JP3154146U - Tool socket - Google Patents

Abstract

An object of the present invention is to provide a tool socket capable of suppressing deterioration due to unnecessary wear and reducing the working time.
[Solution]
The tool socket 100 includes an outer socket 10, an inner socket 20, a coil spring 30, and a lock mechanism 40. The coil spring 30 moves the inner socket 20 in a direction from the front position where the end surface 21 of the inner socket 20 protrudes from the end surface 11 of the outer socket 10 toward the rear position where the end surface 21 of the inner socket 20 is deeper than the end surface 11 of the outer socket 10. Energize. In the lock mechanism 40, the elliptical spring 41 is engaged with the circumferential inner groove 22 described above, whereby the inner socket 20 is fixed at the front position, and the elliptical spring 41 and the circumferential inner groove 22 are This is a mechanism in which the inner socket 20 is released from the front position by releasing the engagement.
[Selection] Figure 3

Description

  The present invention relates to a tool socket including an inner socket and an outer socket.

  A tool socket that functions as a two-way socket by disposing a socket hole corresponding to a difference in two plug sizes at one end socket portion is disclosed (Patent Document 1). The built-in side end of the inner socket in the tool socket disclosed in Patent Document 1 is urged by a spring built in the central part of the outer socket. The tool socket is fixed at a predetermined position by a ring disposed in the outer peripheral groove of the outer socket, and the inner socket end surface is configured to protrude slightly from the outer socket end surface.

JP 2008-188679 A

  However, as shown in FIG. 11, when the tool socket 1100 disclosed in Patent Document 1 is used, when the work object 1000 fitted in the inner socket hole 1026 is to be tightened, the biasing force of the spring 1030 is applied. Accordingly, the inner socket 1020 moves to the back of the outer socket hole 1016. By repeating this movement, unnecessary friction is generated between the inner socket 1020 and the outer socket 1010. Therefore, there is a problem that deterioration due to wear of the outer peripheral portion of the inner socket 1020 and the inner peripheral portion of the outer socket 1010 is accelerated. It was.

  Further, the position of the inner socket 1020 is not stable until the inner socket 1020 has finished moving to the back of the outer socket 1010. Therefore, it is difficult to give sufficient rotation to the work object 1000 until the inner socket 1020 moves to the back of the outer socket 1010. As a result, useless time has occurred for work such as tightening bolts or nuts.

  The present invention greatly contributes to the realization of a tool socket capable of suppressing deterioration due to wear during use and shortening the working time by solving each of the technical problems described above.

  The inventor believes that it is possible to easily fix and release the movement of the inner socket in the rotation axis direction from the standpoint of the worker, and in addition to suppressing the above-described deterioration, the work time can be shortened. It was. As a result of intensive research toward the realization of the inner socket rotation axis direction locking mechanism, the inventor finds the inner socket locking mechanism configuration that realizes an appropriate locking state that dramatically improves workability. succeeded in. The present invention was created from such a viewpoint.

  One tool socket of the present invention includes an outer socket, an inner socket, a coil spring, and a lock mechanism. Here, the inner socket can be moved back and forth in the rotation axis direction with respect to the outer socket in the outer socket, and is engaged with the outer socket so as not to be relatively rotatable. Further, the coil spring is interposed between the inner socket and the outer socket, and the end surface of the inner socket from a front position where the end surface of the inner socket protrudes from the end surface of the outer socket. Urges the inner socket in a direction from the end surface of the outer socket toward the rear position at the back. In addition, the locking mechanism described above is associated with an outer peripheral portion that is partially held by the circumferential outer groove on the inner peripheral surface of the outer socket and a circumferential inner side groove on the outer peripheral surface of the inner socket. An elliptical spring that has an inner peripheral portion that joins and has an opening formed to include one of the vertices of the long axis, and that biases in a direction to reduce the width of the opening. The inner socket is fixed at the front position by engaging with the inner inner groove, and the engagement between the elliptic spring and the circumferential inner groove is released. This is a mechanism in which the inner socket is released from the aforementioned front position.

