JP2011051024A - Power tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power tool capable putting a dust collecting cup thereon and securing good current-carrying performance. <P>SOLUTION: The power tool 1 has a bit mounting part 20 for fixing a bit 11 provided on a front part 2a of a housing and has the bit 11 turned as the bit mounting part 20 turns. The power tool 1 includes a conductor storage part 7 provided on a front face of the front part 2a of the housing while the bit mounting part 20 is exposed from an opening 23 for guiding the bit mounting part 20. A storage part 25 coaxial with a rotation axis of the bit mounting part 20 and formed in a direction of an enlarged diameter from the rotation axis is formed on an inner peripheral surface of the opening 23. A conductor 30 in contact with an outer peripheral surface of the bit mounting part 20 and an inner side face of the storage part 25 is accommodated in the storage part 25. The bit mounting part 20, the conductor storage part 7 and the conductor 30 are conductive. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a power tool, and more particularly, to a power tool provided with a conductor for ensuring a current-carrying state between a bit tip and a tool casing.

  Conventionally, a power tool such as a concrete drill is known as a tool for making a hole or the like in concrete or the like. The concrete drill has a structure in which a concrete wall or the like is drilled by attaching a bit using high-strength diamond at the tip to the tool tip and rotating it at a high speed.

  By the way, in today's general buildings and the like, there are many structures in which a metal pipe or the like is provided inside a wall surface and a telephone line or the like is provided in the metal pipe. However, it is not easy to determine the installation position of a metal pipe from the outside of the concrete wall, so when drilling a concrete wall with a concrete drill, a hole in the metal pipe etc. is inadvertently opened and a telephone line etc. There was a risk of damage.

  In addition, when drilling reinforced concrete, it is not easy to determine the reinforced concrete part from the outside, so the drilling operation is continued with the bit hitting the reinforced part, and the bit tip is worn or damaged. There was a fear of doing.

  In order to prevent such damages such as telephone lines, there is a method of forcibly stopping the driving of the concrete drill by detecting that the tip of the bit has contacted a metal pipe or the like embedded in the concrete wall. It has been proposed (see, for example, Patent Document 1 and Non-Patent Document 1).

  Specifically, a power supply cable part for supplying electric power and an electric cable part for supplying a weak current are provided in advance in the cord of the cord reel for supplying electric power to the electric tool. In the cord reel, when the bit tip contacts the metal tube, etc., a weak current (from the cord reel to the metal tube, etc. (this metal tube functions as the ground of the building) through the cable, the bit, etc.) (Ground current) is detected, and the power supply from the power supply is cut off in response to this detection. A cord reel having such a function is called a cord reel with a metal sensing function.

Japanese Patent Laid-Open No. 7-205052 (page 3-4, FIG. 2)

“Hataya General Catalog” Hataya Manufacturing Co., Ltd., October 2008, p. 27-p. 30

  By the way, as described above, in the method of detecting the contact of the metal pipe or the like at the tip of the bit and forcibly stopping the driving of the concrete drill, the bit and the electric cable need to be electrically connected. In general, it is easy to ensure the energized state between the tool body and the power cable by guiding the power cable into the tool body. However, since the bit rotates at a high speed, there is a problem that it is not easy to ensure the energized state between the bit and the tool body.

  Thus, in order to ensure the electrical connection between the bit and the main body portion, in the invention shown in Patent Document 1, one end of the energizing member formed from a phosphor bronze plate or a carbon brush is fixed to the outside of the main body portion, A configuration has been proposed in which the other end is in sliding contact with a shank or the like. Further, page 30 of Non-Patent Document 1 describes a configuration in which a contact is fixed to the tip of a depth gauge rod and the end of the contact is sandwiched between shanks and the like.

  However, in the case where the current-carrying member provided in the main body is in sliding contact with the shank or the like, there is a problem that a dust collection cup for preventing the diffusion of dust generated during drilling cannot be attached.

  In addition, a member attached to a depth gauge bar or the like may interfere with work, and there is a risk that workability in a narrow place or the like may be reduced. In addition, since the current-carrying member is in sliding contact with the shank, when replacing the bit, it is necessary to remove the current-carrying member (contactor, etc.) before replacing it. There was a problem of increasing.

