KR100215172B1 - Hand grinder - Google Patents

Abstract

Prevents vibration caused by surges in hand-held grinding devices. An internal example drive shaft 4 of the hand-held grinding device body 1 is supported, and one end of the conduit 7 is held through the eccentric crank body 5 on the outer circumference of the drive shaft 4, In the hand-held grinding device in which the other end of (7) is connected to the sock portion 8 of the tool provided at the distal end of the grinding apparatus body 1, an elastic body which is rotated in an electric conduit diagram 7 in one direction. In this way, the weight of the deformation of the conduit 7 can be improved to prevent the occurrence of vibration due to surge or the like.

Description

Hand Grinding Device

As shown in FIG. 4, the conventional hand-operated grinding device includes a drive shaft 101 which is rotated by a drive motor in an apparatus body (not shown) formed in a substantially cylindrical shape so as to be held by a hand. Internally, the one end of the condo diagram 103 is axially engaged via the eccentric crank 102 on the outer circumference of the drive shaft 101, and the other end of the condo diagram 103 is axially oriented toward the distal end of the apparatus main body. It is comprised by connecting via the axis | shaft 105 to the contact | wear part 104 which supported the advancing material summer.

In the conventional grinding apparatus, the eccentric crank 102 is eccentrically rotated by the rotational drive of the drive shaft 101, thereby causing the other end of the condo diagram 103 to reciprocate in the axial axial direction of the apparatus main body, whereby the contact portion It is comprised so that the tool 106, such as the grinding property, attached to the 104 may reciprocate.

However, in the conventional grinding device for handles, the eccentric crank 102 reciprocates also in the radial direction of the apparatus main body by the rotation of the drive shaft, causing vibration in the conduit, and this vibration causes the eccentric crank 102 to be moved. It interferes with the smooth operation, and since the load 103 is also excessively loaded, the durability of the device is reduced.

Thus, in order to solve the above problem, in the hand-held grinding device of the real name 4-9682, as shown in Fig. 5, the coil spacing in the middle of the conduit diagram 103 is also interposed. In addition, the other end of the coil spring 107 is directly coupled to the member of the contact portion 104 which is supported by the guide sleeve 108 or the like in a straight reciprocating direction along the axis of the main body of the apparatus. It consists.

Thereby, the grinding device absorbs the vibration of the conduit 103 generated by the operation of the eccentric crank 102 by the elastic deformation of the coil spring 107 provided in the middle of the eccentric crank 102. Only the reciprocating motion in the direction of the apparatus axial center is transmitted linearly with respect to the locking portion 104, so that the swinging movement of the locking portion 104 can be smoothly performed.

However, as described above, in the case where the coil spring 107 is interposed in the middle of the diagram, when the drive shaft 101 is rotated at a high speed, the turbine is rotated at a high speed, particularly by the unloading of the crimped paper. In driving the drive shaft 101, the elastic deformation of the coil spring 107 cannot follow the operation of the eccentric crank 102 which rotates at a high speed, and vibration due to surging occurs or reciprocation of the contact portion is unnaturally performed. It has become.

SUMMARY OF THE INVENTION An object of the present invention is to provide a structure in which the vibration caused by surging does not occur even in the operating conditions by the high-speed rotational drive with respect to the conventional handle grinding device as described above.

1 is a longitudinal sectional front view showing a hand-held grinding device of the present invention.

2 is a longitudinal sectional front view of the copper grinding device.

3 is a perspective view of a cone;

4 is a structural conceptual view of a conventional handle grinding device.

Fig. 5 is a structural conceptual view of a handle grinding device by placing a coil spring in an intermediate portion of a cone.

Explanation of symbols for main parts of the drawings

(1) ------------ device body, (4) -------------- drive shaft,

(5) ------------ Eccentric Crankcase, (6) -------------- Turbine,

(7) ----------- Konroddo, (8) -------------- Hook part.

MEANS TO SOLVE THE PROBLEM In order to solve the said subject, this invention receives the drive shaft which drives rotationally by receiving a driving force in the inside of the apparatus main body comprised in a substantially cylindrical shape, and fastens one end of a cone through the eccentric crank body on the outer periphery of the drive shaft. In addition, in the hand-held grinding device in which the other end of the conduit is connected to a hook part for a tool which is supported by a straight reciprocating line along the axial center of the main body of the apparatus, the intermediate part is rotated in one direction. It consists of an elastic body which is then bent, and the other end of the condo diagram is integrally coupled to the member of the contact portion.

In addition, the above-mentioned conduit may be configured by one member from one end of the paper sheet to the other end of the coupling portion.

According to the said means, the action described below is accompanied.

When the drive shaft supported by the inside of the device rotates under the driving force, one end of the condo diagram rotates through the eccentric crank body, one example of the shaft center of the drive shaft. The moving component in the direction of the device body axis in this rotational movement. The other end of the condo diagram that receives the linear motion is linearly double-acted in accordance with the leading end shaft center of the grinding device main body.

