JP2008093781A - Power tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power tool capable of improving work efficiency by eliminating a water pipe provided outside so as to make a housing easily grippable. <P>SOLUTION: In this disc sander (power tool) 1, rotation of a motor 3 built in a motor housing 2 is transmitted to a power shaft 19, and the power shaft 19 and a grinding wheel (tip tool) 23 mounted at a tip thereof are rotatably driven, so that a predetermined operation is done while supplying water to the grinding wheel 23 via a water-supplying path. A water-supplying passage 35 constituting one part of the water-supplying path is formed inside a rotor shaft 9 of the motor 3. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a power tool such as a disk sander that performs a polishing operation of stone or the like while supplying water.

  For example, in a disk sander used for polishing stones and the like, a polishing operation is performed while supplying water to the grindstone in order to prevent dust scattering and to cool and lubricate the grindstone. Here, a conventional example of this type of disc sander will be described with reference to FIG.

  FIG. 4 is a side sectional view of a conventional disk sander 101. The illustrated disk sander 101 includes a motor 103 as a drive source in a motor housing 102, and the front end of the motor housing 102 (the left side of FIG. A gear housing 105 is attached to the front and a tail cover 106 is attached to the rear end.

  Thus, when the motor 103 is driven, the rotation of the rotor shaft 109 is decelerated through the pinion 112 and the gear 118 and transmitted to the intermediate shaft 114, and the intermediate shaft 114 is rotationally driven. The rotation of the shaft 114 is further decelerated through the pinion 117 and the bevel gear 122 and the direction is changed to a right angle, and is transmitted to the power shaft 119 disposed vertically in the gear housing 105, so that the power shaft 119 is driven at a predetermined speed. Is driven to rotate. When the power shaft 119 is rotationally driven in this way, a thin truncated cone-shaped grindstone 123 that is detachably screwed to the tip (lower end) of the power shaft 119 is rotationally driven. The surface of is polished.

  On the other hand, a water injection part 126 is provided at the lower part of the tail cover 106, and one end of a hose 127 that extends horizontally is connected to the water injection part 126, and a water injection path 128 that continues to the hose 127 is formed. ing. The water injection section 126 is provided with a cock 129 that opens and closes the water injection path 128. The other end of the hose 127 is connected to a tap.

  Further, a water injection pipe 130 extends forward from the water injection portion 126 along the lower portion of the motor housing 102, and its tip is connected to the lower portion of the gear housing 105. Here, a water injection path 139 connected to the water injection pipe 130 is horizontally formed in the lower part of the gear housing 105, and the water injection path 139 is a water reservoir formed around the power shaft 119 of the gear housing 105. 140 is open. The water reservoir 140 is sealed with a pair of upper and lower oil seals 141.

  The power shaft 119 is provided with a water injection path 142 that opens horizontally to the water reservoir 140 and a water injection path 143 that extends vertically downward from the water injection path 142, and this water injection path 143. Is communicated with a water injection hole 144 formed at the center of the grindstone 123.

Thus, water is supplied from the hose 127 to the water injection section 126 of the disc sander 101. When the cock 129 is opened during the polishing operation, water from the hose 127 is formed in the water injection section 126. Water flows from the water injection path 128 to the gear housing 105 through the water injection pipe 130, flows from the water injection path 139 formed in the gear housing 105 to the water reservoir 140, and water injection paths 142 and 143 formed in the rotating power shaft 119. It passes through the water injection hole 144 of the grindstone 123 and prevents the dust generated by the polishing 123 from being scattered to the surroundings, and the grindstone 123 is cooled and lubricated.
Japanese Utility Model Publication No. 46-008786

  However, since the conventional disc sander 101 shown in FIG. 4 grips the outer frame portion of the motor housing 102 to perform the work, the water injection pipe 130 provided along the motor housing 102 becomes an obstacle. There is a problem that it is difficult to grip the motor housing 102 and the workability is hindered.

  In addition, since the water injection pipe 130 is not securely fixed, it is necessary to work with great care so as not to damage the stone material, especially when polishing the expensive stone material using nerves in the work. was there.

  The present invention has been made in view of the above problems, and an object of the present invention is to provide an electric tool capable of improving workability by eliminating a water injection pipe that has been piped outside and making it easier to grip the housing. It is to provide.

  In order to achieve the above object, the present invention transmits the rotation of a motor built in a motor housing to a power shaft, rotationally drives the power shaft and a tip tool attached to the tip of the power shaft, and passes through the water injection path. An electric power tool that performs a required operation while supplying water to a tip tool is characterized in that a water injection path that constitutes a part of the water injection path is formed inside a rotor shaft of the motor.

