102, and the hole portion 22 a is engaged with the nut 103. In this state, when an external power source is attached to the power transmission unit 26 and the power source is operated, the rotational force around the rotation axis A is transmitted to the flat plate member 22 via the power transmission unit 26 and the nut 103 is It rotates with the flat plate member 22. Thus, the nut 103 can be rotated with respect to the screw portion 102. Note that the nut 104 can be rotated with respect to the screw portion 102 by using a similar method.

  As mentioned above, the rotary tool 21 of 2nd Embodiment has an effect similar to the rotary tool 1 of 1st Embodiment. Further, in the second embodiment, the power transmission unit is provided with a socket part 25 that extends from the flat plate member 22 in the axial direction of the rotation axis A and has a hollow part into which the screw part 102 engaged with the hole 22a is inserted. 26 is provided in the socket portion 25. Therefore, the socket part 25 can be used in a state where it covers the screw part 102, and since the power transmission part 26 is provided on the socket part 25, the entire rotary tool 21 is nuted with the power source attached to the power transmission part 26. It becomes possible to attach and detach from the 101 and the screw portion 102. That is, it is possible to use the rotary tool 21 integrally with an impact driver or the like. Therefore, the rotation of the nut 101 using the rotary tool 21 can be performed more efficiently.

  Further, the rotary tool 21 of the second embodiment includes a flat plate member 22 having a hole 22a that engages with a hexagon nut and a power transmission unit 26. Therefore, the hexagon nut can be rotated with respect to the screw portion 102 by engaging the hole 22 a with the hexagon nut and transmitting the rotational force from the power transmission portion 26 to the flat plate member 22. Therefore, construction work such as attachment of the support member 110 can be performed more efficiently using the rotary tool 21. In addition, the shape of the hole 22a is not limited to the above-described chevron, and may be appropriately changed according to the shape of the nut to be rotated. Thus, by changing the shape of the hole 22a, various nuts can be engaged with the hole 22a and rotated with respect to the screw portion 102.

(Third embodiment)
Next, a third embodiment of the present invention will be described with reference to FIG. The third embodiment is different from the first embodiment only in that a flat plate member 32 having a long hole 32c is used instead of the flat plate member 2, and other configurations are the same as those of the rotary tool 1 of the first embodiment. It is.

  A rotary tool 31 according to the third embodiment includes a flat plate member 32 that functions as a base that rotates around a screw portion 102, a screw 3 having a screwing portion 3a, and a power transmission portion 4 having a hole portion 4a. Has been. The flat plate member 32 has a hole portion similar to the hole portion 2a at a substantially central portion. The flat plate member 32 has a long hole 32c for screwing the two screws 3 together. Two elongated holes 32 c are provided symmetrically with respect to the rotation axis A, and are provided on the same diagonal line of the flat plate member 32. The long hole 32c is formed to extend in a direction (rotational radial direction) orthogonal to the rotation axis A. Further, the inner peripheral portion of the long hole 32c is screwed with the screwing portion 3a, so that the screw 3 can be fixed at an arbitrary position of the long hole 32c. Thus, the distance with respect to the rotation axis A of the screwing part 3a which functions as a projection part can be changed.

  The method of rotating the nut 101 with respect to the screw portion 102 using the rotary tool 31 configured as described above is different from the first embodiment only in that the distance from the screwing portion 3a to the rotation axis A can be changed. Otherwise, the rest is the same as in the first embodiment.

  As mentioned above, the rotary tool 31 of 3rd Embodiment has an effect similar to the rotary tool 1 of 1st Embodiment. Moreover, in 3rd Embodiment, the distance with respect to the rotating shaft A of the screwing part 3a can be changed suitably. Accordingly, not only the nut 101 but also a nut having a different size and shape from the nut 101 can be pressed with the screwing portion 3a on the side surface, and therefore various nuts having different sizes and shapes can be rotated. it can. That is, for example, for a nut having a larger area in plan view than the nut 101, the screwing portion 3a may be fixed at a position away from the rotation axis A, and for a nut having a smaller area in plan view than the nut 101. What is necessary is just to fix the screwing part 3a close to the rotating shaft A.

  In the third embodiment, the example in which the distance to the rotation axis A of the screwing portion 3a is changed by the long hole 32c has been described. However, for example, the fixing position of the screw 3 is set in the direction intersecting the rotation axis A, such as a slide mechanism. If a movable mechanism is used, the long hole 32c may not be provided.

