JP2006102857A - Rotating tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a rotating tool capable of easily changing rotating torque to give to a tool bit and improving working efficiency. <P>SOLUTION: This rotating tool has a rotating spindle to rotate by receiving torque of a rotor, a fluid supply passage 21 to supply fluid to the rotor, an opening and closing valve 5 to open and close the fluid supply passage 21 and a first operation part 6 and a second operation part 7 to be engaged with the opening and closing valve 5 and to actuate the opening and closing valve 5 to open. The rotating spindle is furnished with a mounting part to mount the tool bit on its head end part, and the rotor, a part of the rotating spindle, the fluid supply passage 21 and the opening and closing valve 5 are built in a housing 2. The first operation part 6 and the second operation part 7 are constituted to change opening of the opening and closing valve 5 in actuating the opening and closing valve 5 to open. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a rotary tool capable of working by rotating a tool bit such as a driver using a fluid such as air as a drive source.

For example, when assembling various assembly parts, a fluid such as air is used as a drive source and a tool bit such as a screwdriver attached to the tip is rotated to reduce the burden on the operator. Rotating tools that can be used are frequently used.
As this rotary tool, for example, there is a tightening tool disclosed in Patent Document 1. This tightening tool rotatably supports a drive shaft provided with a rotor in a case, and a base portion of an operation lever is pivotally attached to a rear end portion of the case. Then, air is supplied from the air supply source into the case by the pushing operation of the switch by the operation lever, and the rotor is rotated by this air, and the tool bit attached to the drive shaft is rotationally driven.
Conventionally, in order to adjust the rotational torque generated by the rotary tool, a torque adjustment knob is provided at an appropriate position of the case.

However, the conventional torque adjustment knob is disposed at a position where it cannot be adjusted with the same hand when the operator holds the rotary tool with one hand. Then, in the assembly component, for example, when there are work locations having different target rotational torques depending on the size of the bolt to be tightened, it is necessary to adjust the adjustment knob each time. At this time, the adjustment of the torque adjustment knob needs to be performed using a reverse hand that does not hold the rotary tool, which is a factor that deteriorates workability.
Therefore, it has been desired to develop a rotary tool that can easily change the rotational torque.

JP-A-10-109275

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide a rotary tool capable of easily changing the rotational torque applied to the tool bit and improving workability. .

1st invention is equipped with the attaching part which attaches a tool bit to a front-end | tip part, and receives the rotational force of a rotor, and the rotation main spindle rotates,
A fluid supply path for supplying fluid to the rotor;
An on-off valve for opening and closing the fluid supply path;
A housing including the rotation main shaft, the fluid supply path, and the on-off valve;
In a rotary tool having an operation portion that engages with the on-off valve and opens the on-off valve,
A plurality of the operation units are provided, and each operation unit is configured to have different opening degrees of the on-off valves when the on-off valves are opened. (Claim 1).

  The rotary tool of the present invention has a plurality of operation portions for opening the on-off valve, and the opening degree of the on-off valve when the opening operation is performed at each operation portion is different from each other. Therefore, when working with the tool bit, the following excellent effects can be obtained.

  That is, when using the rotary tool, the operator attaches various tool bits corresponding to the work target to the attachment portion at the tip of the rotary spindle. The rotary tool is connected to a fluid supply source by piping or the like, and fluid is supplied to the fluid supply path. Further, when the operator is not operating the operation unit, the on-off valve closes the fluid supply path, and the rotation of the rotating spindle is stopped.

When the operator operates any of the operation units to open the on-off valve, fluid is supplied from the fluid supply path to the rotor, and the rotor rotates to rotate the rotating spindle, and the tool bit Work can be done.
Next, when performing work on another part having a different target rotational torque, the operator operates another operation unit different from any one of the operation units. At this time, the opening degree of the on-off valve that has been opened by another operating part is different from the opening degree of the on-off valve that has been opened by any one of the above-described operating parts. Thereby, the rotary tool can generate a rotational torque different from the rotational torque when operating any one of the operation units.

