KR20230048185A - Shock buffer for a power tool - Google Patents

Abstract

The present invention relates to power tools, and specifically to a shock absorbing device for power tools that is structurally simple and has excellent durability in absorbing shocks generated by a bit mounted on the tip of a power tool main body or a motor inside the power tool main body and transmitted to a handle. The shock absorbing device for power tools according to the present invention to achieve the above purpose includes a main body with a built-in motor, a handle at both ends connected to the main body, and a shock absorbing part provided at a connection part between the main body and the handle.

Description

Shock buffer for a power tool {Shock buffer for a power tool}

The present invention relates to a power tool, and more particularly, to buffer the shock of a power tool configured to be structurally simple and excellent in durability in buffering shock generated from a bit mounted on the front end of the body of the power tool or a motor inside the body and transmitted to the handle. It's about the device.

The electric tool rotates the bit or reciprocates in a straight line by a built-in motor, thereby increasing the speed of the work and reducing the fatigue of the worker instead of the action to be taken by the operator.

Conventionally, an electric drill as an example of a power tool can drill a hole in an object by mounting a drill on a chuck and rotating the drill with a motor.

Recently, through the development of power tools, power tools that can selectively work in a rotation mode that rotates the bit, an impact mode that applies an impact by moving the bit back and forth in a back-and-forth direction, and a mixed mode that performs both the rotation mode and the impact mote together have been developed. has been developed

However, when operating such a power tool, an impact is generated in the body in which the motor and the bit are mounted. In particular, when operated in an impact mode, the strong impact generated by the bit is transmitted to the operator's wrist through the body and the handle. Therefore, when the impact mode work is continuously performed, fatigue is concentrated on the operator's wrist due to the impact, resulting in damage to the musculoskeletal system, and work fatigue also increases.

US Patent US 9,993,915 B2 (2018.06.12.) US Patent US 10,040,184 B2 (2018.08.07.) US Patent US 10,046,451 B2 (2018.08.14.) US Patent US 10,137,562 B2 (2018.11.27.)

The present invention was invented to solve the problems of the prior art as described above, and a shock absorber is installed to buffer the impact at the part connecting the body and handle of the power tool to protect the wrist and reduce fatigue of the operator. The purpose is to provide a shock absorber for power tools configured to be able to.

A shock absorber for a power tool according to the present invention for achieving the above object includes a main body with a built-in motor, a handle having both ends connected to the main body, and a shock absorber provided at a connection between the main body and the handle. to be

In addition, according to a preferred embodiment of the present invention, the handle has a left case and a right case, and the body and the handle are connected as the left case and the right case of the handle wrap and assemble the connecting portion of the body.

In addition, according to a preferred embodiment of the present invention, a sliding guide having a closed long hole is formed at the connecting portion of the main body, and a pusher inserted into the long hole of the sliding guide is formed inside one of the left case and the right case of the handle. formed, and the pusher expands and contracts the coil spring located in the long hole while moving along the long hole of the sliding guide.

In addition, according to a preferred embodiment of the present invention, the long hole is formed in the longitudinal direction of the main body.

In addition, according to a preferred embodiment of the present invention, a support is formed in contact with the side of the sliding guide on the inside of either or both cases of the left case and the right case of the handle.

In addition, according to a preferred embodiment of the present invention, hooks are formed on the left case and the right case of the handle, slots are formed long in the front and rear directions on the main body, and the left case and the right case of the handle are inserted into the slots with the hooks. As is fixed in alignment, the handle can move forward and backward in the longitudinal direction of the slot.

In addition, according to a preferred embodiment of the present invention, the shock absorber is formed on the spring support fixed between the left case and the right case of the handle, the rod extending from the spring support toward the main body, and the rod penetrates the main body. It includes a stopper having a through hole, a spring support, and a coil spring wrapped around a rod with both ends in contact with the stopper.

Further, according to a preferred embodiment of the present invention, the pusher has a cylindrical or semi-cylindrical structure.

As described above, the shock absorber for power tools according to the present invention reduces the shock transmitted from the main body to the handle by installing a buffer at the part connecting the handle gripped by the operator and the main body, thereby reducing vibration and shock transmitted to the operator. It has the advantage of not only improving workability by reducing , but also preventing damage to the musculoskeletal system in the wrist area during work.

In addition, the shock absorber of the power tool according to the present invention is configured to absorb the shock by accommodating the elastic body to reduce the impact only by assembling the handle and the main body, so that it is structurally simple and is a separate buffer member supporting the elastic body. It has the advantage of reducing the weight of the power tool because it does not require a power tool.