  According to this tool socket, since the lock mechanism for fixing the inner socket at the above-described front position is provided, when the work object is fitted into the socket hole of the inner socket, the operator can move the inner socket to the front position. It is possible to work in a fixed state. Thereby, the unnecessary abrasion which arises between an inner socket and an outer socket can be suppressed. That is, deterioration due to wear of the outer peripheral portion of the inner socket and the inner peripheral portion of the outer socket is suppressed. Further, when the work object is fitted into the socket hole of the inner socket, it is not necessary for the inner socket to move from the front position toward the rear position with respect to the outer socket. As a result, the work time associated with the movement becomes unnecessary, and the work time as a whole is greatly reduced. Furthermore, according to this tool socket, when the inner socket and the elliptical spring are disengaged, the elliptical spring held by the outer socket is moved when the inner socket moves from the front position to the rear position. Since it does not move together with the inner socket, wear of the elliptical spring, the inner socket, and the outer socket is also suppressed. Accordingly, it is possible to further suppress deterioration of the outer peripheral portion of the inner socket and the inner peripheral portion of the outer socket.

  Another tool socket of the present invention includes an outer socket, an inner socket, a coil spring, and a lock mechanism. Here, the inner socket can be moved back and forth in the rotation axis direction with respect to the outer socket in the outer socket, and is engaged with the outer socket so as not to be relatively rotatable. Further, the coil spring is interposed between the inner socket and the outer socket, and the end surface of the inner socket from a front position where the end surface of the inner socket protrudes from the end surface of the outer socket. Urges the inner socket in a direction from the end surface of the outer socket toward the rear position at the back. In addition, the locking mechanism includes an inner peripheral portion that is partially held by the circumferential inner groove portion of the outer peripheral surface of the inner socket, and a circumferential outer side groove portion of the inner peripheral surface of the outer socket. An elliptical spring having an outer peripheral portion to be engaged and an opening formed so as to include one of the vertices of the long axis, and biased in a direction of expanding the width of the opening. By engaging with the outer outer groove portion, the inner socket is fixed at the front position, and the engagement between the elliptical spring and the outer circumferential groove portion is released. This is a mechanism in which the inner socket is released from the aforementioned front position.

  According to this tool socket, since the lock mechanism for fixing the inner socket at the above-described front position is provided, when the work object is fitted into the socket hole of the inner socket, the operator can move the inner socket to the front position. It is possible to work in a fixed state. Thereby, the unnecessary abrasion which arises between an inner socket and an outer socket can be suppressed. That is, deterioration due to wear of the outer peripheral portion of the inner socket and the inner peripheral portion of the outer socket is suppressed. Further, when the work object is fitted into the socket hole of the inner socket, it is not necessary for the inner socket to move from the front position toward the rear position with respect to the outer socket. As a result, the work time associated with the movement becomes unnecessary, and the work time as a whole is greatly reduced.

  Another tool socket of the present invention includes an outer socket, an inner socket, a coil spring, and a lock mechanism. Here, the inner socket can be moved back and forth in the rotation axis direction with respect to the outer socket in the outer socket, and is engaged with the outer socket so as not to be relatively rotatable. Further, the coil spring is interposed between the inner socket and the outer socket, and the end surface of the inner socket from a front position where the end surface of the inner socket protrudes from the end surface of the outer socket. Urges the inner socket in a direction from the end surface of the outer socket toward the rear position at the back. In addition, the locking mechanism described above is associated with an outer peripheral portion that is partially held by the circumferential outer groove on the inner peripheral surface of the outer socket and a circumferential inner side groove on the outer peripheral surface of the inner socket. An elliptical spring that has an inner peripheral portion that joins and has an opening formed to include one of the vertices of the long axis, and that biases in a direction to reduce the width of the opening. The inner socket is fixed at the front position by engaging with the inner inner groove, and the engagement between the elliptic spring and the circumferential inner groove is released. This is a mechanism in which the inner socket is released from the aforementioned front position.

  Furthermore, the inner socket which comprises the above-mentioned tool socket is comprised from an inner socket main body and the regulation member provided with the above-mentioned circumferential inner side groove part while fitting to the outer periphery of the inner socket main body. Here, the aforementioned outer socket and the aforementioned elliptical spring are combined, and the aforementioned inner socket body is directed from the aforementioned front position to the aforementioned rearward position within the outer socket where the elliptical spring is combined. Inserted into. The coil spring is inserted in the direction from the rear position to the front position on the outer peripheral side of the inner socket body and the inner peripheral side of the outer socket. The The restricting member is inserted into the inner socket body in which the coil spring is inserted in the direction from the rear position to the front position.