  On the other hand, Patent Document 1 discloses a method of electrically connecting a conductive lubricant by enclosing it in a bearing (bearing body) provided between a rotating shaft to which a bit is connected and a main body case. In this method, however, there is a problem that it is not easy to always ensure good electrical conductivity.

  The present invention has been made in view of the above problems, and can be reduced in size with respect to a conventional configuration in which a current-carrying member is provided outside the tool body, and a dust collecting cup is attached to the tool body. It is another object of the present invention to provide an electric tool capable of ensuring good energization performance.

  In order to solve the above-described problems, an electric power tool according to the present invention is provided with a bit mounting portion for fixing a bit at a front portion of the casing, and the bit is rotated as the bit mounting portion rotates. A tool having an opening for guiding the bit mounting portion; and a conductor storage portion provided at the front of the housing in a state where the bit mounting portion is exposed from the opening, On the inner peripheral surface of the opening of the conductor storage portion, there is formed a storage portion formed in the direction of diameter expansion with respect to the rotation shaft of the bit mounting portion, and the storage portion includes an outer periphery of the bit mounting portion. A conductor that contacts the surface is accommodated, and the bit mounting part, the conductor accommodating part, and the conductor have electrical conductivity.

  As described above, according to the electric tool of the present invention, the conductor is stored in the storage portion, and the bit mounting portion and the conductor storage portion rotated by the contact of the conductor with the outer peripheral surface of the bit mounting portion. It is possible to always secure and maintain a current-carrying path with the housing front portion provided. For this reason, when one end of a cord reel with a metal sensing function that detects a weak current (ground current) is connected to the front part of the housing, when the bit comes into contact with a metal tube or a reinforcing bar, A weak current can always be detected by a cord reel with a metal sensing function through a bit, a bit mounting portion, a conductor, a conductor storage portion, and a front portion of the housing. By cutting off the electric power supplied to the cord reel with a metal sensing function or the like, it is possible to prevent inadvertently drilling a metal tube or a reinforcing bar.

  Moreover, the electric power tool mentioned above may be formed with a window portion for exchanging the conductor stored in the storage portion on the front surface of the storage portion. Further, the electric conductor of the electric power tool described above may be more wearable than the electric conductor storage part and the bit mounting part.

  As described above, since the window portion for exchanging the conductor stored in the storage portion is formed on the front surface of the storage portion, the conductor can be easily replaced. In particular, when the wearability of the conductor is higher than that of the conductor housing portion and the bit mounting portion, the conductor wears with the rotation of the bit mounting portion. By exchanging through the window portion, it becomes possible to maintain and secure the conductive performance. In addition, when the wearability of the conductor is higher than that of the conductor housing portion and the bit mounting portion, the conductor housing portion and the bit mounting portion are significantly worn due to active wear of the conductor. Since this can be prevented, the performance of the tool can be maintained indefinitely.

  Further, in the above-described electric power tool, the conductor includes an inner curved portion that has an inner diameter corresponding to the outer peripheral diameter of the bit mounting portion and abuts on the outer peripheral surface of the bit mounting portion, and an outer portion with the end portion largely reversed. And an outer curved portion that has an outer diameter corresponding to the shape of the inner surface of the storage portion and is in contact with the inner surface of the storage portion.

  Thus, the conductor has the inner curved portion that contacts the outer peripheral surface of the bit mounting portion and the outer curved portion that contacts the inner side surface of the storage portion, so that the outer peripheral surface of the bit mounting portion of the conductor and the The contact accuracy with the inner surface of the storage portion can be increased, and the energization path between the bit mounting portion and the conductor storage portion can be reliably secured and maintained.

  In addition, by configuring the shape of the conductor with the inner curved portion and the outer curved portion, the shape can be formed simply by bending and deforming a highly conductive metal rod. Reduction can also be achieved.

  Further, in the above-described electric tool, the conductor has a rod shape, and has a characteristic of maintaining the rod shape when an external force is applied to cause bending, and the storage portion is energized. A mounting member having a property, and the conductor is configured such that a part of the conductor is brought into contact with the outer peripheral surface of the bit mounting portion and the other portion is brought into contact with the mounting member, It may be stored in.