Therefore, the operator can change the rotational torque applied to the tool bit only by changing the operating part to be operated. Therefore, for example, even when work locations having different target rotational torques to be generated in the work target are mixed, the worker can cope with the change by merely changing the operation unit to be gripped. And it is not necessary for the operator to use both hands to change the rotational torque, and the workability can be improved.
Therefore, according to the rotary tool of the present invention, the rotational torque applied to the tool bit can be easily changed, and workability can be improved.

The second invention comprises a mounting portion for attaching a tool bit to the tip, and a rotating main shaft that rotates by receiving the rotational force of the rotor;
A fluid supply path for supplying fluid to the rotor;
An on-off valve for opening and closing the fluid supply path;
A housing including the rotation main shaft, the fluid supply path, and the on-off valve;
In a rotary tool having an operation portion that engages with the on-off valve and opens the on-off valve,
The operation unit is configured to rotate about a rotation fulcrum provided in the housing to open the on-off valve, and a position relative to the rotation fulcrum or the amount of protrusion from the back of the rotation lever And an adjustment stopper capable of adjusting the rotation amount of the rotation lever, and changing the position or the protrusion amount of the adjustment stopper to open the opening / closing valve. The rotary tool is characterized in that the opening degree of the on-off valve can be changed.

The rotary tool of the present invention includes an adjustment stopper capable of adjusting the amount of rotation of the rotation lever, and can change the opening degree of the opening / closing valve when the opening / closing valve is opened.
For this reason, when the operator performs the work of the other part having a different target rotational torque after performing the work of the part with the work target, the position of the adjustment stopper with respect to the turning fulcrum or the turning lever Adjust the amount of protrusion of the adjustment stopper from the back side. Thereby, the opening degree of the on-off valve when the on-off valve is opened by the rotary lever can be changed, and the rotary tool is the rotational torque when the work on the part where the work is performed is performed. Different rotational torques can be generated.

Therefore, the operator can change the rotational torque applied to the tool bit only by changing the position of the adjustment stopper or the protrusion amount. For example, even when work locations having different target rotational torques to be generated in a work target are mixed, it is possible to cope with this by simply changing the position of the adjustment stopper or the protrusion amount. Therefore, the operator does not need to use both hands in order to change the position or the protruding amount of the adjustment stopper, and the workability can be improved.
Therefore, even with the rotary tool of the present invention, the rotational torque applied to the tool bit can be easily changed, and workability can be improved.

A preferred embodiment in the first and second inventions described above will be described.
In the first and second inventions, examples of the tool bit include a socket, a wrench, a driver, a polishing blade, a drill blade, a reamer blade, and a grinder.

  The operation unit includes a first operation unit operable from a fully closed position for fully opening the opening / closing valve to a fully opened position for fully opening the opening / closing valve, and from the fully closed position. Preferably, it comprises a second operating portion operable to an intermediate position between the fully closed position and the fully open position. In this case, when the on-off valve is opened by the two operation units, the first operation unit and the second operation unit, a maximum rotation torque and a rotation torque smaller than this can be generated. . Therefore, two types of rotational torque can be easily generated with a simple structure of the rotary tool.

  Moreover, it is preferable that the said 2nd operation part can adjust the said intermediate position (Claim 3). In this case, the rotational torque smaller than the maximum rotational torque can be appropriately changed to a necessary magnitude.

  Further, the first operation part is constituted by a pushing piece disposed in the opening / closing operation direction of the opening / closing valve, and the second operation part is rotated around a rotation fulcrum provided in the housing, It is preferable that the opening / closing valve is constituted by a turning lever for opening the opening / closing valve. In this case, when the pushing piece is pushed from the fully closed position to the fully opened position and the opening / closing valve is opened, the opening degree of the opening / closing valve can be fully opened. Further, when the rotary lever is rotated from the fully closed position to the intermediate position to open the opening / closing valve, the opening degree of the opening / closing valve can be set to a predetermined opening degree. Therefore, two types of rotational torque can be easily generated with a simple structure of the rotary tool.