1 is a perspective view showing an impact power tool according to the present invention;
Figure 2 is a partial perspective view of the impact power tool shown in Figure 1,
3 is an exploded perspective view in which the handle of the impact power tool shown in FIG. 1 is disassembled.
Figure 4 is a detailed view showing the upper buffer shown in Figure 2,
Figure 5 is a detailed view showing the lower buffer shown in Figure 2,
6A and 6B are conceptual diagrams illustrating a relationship in which an impact transmitted from the main body is buffered by an upper buffer unit and a lower buffer unit.

Hereinafter, a preferred embodiment of a shock absorber for a power tool according to the present invention will be described in detail with reference to the accompanying drawings.

In the drawings, FIG. 1 is a perspective view showing an impact power tool according to the present invention, FIG. 2 is a cross-sectional view of the impact power tool shown in FIG. 1, and FIG. 3 is an exploded disassembled handle of the impact power tool shown in FIG. It is a perspective view. And Figure 4 is a detailed view showing the upper buffer shown in Figure 2, Figure 5 is a detailed view showing the lower buffer shown in Figure 2, Figures 6a and 6b is the shock transmitted from the main body to the upper buffer and the lower It is a conceptual diagram showing the relationship that is buffered by the buffer unit.

As shown in Figures 1 to 3, the power tool 100 includes a main body 110 with a built-in motor, and a handle 120 connected to the rear end of the main body 110, the upper end of the handle 120 The upper shock absorbing part 130 is mounted on the connection between the body 110 and the lower shock absorbing part 140 on the connection between the lower end of the handle 120 and the main body 110 .

In this way, as the main body 110 and the handle 120 are connected by the upper buffer part 130 and the lower buffer part 140, the vibration and shock generated in the body 110 are transmitted to the handle 120, and the upper buffer buffer Shock and vibration are reduced in the part 130 and the lower buffer part 140. Therefore, there is an advantage in that shock and vibration transmitted to the operator holding the handle 120 are also reduced.

Hereinafter, a shock absorber for a power tool according to the present invention will be described in more detail.

The body 110 is formed by assembling a left case 111L and a right case 111R, a motor is mounted between the left case 111L and the right case 111R, and a bit is provided at the front end of the body 110. is fitted

On the other hand, a battery mounting portion 113 is formed at the lower rear end of the case 111 of the main body 110 where the left case 111L and the right case 111R are assembled, and the battery installed under the battery mounting portion 113 is removed. Power is supplied to the motor.

Both ends of the handle 120 are mounted to the upper rear end of the body case 111 and the battery mounting part 113, respectively. The upper end of the handle 120 is connected to the upper rear end of the body case 111, and the battery mounting part 113 The lower end of the handle 120 is connected to.

Here, an upper shock absorbing part 130 is provided at a portion where the top of the handle 120 and the body case 111 are connected, and a lower buffer 140 is provided at a portion where the lower end of the handle 120 and the battery mounting portion 113 are connected. provided

As shown in FIG. 4, the upper shock absorber 130 includes a spring support 131, a pair of rods 133 extending from the spring support 131 toward the front body case 111, and a rod It includes a coil spring 135 surrounding 133.

In coupling the left case 121L and the right case 121R of the handle 120, the left case 121L and the right case 121R are positioned on both sides of the spring support 131 in a matched state, respectively, and the left case ( 121L) and the right case 121R are fastened and fixed with bolts, so that the spring support 131 is fixed to the inside of the handle 120. And the rod 133 extending forward from the spring support 131 passes through the through hole formed in the stopper 115 of the body 110 and is positioned.

Both ends of the coil spring 135 surrounding the circumference of the rod 133 come into contact with the spring support 131 and the stopper 115 of the main body 110 .

That is, the coil spring 135 is pressurized and positioned in a state in contact with the spring support 131 fixed to the handle 120 and the stopper 115 formed on the body 110, so that the stopper ( 115) is moved forward and backward, the impact transmitted to the handle 120 is reduced by the elasticity of the coil spring 135.

Meanwhile, the lower buffer 140 is configured as shown in FIG. 5 .

The lower shock absorbing part 140 is provided at a portion where the battery mounting part 113 of the main body 110 and the lower end of the handle 120 are connected.

The battery mounting portion 113 of the body 110 has a structure formed by combining the left case 111L and the right case 111R of the body 110, and the upper portion of the battery mounting portion 113 is the left case of the handle 120. When the left case 121L and the right case 121R are engaged and fixed in a state where the 121L and the right case 121R are wrapped, the battery mounting portion 113 and the lower end of the handle 120 are fixed in alignment.

In this structure, as shown in FIGS. 6A and 6B, the sliding guide 117 of the closed long hole 117H in which the coil spring 119 is accommodated is formed on the upper surface of the battery mounting part 113, and the handle ( A pusher 123 inserted into the long hole 117H of the sliding guide 117 is formed on the inner surface of the left case 121L or the right case 121R of 120, and the pusher 123 is a battery mounting portion 113 ) It is possible to move in the forward and backward directions along the long hole 117H of the sliding guide 117 while being located in the sliding guide 117 formed in the sliding guide 117 .

