JP2023180162A - Impact rotating tool - Google Patents

Abstract

To provide an impact rotating tool configured to turn down sound generated from a housing thereof.SOLUTION: An impact rotating tool 1 comprises a hammer 5, an anvil 6, an output shaft 7, a housing 2 and a bearing (a second bearing 92). The bearing (the second bearing 92) bears the output shaft 7 rotatably. The housing 2 has a cylindrical first site 211a and a cylindrical second site 211b. The first site 211a is provided to surround the bearing (the second bearing 92) to hold the bearing (the second bearing 92). The second site 211b is arranged behind the first site 211a. The first site 211a is configured so that forward force is transmitted through the bearing (the second bearing 92) from the output shaft 7. A thickness T1 of the first site 211a is larger than a thickness T2 of the second site 211b.SELECTED DRAWING: Figure 2

Description

BACKGROUND OF THE INVENTION This disclosure generally relates to impact rotary tools. More specifically, the present disclosure relates to an impact rotary tool in which a housing holds a bearing that rotatably supports an output shaft.

The impact rotary tool described in Patent Document 1 includes a motor, a drive shaft, a hammer, a spring, an anvil, an output shaft, a bearing, a thrust ring, and a main body (housing). A drive shaft rotationally driven by a motor transmits its rotational force to the hammer. When the load increases when tightening or loosening screws, bolts, etc., the hammer will move the anvil in the direction of rotation due to the rotational energy from the motor and the reaction force from the spring. to strike. A shock from this impact is applied to the driver bit. The axial impact due to the reaction force of the spring is received by a thrust ring provided between the bearing and the anvil.

Japanese Patent Application Publication No. 2010-076022

In this manner, in the impact rotary tool described in Patent Document 1, an impact in the axial direction is received by the thrust ring. Axial shocks may be transmitted to the housing via the thrust ring. This may cause the housing to vibrate and generate noise. In particular, if the sound is loud, it may be considered noise.

An object of the present disclosure is to provide an impact rotary tool with low noise generated from the housing.

An impact rotary tool according to one aspect of the present disclosure includes a hammer, an anvil, an output shaft, a housing, and a bearing. The hammer rotates by receiving power from a motor. The anvil rotates upon receiving a striking force from the hammer in a rotational direction of the hammer. The output shaft is disposed on the front side of the anvil, is configured to hold a tip tool, and rotates together with the anvil. The housing accommodates the hammer and the anvil. The bearing rotatably supports the output shaft. The housing has a cylindrical first portion and a cylindrical second portion. The first portion is provided so as to surround the bearing and holds the bearing. The second part is arranged on the rear side of the first part. The first portion is configured such that forward force is transmitted from the output shaft through the bearing. The thickness of the first portion is greater than the thickness of the second portion.

The impact rotary tool of the present disclosure has the advantage that the noise generated from the housing is small.

FIG. 1 is a perspective view of an impact rotary tool according to one embodiment. FIG. 2 is a sectional view of the impact rotary tool same as above. FIG. 3 is a front view of the main parts of the impact rotary tool same as above. FIG. 4 is an exploded perspective view of the main parts of the same impact rotary tool as seen from the front. FIG. 5 is an exploded perspective view of the main parts of the same impact rotary tool as seen from the rear. FIG. 6 is a perspective view of the anvil and output shaft of the impact rotary tool same as above. FIG. 7 is a cross-sectional perspective view of an anvil and an output shaft of the same impact rotary tool. FIG. 8 is a cross-sectional perspective view of an anvil and an output shaft of the same impact rotary tool. FIG. 9 is an exploded perspective view of main parts of the impact rotary tool according to Modification 1. FIG. 10 is a sectional view of a main part of an impact rotary tool according to a second modification.

(Embodiment)
Hereinafter, an impact rotary tool 1 according to an embodiment will be described using the drawings. However, the embodiment described below is only one of various embodiments of the present disclosure. The embodiments described below can be modified in various ways depending on the design, etc., as long as the objective of the present disclosure can be achieved. In addition, each figure described in the following embodiments is a schematic diagram, and the ratio of the size and thickness of each component in the figure does not necessarily reflect the actual size ratio. .

(overview)
As shown in FIGS. 1 and 2, the impact rotary tool 1 of this embodiment includes a hammer 5, an anvil 6, an output shaft 7, a housing 2, and a bearing (second bearing 92). The hammer 5 receives power from the motor 3 and rotates. The anvil 6 receives a striking force from the hammer 5 in the rotational direction of the hammer 5 and rotates. The output shaft 7 is arranged in front of the anvil 6, is configured to hold a tip tool, and rotates together with the anvil 6. Housing 2 accommodates hammer 5 and anvil 6. The bearing (second bearing 92) rotatably supports the output shaft 7. The housing 2 has a cylindrical first portion 211a and a cylindrical second portion 211b. The first portion 211a is provided so as to surround the bearing (second bearing 92), and holds the bearing (second bearing 92). The second portion 211b is arranged on the rear side of the first portion 211a. The first portion 211a is configured such that forward force is transmitted from the output shaft 7 via a bearing (second bearing 92). For example, the output shaft 7 vibrates in the front-rear direction due to the force transmitted from the hammer 5 to the output shaft 7 via the anvil 6, and the forward component of the force due to the vibration of the output shaft 7 is transmitted from the output shaft 7. It is transmitted to the first portion 211a via a bearing (second bearing 92). The thickness T1 of the first portion 211a is greater than the thickness T2 of the second portion 211b.

According to the above configuration, forward force is transmitted from the output shaft 7 to the first portion 211a via the bearing (second bearing 92). This allows the first portion 211a to vibrate, but since the first portion 211a is thicker than the second portion 211b, the vibration of the first portion 211a has a relatively low amplitude (that is, a small sound) and , resulting in relatively high frequency vibration. Furthermore, when vibration is transmitted from the first part 211a to the second part 211b, the vibration is attenuated due to the difference in resonance frequency due to the difference in thickness between the first part 211a and the second part 211b. . Therefore, the sound generated from the housing 2 can be reduced.

Further, as shown in FIGS. 1 and 2, the impact rotary tool 1 of this embodiment includes a hammer 5, an anvil 6, an output shaft 7, a housing 2, a bearing (first bearing 91), and a buffer member. 8. The hammer 5 receives power from the motor 3 and rotates. The anvil 6 receives a striking force from the hammer 5 in the rotational direction of the hammer 5 and rotates. The output shaft 7 is configured to hold the tip tool, and rotates together with the anvil 6 by receiving a force from the anvil 6 in the rotational direction of the anvil 6. Housing 2 accommodates hammer 5 and anvil 6. The bearing (first bearing 91) is held in the housing 2 and rotatably supports the output shaft 7. The buffer member 8 includes an elastic member 81 that is elastically deformed in a thrust direction that is a direction along the rotation axis of the output shaft 7 . The anvil 6 has a first opposing region F1 (see FIG. 7) that faces the output shaft 7 in the thrust direction. The output shaft 7 has a second opposing region F2 (see FIG. 7) that faces the first opposing region F1 in the thrust direction. The buffer member 8 is sandwiched between the anvil 6 and the output shaft 7. The elastic member 81 is compressed in the thrust direction by the load transmitted from the hammer 5 in the thrust direction. The buffer member 8 is configured such that when the maximum load transmitted from the hammer 5 is applied to the elastic member 81, the second opposing region F2 faces the first opposing region F1 with a gap in the thrust direction. The distance between the second opposing area F2 and the first opposing area F1 is regulated.