  The second operation unit includes an adjustment stopper capable of adjusting a rotation amount of the rotation lever by changing a position with respect to the rotation fulcrum portion or a protruding amount from the back surface of the rotation lever. It is preferable that the intermediate position is fixed to a predetermined position by changing the position or the protruding amount of the adjustment stopper. In this case, the operator can easily change the position or the protruding amount of the adjustment stopper. For example, the operator can operate the adjustment stopper with the same hand as the hand operating the rotation lever. Thereby, the intermediate position of the rotation lever can be easily changed, and this intermediate position can be easily fixed at a predetermined position.

Hereinafter, embodiments of the rotary tool of the present invention will be described with reference to the drawings.
Example 1
As shown in FIGS. 1 to 4, the rotary tool 1 of the present example is a device in which a rotational torque of a different magnitude is generated by a simple operation by an operator.
That is, as shown in FIGS. 1 and 2, the rotary tool 1 includes a rotor 31 that rotates by a fluid, a rotating main shaft 32 that rotates by receiving the rotational force of the rotor 31, and a fluid supply path that supplies fluid to the rotor 31. 21, an on-off valve 5 for opening and closing the fluid supply path 21, and a first operating unit 6 and a second operating unit 7 that engage with the on-off valve 5 and open the on-off valve 5. Yes.

Further, the rotation main shaft 32 includes a mounting portion 33 for attaching the tool bit 4 to the tip portion thereof, and the rotor 31, a part of the rotation main shaft 32, the fluid supply path 21 and the on-off valve 5 are built in the housing 2. ing.
Moreover, the 1st operation part 6 and the 2nd operation part 7 are comprised so that the opening degree of the on-off valve 5 when opening and closing the on-off valve 5 may mutually differ.
This will be described in detail below.

  As shown in FIGS. 1 to 4, the fluid in this example is air, and the rotary tool 1 is an air rotary tool 1 operated by air. The tool bit 4 is a hexagon wrench that engages a socket that engages the head of the hexagon bolt or a hexagonal recess of the cap bolt.

As shown in FIG. 2, the rotor 31 has a cylindrical shape and has a plurality of rotating blades (not shown) on the outer peripheral surface thereof. Then, when the fluid collides with the rotary blade, a rotational force for rotating the rotary main shaft 32 is generated. Further, the rotational force generated by the rotor 31 changes as the flow rate (pressure) of the fluid supplied from the fluid supply path 21 changes depending on the opening degree of the on-off valve 5.
The rotation main shaft 32 is connected to the tip end side of the rotor 31 and is rotated by receiving the rotational force of the rotor 31 to rotate the tool bit 4 attached to the attachment portion 33.

  As shown in FIG. 1, the on-off valve 5 is slidably disposed in the housing 2 so as to block or open the fluid supply path 21 in the middle thereof. The on-off valve 5 shuts off the upstream portion and the downstream portion of the fluid supply passage 21 when the opening is fully closed, and on the other hand, when the opening is fully opened, The upstream portion and the downstream portion are communicated.

  The on-off valve 5 is provided with an on-off valve that urges the on-off valve 5 in the closing direction to the side opposite to the side where the slide pin portion 61 of the push-in piece 6 is fixed, and slides the push-in piece 6 to the fully closed position C. A spring 51 is provided. Then, after opening any of the operating portions to open the on-off valve 5, the on-off valve 5 is closed by the urging force of the on-off valve urging spring 51, and the pushing piece 6 is in the fully closed position C. Slide to.

  As shown in FIG. 1, the first operation portion 6 of this example is configured using a pushing piece 6 disposed in the opening / closing operation direction of the on-off valve 5, and the second operation portion 7 is provided on the housing 2. The pivot lever 7 pivots around the pivot fulcrum (rotation support) 22 and opens the on-off valve 5. The pushing piece 6 can be operated from a fully closed position C (see FIG. 1) where the opening degree of the on-off valve 5 is fully closed to a fully open position O (see FIG. 3) where the opening degree of the on-off valve 5 is fully opened. The rotation lever 7 can be operated from the fully closed position C to an intermediate position M (see FIG. 4) between the fully closed position C and the fully open position O.