The coil spring 119 is located inside the long hole 117H of the sliding guide 117, and the pusher 123 presses the coil spring 119 in a state in contact with the rear end of the coil spring 119.

In this structure, when the battery mounting part 113 of the main body 110 moves backward, the pusher 123 relatively moves forward along the long hole 117H of the sliding guide 117, and the sliding guide 117 The coil spring 119 located inside is pressurized. In this way, the impact transmitted from the main body 110 is transferred to the handle 120 in a buffered state by the expansion and contraction of the coil spring 119 located inside the sliding guide 117 .

On the other hand, the pusher 123 may be configured as a boss for assembling and fixing the left case 121L and the right case 121R of the handle 120 with bolts, and the pusher 123 is formed of the handle 120 On the inner surface of the case 121, a support 124 is formed radially so as to stably come into contact with the side surface of the sliding guide 117. As the left case 121L and the right case 121 of the handle 120 are assembled in a state in which the side surface of the sliding guide 117 is in contact with the support 124, the support 124 reduces the play occurring in the lateral direction, direction, that is, it is configured to be movable only in the direction of the long hole 117H of the sliding guide 117.

In addition, as the left case 121L and the right case 121R of the handle 120 are assembled by bolts in a state located on the left and right sides of the battery mounting portion 113, respectively, on both sides of the case 121 of the handle 120 A hook 125 is formed, and a slot 113S into which the hook 125 is inserted is formed long in the same direction as the long hole 117H of the sliding guide 117 in the battery mounting portion 113. The left case 121L and the right case 121R of the handle 120 in a state in which the hooks 125 formed on both sides of the handle 120 having the structure are matched with the slots 113S formed on both sides of the battery mounting part 113. ) When assembled and fixed with bolts, the hooks 125 formed on both sides of the handle 120 are fixed in a matched state to the slots 113S formed on both sides of the battery mounting part 113. Therefore, the handle 120 can be moved along the longitudinal direction of the slot 113S in the forward and backward directions by the impact.

Meanwhile, in the drawings for explaining the present invention, the pusher 123 is illustrated as having a cylindrical shape, but a portion in contact with the coil spring 119 may be formed in a semi-cylindrical structure, which is a flat plate structure.

100: power tool
110: body
111: case
113: battery mounting part
113S: slot
115: stopper
117: sliding guide
117H: long hole
119: coil spring
120: handle
121: case
123: pusher
124: support
125: hook
130: upper buffer part
131: spring support
133: load
135: coil spring
140: lower buffer part

Claims (8)

A body 110 with a built-in motor;
A handle 120 having both ends connected to the main body 110;
A shock absorber for a power tool, characterized in that it comprises shock absorbing parts (130, 140) provided at the connection between the main body (110) and the handle (120).
According to claim 1,
The handle 120 includes a left case 121L and a right case 121R,
As the left case 121L and the right case 121R of the handle 120 are wrapped around the connection portion of the main body 110 and assembled, the main body 110 and the handle 120 are connected to the impact buffer of the power tool, characterized in that Device.
According to claim 2,
The buffer unit 140,
It is formed at the connection part of the main body 110 and has a sliding guide 117,
A pusher 123 formed inside one of the left case 121L and right case 121R of the handle 120 and inserted into the long hole 117H of the sliding guide 117;
A shock absorber for power tools, characterized in that it includes a coil spring 119 located in the long hole 117H and extending and contracting while the pusher 123 moves along the long hole 117H of the sliding guide 117.
According to claim 3,
The long hole (117H) is a shock absorber for a power tool, characterized in that formed in the longitudinal direction of the main body (110).
According to claim 3,
Impact buffering of electric tools, characterized in that the support 124 in contact with the side surface of the sliding guide 117 is formed on the inside of either or both cases of the left case 121L and the right case 121R of the handle 120. Device.
According to claim 2,
Hooks 125 are formed in the left case 121L and the right case 121R of the handle 120, a slot 113S is formed long in the front and rear directions in the main body 110, and the hook 125 is a slot 113S. ) Power tool characterized in that the handle 120 can move forward and backward in the longitudinal direction of the slot 113S as the left case 121L and the right case 121R of the handle 120 are mated and fixed in a state inserted into the handle 120 shock absorber.
According to claim 2,
The buffer unit 130,
A spring support 131 positioned and fixed between the left case 121L and the right case 121R of the handle 120,
A rod 133 extending from the spring support 131 toward the body 110,
A stopper 115 formed on the main body 110 and having a through hole through which the rod 133 passes;
A shock absorber for a power tool, characterized in that it includes a coil spring 135 positioned around the rod 133 and in contact with both ends of the spring support 131 and the stopper 115.
According to claim 3,
The pusher 123 is a shock absorber for power tools, characterized in that the cylindrical or semi-cylindrical structure.

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