As described above, when the other end of the condo diagram rotates around the axis of the drive shaft, and the other end of the condo dota is linearly reciprocated together with the hook portion, the intermediate portion of the condo diagram is rotated every time the drive shaft is rotated once. The load to be deformed is applied in the direction perpendicular to the axis of the axis. The load is absorbed by bending the intermediate portion of the diagram in one direction each time the drive shaft is rotated by one rotation, whereby the contact portion can linearly reciprocate smoothly.

Hereinafter, one embodiment of the present invention will be described with reference to the drawings.

In the handle grinding device shown in Figs. 1 and 2, the outer case made of synthetic resin is fitted to the outer circumference of the inner case lb of a deformation cylinder made of light metal such as aluminium, and the inner case ( The device body 1 is constructed by cutting (screwing) the tip camp 1c into the front end of lb) and the rear camp 1d into the rear end of the case lb.

In the rear end of the apparatus main body 1, the cap lid 2 serving as the inlet of the compressed air is exited in the airtight state.

At the rear end of the cap lid 2, the air supply port 2a for connecting the supply air (not shown) of the compressed air is protruded, and the air supply port 2b communicating with the air supply port 2a is closed. It is comprised so that it may supply to the nozzle body 3 provided in the front surface of the lid 2.

The nozzle body 3 exits in the airtight state with respect to the front surface of the said cap lid 2,

The turbine 6 which rotates in the apparatus main body 1 the nozzle hole 3a which was directed toward the true direction.

It is close to the outer peripheral part of the.

The turbine 6 is formed in substantially light order using synthetic resin, and rotates around the drive shaft 4 bearing the bearing shaft in the state passing through the main body 1. A plurality of blades 6a are formed on the outer circumferential portion of the turbine 6 by inclining toward one direction, and a slight aliasing is applied to the outer circumferential portion of the nozzle port 3a of the nozzle body 3. It arrange | positions so that it may interpose. Therefore, the female shaft air blown out from the nozzle port 3a of the said nozzle body 3 is matched with the braid 6a of the main part of the turbine 6, and gives rotation force to the copper turbine 6. As shown in FIG.

In addition, the air blown into the apparatus body 1 from the nozzle port 3a passes through an exhaust path 2c formed along the periphery of the cap lid 2, and an exhaust port 2d at the rear end of the cap lid 2 is provided. It is configured to exhaust from the outside.

The drive shaft 4 integrated with the turbine 6 is rotatably supported by both bearings 4a, and rotates in accordance with the rotational drive of the turbine 6. A pair of face core crank bodies 5 are integrally attached to the outer peripheral portion of the drive shaft 4. The eccentric crank body 5 is a transparent body which eccentrically hollowed out, and the drive shaft 4 is fixed by fixing to the peripheral part of the said drive shaft 4 by the meditation which clamps the turbine 6 from both sides. It constitutes a crankshaft which is eccentric with respect to the axial center. On these eccentric crankshafts 5,

One end of the condo diagram 7 to be used is held. The cone 7 connects the eccentric crank body 5 and the locking part 8 provided at the front end of the apparatus main body 1.

The locking part 8 is detachably gripped by the grinding tool, and is supported to linearly reciprocate along the axial center portion of the tip of the apparatus body 1, and includes a sliding body 8b and a sliding body 8b which are configured substantially in shaft name. The coating 8a is provided at the tip of the head).

The covet 8a inserts the proximal end of the cutting tool, and is fastened and detachably fixed by the screw 10. The covet 8a is fitted to the distal end of the sliding body 8b and fixed with the screw 11. The sliding body 8b is a hollow shaft body, and the apparatus is provided by interposing a slit bearing 9a with respect to the hollow of the guide sleeve 9 which is wound around the front end of the inner case lb of the apparatus body 1. Supports the forward and backward movement freely along the axis of the tip of the main body (1).

The sliding body 8b of the said locking part 8 and the eccentric crank body 5 of the electric drive shaft 4 are connected through the cone | rod 7.

The conduit 7 is formed in a substantially floating shape using a synthetic resin in which short fibers are mixed, and has an appropriate elasticity so as to be crushed and broken in the middle portion.

As shown in FIG. 3, the conduit diagram 7 is formed in a Taiwan shape, branched at one end thereof in a bifurcation shape, and bearing both the eccentric crank bodies 5 described above at the branched portions. The bearing portion 7a which receives the bearing via the body is integrally known. The biaxial bearing part 7a divides a general part, and is detachably connected by the screw 13 in the state which the said bearing 12 was fitted. That is, one end of the conduit 7 is axially held relative to the eccentric crank body 5, and by the rotation of the composition shaft 4, the eccentric crank body 5 is centered on the axial center of the drive shaft 4. As it rotates eccentrically, it reciprocates along the axial direction of the apparatus main body 1.

The other end of the conduit 7 is formed axially and connected to the rear end of the sliding body 8b facing the rear end of the guide sleeve 9. Therefore, as described above, one end of the cone (7) in accordance with the eccentric rotation of the eccentric crank body 5, the sliding body is directly connected to the lower end of the concentric direction, the other end of the same diagram (7) 8b is linearly double acting along the guide sleeve 9. The stroke of the reciprocating motion of the sliding body 8b is twice the amount of eccentricity of the eccentric crank body 5.