As shown in FIG. 1, the pushing piece 6 of this example is formed with a slide pin portion 61 slidable in a slide hole 24 formed in the housing 2 and an enlarged diameter at the outer end portion of the slide pin portion 61. And the pressed portion 62. The slide pin portion 61 is inserted and disposed in the slide hole 24, and the pressing portion 62 is disposed outside the housing 2. The inner end of the slide pin portion 61 is fixed to the on-off valve 5.
The housing 2 has a cylindrical shape, and the rotating lever 7 is disposed along the axial direction L of the housing 2.

  As shown in FIG. 1, the rotating lever 7 of this example is formed with a rotating shaft portion 71 rotatably supported on the rotating fulcrum portion 22 of the housing 2 at the rear end thereof. It is configured to engage with the on-off valve 5 at a position closer to the tip than the portion 71. The rotating lever 7 of this example is configured to engage the slide pin portion 61 of the pushing piece 6 to open the on-off valve 5. That is, the slide pin portion 61 has a general portion 611 and a reduced-diameter portion 612 having a diameter smaller than that of the general portion 611 at the pressing portion 62 side. A stepped portion 613 is formed between 612 and 612. Further, the rotation lever 7 is formed with an insertion hole 72 for inserting the reduced diameter portion 612 of the slide pin.

  Further, the reduced diameter portion 612 of the slide pin portion 61 is inserted into the insertion hole 72 of the rotation lever 7 and rotates the rotation lever 7 around the rotation fulcrum portion 22 as shown in FIG. Then, the outer edge portion of the insertion hole 72 comes into contact with the step portion 613 of the slide pin portion 61. Thus, when the turning lever 7 is turned, the pushing piece 6 slides and the opening / closing valve 5 can be opened.

Further, as shown in FIG. 1, the rotation lever 7 includes an adjustment stopper 8 that can change the position of the rotation fulcrum 22 and adjust the rotation amount of the rotation lever 7. The adjustment stopper 8 is disposed on the distal end side of the rotation lever 7 with respect to the position where the insertion hole 72 is formed. Further, the rotation lever 7 of this example is formed with screw holes 73 at a plurality of locations in the axial direction L of the housing 2, and the adjustment stopper 8 of this example has bolts 80 in any one of the screw holes 73. And the position with respect to the rotation fulcrum portion 22 is changed by changing the screw hole 73 into which the bolt 80 is screwed.
When the operator rotates the rotation lever 7, the rotation position of the rotation lever 7 can be fixed to the intermediate position M by the tip portion of the bolt 80 contacting the housing 2.

As shown in FIGS. 1 and 2, a fluid inlet 23 for taking in air as a fluid into the fluid supply path 21 is formed at the rear end of the housing 2.
Further, the rotary tool 1 has a gripping portion 11 for the operator to grip at the position where the rotation lever 7 is disposed.
A lever urging means (not shown) for urging the rotation lever 7 to the fully closed position C is disposed on the rotation fulcrum portion 22 provided in the housing 2. This lever urging means can be constituted by a torsion coil spring or the like.

  The rotary tool 1 of the present example has a first operation unit 6 and a second operation unit 7 for opening the opening / closing valve 5, and the opening / closing valve 5 when the opening operation is performed in each operation unit 6, 7. The degree of opening is different from each other. Therefore, when working with the tool bit 4 attached to the rotary tool 1, the following excellent effects can be obtained. In this example, the tool bit 4 is a socket or a wrench that engages the head of the bolt, and two types are prepared so that two types of bolts can be fastened to the assembly part. In the following, the tool bit 4 that engages with the large first bolt is referred to as a first tool bit 4, and the tool bit 4 that engages with a second bolt smaller than the first bolt is the second tool bit. Four.