According to the above configuration, the possibility that the anvil 6 collides with the output shaft 7 can be reduced. Therefore, the possibility that collision noise will be generated and vibrations due to the collision will be transmitted to the housing 2 can be reduced. Further, since the vibration of the anvil 6 in the thrust direction is reduced by the buffer member 8 and then transmitted to the output shaft 7, the vibration of the output shaft 7 can be suppressed.

Further, the impact rotary tool 1 of this embodiment includes a hammer 5, an anvil 6, an output shaft 7, a housing 2, and a bearing (first bearing 91). The hammer 5 receives power from the motor 3 and rotates. The anvil 6 receives a striking force from the hammer 5 in the rotational direction of the hammer 5 and rotates. The output shaft 7 is configured to hold the tip tool, and rotates together with the anvil 6 by receiving a force from the anvil 6 in the rotational direction of the anvil 6. Housing 2 accommodates hammer 5 and anvil 6. The bearing (first bearing 91) is held in the housing 2. Anvil 6 includes a first contact portion 63 . The first contact portion 63 contacts the output shaft 7 . The output shaft 7 includes a second contact portion 72 . The second contact portion 72 contacts the first contact portion 63. The second contact portion 72 receives a force for rotating the output shaft 7 from the first contact portion 63 . The bearing (first bearing 91) is in contact with at least one of the first contact portion 63 and the second contact portion 72, and rotatably supports at least one of the output shaft 7 and the anvil 6.

According to the above configuration, the mechanical strength of at least one of the first contact portion 63 and the second contact portion 72 is reinforced by contacting the bearing (first bearing 91). In particular, at least one of the first contact portion 63 and the second contact portion 72 has reinforced mechanical strength against vibrations in the radial direction of the output shaft 7. This improves the durability of at least one of the anvil 6 and the output shaft 7.

(detail)
(1) Overall configuration The impact rotary tool 1 of this embodiment will be described in detail below.

In the following explanation, the direction in which the anvil 6 and the output shaft 7 are lined up is defined as the front-back direction, the output shaft 7 side seen from the anvil 6 is defined as the front, and the anvil 6 side seen from the output shaft 7 is defined as the rear. It is stipulated that In addition, in the following description, the direction in which the later-described accommodating part 21 and the grip part 22 are lined up is defined as the up-down direction, the accommodating part 21 side seen from the grip part 22 is defined as the top, and the direction in which the accommodating part 21 and the grip part 22 are lined up is defined as the top. The grip portion 22 side is defined as the bottom. Further, a direction perpendicular to the front-rear direction and the up-down direction is defined as the left-right direction. However, these regulations are not intended to define the direction in which the impact rotary tool 1 is used. Moreover, the arrows representing front and back and up and down in FIG. 2 are only shown for explanation and have no substance.

Further, the thrust direction referred to in the present disclosure refers to a direction along the rotation axis of the output shaft 7. The thrust direction is a direction along the front-rear direction.

The impact rotary tool 1 of this embodiment is a portable power tool. As shown in FIGS. 1 and 2, the impact rotary tool 1 includes a housing 2, a motor 3, a transmission mechanism 4, a hammer 5, an anvil 6, an output shaft 7, a buffer member 8, and a first bearing. 91, a second bearing 92, a first stopper 93, a second stopper 94, a drive circuit 11, a control circuit 12, and an operation section 13.

(2) Housing The housing 2 includes the motor 3, the transmission mechanism 4, the hammer 5, the anvil 6, the buffer member 8, the first bearing 91, the second bearing 92, the first stopper 93, the second stopper 94, the drive circuit 11, and the control It houses the circuit 12. As shown in FIG. 1, the housing 2 includes a housing section 21, a grip section 22, and a mounting section 23.

The housing portion 21 is made of, for example, metal (aluminum or the like). The shape of the accommodating portion 21 is a hollow cylinder. The housing section 21 includes a first housing section 211 and a second housing section 212. The first accommodating part 211 is provided in front of the second accommodating part 212. The first accommodating part 211 is connected to the second accommodating part 212. The first housing part 211 houses at least the hammer 5 and the anvil 6. A first bearing 91 and a second bearing 92 are held in the first housing portion 211 . The first accommodating portion 211 has a through hole 2110 through which the output shaft 7 is passed.

The first accommodating portion 211 has a recess 2111 (see FIG. 2) on its inner surface. The through hole 2110 is provided on the bottom surface of the recess 2111. The second bearing 92 is inserted into the recess 2111. In this embodiment, the second bearing 92 is held in the first housing part 211 by being press-fitted into the recess 2111.

As shown in FIGS. 1 and 2, the first accommodating portion 211 includes a first portion 211a and a second portion 211b. The first portion 211a and the second portion 211b are each hollow. The first portion 211a has a cylindrical shape. The axial direction of the first portion 211a is along the front-rear direction. The shape of the second portion 211b is cylindrical. The axial direction of the second portion 211b is along the front-rear direction. The second portion 211b is connected to the first portion 211a. The second portion 211b projects rearward from the rear end of the first portion 211a.

The first portion 211a is integrally formed with the second portion 211b. More specifically, one member constituting the first housing portion 211 includes a first portion 211a and a second portion 211b.

The second portion 211b has a front end portion 211f that includes the front end of the second portion 211b, and a main body portion 211r that protrudes rearward from the front end portion 211f. The front end portion 211f is formed in the shape of a truncated cone, with the outer diameter increasing toward the rear. The main body portion 211r is formed in a cylindrical shape.

The outer diameter of the main body portion 211r is substantially constant in the front-rear direction. More specifically, the rate of change in the outer diameter of the main body portion 211r in the front-rear direction is smaller than the rate of change in the outer diameter of the front end portion 211f in the front-rear direction.

In other words, the second portion 211b has a larger outer diameter at the front end 211f toward the rear, and the outer diameter of the main body 211r differs depending on the position in the front-rear direction compared to the front end 211f. small. In other words, the difference in the outer diameter depending on the position in the front-rear direction is the rate of change in the outer diameter per unit length in the front-rear direction.

Further, the outer diameter of the first portion 211a is substantially constant in the front-rear direction. More specifically, the rate of change in the outer diameter of the first portion 211a in the front-rear direction is smaller than the rate of change in the outer diameter of the front end portion 211f in the front-rear direction.

The outer diameter of the first portion 211a is smaller than the outer diameter of the second portion 211b. More specifically, the outer diameter of the first portion 211a is smaller than both the outer diameter of the front end portion 211f of the second portion 211b and the outer diameter of the main body portion 211r.