As described above, when the other end of the conduit 7 directly connected to the sliding body 8b in accordance with the eccentric rotation of the eccentric crank body 5 linearly doubles in the axial center direction of the device body 1, the drive shaft 4 Each time one rotation is made, one end of the conduit 7 reciprocates in the radial direction of the apparatus main body 1, so that it is composed of ten thousand people so as to absorb the abrupt movement of the monrod 7. The load to transform the cone 7 in the thickness direction is applied. The above-mentioned load is applied every time the drive shaft rotates, so that the middle portion of the approximately 70,000 people of the condo diagram 7 is directed in the direction of the stroke. It is absorbed by being flexed and bent elastically, whereby the eccentric rotational movement by the eccentric crank body 5 can be smoothly converted into linear and double motion of the sliding body 8b.

By the way, in the conduit 7, the rib 7b whose height changes to the tapered shape along one side of the sheep lead is integrally matched, and the thickness of the other end formed by the axis name is reduced by the secondary curve. By making it, the thickness part of ten thousand people is made in the middle part near the other end, and the curved part 7c which produces the shape which concentrated the said bending deformation is comprised.

In addition, the above-mentioned conduit 7 may be constituted by any member as long as it is appropriately elastically deformed, and may be constituted using only metal or FRP, for example. good.

The handle grinding device configured as described above has an eccentric crank body 5 integrated with the drive shaft 4 when compressed air is blown out of the nozzle portion 3a and the turbine 6 and the drive shaft 4 rotate at high speed. It rotates eccentrically about the axial center of the drive shaft 4.

In accordance with the eccentric rotation, the conduit 7 vibrates, and the moving component in the axial direction of the apparatus main body 1 in the eccentric rotation is connected to the contact portion 8 from the other end of the conduit 7. 8b). As a result, the sliding body 8b is guided to the guide sleeve 9 and linearly doubles, and the coating 8a which is integrated with the sliding body 8b and the grinding tool mounted on the coating 8a are Reciprocate at high speed.

In the above-mentioned handle grinding device, the eccentric rotation of the eccentric crank body 5 is converted into the linear reciprocating motion of the sliding body 8b of the locking part 8 by interposing the conduit diagram 7 to bend and change. However, the elastic bending excitation of the conduit 7 can sufficiently follow the high speed rotation of the turbine 6, so that the reciprocating operation of the grinding tool can be surely expanded. In addition, vibration due to surging does not occur.

The above-described handle grinding device includes a guide sleeve 9 for guiding the sliding body 8b, a bearing 4b for receiving both ends of the drive shaft 4, and an inner case lb of the apparatus body 1; The earrings 14 and 15 made of an elastic material are individually fitted to the supporting portion of the " Therefore, the vibration generating member supported by the apparatus main body 1 can be absorbed by 14 and 15 when the danper function is released, thereby effectively enjoying the vibration felt by the user's hand during the operation. have.

In addition, the above-described handle grinding device is configured to rotate the drive side 4 by a turbine that rotates by compressed air, but the drive source of the drive shaft can be arbitrarily changed, even when using an air motor or an electric motor. good.

As described above, the eccentric crank body is composed of an elastic body which is bent by bending a conduit connecting between the locking portions in one direction. Therefore, the conrot which rotates around the drive shaft is integrated with one end and the locking portion. It is possible to absorb the load force generated between the other end of the linearly reciprocating and linearly reciprocating ends by rotating the middle part of the same diagram in one direction, thereby rotating the eccentric crank. It can be changed smoothly by linear movement which reciprocates the locking part of a main-body front part. In addition, the above-described curved deformation of the conduit can be sufficiently followed even when the drive shaft rotates at high speed, and thus does not generate vibration due to surge.

In addition, when the above-described conduit is constituted by a partial material from one end of the shaft support to the other end of the connecting portion, as in the prior art, the coil spring is interposed between the both ends of the condo, and It is not necessary to connect the coil springs, and by simplifying the structure, it is possible to reduce the number of parts and to reduce the effort required for assembly work.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a hand-held grinding device which cools the grinding and polishing of a workpiece by converting the rotational drive of the drive shaft into a reciprocating straight line to reciprocate a work such as a stone that is attached to the hook portion of the device tip. .

Claims (2)

Receiving a drive shaft 4 driven by a driving force in the inside of the apparatus body 1 having a substantially cylindrical shape, and having one end of the cone 7 via the face center crank body 5 on the outer circumference of the drive shaft 4. In the hand-held grinding device in which the other end of the conduit (7) is connected to the hook portion (8) for the tool, which is supported linearly reciprocally along the shaft center of the distal end of the apparatus body (1). , The electric conduit (7) is composed of an elastic agent that is bent by bending the middle portion in one direction, the handle grinding is formed by integrally coupling the other end of the condo (7) to the member of the locking portion (8) Device. The hand-held grinding device according to claim 1, wherein the condo diagram (7) is composed of one member from one end of the shaft support to the other end of the engaging portion.