When using the rotary tool 1 to fasten the bolt to the assembly part, the operator uses the first tool bit 4 for fastening the large first bolt to the mounting portion 33 of the rotary main shaft 32. Install. Then, the operator connects a fluid supply source to the fluid inlet 23 of the rotary tool 1 through a pipe or the like. At this time, fluid is supplied to the fluid supply path 21.
Further, as shown in FIG. 1, when the operator is not operating the operation units 6 and 7, the operation units 6 and 7 are in the fully closed position C and the opening degree of the on-off valve 5 is fully closed. Yes. As a result, the fluid supply path 21 is closed by the on-off valve 5, and the rotation of the rotary main shaft 32 is stopped.

Then, as shown in FIG. 3, the operator pushes the pushing piece 6 as the first operation unit 6 by holding the holding part 11 in the rotary tool 1, and slides it from the fully closed position C to the fully open position O. The opening of the on-off valve 5 is fully opened. As a result, fluid is supplied from the fluid supply path 21 to the rotor 31, and the rotation main shaft 32 rotates at the maximum rotational speed by rotating the rotor 31 at the maximum rotational speed. Thus, the maximum rotational torque can be generated in the first tool bit 4 and the first bolt can be tightened with the first tool bit 4.
The maximum rotational speed or maximum rotational torque refers to the maximum rotational speed or rotational torque generated by the pressure of the fluid supplied to the fluid supply path 21.

Next, when performing the tightening operation of the second bolt, which has a target tightening torque different from that of the first bolt, the operator removes the first tool bit 4 from the mounting portion 33 of the rotary tool 1 and puts the first bolt in the mounting portion 33. 2 Install the tool bit 4.
Then, as shown in FIG. 4, the operator rotates the rotation lever 7 as the second operation unit 7 by holding the holding unit 11 in the rotary tool 1, and moves this from the fully closed position C to the intermediate position M. When it is rotated, the pushing piece 6 slides to an intermediate position M between the fully closed position C and the fully opened position O, and the opening degree of the on-off valve 5 becomes a predetermined opening degree.

As a result, fluid is supplied from the fluid supply path 21 to the rotor 31, and the rotor 31 rotates at a predetermined rotational speed, whereby the rotation main shaft 32 rotates at a predetermined rotational speed. Thus, the second tool bit 4 can generate a predetermined rotational torque, and the second tool bit 4 can be used to tighten the second bolt.
Further, when the rotary tool 1 operates the second operation unit 7, the rotary tool 1 can generate a rotational torque different from the rotational torque when the first operation unit 6 is operated.

In this way, the operator can change the rotational torque applied to the tool bit 4 simply by changing the operating units 6 and 7 to be operated. Therefore, for example, even when work locations having different target tightening torques to be generated in the assembled parts are mixed, the operator can cope with the change by simply changing the operation units 6 and 7 to be gripped. And it is not necessary for the operator to use both hands to change the rotational torque, and the workability can be improved.
Therefore, according to the rotary tool 1 of this example, the rotational torque applied to the tool bit 4 can be easily changed, and workability can be improved.

(Example 2)
As shown in FIGS. 5 to 8, the rotary tool 1 of this example does not include the first operation unit 6, and the adjustment stopper 8 in the rotating lever 7 as the second operation unit 7 can be easily adjusted. As a result, the opening degree of the on-off valve 5 is easily changed to generate different rotational torques.
That is, as shown in FIGS. 5 and 6, the rotary tool 1 of this example is fixed to the opening / closing valve 5 and engaged with the rotating lever 7 instead of the pushing piece 6 as the first operating portion 6. A slide pin 63 is provided. When the turning lever 7 is turned, the engagement slide pin 63 and the on-off valve 5 slide.

  Further, the rotation lever 7 of this example has a stopper engaging portion 74 for enabling the adjustment stopper 8 to move in the axial direction L of the housing 2. Further, the adjustment stopper 8 of the present example includes a stopper main body 81 and a protrusion 82 capable of changing the protrusion amount with respect to the stopper main body 81.