  According to this tool socket, since the lock mechanism for fixing the inner socket at the above-described front position is provided, when the work object is fitted into the socket hole of the inner socket, the operator can move the inner socket to the front position. It is possible to work in a fixed state. Thereby, the unnecessary abrasion which arises between an inner socket and an outer socket can be suppressed. That is, deterioration due to wear of the outer peripheral portion of the inner socket and the inner peripheral portion of the outer socket is suppressed. Further, when the work object is fitted into the socket hole of the inner socket, it is not necessary for the inner socket outer to move from the front position toward the rear position with respect to the socket. As a result, the work time associated with the movement becomes unnecessary, and the work time as a whole is greatly reduced. Furthermore, according to this tool socket, when the inner socket and the elliptical spring are disengaged, the elliptical spring held by the outer socket is moved when the inner socket moves from the front position to the rear position. Since it does not move together with the inner socket, wear of the elliptical spring, the inner socket, and the outer socket is also suppressed. Accordingly, it is possible to further suppress deterioration of the outer peripheral portion of the inner socket and the inner peripheral portion of the outer socket. Further, according to this tool socket, since the outer socket, the elliptical spring, the inner socket body, the coil spring, and the regulating member are combined in this order, the manufacture of a highly functional tool socket can be realized very easily.

  Another tool socket of the present invention includes an outer socket, an inner socket, a coil spring, and a lock mechanism. Here, the inner socket can be moved back and forth in the rotation axis direction with respect to the outer socket in the outer socket, and is engaged with the outer socket so as not to be relatively rotatable. Further, the coil spring is interposed between the inner socket and the outer socket, and the end surface of the inner socket from a front position where the end surface of the inner socket protrudes from the end surface of the outer socket. Urges the inner socket in a direction from the end surface of the outer socket toward the rear position at the back. In addition, the locking mechanism includes an inner peripheral portion that is partially held by the circumferential inner groove portion of the outer peripheral surface of the inner socket, and a circumferential outer side groove portion of the inner peripheral surface of the outer socket. An elliptical spring having an outer peripheral portion to be engaged and an opening formed so as to include one of the vertices of the long axis, and biased in a direction of expanding the width of the opening. By engaging with the outer outer groove portion, the inner socket is fixed at the front position, and the engagement between the elliptical spring and the outer circumferential groove portion is released. This is a mechanism in which the inner socket is released from the aforementioned front position.

  Furthermore, the inner socket which comprises the above-mentioned tool socket is comprised from an inner socket main body and the regulation member provided with the above-mentioned circumferential inner side groove part while fitting to the outer periphery of the inner socket main body. Here, the aforementioned outer socket and the aforementioned elliptical spring are combined, and the aforementioned inner socket body is directed from the aforementioned front position to the aforementioned rearward position within the outer socket where the elliptical spring is combined. Inserted into. The coil spring is inserted in the direction from the rear position to the front position on the outer peripheral side of the inner socket body and the inner peripheral side of the outer socket. The The restricting member is inserted into the inner socket body in which the coil spring is inserted in the direction from the rear position to the front position.

  According to this tool socket, since the lock mechanism for fixing the inner socket at the above-described front position is provided, when the work object is fitted into the socket hole of the inner socket, the operator can move the inner socket to the front position. It is possible to work in a fixed state. Thereby, the unnecessary abrasion which arises between an inner socket and an outer socket can be suppressed. That is, deterioration due to wear of the outer peripheral portion of the inner socket and the inner peripheral portion of the outer socket is suppressed. Further, when the work object is fitted into the socket hole of the inner socket, it is not necessary for the inner socket to move from the front position toward the rear position with respect to the outer socket. As a result, the work time associated with the movement becomes unnecessary, and the work time as a whole is greatly reduced. Furthermore, according to this tool socket, when the inner socket and the elliptical spring are disengaged, the elliptical spring held by the outer socket is moved when the inner socket moves from the front position to the rear position. Since it does not move together with the inner socket, wear of the elliptical spring, the inner socket, and the outer socket is also suppressed. Accordingly, it is possible to further suppress deterioration of the outer peripheral portion of the inner socket and the inner peripheral portion of the outer socket. Further, according to this tool socket, since the outer socket, the elliptical spring, the inner socket body, the coil spring, and the regulating member are combined in this order, the manufacture of a highly functional tool socket is easily realized.

  According to the tool socket of the present invention, when the work object is fitted into the socket hole of the inner socket, the worker can work in a state where the inner socket is fixed at the front position. Therefore, according to this tool socket, it is possible to suppress deterioration due to unnecessary wear and shorten the working time.

