1. Field of the Invention
The present invention relates to a socket unit used for tightening a nut while interposing a reaction washer therebetween and to a tightening machine having the socket unit, and more particularly, the present invention relates to a tightening machine having a socket unit, even in a phase misalignment between a nut and a reaction washer, capable of easily fitting an outer socket to a reaction washer in a state where a nut is fitted to an inner socket.
2. Description of Related Art
As shown in
The tightening machine is concentrically provided with an inner socket holder and an outer socket holder which rotate in opposite directions from each other. The socket unit includes an inner socket and an outer socket which are formed concentrically.
The inner socket is provided at its base end outer periphery with a mounting projection. The mounting projection detachably engages with the inner socket holder of the tightening machine. A mounting groove is formed in an inner periphery of the inner socket holder. The inner socket is fitted to a mounting groove formed in an inner periphery of the inner socket holder without clearance in its circumferential direction. The outer socket also detachably engages with the outer socket holder, and if the tightening machine is operated, the inner socket and the outer socket rotate in opposite directions from each other.
The nut 93 is tightened in such a manner that an inner peripheral surface of a tip end of the inner socket is fitted to the nut 93, and then an inner peripheral surface of a tip end of the outer socket is fitted to the reaction washer 95 and in this state, the tightening machine is operated.
It is necessary to tighten the nut 93 under preset torque, but primary tightening (temporarily tightening) is carried out before a so-called final tightening operation for tightening the nut 93 under the set torque. In this primary tightening operation, positions in the rotation direction (“phase”, hereinafter) of the reaction washer 95 and the nut 93 align with each other in some cases as shown in
When the nut 93 and the reaction washer 95 are compared with each other, the nut 93 is thicker than the reaction washer 95 as shown in
When the inner socket and the nut 93 are fitted to each other, even if the phases of the inner socket and the nut 93 are misaligned each other, if an operator rotates the tightening machine itself around its axis, the phase misalignment can be solved. Therefore, the inner socket can be fitted to the nut 93.
However, when the reaction washer 95 is to be fitted to the outer socket after the nut 93 is fitted to the inner socket, the outer socket does not excellently mesh with the concavo-convex periphery 96 of the reaction washer 95 depending upon the phase misalignment between the reaction washer 95 and the nut 93, as shown in the above and in
Hence, it is proposed that an inner surface shape of a nut-engaging hole 32 formed in the inner socket to which the nut 93 is fitted is not formed into the same hexagonal shape as that of the nut 93, a width of a bottom surface 33a of a groove 33 is widened to about 30° and an inner socket 30 having a nut-engaging hole 32 having clearance is used. Concerning a shape of the groove 33 of the inner socket, see a front view of
By widening the width of the groove 33, it is possible to provide clearance of about 30° in the case of the illustrated example. Therefore, if a phase misalignment between the reaction washer 95 and the nut 93 is as small as 5° or 10° and is much smaller than 30°, it is theoretically possible to engage the reaction washer 95 with the outer socket if an operator rotates the tightening machine itself around its axis after the nut 93 is made to mesh with the inner socket.
The maximum phase misalignment between the reaction washer and the nut is theoretically 30° but members vary and the nut and the reaction washer are not concentric. Therefore, the maximum phase misalignment between the reaction washer and the nut exceeds 30° in some cases. In such a case, even if the tightening machine itself is rotated, the reaction washer cannot be engaged with the outer socket. Hence, in such a case, a so-called inching operation is required. In the inching operation, the tightening machine is slightly operated to align the phases of the outer socket and the inner socket from each other. If the phases do not align by one inching operation, the inching operation must be repeated many times and this deteriorates operation efficiency.
An object of the present invention is to provide a tightening machine having a socket unit, even if a phase misalignment occurs between a nut and a reaction washer, capable of easily fitting an outer socket to a reaction washer in a state where the nut is fitted to an inner socket.
To solve the above problem, the present invention provides a tightening machine having a socket unit for tightening a reaction washer fitted to a bolt which projects from a structure, the socket unit including an inner socket whose tip end can engage with the nut, and an outer socket which is formed concentrically with the inner socket and whose tip end can engage with the reaction washer, the tightening machine concentrically including an inner socket holder and an outer socket holder which can rotate in opposite directions from each other, the outer socket holder being formed on an outer periphery of the inner socket holder, the inner socket being detachably engaged with the inner socket holder, and the outer socket being detachably engaged with the outer socket holder, wherein the inner socket is engaged with the inner socket holder with clearance in its circumferential direction.