  As mentioned above, this embodiment demonstrates embodiment of the rotary tool which concerns on this invention, and the rotary tool which concerns on this invention is not limited to what was described in this embodiment. The rotary tool according to the present invention may be one obtained by modifying the rotary tool according to the present embodiment or applying it to another so as not to change the gist described in each claim.

  For example, in this embodiment, the example using the flat plate members 2, 22, and 32 having a square shape in plan view has been described. However, instead of the flat plate members 2, 22, and 32, for example, a flat plate member 42 having an arbitrary shape as shown in FIG. 10A can be used, and the shape of the flat plate member that functions as the base is not particularly limited. . The flat plate member 42 has a hole 42 a for inserting the screw portion 102, and the rotary tool 41 provided with the flat plate member 42 includes a protrusion 43 that protrudes downward from the flat plate member 42. Then, the screw portion 102 is inserted from below the hole portion 42a, the projecting portion 43 is brought into contact with, for example, the side surface 101s of the nut 101, and a rotational force is transmitted to the projecting portion 43 from an impact driver or the like. It is possible to rotate with respect to 102.

  Moreover, in this embodiment, the example provided with the hole parts 2a and 22a opened circularly as an engaging part which engages the screw part 102 was demonstrated. However, the shape of the engaging portion is not necessarily circular, but may be any shape as long as the screw portion 102 can be engaged. Further, instead of the holes 2a and 22a, for example, a notch 52a as shown in FIG. 10 (b) may be used. The rotary tool 51 provided with the notch 52a includes a substantially rectangular flat plate member 52 and a projection 53 that protrudes downward from the flat plate member 52. Then, the threaded portion 102 is engaged with the notch 52a, the projecting portion 53 is brought into contact with, for example, the side surface 101s of the nut 101, and the projecting portion 53 is transmitted to the projecting portion 53 from an impact driver or the like. The side surface 101 s of the nut 101 is pressed, and the nut 101 can be rotated with respect to the screw portion 102.

  Further, in the present embodiment, the example in which two or four screwing portions 3a or protrusions 23 that contact the side surface 101s of the nut 101 are provided has been described. However, the number of protrusions may be any number, for example, one as shown in FIG. If the number of protrusions is increased, the number of contact points between the protrusions and the side surfaces of the nut increases when the rotary tool is mounted on the nut, so that the rotating shaft is less likely to shake and the nut can be rotated stably. it can.

  Moreover, the operation | work which fixes the supporting member 110 which supports the wall panel K to frame 120, such as a slab concrete floor, was demonstrated as construction work performed using the rotary tool which concerns on this embodiment. However, the application target of the rotary tool according to the present embodiment is not limited to the above-described construction work, and can be applied to a work for fixing a support member that supports a window frame such as an aluminum sash to the housing. Furthermore, if the rotary tool which concerns on this embodiment is a work which has the process of rotating a nut with respect to a thread part, it can be applied to various work.

  1, 2, 31, 41, 51 ... rotating tool, 2, 22, 32, 42, 52 ... flat plate member, 2a, 22a, 42a ... hole, 3 ... screw, 3a ... screwing portion (protrusion), 4 ... Power transmission part, 4a ... Hole part, 23, 43, 53 ... Projection part, 25 ... Socket part, 26 ... Power transmission part, 32c ... Long hole, 52a ... Notch part, 101 ... Nut, 101s ... Side face, 102 ... Screw part, 110 ... Support member, 120 ... Housing, A ... Rotating shaft, F ... Rotational force.

Claims (4)

A rotary tool for rotating a nut screwed to a screw part with respect to the screw part,
A base portion having a hole portion through which the screw portion is inserted, and a base portion rotating around the screw portion;
Provided in the base, projecting in the direction of the rotation axis at a position away from the hole in the radial direction, contacting the side surface of the nut with the threaded portion inserted through the hole , A protrusion that presses the side surface of the nut in the rotational circumferential direction when a rotational force about the rotational axis is applied;
A power transmission unit that transmits a rotational force supplied from an external power source to the base;
Equipped with a,
On the inner wall of the hole, a chevron that has an upward slope and a downward slope along the circumferential direction and that can be engaged with a hexagon nut is formed.
Rotary tool.   The rotary tool according to claim 1, wherein at least two protrusions are provided symmetrically with respect to the rotation axis. The power transmission unit is a detachable connector the power source, the rotary tool according to claim 1 or 2. A socket portion formed extending from the base portion in the axial direction of the rotating shaft and having a hollow portion for inserting a screw portion inserted through the hole portion ;
The rotary tool according to claim 3 , wherein the connector part is provided in the socket part.

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