  According to the present invention, since the water injection path constituting a part of the water injection path is formed inside the rotor shaft of the motor, there is no need to install the water injection pipe outside the motor housing as in the prior art, and the motor housing is gripped. It becomes easy to do and workability | operativity is improved.

  Moreover, since it can concentrate on a work | work without paying attention to the water injection pipe whose fixation is unstable like the past, a beautiful finish is attained.

  Embodiments of the present invention will be described below with reference to the accompanying drawings.

  FIG. 1 is a side sectional view of a disc sander as an embodiment of an electric tool according to the present invention, FIG. 2 is an enlarged detail view of a portion A in FIG. 1, and FIG. 3 is an enlarged detail view of a portion B in FIG.

  A disc sander 1 shown in FIG. 1 has a motor 3 as a drive source built in a motor housing 2, and an inner cover 4 is interposed between the front end of the motor housing 2 (the left side in FIG. 2 is the front). A gear housing 5 is attached, and a tail cover 6 is attached to the rear end.

  The motor 3 is configured such that a rotor 8 is rotatably disposed inside a cylindrical stator 7 fixed to the motor housing 2, and a rotor shaft 9 extending in the front-rear direction at the center of the rotor 8. Both ends in the axial direction are supported rotatably by bearings 10 and 11. A small-diameter pinion 12 is integrally formed at the front end portion protruding forward from the bearing 10 in front of the rotor shaft 9, and a cooling fan 13 is attached to the rear of the bearing 10 of the rotor shaft 9. Yes.

  An intermediate shaft 14 is disposed in parallel with the rotor shaft 9 inside the inner cover 4 and the gear housing 5, and both axial ends of the intermediate shaft 14 are rotatably supported by bearings 15 and 16. Has been. Then, a small-diameter pinion 17 is integrally formed at the front end portion protruding forward from the bearing 15 in front of the intermediate shaft 14, and in the intermediate portion in the axial direction between the bearings 15 and 16 of the intermediate shaft 14, A gear 18 having a diameter larger than that of the pinion 12 is attached, and the gear 18 and the pinion 12 mesh with each other.

  Further, a power shaft 19 is disposed vertically inside the gear housing 5, and the power shaft 19 is rotatably supported by the gear housing 5 via upper and lower bearings 20 and 21. A bevel gear 22 having a diameter larger than that of the pinion 17 is attached to a portion of the power shaft 19 below the bearing 20, and the bevel gear 22 and the pinion 17 mesh with each other.

  Further, a thin truncated cone-shaped grindstone 23 as a tip tool is detachably screwed to a lower end portion of the power shaft 19 protruding downward from the gear housing 5, and a part of the periphery of the grindstone 23 is The lower surface of the gear housing 5 is covered with a cover 25 attached by screws 24.

  Incidentally, a water injection section 26 is provided at the lower part of the tail cover 6, and one end of a hose 27 extending horizontally is connected to the water injection section 26, and a water injection path 28 connected to the hose 27 is formed. ing. The water injection section 26 is provided with a cock 29 that opens and closes the water injection path 28. The other end of the hose 27 is connected to a tap.

  A water injection pipe 30 extends from the water injection portion 26 through the lower portion of the tail cover 6 and extends upward in the tail cover 6, and is then bent at a right angle toward the front to the rear end of the bearing case 31. It is connected.

  Here, as shown in detail in FIG. 2, the rear end portion of the rotor shaft 9 faces the bearing case 31, and the oil seal 32 slidably contacting the outer periphery of the rear end portion of the rotor shaft 9 and the above-mentioned A sealed water reservoir 34 is formed in the bearing case 31 by an O-ring 33 fitted to the outer periphery of the front end portion of the water injection pipe 30. A water injection path 35 is formed in the central portion of the rotor shaft 9, and the rear end of the water injection path 35 opens to the water reservoir 34 formed in the bearing case 31.

  Further, as shown in detail in FIG. 3, the water between the pinion 12 at the front end portion of the rotor shaft 9 and the bearing 10 is sealed by a pair of front and rear oil seals 36 that are in sliding contact with the outer periphery of the rotor shaft 9. A reservoir 37 is formed. The water reservoir 37 includes a water injection path 38 that extends radially outward from a front end portion of the water injection path 35 formed in the rotor shaft 9, and an injection formed in the inner cover 4 and the gear housing 5. One end of the water channel 39 is open.