It is a top view which shows the state which attached the socket for tools of one Embodiment of this invention to the electric tool. It is a top view which shows the socket for tools of one embodiment of this invention. It is sectional drawing in the front position of the socket for tools of one Embodiment of this invention. It is sectional drawing in the back position of the socket for tools of one Embodiment of this invention. It is a front view which shows the elliptical spring which comprises the socket for tools of one Embodiment of this invention. It is a front view which shows the fixing member which comprises the socket for tools of one Embodiment of this invention. It is explanatory drawing which shows the manufacturing process of the socket for tools of one Embodiment of this invention. It is sectional drawing in the front position of the socket for tools of other embodiment of this invention. It is sectional drawing in the back position of the socket for tools of other embodiment of this invention. It is sectional drawing in the front position of the socket for tools of other embodiment of this invention. It is sectional drawing which shows the use condition of the conventional tool socket.

  Embodiments of the present invention will be described in detail with reference to the accompanying drawings. In this description, common parts are denoted by common reference symbols throughout the drawings unless otherwise specified. In the drawings, the elements of the present embodiment are not necessarily shown to scale. In addition, in order to make each drawing easy to see, some symbols may be omitted.

<First Embodiment>
FIG. 1 is a view showing a state in which the tool socket 100 of the present embodiment is attached to an electric tool. FIG. 2 is a plan view showing the tool socket 100 of the present embodiment. 3 is a cross-sectional view at the front position of the tool socket 100 of the present embodiment, and FIG. 4 is a cross-sectional view at the rear position thereof.

  As shown in FIG. 1, the tool socket 100 of the present embodiment is connected to an electric tool 110. In the state shown in FIG. 1, the work object such as a nut or a bolt is fitted into the socket hole 26 of the inner socket 20 or the socket hole 16 of the outer socket 10, so that the worker can tighten or loosen the work object. Can do.

  As shown in FIGS. 2 to 4, the tool socket 100 of the present embodiment is interposed between the outer socket 10, the inner socket 20 that engages with the outer socket 10, and the inner socket 20 and the outer socket 10. A coil spring 30 and a chuck member 60 for connection to the electric tool 110 are provided.

  The inner socket 20 is movable back and forth in the direction of the rotation axis with respect to the outer socket 10 in the outer socket 10 and is engaged with the outer socket 10 so as not to be relatively rotatable. The coil spring 30 has a direction (arrow) from the front position (see FIG. 3) where the end surface 21 of the inner socket 20 protrudes from the end surface 11 of the outer socket 10 toward the rear position (see FIG. 4) behind the end surface 11. The inner socket 20 is urged toward (A direction).

  In addition, the tool socket 100 of the present embodiment further includes a lock mechanism 40. FIG. 5 is a front view showing an elliptical spring 41 that constitutes a part of the lock mechanism 40.

  The lock mechanism 40 according to the present embodiment includes an outer peripheral portion 41 a that is partially held by the circumferential outer groove portion 12 on the inner peripheral surface of the outer socket 10, and a circumferential inner side groove portion 22 on the outer peripheral surface of the inner socket 20. And an elliptical spring 41 having an inner peripheral portion 41b engaged therewith. The elliptical spring 41 is formed with an opening 41c so as to include one of the long-axis vertices X, and is biased in a direction to reduce the width of the opening 41c. When the elliptical spring 41 is engaged with the circumferential inner groove 22, the inner socket 20 is fixed at the front position, and the engagement between the elliptical spring 41 and the circumferential inner groove 22 is released. As a result, the inner socket 20 is released from the forward position. When the elliptical spring 41 and the circumferential inner groove 22 are engaged, a part of the elliptic spring 41 including the short axis vertex Y is in contact with the circumferential inner groove 22. For this reason, the engagement between the inner socket 20 and the elliptical spring 41 can be released by an appropriate load. Therefore, if the tool socket 100 of this embodiment is used, the operator can operate the lock mechanism 40 by one-handed work, for example.

  Further, in the present embodiment, the tapered portion 23 is formed on the front position side from the circumferential inner side groove portion 22 of the inner socket 20 so as to be separated from the inner peripheral surface of the outer socket 10 from the rear position toward the front position. . Therefore, the inner socket 20 can move smoothly from the rear position to the front position, in other words, in the direction in which the inner socket 20 is fixed. On the contrary, since the taper part is not formed in the back position side from the circumferential inner side groove part 22 of the inner socket 20, as described above, the lock cannot be released unless an appropriate load is applied.

  In addition, in order to restrict the movement of the inner socket 20 further forward than the front position, the inner socket 20 includes an inner-side forward restriction portion 24, and the outer socket 10 includes an outer-side forward restriction portion 14. Further, in order to restrict the movement of the inner socket 20 from the rear position to the back, the inner socket 20 includes an inner side rear restricting portion 25, and the outer socket 10 includes an outer side rear restricting portion 15.