  In this way, the conductor is constituted by a rod-like member that maintains the shape when an external force is applied and the bending occurs, and a part of the conductor is brought into contact with the outer peripheral surface of the bit mounting portion, With the configuration in which the other portion is in contact with the mounting member and is stored in the storage portion, the conductor is in contact with the bit mounting portion and further locked in contact with the mounting member. The energization path between the bit mounting portion and the conductor storage portion can be reliably secured and maintained.

  In addition, since a conductor can be formed by using a rod-like body such as a metal having electrical conductivity, it becomes easy to mold and cost can be reduced.

  As described above, according to the power tool of the present invention, the conductor is stored in the storage portion, and the bit mounting portion and the conductor storage that are rotated when the conductor comes into contact with the outer peripheral surface of the bit mounting portion. It is possible to always secure and maintain a current-carrying path with the front part of the housing where the part is provided. For this reason, when one end of a cord reel with a metal sensing function that detects a weak current (ground current) is connected to the front part of the housing, when the bit comes into contact with a metal tube or a reinforcing bar, A weak current can always be detected by a cord reel with a metal sensing function through a bit, a bit mounting portion, a conductor, a conductor storage portion, and a front portion of the housing. By cutting off the electric power supplied to the cord reel with a metal sensing function or the like, it is possible to prevent inadvertently drilling a metal tube or a reinforcing bar.

It is the perspective view which showed the concrete drill which concerns on this Embodiment. (A) is the sectional side view which showed the concrete drill which concerns on this Embodiment, (b) is the side expanded sectional view which expanded the part shown to A of (a). (A) is the expansion | deployment perspective view which showed the rotational drive transmission part which concerns on this Embodiment, an electroconductive part, and an electrically-conductive metal fitting, (b) is the state in which the rotational drive transmission part, the electroconductive part, and the electrically-conductive metal fitting were assembled. It is the perspective view which showed. (A) is the front view which showed the electrically-conductive metal fitting, (b) is sectional drawing which showed the BB cross section of the electroconductive part shown in FIG.3 (b) from the arrow direction, (c), It is the front view which showed the electroconductive part shown in FIG.3 (b) from the tool front. (A) is the perspective view of the other tool which showed the state by which the rotational drive transmission part, the electroconductive part, and the electrically-conductive metal fitting were assembled, (b) is CC cross section of the electroconductive part shown to (a). It is sectional drawing shown from the arrow direction. (A) is the perspective view of the further different tool which showed the state by which the rotational drive transmission part, the electroconductive part, and the electrically-conductive metal fitting were assembled, (b) showed the electroconductive part shown to (a) from the tool front. It is a front view.

  Hereinafter, an electric tool according to the present invention will be described in detail with reference to the drawings. FIG. 1 is a perspective view showing a concrete drill as a power tool according to Embodiment 1, and FIG. 2 is a side sectional view.

  The concrete drill 1 is roughly configured by a main switch 3, a main motor 4, a rotation drive transmission unit 5, a power assist mechanism unit 6, and a conductive unit (conductor storage unit) 7 disposed in the housing 2.

  The housing 2 includes a front housing (housing front portion) 2a that covers the front portion of the concrete drill 1 and a rear housing 2b that covers the rear portion. The front casing 2a is formed of a member having electrical conductivity (for example, a metal such as aluminum), while the rear casing 2b is formed of a resin casing member.

  A power supply unit 9 is provided at the lower portion of the housing 2, and one end of a power cable 10 extending from the rear lower portion of the housing 2 is electrically connected to the power supply unit 9. . The other end of the power cable 10 is connected to a power source for driving the concrete drill 1 through a cord reel with a metal sensing function (not shown). Furthermore, an electric cable 12 for detecting whether or not the tip of the bit 11 is in contact with a metal tube or the like is provided at one end of the power cable 10, and the tip of the electric cable 12 is made of the above-described aluminum. It is connected to the front case 2a made of metal in a state where electricity can be applied. Moreover, the electric wire cable 12 provided from the other end of the power cable 10 is connected to the energization detection sensor portion of the cord reel.