According to the tightening machine having the socket unit of the present invention, the inner socket has clearance in the rotation direction with respect to the inner socket holder. Hence, the tightening machine is not influenced by a phase misalignment between the reaction washer and the nut, and if an operator rotates the tightening machine itself around its axis in a state where the nut is engaged with the inner socket, the inner socket can be rotated with respect to the outer socket and the phase of the outer socket with respect to the inner socket can be shifted. Therefore, the phases of the reaction washer and the outer socket can align with each other, and the outer socket can be engaged with the reaction washer.
Hence, the inching operation for operating the tightening machine and aligning the phases of the reaction washer and the outer socket with each other becomes unnecessary. Therefore, it is possible to remarkably enhance the efficiency of the final tightening operation.
<Socket Unit>
As shown in
As shown in
The outer socket body 51 includes a plurality of mounting recesses 52 (see
A diameter of the outer socket body 51 on the side of the tightening machine 10 (hereinafter referred to as “base end” or “base end side”) is reduced, and the inner socket 30 rotatably and slidably abuts against a support surface 54 whose diameter is reduced and which is perpendicular to the axial direction.
A mounting flange 55 having a plurality of notches projects from a diameter-reduced side peripheral surface of the outer socket body 51, the mounting flange 55 meshes with a flange receiving portion 81 of an outer socket holder 80, and the mounting flange 55 functions as a detent member when the outer socket 50 is mounted on the outer socket holder 80. A peripheral groove 56 into which a lock screw 82 is fitted is formed at a location closer to the base end side than the mounting flange 55, and the lock screw 82 functions as a detent member when the mounting flange 55 is mounted on the outer socket holder 80.
The reaction washer-engaging portion 60 is mounted on a tip end of the outer socket body 51, and includes a reaction washer-engaging hole 61 having an inner periphery into which a concavo-convex periphery 96 of an outer periphery of the reaction washer 95 is fitted. When the reaction washer 95 has twelve V-shaped concavo-convex peripheries 96, twelve V-shaped bottom grooves 62 are arranged in the reaction washer-engaging hole 61 at equally-spaced intervals in the circumferential direction.
A mounting projection 63 which is fitted into the mounting recess 52 of the outer socket body 51 projects from an outer periphery of the reaction washer-engaging portion 60 as described above. Notches are formed in the illustrated mounting projection 63 at predetermined intervals, projections formed between the notches mesh with the mounting recess 52 of the outer socket body 51.
An inner diameter of the base end of the reaction washer-engaging portion 60 is greater than a diameter of the reaction washer-engaging hole 61, and a step formed by this configuration functions as a later-described detent member 64 of the inner socket 30.
As shown in
A diameter of the inner socket 30 at a location closer to its base end than the nut-engaging hole 32 is reduced, and its step 34 slidably abuts against the support surface 54 of the outer socket body 51.
A base end side of the inner socket body 31 projects more than a base end of the outer socket body 51 when the inner socket body 31 is mounted on the outer socket 50, a plurality of projections 35 project from a projecting peripheral surface in a direction along its axis, and the projections 35 engage with recesses 71 of a later-described inner socket holder 70 with clearance.
Widths of the projections 35 and the recesses 71 can appropriately be set in accordance with an amount of clearance required by the inner socket 30 with respect to the inner socket holder 70. It is preferable that the clearance has an angle exceeding 30° and in this case, it should be configured such that the projection 35 can rotate within the recess 71 beyond 30° in the circumferential direction. It is preferable that the clearance is set in a range of 35° or more and 45° or less, and more preferably 40° or more. By setting the clearance in this manner, the number of the phase alignment points of the reaction washer 95 matches with the phase of the outer socket 50 can be set to one or two.
In the illustrated embodiment, the number of the projections 35 is four, but if there is a margin of strength, the number of the projections 35 may be two or three. It is of course possible to provide five or more projections 35 depending upon a required amount of clearance.
In this embodiment, the projections 35 are formed on the inner socket 30 and the recesses 71 are formed in the inner socket holder 70, the projections 35 and the recesses 71 are nominal names in terms of description and the recesses may be formed in the inner socket 30 and the projections may be formed on the inner socket holder 70. The clearance is not limited to the engagement between the projection and the recess, and other configuration can also be employed.
The inner socket 30 having the above-described configuration is fitted into the outer socket body 51 with the bush 22 interposed therebetween, the mounting projections 63 of the reaction washer-engaging portion 60 is meshed with the mounting recess 52 of the outer socket body 51 and they are screwed, and the socket unit 20 shown in
<Tightening Machine>
As shown in
The present invention is characterized in that the inner socket 30 of the socket unit 20 is engaged with the inner socket holder 70 of the tightening machine 10 with clearance. Description of a mechanism which rotates the inner socket holder 70 and the outer socket holder 80 in the opposite directions will not be given.