The first portion 211a includes the first bearing 91, the second bearing 92, at least a portion of the anvil 6 (the two first contact portions 63), and at least a portion of the output shaft 7 (the two second contact portions 72). ) and are provided to surround it. The first portion 211a holds a first bearing 91 and a second bearing 92. The first portion 211a has the above-described through hole 2110.

The second portion 211b is provided so as to surround the hammer 5. Further, the second portion 211b is provided so as to surround a drive shaft 42, which will be described later. In other words, the second portion 211b accommodates the hammer 5 and the drive shaft 42.

The thickness T1 of the first portion 211a is greater than the thickness T2 of the second portion 211b. A preferable ratio between the thickness T1 and the thickness T2 is, for example, in the range of 1.5 to 2.5. In this embodiment, the thickness T1 is the length measured along the radial direction of the first portion 211a. In this embodiment, the thickness T2 is the length measured along the radial direction of the second portion 211b.

Note that when the first portion 211a has a plurality of portions having different thicknesses, the thickness T1 of the first portion 211a is defined as, for example, the average thickness of the entire first portion 211a. The same applies to the thickness T2 of the second portion 211b.

The grip portion 22 protrudes from the outer peripheral surface of the housing portion 21 in one direction along the radial direction of the housing portion 21 . More specifically, the grip portion 22 protrudes from the second housing portion 212. The above-mentioned one direction is along the up-down direction. The grip portion 22 is formed into a hollow cylindrical shape that is elongated in one direction. The operator can grasp the grip portion 22 and perform work such as tightening screws. Furthermore, the grip section 22 holds an operation section 13 that receives operations from an operator.

The internal space of the grip part 22 is connected to the internal space of the accommodating part 21. The accommodating part 21 is connected to one end of the grip part 22 in the longitudinal direction, and the mounting part 23 is connected to the other end.

A battery pack is detachably attached to the attachment part 23. The impact rotary tool 1 operates using a battery pack as a power source. That is, the battery pack is a power source that supplies current to drive the motor 3. The battery pack is not a component of the impact rotary tool 1. However, the impact rotary tool 1 may include a battery pack.

(3) Motor As shown in FIG. 2, the motor 3 is housed in the housing portion 21 of the housing 2. The motor 3 is, for example, a brushless motor. The motor 3 includes a rotor 31 having a rotating shaft 311 and a permanent magnet, and a stator 32 having a coil. The rotor 31 rotates relative to the stator 32 due to the electromagnetic interaction between the permanent magnets and the coils.

Moreover, the motor 3 is a servo motor. The torque and rotational speed of the motor 3 change according to control by the control circuit 12 (see FIG. 1). Control circuit 12 is a servo driver. The control circuit 12 controls the operation of the motor 3 through feedback control that controls the torque and rotational speed of the motor 3 to approach target values.

The worker operates the operation unit 13. Specifically, the operator pulls in the operating section 13. The control circuit 12 determines the target value of the rotational speed of the motor 3 according to the amount of retraction of the operating section 13 . The control circuit 12 increases the target value of the rotational speed of the motor 3 as the retraction amount increases.

The drive circuit 11 (see FIG. 2) includes a substrate and a plurality of electronic components mounted on the substrate. The plurality of electronic components include a plurality of power elements that constitute an inverter circuit. Each power element is, for example, a FET (Field Effect Transistor) element.

Control circuit 12 controls motor 3 via drive circuit 11 . That is, the control circuit 12 controls the power supplied to the motor 3 via the plurality of power elements (inverter circuits) by switching on/off the plurality of power elements of the drive circuit 11.

(4) Transmission mechanism As shown in FIG. 2, the transmission mechanism 4 is housed in the housing portion 21 of the housing 2. The transmission mechanism 4 transmits the power of the motor 3 to the hammer 5. This causes the hammer 5 to rotate.

The transmission mechanism 4 includes a planetary gear mechanism 41, a drive shaft 42, a return spring 43, two first spherical bodies 44 (steel balls), two second spherical bodies 45 (steel balls), and a ring 46. ,including.

The planetary gear mechanism 41 converts the rotation speed and torque of the rotating shaft 311 of the motor 3 into a predetermined rotation speed and predetermined torque. The planetary gear mechanism 41 is a speed reduction device. Torque of the rotating shaft 311 of the motor 3 is transmitted to the drive shaft 42 via the planetary gear mechanism 41. The torque of the drive shaft 42 is transmitted to the hammer 5. This causes the hammer 5 to rotate.

The return spring 43 of this embodiment is a conical coil spring. The return spring 43 applies a force pushing the hammer 5 forward. A ring 46 is arranged between the return spring 43 and the hammer 5. Two second spherical bodies 45 are sandwiched between the ring 46 and the hammer 5. Thereby, the hammer 5 is rotatable relative to the return spring 43.

(5) Hammer, Anvil, and Output Shaft The impact rotary tool 1 of this embodiment is an electric impact driver that tightens screws while performing an impact operation. In the impact operation, a striking force is applied from the hammer 5 to the anvil 6, and the striking force is transmitted to the tip tool via the output shaft 7.

As shown in FIGS. 3 to 5, the hammer 5 includes a hammer body 51 and two hammer claws 52. The shape of the hammer body 51 is cylindrical. The two hammer claws 52 protrude forward from the hammer body 51. The hammer body 51 has a through hole 510 through which the drive shaft 42 passes.

The hammer body 51 has two grooves 511 on the inner peripheral surface of the through hole 510. As shown in FIG. 2, the drive shaft 42 has two grooves 421 on its outer peripheral surface. The two groove portions 421 are connected. A corresponding first spherical body 44 is sandwiched between each groove portion 511 and the corresponding groove portion 421. The groove portion 511, the groove portion 421, and the first spherical body 44 constitute a cam mechanism. While the first spherical body 44 moves in the grooves 511 and 413, the hammer 5 is movable in the axial direction (back and forth direction) of the drive shaft 42, and It is rotatable. As the hammer 5 moves forward or backward along the axial direction of the drive shaft 42, the hammer 5 rotates with respect to the drive shaft 42.

The anvil 6 faces the hammer main body 51 in the front-back direction. As shown in FIGS. 3 to 5, the anvil 6 includes an anvil body 61, two anvil claws 62, and two first contact portions 63. The anvil body 61 has a cylindrical shape. The two anvil claws 62 protrude from the anvil body 61 in the radial direction of the anvil body 61. The two first contact portions 63 protrude forward from the anvil body 61. That is, the two first contact portions 63 protrude from the anvil body 61 in the thrust direction. The two first contact portions 63 are lined up in the rotation direction of the anvil 6.

The anvil body 61 has a first recess 611 on the rear surface into which the tip of the drive shaft 42 is inserted. Further, the anvil body 61 has a second recess 612 on the front surface into which the buffer member 8 is inserted.

When the hammer 5 rotates, the two hammer claws 52 push the two anvil claws 62 in the rotational direction of the hammer 5, causing the anvil 6 to rotate.