  The cord reel with a metal sensing function has a function of determining that the tip of the bit 11 has contacted a metal tube or the like by detecting a weak current flowing through the electric cable 12. Since the technical contents are disclosed in detail in Non-Patent Document 1, Patent Document 1, and the like, description in the present embodiment is omitted.

  A grip 14 for holding the concrete drill 1 is formed at the rear end of the housing 2, and the main switch 3 is provided at a position where the finger can be easily turned on / off with the grip 14 held. It has been.

  The main switch 3 is a switch for performing an on / off operation of the concrete drill 1. By turning on this switch, the main motor 4 and the power assist mechanism 6 driven by the power supply unit 9 can be controlled. It is possible.

  The main motor 4 is a motor for rotationally driving the bit 11 attached to the tip of the tool via the rotational drive transmission unit 5. The drive control of the main motor 4 is performed according to the on / off operation of the main switch 3.

  The power assist mechanism 6 is a device for applying an excitation force in the front-rear direction of the tool. The power assist mechanism unit 6 includes a power assist motor 15 and is configured to generate an excitation force by rotating the eccentric weight unit 16 as the power assist motor 15 rotates. The power assist motor 15 is a motor whose rotational output is smaller than that of the main motor 4 and is disposed below the main motor 4. Similarly to the main motor 4, the power assist motor 15 is driven and controlled according to the on / off operation of the main switch 3.

  The rotation drive transmission unit 5 has a role of transmitting a driving force on the rotation shaft 4a of the main motor 4 to the bit 11 (more specifically, to a bit tip 18 installed at the tip of the bit 11). The rotation drive transmission unit 5 is provided with a rotation shaft portion 5a that rotates in conjunction with the rotation of the rotation shaft 4a of the main motor 4, and a bit 11 can be attached to the tip of the rotation shaft portion 5a. Yes.

  Specifically, by using a spanner, the base portion of the shank 21 of the bit 11 is screwed into the screw portion 22 of the shank mounting portion (bit mounting portion) 20 formed at the tip of the rotating shaft portion 5a. The bit 11 is fixed to the tip of the rotating shaft portion 5a. Note that both the bit 11 and the shank mounting portion 20 are formed of a material having electrical conductivity.

  In addition, a conductive portion 7 having a circular opening (opening) 23 formed in the center is provided on the front surface of the tool of the front housing 2a. An oil seal (not shown) is provided on the front housing 2 a side of the conductive portion 7, and the front surface of the rotating shaft portion 5 a is exposed with the shank mounting portion 20 exposed to the outside of the tool through the circular opening 23. By covering, the oil seal of the front housing | casing 2a with respect to the rotating shaft part 5a is provided. Similarly to the bit 11 and the shank mounting portion 20, the conductive portion 7 also has a conductive performance.

2 to 4, the tool front side portion of the conductive portion 7 is concentric (coaxial) O ₁ with the shank mounting portion 20 guided by the circular opening 23. A circular dish-shaped recess (housing portion) 25 formed in the diameter increasing direction is formed, and a rib 26 is formed in an annular shape on the front edge portion. The conductive metal fitting (conductor) 30 can be accommodated in the recess 25 through a space (window portion) 27 between the rib 26 and the outer peripheral surface of the shank mounting portion 20.

  The conductive metal fitting 30 is a metal material having higher wearability (lower hardness) than the shank mounting portion 20 and the conductive portion 7, and has elasticity that can return to its original shape even when an external force is applied. And is bent into a shape as shown in FIG. Specifically, the inner curved portion 30a having an inner diameter corresponding to the outer peripheral diameter of the shank mounting portion 20 and abutting on the outer peripheral surface of the shank mounting portion 20 and the end portion of the inner curved portion 30a are largely reversed and bent outward. Thus, the outer curved portion 30b having an outer diameter corresponding to the ring shape of the inner surface of the recess 25 and abutting on the recess 25 is formed. When the conductive metal fitting 30 is stored in the recess 25, the conductive metal fitting 30 is inserted into the recess 25 through the space between the rib 26 and the shank mounting portion 20 by lightly pressing the outer curved portion 30b. The conductive metal fitting 30 accommodated in the recess 25 can be restored to its original shape due to its elasticity, so that the inner curved portion 30a abuts against the outer peripheral surface of the shank mounting portion 20 and the outer curved portion. The part 30b is maintained in contact with the inner surface of the recess 25.