The inner socket holder 70 is the cylindrical holder which rotatably engages with the inner socket 30 of the socket unit 20 with clearance, is disposed at a location behind the outer socket holder 80, and as shown in
The outer socket holder 80 is a cylindrical holder disposed on the outer periphery of the inner socket holder 70 such that the outer socket holder 80 can rotate in the direction opposite from that of the inner socket holder 70, and the outer socket holder 80 is provided at its tip end with the flange receiving portion 81 including the plurality of notches with which the mounting flange 55 of the outer socket holder 80 meshes. Screw holes 83, 83 are formed in the outer socket holder 80 at locations close to its tip end. Lock screws 82 which enter peripheral grooves 56 of the base end of the outer socket 50 are fitted into the screw holes 83, 83 when the outer socket 50 is mounted.
The socket unit 20 is detachably mounted on the inner socket holder 70 and the outer socket holder 80 of the tightening machine 10. The socket unit 20 is fitted in a state where it is aligned such that the projections 35 of the tip end of the inner socket 30 are fitted to the recesses 71 of the inner periphery of the inner socket holder 70 (see
Since the outer socket holder 80 and the inner socket holder 70 are closely connected to the power mechanism of the tightening machine 10, free rotation is prevented. Therefore, if the socket unit 20 is mounted on the tightening machine 10, the outer socket 50 and the outer socket holder 80 become one piece and they cannot be rotated. On the other hand, the inner socket 30 can rotate with respect to the outer socket 50 and the inner socket 30 has clearance in the rotation direction with respect to the inner socket holder 70. Therefore, the inner socket 30 can rotate within a range of clearance.
In the tightening machine 10 having the socket unit 20, the primary tightened nut 93 is finally tightened under predetermined torque. The final tightening operation is carried out in such a manner that the axis of the bolt 91 and the axis of the socket unit 20 are aligned with each other, the tightening machine 10 is moved forward such that the socket unit 20 approaches the nut 93 and the reaction washer 95 and in this state, the nut 93 is engaged with the nut-engaging hole 32 of the inner socket 30.
If the phases of the nut 93 and the groove 33 of the nut-engaging hole 32 are misaligned with each other, an operator rotates the tightening machine itself around its axis. In this embodiment, since the nut-engaging hole 32 has the twelve grooves 33 as shown in
The tightening machine 10 is further moved forward in the state where the inner socket 30 and the nut 93 are engaged with each other, and the outer socket 50 and the reaction washer 95 are engaged with each other. At that time, if the concavo-convex periphery 96 of the reaction washer 95 and the grooves 62 of the outer socket 50 are not misaligned in phase from each other, the outer socket 50 can be engaged with the reaction washer 95 by moving the tightening machine 10 forward as it is. However, if the nut 93 and the reaction washer 95 have phase misalignment generated at the time of primary tightening as shown in
In the present invention, since the inner socket 30 has clearance exceeding 30° in the rotation direction with respect to the inner socket holder 70, if an operator rotates the tightening machine itself around its axis in a state where the nut 93 is engaged with the inner socket 30, the inner socket 30 rotates with respect to the outer socket 50 and the phase of the outer socket 50 with respect to the inner socket 30 is shifted. Therefore, the phase of the concavo-convex periphery 96 of the reaction washer 95 and the phase of the groove 62 of the reaction washer-engaging hole 61 of the outer socket 50 can align with each other and the outer socket 50 can be engaged with the reaction washer 95. Further, if the clearance is 30°, the number of the phase alignment point becomes one or less, but if the clearance is set to the angle exceeding 30°, the number of the phase alignment points become one or two, and it becomes easy to engage the reaction washer 95 with the outer socket 50.
Therefore, the inching operation for operating the tightening machine 10 and making the phases of the reaction washer 95 and the outer socket 50 align with each other becomes unnecessary. Hence, it is possible to remarkably enhance the efficiency of the final tightening operation.
The nut-engaging hole 32 of the inner socket 30 has the twelve grooves 33, but the number of the grooves 33 can be six or eighteen.