As shown in FIGS. 4 and 7, the anvil 6 has a first contact surface C1 and a first opposing region F1.

The first contact surface C1 is a surface that comes into contact with a second contact surface C2, which will be described later, of the output shaft 7. The first contact surface C1 faces and contacts the second contact surface C2 in the rotational direction of the anvil 6. The first contact surface C1 is a surface of the two first contact portions 63, and is a surface along the front-rear direction.

The first facing area F1 is an area facing a second facing area F2, which will be described later, of the output shaft 7. A part of the first opposing region F1 is a region of the front surface of the anvil body 61 excluding the region where the two first contact portions 63 are provided. Another part of the first opposing region F1 is the front surface of each of the two first contact parts 63.

The output shaft 7 includes an output shaft main body 71 and two second contact parts 72. The output shaft main body 71 has a cylindrical shape. The output shaft main body 71 is passed through the through hole 2110 (see FIG. 1) of the housing 2, and the front end of the output shaft main body 71 is exposed to the outside of the housing 2. The output shaft main body 71 has a recess 711 on the rear surface into which the buffer member 8 is inserted. The two second contact portions 72 protrude rearward from the output shaft main body 71. That is, the two second contact portions 72 protrude from the output shaft main body 71 in the thrust direction. The two second contact portions 72 are lined up in the rotational direction of the output shaft 7.

The output shaft main body 71 has a column portion 71a and a stepped portion 71b. In other words, the output shaft 7 has a pillar portion 71a and a stepped portion 71b. The column portion 71a is formed in a cylindrical shape extending in the front-rear direction. The step portion 71b is connected to the rear end of the column portion 71a. When viewed from the front side, the stepped portion 71b protrudes away from the center of the column portion 71a (see FIG. 4). More specifically, the step portion 71b of this embodiment is formed into a cylindrical shape having a larger diameter than the column portion 71a.

As shown in FIGS. 5 and 7, the output shaft 7 has a second contact surface C2 and a second opposing region F2.

The second contact surface C2 is a surface that contacts the first contact surface C1 of the anvil 6. The second contact surface C2 faces and contacts the first contact surface C1 in the rotational direction of the anvil 6. The output shaft 7 receives the rotational force of the anvil 6 at the second contact surface C2 and rotates. The second contact surface C2 is a surface of the two second contact portions 72, and is a surface along the front-rear direction.

The second facing area F2 is an area facing the first facing area F1 of the anvil 6. A part of the second facing region F2 is a region of the rear surface of the output shaft main body 71 excluding the region where the two second contact portions 72 are provided. Another part of the second opposing region F2 is the rear surface of each of the two second contact portions 72.

Thus, the output shaft 7 includes the output shaft main body 71 and the two second contact parts 72, and the two second contact parts 72 protrude from the output shaft main body 71 in the thrust direction. The two second contact parts 72 contact the two first contact parts 63. The two second contact portions 72 receive a force for rotating the output shaft 7 from the two first contact portions 63 .

The output shaft 7 holds a tip tool. More specifically, a tip tool can be attached to and detached from the output shaft 7. In this embodiment, a tip tool is connected to the output shaft 7 via a chuck. The output shaft 7 receives torque from the motor 3 and rotates together with the chuck and the tip tool.

When the anvil 6 rotates, the two first contact parts 63 of the anvil 6 push the two second contact parts 72 of the output shaft 7 in the direction of rotation of the anvil 6, causing the output shaft 7 to rotate. The output shaft 7 rotates at the same rotation speed as the anvil 6.

The direction of rotation of the anvil 6 matches the direction of rotation of the hammer 5. As shown in FIG. 6, the anvil 6 and the output shaft 7 are configured such that the unevenness formed by the two first contact parts 63 and the unevenness formed by the two second contact parts 72 mesh with each other.

The chuck and the tip tool are not components of the impact rotary tool 1. However, the impact rotary tool 1 may include at least one of a chuck and a tip tool. Further, a tip tool may be directly connected to the output shaft 7 without using a chuck.

The tip tool is, for example, a driver bit. The tip tool fits into a screw (bolt, screw, etc.) to be worked on. By rotating the tip tool in a state where the tip tool is fitted with the screw, it becomes possible to perform operations such as tightening or loosening the screw.

When the impact rotary tool 1 is not performing an impact operation, the two hammer claws 52 and the two anvil claws 62 are in contact with each other in the rotational direction of the hammer 5, and the hammer 5 and anvil 6 rotate at the same rotation speed. do. Therefore, at this time, the drive shaft 42, the hammer 5, the anvil 6, and the output shaft 7 rotate at the same number of rotations.

The impact rotary tool 1 performs an impact operation when a torque condition regarding the magnitude of the torque (hereinafter referred to as load torque) applied to the output shaft 7 is satisfied. The impact operation is an operation in which impact force is applied from the hammer 5 to the anvil 6. In this embodiment, the torque condition is that the load torque is equal to or greater than a predetermined value. That is, as the load torque increases, the component of the force generated between the hammer 5 and the anvil 6 in the direction of retracting the hammer 5 also increases. When the load torque exceeds a predetermined value, the hammer 5 moves backward while compressing the return spring 43. Then, as the hammer 5 moves backward, the two hammer claws 52 of the hammer 5 get over the two anvil claws 62 of the anvil 6, and the hammer 5 rotates. Thereafter, the hammer 5 receives the return force from the return spring 43 and moves forward. Then, when the drive shaft 42 rotates approximately half a rotation, the two hammer claws 52 of the hammer 5 collide with the side surfaces 620 (see FIG. 3) of the two anvil claws 62 of the anvil 6. The two hammer claws 52 of the hammer 5 collide with the two anvil claws 62 of the anvil 6 every time the drive shaft 42 rotates approximately half a rotation. That is, the hammer 5 applies a striking force to the anvil 6 every time the drive shaft 42 rotates approximately half a rotation.

In this manner, in the impact rotary tool 1, collisions between the hammer 5 and the anvil 6 repeatedly occur. The torque generated by this collision allows the screw to be tightened more strongly than when there is no collision.

(6) Buffer member As shown in FIGS. 4 and 7, the buffer member 8 includes an elastic member 81 and an adjustment member 82. The shapes of the elastic member 81 and the adjustment member 82 are, for example, cylindrical.

The elastic member 81 is an elastic body such as rubber. The elastic member 81 is elastically deformed in the thrust direction (front-back direction).

The adjustment member 82 is made of metal, for example. The adjustment member 82 is formed separately from the anvil 6 and the output shaft 7.

The modulus of elasticity of the adjustment member 82 in the thrust direction is greater than the modulus of elasticity of the elastic member 81 in the thrust direction. The elastic member 81 and the adjustment member 82 are arranged in the thrust direction.

The buffer member 8 is sandwiched between the anvil 6 and the output shaft 7. More specifically, the adjustment member 82 is inserted into the second recess 612 of the anvil 6, and the elastic member 81 is inserted into the recess 711 of the output shaft 7. The elastic member 81 is sandwiched between the adjustment member 82 and the output shaft 7. The adjustment member 82 is sandwiched between the elastic member 81 and the anvil 6.