  By installing the conductive metal fitting 30 in this manner, the shank mounting portion 20 and the conductive portion 7 are electrically energized, and the conductive portion 7 is attached to the front surface of the front housing 2a. The energized state is secured from the bit 11 to the shank mounting portion 20, the conductive metal fitting 30, the conductive portion 7, and the front housing 2a. Furthermore, since one end of the electric wire cable 12 is connected to the front housing 2a, the other end of the electric wire cable 12 is connected to a cord reel with a metal sensing function, whereby an energization path from the bit tip 18 to the cord reel. Can be secured.

  When the concrete drill 1 is driven in a state in which the conductive metal fitting 30 is housed in the recess 25 of the conductive portion 7, the conductive metal fitting 30 can rotate in the recess 25 as the bit 11 rotates. Even when the metal fitting 30 rotates, it is possible to maintain the conductive state between the shank mounting portion 20 and the conductive portion 7 with the conductive metal fitting 30. Accordingly, when the bit tip 18 comes into contact with a metal pipe or the like embedded in the building, the contact causes the cable cable 12, the front housing 2a, the conductive portion 7, the conductive fitting 30, and the shank mounting portion 20 from the cord reel. In addition, the weak current flowing to the metal tube via the bit 11 can be surely detected by the cord reel, and the power supplied from the power cable 10 to the power supply unit 9 is instantaneously cut off by this detection. Is possible.

  Further, since the conductive metal fitting 30 is housed in the recess 25 of the conductive portion 7, a conventionally used dust collection cup can be attached and used in the same manner as in the past. Furthermore, the conductive metal fitting 30 is provided on the conductive portion 7 so as to contact the shank mounting portion 20, but does not directly contact the bit 11, so that the bit 11 is removed from the shank mounting portion 20 when the bit 11 is replaced. Also in the case of detaching / attaching, there is an effect that the conductive metal fitting 30 does not get in the way and does not increase the burden of replacement work.

  Furthermore, since the conductive metal fitting 30 is configured to be housed in the conductive portion 7, the conductive metal fitting 30 does not get in the way when using a depth gauge or the like.

  On the other hand, since the conductive metal fitting 30 is made of a metal material having higher wearability (lower hardness) than the conductive portion 7 and the shank mounting portion 20, the conductive metal fitting 30 is rotated with the rotation of the bit 11. Even so, it is possible to wear only the conductive metal fitting 30 without wearing the conductive portion 7 and the bit 11. When it becomes difficult to maintain the shape of the conductive metal fitting 30 due to wear or the like, and the conductive state of the conductive part 7 and the shank mounting part 20 cannot be maintained, the conductive metal piece 30 is removed from the recess 25 of the conductive part 7. Then, by storing the new conductive metal fitting 30 in the recess 25 of the conductive portion 7, the conductive metal fitting 30 can be easily replaced, and the energized state can be reliably ensured.

  Further, since the conductive portion 30 and the shank mounting portion 20 can be prevented from being significantly worn due to wear of the conductive metal fitting 30, the performance of the tool can be maintained forever.

  Further, since the conductive metal fitting 30 has an inner curved portion 30 a that abuts on the outer peripheral surface of the shank mounting portion 20 and an outer curved portion 30 b that abuts on the inner side surface of the recess 25, The contact accuracy between the outer peripheral surface of the mounting portion 20 and the inner surface of the recess 25 can be increased, and the energization path between the shank mounting portion 20 and the conductive portion 7 can be reliably secured and maintained.

  Further, by forming the shape of the conductive metal fitting 30 with the inner curved portion 30a and the outer curved portion 30b, the outer shape can be formed simply by bending and deforming a highly conductive metal rod, so that the molding burden is easy. In addition, the cost can be reduced.

  Next, an embodiment using a conductive part different from the conductive part 7 described above will be described. In addition, the same code | symbol shall be used about the part which is common in embodiment mentioned above, and the description is abbreviate | omitted.