Further, as shown in FIG. 6, the stopper engaging portion 74 of the present example is formed on the side of the elongated hole portion 741 and the elongated hole portion 741 in which the stopper main body portion 81 is slidable in the axial direction L, and protrudes. A plurality of arrangement groove portions 742 formed in parallel in the axial direction L of the rotation lever 7 so as to arrange the portion 82. The plurality of arrangement groove portions 742 in this example have a wave shape formed continuously in the axial direction L of the rotation lever 7. Further, the projecting portion 82 is configured to project from the stopper main body 81 upon receiving a biasing force by a biasing spring (not shown).
Then, when the operator rotates the rotation lever 7, the tip end portion of the stopper main body 81 abuts the housing 2 in a state where the protruding portion 82 is disposed in any of the disposition groove portions 742. The rotation position of the rotation lever 7 can be fixed at the intermediate position M.

Further, when the position of the adjustment stopper 8 is adjusted to change the intermediate position M of the rotation lever 7, the operator slides the adjustment stopper 8 in the axial direction L of the housing 2. At this time, the protruding portion 82 is disposed in another adjacent disposition groove portion 742 against the urging force of the urging spring. Accordingly, as shown in FIGS. 7 and 8, the opening degree of the opening / closing valve 5 when the opening / closing valve 5 is opened by the rotating lever 7 can be easily changed. Therefore, the operator can change the position of the adjustment stopper 8 with the same hand as the hand operating the rotation lever 7, and the workability can be improved.
In FIG. 8, when the adjustment stopper 8 is at the farthest position from the on-off valve 5, the turning lever 7 can be in the fully open position O that fully opens the on-off valve 5.

Therefore, also with the rotary tool 1 of this example, the rotational torque applied to the tool bit 4 can be easily changed, and workability can be improved.
Also in this example, the other parts are the same as those in the first embodiment, and the same effects as those in the first embodiment can be obtained.

(Example 3)
Similar to the second embodiment, the rotary tool 1 of the present example does not include the first operation unit 6 and facilitates the adjustment of the adjustment stopper 8 in the rotation lever 7 as the second operation unit 7. Thus, the opening degree of the on-off valve 5 is easily changed to generate different rotational torques. The adjustment stopper 8 of this example is configured to adjust the amount of rotation of the rotation lever 7 by changing the amount of protrusion from the back surface of the rotation lever 7. Further, the rotary tool 1 of this example has the engagement slide pin 63 instead of the pushing piece 6 as the first operation portion 6.

  That is, as shown in FIGS. 9 to 11, the adjustment stopper 8 is fixed to the rotating lever 7 and the fixed main body 83, and the pressing portion 84 that can be pressed in the direction facing the housing 2 with respect to the fixed main body 83. And make up. Further, the push-in portion 84 can change the amount of protrusion of its inner end protruding from the back surface (the surface facing the housing 2) of the rotating lever 7, and the push-in for pushing operation to the outer end thereof is possible. An operation unit 841 is formed.

When the pushing portion 84 is pressed, the inner end portion protrudes from the back surface of the rotating lever 7, and when the pushing portion 84 is pressed again, the inner end portion is moved from the back surface of the rotating lever 7 to the inside of the rotating lever 7. Be drawn into.
Accordingly, as shown in FIG. 10, when the inner end portion of the push-in portion 84 protrudes from the back surface of the turning lever 7, the turning lever 7 is operated to open the on-off valve 5, thereby turning the turning lever. 7 stops at the intermediate position M, the opening of the on-off valve 5 is set to a predetermined opening, and the rotary tool 1 can generate a rotating torque of a predetermined magnitude.

On the other hand, as shown in FIG. 11, when the inner end portion of the push-in portion 84 is pulled into the rotating lever 7, when the opening / closing valve 5 is opened by operating the rotating lever 7, the rotating lever 7 is moved. The rotary tool 1 stops at the fully open position O and the opening degree of the on-off valve 5 is fully opened, so that the rotary tool 1 can generate the maximum rotational torque.
Also in this example, the other parts are the same as those in the second embodiment, and the same effects as those in the second embodiment can be obtained.