  As shown in FIG. 1, the water injection path 39 extends vertically downward from the water reservoir portion 37 in the inner cover 4, and then is bent at a right angle toward the front so as to pass through the inner cover 4 and the gear housing 5. It extends toward the front, and its end opens to a water reservoir 40 formed around the power shaft 19 of the gear housing 5. Here, the water reservoir 40 formed in the gear housing 5 is sealed by a pair of upper and lower oil seals 41 that are in sliding contact with the outer periphery of the power shaft 19.

  The power shaft 19 is provided with a water injection path 42 that opens horizontally to the water reservoir 40 and a water injection path 43 that extends vertically downward from the water injection path 42. Is communicated with a water injection hole 44 formed at the center of the grindstone 23.

  The disc sander 1 configured as described above is used for polishing stone or the like while the motor housing 2 is gripped. That is, when the motor 3 which is a drive source is driven, the rotation of the rotor shaft 9 is decelerated through the pinion 12 and the gear 18 and transmitted to the intermediate shaft 14, and the intermediate shaft 14 is rotationally driven. The rotation of the intermediate shaft 14 is further decelerated through the pinion 17 and the bevel gear 22, and the direction is changed to a right angle and transmitted to the power shaft 19, and the power shaft 19 is rotationally driven at a predetermined speed. When the power shaft 19 is rotationally driven in this way, the grindstone 23 that is detachably screwed to the tip (lower end) of the power shaft 19 is rotationally driven, and the surface of the stone or the like is polished by the rotation of the grindstone 23. The

  Further, water is supplied from the hose 27 to the water injection section 26 of the disc sander 1, and when the cock 29 is opened during the polishing operation, the water from the hose 27 is supplied to the water injection path 28 formed in the water injection section 26. Then, it flows into the water reservoir 34 in the bearing case 31 through the water injection pipe 30 and flows forward through the water injection path 35 formed in the rotor shaft 9. The water flows from the water injection path 38 formed at the front end of the rotor shaft 9 into the water reservoir 37 by centrifugal force, and then passes through the water injection path 39 formed in the inner cover 4 and the gear housing 5. Into the water reservoir 40 in the gear housing 5, passes through the water injection passages 42 and 43 formed in the rotating power shaft 19, and is ejected from the water injection hole 44 of the grindstone 23 to the surroundings of the dust generated by polishing. While preventing scattering, the grindstone 23 is cooled and lubricated.

  As described above, in the disc sander 1 according to the present invention, since the water injection path 35 constituting a part of the water injection path is formed inside the rotor shaft 9 of the motor 3, the conventional disc cider 101 shown in FIG. Thus, it is not necessary to pipe the water injection pipe 130 outside the motor housing 102, and the motor housing 2 can be easily gripped, thereby improving the workability.

  Moreover, since it can concentrate on a work | work without paying attention to the water injection pipe 130 in which fixation is unstable like the past, a beautiful surface finish is attained.

  In the above, the embodiment in which the present invention is applied to the disc sander has been described. However, the present invention can be similarly applied to any other electric tool that performs work while supplying water to the tip tool. Of course.

It is a sectional side view of the disc sander concerning the present invention. It is the A section enlarged detail drawing of FIG. It is the B section enlarged detail drawing of FIG. It is a sectional side view of the conventional disk sander.

Explanation of symbols

1 Disc sander (electric tool)
2 Motor housing 3 Motor 4 Inner cover 5 Gear housing 6 Tail cover 7 Stator 8 Rotor 9 Rotor shaft 10, 11 Bearing 12 Pinion 13 Cooling fan 14 Intermediate shaft 15, 16 Bearing 17 Pinion 18 Gear 19 Power shaft 20, 21 Bearing 22 Bevel gear 23 Grinding wheel (tip tool)
24 Screw 25 Cover 26 Water injection part 27 Hose 28 Water injection path 29 Cock 30 Water injection pipe 31 Bearing case 32 Oil seal 33 O-ring 34 Water reservoir 35 Water injection path 36 Oil seal 37 Water reservoir 38, 39 Water injection path 40 Water reservoir 41 Oil seal 42, 43 Water injection path 44 Water injection hole

Claims (1)

The rotation of the motor built in the motor housing is transmitted to the power shaft, the power shaft and the tip tool attached to the tip of the power shaft are driven to rotate, and the required work is performed while supplying water to the tip tool through the water injection path. In the electric tool that performs
An electric power tool characterized in that a water injection path constituting a part of the water injection path is formed inside a rotor shaft of the motor.

Images