  FIG. 5A is a perspective view showing a state in which the conductive portion 40 having a configuration different from that of the conductive portion 7, the rotational drive transmission portion 5, and the conductive metal fitting 30 are assembled, and FIG. It is sectional drawing which showed CC cross section of the electroconductive part 40 shown to (a) from the arrow direction.

  The conductive portion 40 is provided on the front surface of the tool of the front housing 2a, and a circular opening (opening) is formed at the center. An oil seal (not shown) is provided on the front casing 2a side of the conductive portion 40, and covers the front surface of the rotating shaft portion 5a in a state where the shank mounting portion 20 is exposed to the outside of the tool through the circular opening. By this, it has the function to hold | maintain the oil seal of the front housing | casing 2a with respect to the rotating shaft part 5a. The conductive part 40 also has conductive performance like the conductive part 7.

As shown in FIG. 5 (a) (b), the tool front side portion of the conductive portion 40, around a slightly offset position from the axis position O ₂ of the shank attachment portion 20 which is guided in a circular opening position O as ₃ (with the center position O ₃ is offset from the axis position O ₂ of the shank attachment portion 20), which is formed in the diameter direction of the shank attachment portion 20 a circular dish-shaped recess (storage portion) 41 is formed The rib 26 is formed in an annular shape at the front edge portion. The conductive metal fitting (conductor) 30 can be accommodated in the recess 41 through a space (window) 27 between the rib 26 and the outer peripheral surface of the shank mounting portion 20.

As shown in FIG. 5 (b), since the center position O ₃ of the recess 41 is slightly shifted from the shaft position O ₂ of the shank mounting portion 20, the conductive metal fitting housed in the recess 41. In the 30 storage spaces, the distance between the outer peripheral surface of the shank mounting portion 20 and the inner surface of the recess 41 is a different distance (non-uniform interval) depending on the peripheral position. Therefore, as shown in FIG. 5B, the inner curved portion 30 a of the conductive metal fitting 30 housed in the recess 41 abuts on the outer peripheral surface of the shank mounting portion 20, and the outer curved portion 30 b is the recess 41. In the state where it abuts on the inner side surface, the conductive metal fitting 30 becomes difficult to rotate in the recess 41, and the state shown in FIG.

  FIG. 6 is a diagram showing still another embodiment. In the above-described embodiment, the case where the conductive metal fitting 30 is formed of an elastic metal rod and is bent into a shape as shown in FIGS. 3 to 5 has been described. However, the shape of the conductive metal fitting 30 is not limited to such a bent shape.

  FIG. 6A is a perspective view showing a state in which the conductive metal fitting 42 having a shape different from that of the conductive metal fitting 30, the rotational drive transmission portion 5, and the conductive portion 7 are assembled, and FIG. It is the front view which showed the electroconductive part 7 shown to (a) from the tool front.

  As shown in FIGS. 6 (a) and 6 (b), the conductive metal fitting 42 is composed of a metal piece having a rod shape, and when the external force is applied to cause bending, the conductive metal fitting 42 is intended to maintain the rod shape. It has. In the recess 25 of the conductive portion 7, a pair of mounting pins 44 that lock the conductive metal fitting 42 in the recess 25 in cooperation with the outer peripheral surface of the shank mounting portion 20 are provided as mounting members. The conductive metal fitting 42 and the mounting pin 44 also have conductive performance.

  When the conductive metal fitting 42 is housed in the recess 25, one end of the conductive metal fitting 42 is connected to one mounting pin 44 with the substantially central portion of the conductive metal fitting 42 being in contact with the outer peripheral surface of the shank mounting portion 20. The other end portion of the conductive metal fitting 42 is brought into contact with the side surface of the other mounting pin 44 on the shank mounting portion 20 side. By storing the conductive metal fitting 42 in this way, as shown in FIG. 6 (b), the conductive metal fitting 42 is in a state where the central portion of the conductive metal fitting 42 abuts against the outer peripheral surface of the shank mounting portion 20 and slightly warps. It is locked by the pair of mounting pins 44. In this way, the conductive metal fitting 42 is brought into contact with the shank mounting portion 20 and is locked while being in contact with the mounting pin 44, whereby the energized state between the shank mounting portion 20 and the conductive portion 7 is secured. .