The buffer member 8 is sandwiched between the anvil 6 and the output shaft 7, thereby regulating the distance between the anvil 6 and the output shaft 7. That is, since the buffer member 8 is sandwiched between the anvil 6 and the output shaft 7, the distance between the anvil 6 and the output shaft 7 is determined by the length of the buffer member 8 in the thrust direction.

The buffer member 8 is arranged on the central axis of the output shaft 7. Therefore, the stress applied to the anvil 6 and the output shaft 7 is likely to be distributed isotropically around the central axis of the output shaft 7. In other words, stress concentration on the anvil 6 and the output shaft 7 can be suppressed.

The force acting on the anvil 6 from the hammer 5 may include a forward component. Therefore, the anvil 6 may move forward toward the output shaft 7 while compressing the elastic member 81 due to the force received from the hammer 5 . FIG. 7 shows the positional relationship between the anvil 6 and the output shaft 7 in a state where no forward force is acting on the anvil 6 from the hammer 5. FIG. 8 shows the positional relationship between the anvil 6 and the output shaft 7 in a state where a forward force is applied to the anvil 6 from the hammer 5. As the anvil 6 moves forward, the length of the elastic member 81 in the front-rear direction decreases from length L1 to length L11. Further, as the anvil 6 moves forward, the length of the gap between the first opposing region F1 and the second opposing region F2 is shortened from the lengths W1 and W2 to the lengths W11 and W12. Lengths W1 and W11 are the lengths of the gaps between the anvil body 61 and the two second contact parts 72, and lengths W2 and W12 are the lengths of the gaps between the output shaft body 71 and the two first contact parts 63. It is the length.

(7) First Bearing and Second Bearing As shown in FIG. 2, the first bearing 91 is held in the housing 2. More specifically, the first bearing 91 is held in the first housing part 211. The first bearing 91 is in contact with the two first contact parts 63 and the two second contact parts 72, and rotatably supports the anvil 6 and the output shaft 7.

The first bearing 91 is, for example, a needle bearing. By using a needle bearing as the first bearing 91, it is possible to reduce the possibility that vibrations in the thrust direction of the anvil 6 and the output shaft 7 are directly transmitted to the first bearing 91. Thereby, it is possible to reduce the possibility that the load in the thrust direction will be concentrated near the contact point with the first bearing 91 among the anvil 6 and the output shaft 7, thereby improving the durability of the anvil 6 and the output shaft 7. I can do it.

The external shape of the first bearing 91 is annular (see FIG. 4). The first bearing 91 surrounds the two first contact portions 63 of the anvil 6 and the two second contact portions 72 of the output shaft 7 . More specifically, the first bearing 91 surrounds the two first contact portions 63 from their front ends to their rear ends. Further, the first bearing 91 surrounds the two second contact portions 72 from their front ends to their rear ends.

The first bearing 91 is in contact with the two first contact portions 63 of the anvil 6 and the anvil body 61 in order to rotatably support the anvil 6.

The first bearing 91 contacts the two second contact portions 72 of the output shaft 7 and the output shaft main body 71 in order to rotatably support the output shaft 7 .

The second bearing 92 is arranged further forward than the first bearing 91. The second bearing 92 is held in the housing 2. More specifically, the second bearing 92 is held in the first housing part 211. The second bearing 92 is provided so as to surround the column portion 71a of the output shaft 7. The inner surface of the second bearing 92 is in contact with the outer surface of the column portion 71a. The second bearing 92 rotatably supports the output shaft 7.

The second bearing 92 is, for example, a ball bearing. The external shape of the second bearing 92 is annular (see FIG. 4).

The second bearing 92 is in contact with the output shaft body 71 in order to rotatably support the output shaft 7. By providing the second bearing 92, it is possible to reduce the possibility that shaft wobbling of the output shaft 7 will occur.

Further, in order to suppress backlash of the first bearing 91 and the second bearing 92 in the front-rear direction, a first stopper 93 and a second stopper 94 are provided (see FIGS. 2 and 4).

The first stopper 93 has an annular shape. The first stopper 93 is arranged behind the first bearing 91. The first stopper 93 faces the first bearing 91 .

The shape of the second stopper 94 is annular. The second stopper 94 is arranged in front of the first bearing 91. More specifically, the second stopper 94 is arranged between the first bearing 91 and the second bearing 92. The second stopper 94 faces the first bearing 91 and the second bearing 92.

When the first bearing 91 attempts to move in the front-rear direction, it comes into contact with the first stopper 93 or the second stopper 94, thereby restricting the movement of the first bearing 91. Furthermore, when the second bearing 92 attempts to move rearward, it comes into contact with the second stopper 94, thereby restricting the movement of the second bearing 92. Further, the front surface of the stepped portion 71b of the output shaft 7 faces the rear surface of the second stopper 94. When the output shaft 7 attempts to move forward, the stepped portion 71b contacts the second stopper 94, thereby restricting the movement of the output shaft 7. The second stopper 94 is arranged between the step portion 71b and the second bearing 92.

A forward force is transmitted to the first portion 211a of the housing 2 from the stepped portion 71b of the output shaft 7 via the second bearing 92. That is, when the output shaft 7 is pushed forward by the thrust direction (forward) component of the force transmitted from the anvil 6, the forward force is transmitted to the second bearing 92 via the second stopper 94, and the A forward force is transmitted to the first portion 211a through the two bearings 92. More specifically, the forward force is transmitted from the second bearing 92 to the bottom surface of the recess 2111 (periphery of the through hole 2110) provided on the inner surface of the first portion 211a.

(8) Amount of Compression of Elastic Body As mentioned above, as a forward force is applied from the hammer 5 to the anvil 6, the anvil 6 compresses the elastic member 81 while compressing the output shaft 7. It may move forward to get closer. Here, when the anvil 6 collides with the output shaft 7 and vibration is generated, a collision sound is generated from the anvil 6 and the output shaft 7, or the vibration is transmitted to the housing 2 and the entire housing 2 generates a sound. Well, I don't like it. Furthermore, when the housing 2 vibrates, the vibrations may be transmitted to the worker who is gripping the housing 2, which may impede the comfort of the worker's work. Therefore, in the impact rotating tool 1 of this embodiment, the parameters of the buffer member 8 are designed to reduce the possibility that the anvil 6 will collide with the output shaft 7. The parameters of the buffer member 8 include, for example, the lengths of the elastic member 81 and the adjustment member 82 in the thrust direction, the elastic modulus of the elastic member 81 in the thrust direction, and the like.

Specifically, when the maximum load transmitted from the hammer 5 is applied to the elastic member 81, the second opposing region F2 faces the first opposing region F1 with a gap in the thrust direction. , the parameters of the buffer member 8 are designed. The magnitude of the maximum load transmitted from the hammer 5 to the elastic member 81 depends on the shape and elastic modulus of the return spring 43, the rotational speed of the motor 3, and the like.