Sectional explanatory drawing which shows the state which has the 1st operation part and 2nd operation part in a fully-closed position in Example 1, and the on-off valve has closed the fluid supply path. Explanatory drawing which shows the rotary tool in Example 1. FIG. Sectional explanatory drawing which shows the state which has the 1st operation part in the fully open position in Example 1, and the on-off valve has made the fluid supply path fully open. Cross-sectional explanatory drawing which shows the state in which the 2nd operation part in Example 1 exists in an intermediate position, and the on-off valve has opened the fluid supply path by the predetermined opening degree. Sectional explanatory drawing which shows the state which has the 2nd operation part in the fully closed position in Example 2, and the on-off valve has closed the fluid supply path. FIG. 9 is an explanatory diagram illustrating a second operation unit in the second embodiment. Sectional explanatory drawing which shows the state which operates the 2nd operation part in Example 2, and the on-off valve has opened the fluid supply path by the predetermined opening degree. Sectional explanatory drawing which shows the state which operates the 2nd operation part in Example 2, and the on-off valve has opened the fluid supply path by the predetermined opening degree. Sectional explanatory drawing which shows the state in which the 2nd operation part in Example 3 exists in a fully closed position, and the on-off valve has closed the fluid supply path. Sectional explanatory drawing which shows the state in which the 2nd operation part in Example 3 exists in an intermediate position, and the on-off valve has opened the fluid supply path by the predetermined opening degree. Sectional explanatory drawing which shows the state in which the 2nd operation part in Example 3 exists in a full open position, and the on-off valve has fully opened the fluid supply path.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Rotating tool 2 Housing 21 Fluid supply path 22 Rotating fulcrum part 31 Rotor 32 Rotation main shaft 33 Attaching part 4 Tool bit 5 On-off valve 6 First operation part (pushing piece)
7 Second operation part (turning lever)
8 Adjustment stopper O Fully open position C Fully closed position M Intermediate position

Claims (6)

A rotating spindle that is provided with a mounting portion for attaching a tool bit to the tip, and that rotates by receiving the rotational force of the rotor;
A fluid supply path for supplying fluid to the rotor;
An on-off valve for opening and closing the fluid supply path;
A housing including the rotation main shaft, the fluid supply path, and the on-off valve;
In a rotary tool having an operation portion that engages with the on-off valve and opens the on-off valve,
A rotating tool comprising a plurality of the operating sections, wherein each operating section is configured to vary the opening degree of the on-off valve when the on-off valve is opened.   In Claim 1, the said operation part is a 1st operation part which can be operated from the fully-closed position which opens the opening degree of the said on-off valve to the fully-open position which fully opens the opening degree of this on-off valve, A rotary tool comprising a second operating portion operable from a closed position to an intermediate position between the fully closed position and the fully opened position.   The rotary tool according to claim 2, wherein the second operation unit is capable of adjusting the intermediate position. In Claim 2 or 3, said 1st operation part is constituted from a pushing piece arranged in the opening-and-closing operation direction of said on-off valve,
The rotary tool characterized in that the second operation part is constituted by a turning lever that turns around a turning fulcrum provided in the housing and opens the on-off valve.   In Claim 4, The said 2nd operation part is equipped with the adjustment stopper which can adjust the rotation amount of the said rotation lever by changing the protrusion amount from the back surface of the said rotation fulcrum part or the said rotation lever. A rotating tool configured to fix the intermediate position to a predetermined position by changing the position or the protruding amount of the adjustment stopper. A rotating spindle that is provided with a mounting portion for attaching a tool bit to the tip, and that rotates by receiving the rotational force of the rotor;
A fluid supply path for supplying fluid to the rotor;
An on-off valve for opening and closing the fluid supply path;
A housing including the rotation main shaft, the fluid supply path, and the on-off valve;
In a rotary tool having an operation portion that engages with the on-off valve and opens the on-off valve,
The operation unit is configured to rotate about a rotation fulcrum provided in the housing to open the on-off valve, and a position relative to the rotation fulcrum or the amount of protrusion from the back of the rotation lever And an adjustment stopper capable of adjusting the rotation amount of the rotation lever, and changing the position or the protrusion amount of the adjustment stopper to open the opening / closing valve. A rotary tool characterized in that the opening degree of the on-off valve can be changed.

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