  Moreover, since the electrically-conductive metal fitting 42 is comprised by the electroconductive metal piece which exhibits a rod shape, it also becomes possible to aim at reduction and cost reduction.

  As mentioned above, although the electric tool which concerns on this invention was demonstrated in detail using drawing, the electric tool which concerns on this invention is not limited only to the structure of the concrete drill 1 mentioned above. It will be apparent to those skilled in the art that various changes and modifications can be made within the scope of the claims, and these are naturally within the technical scope of the present invention. Understood.

  For example, the above-described conductive metal fitting 30 has been described with respect to the configuration in which the bit 11 can rotate in the recess 25 of the conductive portion 7, but a protrusion or the like for preventing rotation is formed inside the recess 25. By doing so, it is also possible to adopt a configuration in which the conductive metal fitting 30 maintains a stationary state inside the recess 25 even if the bit 11 is rotated.

  In the present embodiment, the concrete drill 1 is described as an example of the electric tool. However, the electric tool is not limited to the concrete drill, and is driven by electric power supplied from a power source. As long as there is a possibility of damaging a metal pipe or the like in the building due to the rotation, the same effect can be obtained by adopting the same configuration even with other power tools.

1 ... Concrete drill (electric tool)
2 ... casing 2a ... front casing (in casing) (front of casing)
2b ... rear housing 3 (in housing) ... main switch 4 ... main motor 4a ... rotating shaft 5 (of main motor) ... rotating drive transmission portion 5a ... rotating shaft portion 6 (of rotational drive transmission portion) ... power assist mechanism 7 and 40: Conductive part (conductor storage part)
DESCRIPTION OF SYMBOLS 9 ... Power supply unit 10 ... Power supply cable 11 ... Bit 12 ... Electric wire cable 14 ... Holding part 15 (in a housing | casing) ... Power assist motor 16 (of a power assist mechanism part) ... Eccentric weight part 18 (of a power assist mechanism part) ... Bit tip 20 ... Shank mounting part (rotating shaft part) (bit mounting part)
21 ... Shank 22 ... Screw part 23 (of shank mounting part) ... Circular opening (of opening part) (opening part)
25, 41 ... (conducting part) recess (housing part)
26 ... rib 27 (of conductive part) ... space (window)
30, 42 ... Conductive metal fittings (conductor)
30a ... inner curved part 30b (of the conductive metal) ... outer curved part 44 (of the conductive metal) ... mounting pin (mounting member)

Claims (5)

A bit mounting part for fixing a bit is provided in the front part of the housing, and the bit is rotated with the rotation of the bit mounting part,
An opening for guiding the bit mounting portion; and a conductor storage portion provided at the front of the housing in a state where the bit mounting portion is exposed from the opening,
On the inner peripheral surface of the opening of the conductor housing portion, a housing portion formed in the diameter increasing direction with respect to the rotation shaft of the bit mounting portion is formed,
The storage portion stores a conductor that contacts the outer peripheral surface of the bit mounting portion,
The power tool, wherein the bit mounting portion, the conductor housing portion, and the conductor have electrical conductivity.   The power tool according to claim 1, wherein a window for exchanging the conductor stored in the storage unit is formed on a front surface of the storage unit.   The electric power tool according to claim 1, wherein the electric conductor is more wearable than the electric conductor housing part and the bit mounting part. The conductor includes an inner curved portion having an inner diameter corresponding to the outer diameter of the bit mounting portion and abutting on the outer peripheral surface of the bit mounting portion; The power tool according to any one of claims 1 to 3, further comprising an outer curved portion having an outer diameter corresponding to the shape of the inner surface and abutting against the inner surface of the storage portion. The conductor has a characteristic of trying to maintain a bar shape when the external body exerts a bar shape and is bent due to an external force.
An attachment member having electrical conductivity is formed in the storage portion,
The conductor is housed in the housing portion in a state in which a part of the conductor is brought into contact with the outer peripheral surface of the bit mounting portion and the other portion is brought into contact with the mounting member. The power tool according to any one of claims 1 to 3.

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