Distance in the thrust direction between the first opposing region F1 and the second opposing region F2 (lengths W1, W2) when a load of a predetermined size smaller than the above maximum load is applied to the elastic member 81 It is sufficient if the compression amount P defined next is smaller than that. The amount of compression P is calculated from the length L1 of the elastic member 81 in the thrust direction (see FIG. 7) when the predetermined load is applied to the elastic member 81, and the amount of compression P when the maximum load is applied to the elastic member 81. This is the amount obtained by subtracting the length L11 (see FIG. 8) of the elastic member 81 in the thrust direction. Thereby, the possibility that the anvil 6 and the output shaft 7 will collide when the maximum load is applied to the elastic member 81 can be reduced.

The predetermined size may be zero. In other words, when a predetermined amount of load is applied to the elastic member 81, the elastic member 81 may be in an unloaded state.

Further, the elastic member 81 may be subjected to a load not only from the hammer 5 but also from the output shaft 7 . Therefore, there is a possibility that a load larger than the maximum load transmitted from the hammer 5 to the elastic member 81 is applied to the elastic member 81 . Even in such a case, it is preferable that the first opposing region F1 and the second opposing region F2 face each other with a gap in the thrust direction.

Therefore, when a load is applied to the elastic member 81 that is less than the upper limit of the elastic range of the elastic member 81, the second opposing region F2 faces the first opposing region F1 with a gap in the thrust direction. The parameters of the buffer member 8 may be designed. For example, when the elastic member 81 is subjected to a load equal to or less than a predetermined times the upper limit of the elastic range of the elastic member 81 (the predetermined times is less than 1 times, for example, 0.9 times), the second opposing region F2 The parameters of the buffer member 8 may be designed such that the buffer member 8 faces the first opposing region F1 with a gap in the thrust direction.

Further, the buffer member 8 of this embodiment includes an adjustment member 82 in addition to the elastic member 81. The adjustment member 82 has a higher elastic modulus than the elastic member 81. More specifically, the adjustment member 82 is hardly compressively deformed.

The elastic member 81 and the adjustment member 82 are lined up in the thrust direction. Therefore, compared to the case where the buffer member 8 includes only the elastic member 81, the length of the elastic member 81 in the thrust direction can be shortened by the length of the adjustment member 82.

When the elastic member 81 is shorter in the thrust direction, the elastic member 81 is less likely to deform. In other words, the shorter the elastic member 81 is in the thrust direction, the smaller the amount of compression of the elastic member 81 when a predetermined force in the thrust direction is applied to the elastic member 81. Therefore, when the elastic member 81 is shorter in the thrust direction, the distance between the first opposing region F1 and the second opposing region F2 (gap lengths W1, W2) due to the thrust direction force being applied to the elastic member 81 becomes smaller. The amount of change becomes smaller. Therefore, the distance between the first opposing region F1 and the second opposing region F2 when a predetermined force in the thrust direction is not applied to the elastic member 81 can be further reduced, and the distance between the first opposing region F1 and the second opposing region F2 can be further reduced. The length from the end to the front end of the output shaft 7 can be shortened. Therefore, the impact rotary tool 1 can be made smaller.

(9) Reinforcement by the first bearing The first bearing 91 of the present embodiment is in contact with the first contact portion 63 of the anvil 6 and the second contact portion 72 of the output shaft 7, and the anvil 6 and the output shaft 7 are in contact with each other. rotatably supported. The mechanical strength of the first contact portion 63 and the second contact portion 72 is reinforced by contacting the first bearing 91 . In particular, the first contact portion 63 and the second contact portion 72 have reinforced mechanical strength against vibrations in the radial direction of the output shaft 7. This improves the durability of the anvil 6 and the output shaft 7.

Further, in the configuration of the anvil 6, the first contact portion 63 has a lower rigidity than the anvil main body 61, and in the configuration of the output shaft 7, the second contact portion 72 has a lower rigidity than the output shaft main body 71. By reinforcing the first contact portion 63 and the second contact portion 72, it is possible to extend the life of the anvil 6 and the output shaft 7.

(10) Suppression of Sound When a force that pushes the output shaft 7 forward, such as a force that vibrates the output shaft 7 in the front-rear direction, the first A forward force is transmitted to portion 211a. This allows the first portion 211a to vibrate. Further, vibration can be transmitted from the first portion 211a to the second portion 211b.

Since the thickness T1 of the first portion 211a is larger than the thickness T2 of the second portion 211b, the vibration of the first portion 211a is a relatively low amplitude (that is, a small sound) and a relatively high frequency vibration. becomes.

Further, since the thickness T1 of the first portion 211a and the thickness T2 of the second portion 211b are different, the resonance frequency of the first portion 211a and the resonance frequency of the second portion 211b are different. Due to the difference in resonance frequency, the vibration is attenuated when it is transmitted from the first portion 211a to the second portion 211b.

In this way, by making the thickness T1 larger than the thickness T2, the sound generated from the housing 2 can be reduced.

Further, in the impact rotary tool 1, the stepped portion 71b of the output shaft 7 is provided separately from the two anvil claws 62 of the anvil 6. That is, the stepped portion 71b for dissipating the vibration of the output shaft 7 to the housing 2 is provided separately from the two anvil claws 62 that receive the impact force from the hammer 5. Therefore, the vibration of the housing 2 can be suppressed compared to the case where the vibration is directly released from the two anvil claws 62 to the housing 2. Here, when the maximum load transmitted from the hammer 5 is applied to the elastic member 81, it is preferable that no forward force is transmitted from the two anvil claws 62 to the housing 2. In other words, it is preferable that the two anvil claws 62 do not contact the housing 2 at this time, and that no other members (such as the first stopper 93) are sandwiched between the two anvil claws 62 and the housing 2. . Thereby, vibration of the housing 2 can be suppressed. It is also preferable that no forward force is transmitted from the two anvil claws 62 to the housing 2 when the elastic member 81 is loaded with a load that is less than the upper limit of the elastic range of the elastic member 81.

(Modification 1)
Hereinafter, the impact rotary tool 1 according to Modification Example 1 will be described with reference to FIG. 9. Components similar to those in the embodiment will be given the same reference numerals and descriptions will be omitted.

The impact rotary tool 1 of Modification 1 includes an anvil 6A, an output shaft 7A, and a buffer member 8A instead of the anvil 6, output shaft 7, and buffer member 8.

The anvil 6A includes an anvil body 61, two anvil claws 62, and a first contact portion 63. The anvil body 61 has a cylindrical shape. The two anvil claws 62 protrude from the anvil body 61 in the radial direction of the anvil body 61. The first contact portion 63 has a cylindrical shape. The first contact portion 63 projects forward from the anvil body 61.

The first contact portion 63 has a recess 630 on the front surface into which the second contact portion 72 of the output shaft 7A and the buffer member 8A are inserted. Furthermore, the area of the front surface of the first contact portion 63 excluding the recess 630 is a first facing area F1 facing the output shaft 7A.