  As described above, the tool socket 100 of the present embodiment includes the lock mechanism 40 that the inner socket 20 fixes at the front position. Therefore, when the work object is fitted into the socket hole 26 of the inner socket 20, the worker can work with the inner socket 20 fixed at the front position. As a result, unnecessary wear occurring between the inner socket 20 and the outer socket 10 can be suppressed. That is, deterioration due to wear of the outer peripheral portion of the inner socket 20 and the inner peripheral portion of the outer socket 10 is suppressed. Further, when the work object is fitted into the socket hole 26 of the inner socket 20, it is necessary for the inner socket 20 to move in the direction from the front position to the rear position (arrow A direction) with respect to the outer socket 10. do not do. As a result, the work time associated with the movement becomes unnecessary, and the work time as a whole is greatly reduced. Furthermore, according to the tool socket 100 of the present embodiment, when the inner socket 20 and the elliptical spring 41 are disengaged, the outer socket 10 is moved when the inner socket 20 moves from the front position to the rear position. The elliptical spring 41 held by the inner socket 20 does not move together. Therefore, wear of the elliptic spring 41, the inner socket 20, and the outer socket 10 is also suppressed. As a result, deterioration due to wear of the outer peripheral portion of the inner socket 20 and the inner peripheral portion of the outer socket 10 can be further suppressed.

  Further, when the work object is fitted into the socket hole 16 of the outer socket 10, an appropriate load is applied to the inner socket 20 toward the rear position by the worker. As a result, the engagement between the inner socket 20 and the elliptical spring 41 is released. When the engagement between the inner socket 20 and the elliptical spring 41 is released, the inner socket 20 quickly moves to the rear position by the biasing force of the coil spring 30. Thus, the work by the outer socket 10 is performed. Further, once the inner socket 20 moves to the rear position, the inner socket 20 stays at the rear position by the biasing force of the coil spring 30. Therefore, when the work object fitted into the socket hole 16 of the outer socket 10 continues, the worker can continue working with the inner socket 20 staying at the rear position. Thereby, the unnecessary wear which arises between the inner socket 20 and the outer socket 10 can be suppressed markedly. That is, deterioration due to wear of the outer peripheral portion of the inner socket 20 and the inner peripheral portion of the outer socket 10 is suppressed.

  In this embodiment, the inner socket 20 is comprised from the inner socket main body 20a and the control member 20b fitted to the outer periphery of the inner socket main body 20a. The restricting member 20b includes the above-described circumferential inner groove portion 22, the above-described tapered portion 23, and the above-described inner-side front restricting portion 24. In addition, the restricting member 20b is restricted by the fixing ring 50 from moving in the direction from the front position to the rear position (arrow A direction) with respect to the inner socket body 20a. FIG. 6 is a front view showing the fixing ring 50. The fixing ring 50 has an opening 51. The fixing ring 50 is fixed to the inner socket 20 by fitting the inner peripheral portion 52 of the fixing ring 50 with the fixing groove 27 formed at the rear of the regulating member 20b.

  Next, the manufacturing process of the tool socket 100 of this embodiment will be described. FIG. 7 is an explanatory view showing a manufacturing process of the tool socket 100 of the present embodiment.

  When manufacturing the tool socket 100, first, as shown in FIG. 7A, the elliptical spring 41 is inserted into the outer socket 10 so that the outer socket 10 and the elliptical spring 41 are separated. Combined. Next, as shown in FIG. 7B, the inner socket body 20 a is inserted into the outer socket 10 combined with the elliptical spring 41 in the direction from the front position toward the rear position (arrow A direction). Further, as shown in FIG. 7C, the coil spring 30 is located on the outer peripheral side of the inner socket body 20 a inserted into the outer socket 10 and on the inner peripheral side of the outer socket 10 from the rear position to the front position. Is inserted in the direction toward (in the direction of arrow B). Thereafter, as shown in FIG. 7D, the restricting member 20b is inserted into the inner socket body 20a in which the coil spring 30 is inserted in the direction from the rear position to the front position (arrow B direction). Thereafter, as shown in FIG. 7E, the fixing ring 50 is fitted from the direction perpendicular to the paper surface to the inner socket body 20a into which the regulating member 20b is inserted. Further, as shown in FIG. 7F, a chuck member 60 for connection to the electric tool 110 is combined with the inner socket body 20a.