Concerning the nut-engaging hole 32 of the inner socket 30, if the bottom surfaces 33a of the grooves 33 with which the nut 93 engages are made as six groove-shapes each having a width in the circumferential direction as shown in
As shown in
An engaging hole 42 is formed in the nut-side member 40 over substantially the entire length in its axial direction to penetrate the nut-side member 40 where a nut 93 and the holder-side member 45 can engage with the engaging hole 42. The engaging hole 42 is provided at its inner periphery with grooves 33 with which the nut 93 and the holder-side member 45 can engage, each of the grooves 33 has a width in the circumferential direction of the bottom surface 33a as shown in
In the illustrated embodiment, each of the groove bottom surfaces 33a has the width of about 30°, and the nut 93 and the holder-side member 45 can be fitted into the engaging hole 42 with clearance of about 30° each.
A diameter of an inner periphery of the base end of the nut-side member 40 is increased, and forms a receiving portion 43 for the holder-side member 45 which will be described next.
As shown in
A diameter of a base end of the fitting member 46 is increased, and this configures a projection 47 which is turnably fitted into the receiving portion 43 of the nut-side member 40. A plurality of mounting projections 48 project in a direction along the axial direction from a side closer to the base end than the projection 47. The mounting projections 48 engaged with a mounting recess (not shown) formed in the inner socket holder 70 without clearance, and the mounting projections 48 rotate to follow the inner socket holder 70.
The fitting member 46 is fitted into the engaging hole 42 of the nut-side member 40, the holder-side member 45 is accommodated in the outer socket body 51, and the holder-side member 45 cannot come out due to the reaction washer-engaging portion 60 of the outer socket 50.
Concerning the socket unit 20 of the above configuration, since the fitting member 46 of the holder-side member 45 and the engaging hole 42 of the nut-side member 40 are engaged with each other with clearance as shown in
Therefore, the nut 93 has clearance of two times of the above clearance, i.e., clearance of about 60° in this embodiment with respect to the holder-side member 45 which is non-turnably mounted on the inner socket holder 70.
In the tightening machine 10 having the socket unit 20, the primary tightened nut 93 is finally tightened under predetermined torque. The final tightening operation is carried out in such a manner that an axis of the bolt 91 and an axis of the socket unit 20 are made to align with each other, the tightening machine 10 is moved forward such that the socket unit 20 approaches the nut 93 and the reaction washer 95 and in this state, the nut 93 is engaged with the engaging hole 42 of the inner socket 30.
If the phases of the nut 93 and the groove 33 of the nut-engaging hole 32 are misaligned with each other, an operator rotates the tightening machine itself around its axis. In this embodiment, since the groove 33 of the engaging hole 42 has the bottom surface 33a of about 30° as shown in
The tightening machine 10 is further moved forward in the state where the inner socket 30 and the nut 93 are engaged with each other, and the outer socket 50 and the reaction washer 95 are engaged with each other. At that time, if the concavo-convex periphery 96 of the reaction washer 95 and the grooves 62 of the outer socket 50 are not misaligned in phase from each other, the outer socket 50 can be engaged with the reaction washer 95 by moving the tightening machine 10 forward as it is. However, if the nut 93 and the reaction washer 95 have phase misalignment generated at the time of primary tightening as shown in
According to the inner socket 30 of the present invention, the nut-side member 40 has the clearance in the circumferential direction with respect to the holder-side member 45, and the nut 93 has the clearance in the circumferential direction with respect to the nut-side member 40. Therefore, if an operator rotates the tightening machine itself around its axis in the state where the nut 93 is engaged with the inner socket 30, the nut-side member 40 rotates with respect to the holder-side member 45 and the nut 93 rotates with respect to the nut-side member 40. Hence, the phase of the outer socket 50 with respect to the nut 93 can be shifted, the phase of the concavo-convex periphery 96 of the reaction washer 95 and the phase of the groove 62 of the reaction washer-engaging hole 61 of the outer socket 50 can be made to align with each other, and the outer socket 50 can be engaged with the reaction washer 95.
Therefore, the inching operation for operating the tightening machine 10 and making the phases of the reaction washer 95 and the outer socket 50 align with each other becomes unnecessary. Hence, it is possible to remarkably enhance the efficiency of the final tightening operation.
In the above embodiment, the clearance between the nut-side member 40, the holder-side member 45 and the nut 93 is set to about 30° (total about 60°). However, the total clearance is not limited to this, and it is preferable that the clearance is set to an angle exceeding 30°, more preferably 35° or more and 45° or less, and more preferably 40° or more.
The present invention is effective as a tightening machine having a socket unit capable of easily fitting an outer socket to a reaction washer in a state where a nut is fitted to an inner socket even if phases of the nut and the reaction washer are misaligned each other.
Number | Date | Country | Kind |
---|---|---|---|
2010-279170 | Dec 2010 | JP | national |