The output shaft 7A includes an output shaft main body 71 and a second contact portion 72. The output shaft main body 71 has a cylindrical shape. The shape of the second contact portion 72 is columnar. The second contact portion 72 projects rearward from the output shaft main body 71. The area of the rear surface of the output shaft main body 71 excluding the area where the second contact portion 72 is provided is a second opposing area F2 that faces the first opposing area F1. In the front-rear direction, a gap is provided between the first opposing area F1 and the second opposing area F2.

The shape of the second contact portion 72 follows the shape of the recess 630 of the first contact portion 63. More specifically, the second contact portion 72 has a square shape when viewed from the rear. When viewed from the front, the recess 630 has a square shape. The outer surface (second contact surface C2) of the second contact portion 72 along the front-rear direction contacts the inner surface (first contact surface C1) of the recess 630 along the front-rear direction. Thereby, the rotation of the anvil 6A is transmitted to the output shaft 7A.

The buffer member 8A includes an elastic member 81 and an adjustment member 82 arranged in the front-rear direction. The buffer member 8A is sandwiched between the second contact portion 72 and the bottom surface of the recess 630.

Further, the first bearing 91 (see FIG. 2) is in contact with the first contact portion 63 and rotatably supports the anvil 6A. The output shaft 7A is supported by the first bearing 91 via the anvil 6A.

Also in the present modification example 1, the distance between the first opposing region F1 of the anvil 6A and the second opposing region F2 of the output shaft 7A can be regulated by the buffer member 8A. Furthermore, in this first modification as well, the anvil 6A and the output shaft 7A can be reinforced by the first bearing 91.

By the way, in this modification 1, the second contact part 72 is inserted into the recess 630 provided in the first contact part 63. On the contrary, the first contact part 63 may be inserted into the recess provided in the second contact part 72.

As a further modification 2 of the present modification 1, as shown in FIG. 10, the second contact portion 72 may be formed in a spline shape. That is, a plurality of teeth may be provided on the outer peripheral surface of the second contact portion 72. Further, a plurality of teeth that mesh with a plurality of teeth of the second contact portion 72 may be provided on the inner surface of the first contact portion 63 .

Note that the shapes of the anvil 6A and the output shaft 7A of Modifications 1 and 2 are different from the shapes of the anvil 6 and the output shaft 7 of the embodiment. Therefore, in order to transmit a torque equivalent to the torque transmitted from the anvil 6 to the output shaft 7 in the embodiment from the anvil 6A to the output shaft 7A in the present modification 1, the diameters of the anvil 6A and the output shaft 7A must be adjusted. It needs to be large compared to the form. On the other hand, with the configuration in which the plurality of first contact portions 63 are arranged in the rotational direction of the anvil 6 and the plurality of second contact portions 72 are arranged in the rotational direction of the output shaft 7 as in the embodiment, the anvil 6 and the output shaft 7 are can be made smaller.

(Other variations of the embodiment)
Other modifications of the embodiment will be listed below. The following modified examples may be realized in combination as appropriate. Further, the following modified examples may be realized by appropriately combining with each of the above-mentioned modified examples.

The number of hammer claws 52 and the number of anvil claws 62 are not limited to two, and may be one or three or more.

The number of first contact portions 63 of the anvil 6 and the number of second contact portions 72 of the output shaft 7 are not limited to two, and may be one or three or more.

Each of the first opposing region F1 and the second opposing region F2 is not limited to a plane, but may be a curved surface.

In the embodiment, the elastic member 81 is located in front of the adjustment member 82. On the other hand, the adjustment member 82 may be located in front of the elastic member 81.

The buffer member 8 may include a plurality of elastic members 81.

The buffer member 8 may include a plurality of adjustment members 82.

In the embodiment, the first bearing 91 surrounds the first contact portion 63 of the anvil 6 . On the other hand, the first bearing 91 may surround a part of the first contact portion 63.

In the embodiment, the first bearing 91 surrounds the second contact portion 72 of the output shaft 7 . On the other hand, the first bearing 91 may surround a part of the second contact portion 72.

It is not essential that the first bearing 91 be in contact with the anvil body 61.

It is not essential that the first bearing 91 be in contact with the output shaft main body 71.

The first bearing 91 is not limited to a needle bearing. The first bearing 91 may be, for example, a bush, a ball bearing, or a double row angular ball bearing.

The second bearing 92 is not limited to a ball bearing. The second bearing 92 may be, for example, a bush, a needle bearing, or a double row angular ball bearing.

The adjustment member 82 may be formed integrally with the anvil 6 or the output shaft 7. However, it is preferable for the adjustment member 82 to be separate from the anvil 6 because stress concentration on the anvil 6 can be suppressed. Further, it is preferable that the adjustment member 82 is separate from the output shaft 7 because stress concentration on the output shaft 7 can be suppressed.

The elastic member 81 and the adjustment member 82 may be coupled to each other by adhesive or the like.

The magnitude of the maximum load transmitted from the hammer 5 to the elastic member 81 may be defined as being equal to the maximum spring force acting on the hammer 5 from the return spring 43.

The anvil 6 and the output shaft 7 may be integrally formed. For example, when the anvil 6 and the output shaft 7 are seamlessly connected, it can be said that the anvil 6 and the output shaft 7 are integrally formed. Alternatively, the anvil 6 and the output shaft 7 may be coupled to each other by adhesive, welding, or the like. When the anvil 6 and the output shaft 7 are integrally formed or connected to each other, it is preferable that the impact rotary tool 1 does not include the buffer member 8. Furthermore, when the anvil 6 and the output shaft 7 are integrally formed or coupled to each other, it is also preferable that the impact rotary tool 1 does not include the first bearing 91.

The shape of the first portion 211a is not limited to a cylindrical shape. The shape of the first portion 211a may be, for example, a hollow truncated cone shape whose outer diameter is smaller toward the front.

The first portion 211a of the embodiment includes not only a portion of the first housing portion 211 where the second bearing 92 is provided, but also a portion where the first bearing 91 is provided. On the other hand, the first portion 211a only needs to include at least a portion where the second bearing 92 is provided. A portion of the first housing portion 211 where the first bearing 91 is provided may be included in the second portion 211b instead of the first portion 211a. In other words, even if the thickness of the part of the first housing part 211 where the first bearing 91 is provided (the second part 211b) is smaller than the part where the second bearing 92 is provided (the first part 211a), good.

The second stopper 94 is not an essential component of the impact rotary tool 1. If the impact rotary tool 1 does not include the second stopper 94, forward force may be transmitted from the output shaft 7 to the second bearing 92 by contact between the output shaft 7 and the second bearing 92.

The second bearing 92 does not need to be provided near the front end of the first portion 211a as in the embodiment. It is sufficient that the second bearing 92 rotatably supports the output shaft 7 and is provided at a position where forward force is transmitted from the output shaft 7 .

In the embodiment, the first accommodating part 211 and the second accommodating part 212 of the housing 2 are connected to each other. Alternatively, the first accommodating part 211 and the second accommodating part 212 may be integrally formed. For example, when the first accommodating part 211 and the second accommodating part 212 are seamlessly connected, it can be said that the first accommodating part 211 and the second accommodating part 212 are integrally formed.

(summary)
The following aspects are disclosed from the embodiments described above.

The impact rotary tool (1) according to the first aspect includes a hammer (5), an anvil (6, 6A), an output shaft (7, 7A), a housing (2), and a bearing (second bearing 92). and. The hammer (5) receives power from the motor (3) and rotates. The anvil (6, 6A) rotates by receiving a striking force from the hammer (5) in the rotational direction of the hammer (5). The output shaft (7, 7A) is arranged in front of the anvil (6, 6A), is configured to hold the tip tool, and rotates together with the anvil (6, 6A). The housing (2) accommodates the hammer (5) and the anvil (6, 6A). The bearing (second bearing 92) rotatably supports the output shaft (7, 7A). The housing (2) has a cylindrical first portion (211a) and a cylindrical second portion (211b). The first portion (211a) is provided to surround the bearing (second bearing 92) and holds the bearing (second bearing 92). The second part (211b) is arranged on the rear side of the first part (211a). The first portion (211a) is configured such that forward force is transmitted from the output shaft (7, 7A) via the bearing (second bearing 92). The thickness (T1) of the first portion (211a) is greater than the thickness (T2) of the second portion (211b).

According to the above configuration, forward force is transmitted from the output shaft (7, 7A) to the first portion (211a) via the bearing (second bearing 92). As a result, the first part (211a) can vibrate, but since the first part (211a) is thicker than the second part (211b), the vibration of the first part (211a) has a relatively low amplitude, In addition, the vibration has a relatively high frequency. Furthermore, when vibration is transmitted from the first part (211a) to the second part (211b), the difference in resonance frequency due to the difference in thickness between the first part (211a) and the second part (211b) As a result, vibrations are damped. Therefore, the sound generated from the housing (2) can be reduced.

Moreover, in the impact rotary tool (1) according to the second aspect, the output shaft (7, 7A) has a column part (71a) and a step part (71b) in the first aspect. The column portion (71a) is formed in a cylindrical shape extending in the front-rear direction. The stepped portion (71b) is connected to the rear end of the column portion (71a). The bearing (second bearing 92) is provided so as to surround the column (71a). Seen from the front side, the step portion (71b) protrudes away from the center of the column portion (71a). The first portion (211a) is configured such that forward force is transmitted from the step portion (71b) via the bearing (second bearing 92).

According to the above configuration, the output shaft (7, 7A) can be forward-directed from the output shaft (7, 7A) to the first portion (211a) via the bearing (second bearing 92) without providing a complicated structure to the output shaft (7, 7A). power can be transmitted. Therefore, the output shaft (7, 7A) can be easily manufactured, and manufacturing costs can be reduced.

Moreover, the impact rotary tool (1) according to the third aspect further includes a buffer member (8, 8A) in the first or second aspect. The buffer members (8, 8A) include elastic members (81) that are elastically deformed in the front-rear direction. The output shaft (7, 7A) is separate from the anvil (6, 6A), and rotates together with the anvil (6, 6A) by receiving a force from the anvil (6, 6A) in the rotational direction of the anvil (6, 6A). do. The buffer member (8, 8A) is sandwiched between the anvil (6, 6A) and the output shaft (7, 7A).

According to the above configuration, the possibility that the anvil (6, 6A) collides with the output shaft (7, 7A) can be reduced. Therefore, it is possible to reduce the possibility that collision noise will be generated and vibrations caused by the collision will be transmitted to the housing (2).

Further, in the impact rotary tool (1) according to the fourth aspect, in any one of the first to third aspects, the second portion (211b) is provided so as to surround the hammer (5).

According to the above configuration, the length of the first portion (211a) in the front-rear direction can be shortened compared to the case where the first portion (211a) surrounds the hammer (5). By shortening the length of the thick first portion (211a) in the front-rear direction, it is possible to reduce the weight of the impact rotary tool (1).

Further, in the impact rotary tool (1) according to the fifth aspect, in any one of the first to fourth aspects, the first portion (211a) is formed integrally with the second portion (211b). .

According to the above configuration, the number of members can be reduced compared to the case where the first part (211a) and the second part (211b) are separate bodies.

Further, in the impact rotary tool (1) according to the sixth aspect, in any one of the first to fifth aspects, the outer diameter of the first portion (211a) is greater than the outer diameter of the second portion (211b). It's also small.

According to the above configuration, it is possible to reduce the possibility that the first portion (211a) interferes with the work object (screw, etc.). Therefore, it becomes easier for the operator to perform work using the impact rotary tool (1).

Furthermore, in the impact rotary tool (1) according to the seventh aspect, in the sixth aspect, the second portion (211b) has a front end portion (211f) that includes the front end of the second portion (211b). The front end portion (211f) is formed into a truncated cone shape with the outer diameter increasing toward the rear.

According to the above configuration, the outer diameter of the second portion (211b) can be increased.

The configurations other than the first aspect are not essential to the impact rotary tool (1) and can be omitted as appropriate.

1 Impact rotating tool 2 Housing 3 Motor 5 Hammer 6, 6A Anvil 7, 7A Output shaft 8, 8A Buffer member 71a Pillar portion 71b Step portion 81 Elastic member 92 Second bearing (bearing)
211a First part 211b Second part 211f Front end parts T1, T2 Thickness

Claims (7)

A hammer that rotates with power from a motor,
an anvil that rotates in response to a striking force from the hammer in the rotational direction of the hammer;
an output shaft disposed on the front side of the anvil, configured to hold a tip tool, and rotating together with the anvil;
a housing that accommodates the hammer and the anvil;
a bearing rotatably supporting the output shaft;
The housing includes:
a cylindrical first portion that is provided to surround the bearing and that holds the bearing;
a cylindrical second part disposed on the rear side of the first part,
The first portion is configured such that forward force is transmitted from the output shaft via the bearing,
The thickness of the first portion is greater than the thickness of the second portion.
Impact rotary tool. The output shaft is
A cylindrical pillar part along the front-back direction,
a step part connected to the rear end of the pillar part,
The bearing is provided so as to surround the column part,
When viewed from the front side, the step portion protrudes away from the center of the column portion,
The first portion is configured such that the forward force is transmitted from the step portion through the bearing.
The impact rotary tool according to claim 1. further comprising a buffer member including an elastic member that elastically deforms in the front-rear direction,
The output shaft is separate from the anvil, and rotates together with the anvil in response to a force from the anvil in a rotational direction of the anvil,
the buffer member is sandwiched between the anvil and the output shaft;
The impact rotary tool according to claim 1. the second portion is provided to surround the hammer;
The impact rotary tool according to claim 1. The first part is integrally formed with the second part,
The impact rotary tool according to claim 1. The outer diameter of the first portion is smaller than the outer diameter of the second portion.
The impact rotary tool according to claim 1. The second part has a front end including a front end of the second part,
The front end portion is formed in a truncated conical shape with an outer diameter larger toward the rear side.
The impact rotary tool according to claim 6.

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