  By manufacturing the tool socket 100 in the above-described order, it is very easy to manufacture the tool socket 100 with high functionality.

<Second Embodiment>
FIG. 8 is a cross-sectional view at the front position of the tool socket 200 of the present embodiment, and FIG. 9 is a cross-sectional view at the rear position thereof.

  The tool socket 200 according to this embodiment includes an outer socket 210 instead of the outer socket 10, an inner socket 220 instead of the inner socket 20, and a lock mechanism 240 instead of the lock mechanism 40. Except for these points, it has the same configuration as the tool socket 100 of the first embodiment. Therefore, the description which overlaps with 1st Embodiment may be abbreviate | omitted.

  The inner socket 220 of this embodiment includes an inner socket body 220a and a restriction member 220b. The restricting member 220b has the same configuration as the restricting member 20b of the first embodiment, except that the tapered portion 23 is not provided. The inner socket body 220a has the same configuration as the inner socket body 20a of the first embodiment except that an inner side groove portion 222 is provided instead of the inner side groove portion 22. The outer socket 210 has the same configuration as the outer socket 10 of the first embodiment, except that the outer side groove portion 212 is provided instead of the outer side groove portion 12. In addition, as shown in FIG. 5, the elliptical spring 241 constituting the locking mechanism 240 of the present embodiment is provided with an opening 241 c like the elliptical spring 41. However, the elliptical spring 241 of the present embodiment is different from the elliptical spring 41 of the first embodiment in that it is biased in the direction in which the width of the opening 241c is enlarged.

  A part of the inner peripheral portion 241 b of the elliptical spring 241 is held by the circumferential inner side groove 222 on the inner peripheral surface of the inner socket 220, and the outer peripheral portion 241 a of the elliptical spring 241 is formed on the outer peripheral surface of the outer socket 210. Engage with the circumferential outer groove 212. In the present embodiment, the elliptical spring 241 engages with the circumferential outer groove portion 212, whereby the inner socket 220 is fixed at the front position, and the elliptical spring 241 and the circumferential outer groove portion 212 are connected to each other. When the engagement is released, the inner socket 20 is released from the front position.

  When the elliptical spring 41 and the circumferential outer groove portion 212 are engaged, a portion including the short axis vertex Y of the elliptical spring 241 is in contact with the circumferential outer groove portion 212. For this reason, the engagement between the outer socket 210 and the elliptical spring 241 can be released by an appropriate load. Therefore, if the tool socket 100 of this embodiment is used, the operator can operate the lock mechanism 40 by one-handed work, for example.

  In addition, since the inner socket 220 of the present embodiment does not include the tapered portion 23, the engagement between the inner side groove portion 222 and the elliptical spring 241 is relatively difficult to be released. Therefore, along with the movement of the inner socket 220 between the front position and the rear position, the elliptical spring 241 moves between the front position and the rear position while being engaged with the inner side groove portion 222.

  By using the tool socket 200 of the present embodiment, some of the effects of the first embodiment are exhibited. However, in the tool socket 200 according to the present embodiment, the elliptical spring 41 moves to the rear position together with the inner socket 220 after the engagement between the elliptical spring 41 and the circumferential outer groove 212 is released. Therefore, the possibility that the inner peripheral portion of the outer socket 210 is worn by the elliptic spring 41 during the movement increases. Therefore, from the viewpoint of suppressing deterioration due to wear, it is preferable to employ the tool socket 100 of the first embodiment.

<Other embodiments>
By the way, in 1st Embodiment, although the structure in which the taper part 23 is formed in the inner socket 20 is employ | adopted, even if the structure in which the taper part 23 is not formed is employ | adopted, the one part effect of this invention is demonstrated. Played. However, from the viewpoint of smoothly moving the inner socket 20 from the rear position to the front position, it is a preferable aspect that the inner socket 20 includes the tapered portion 23.

  Further, in the above-described embodiment, a configuration in which the movement of the regulating member 20b is regulated by the fixing ring 50 is adopted, but the configuration is not limited thereto. Even if the restriction of the movement of the restriction member 20b is performed by a known fixing means such as joining or bonding to the inner socket main bodies 20a and 220a, the same effects as those of the above-described embodiments can be obtained.

  Further, in the above-described second embodiment, a configuration including the outer socket 210 that holds the elliptical spring 241 is employed, but the configuration is not limited thereto. For example, the tool socket 300 shown in FIG. 10 includes an outer socket 310 in which a tapered portion 313 is formed instead of the outer socket 210 of the second embodiment. The tapered portion 313 is formed on the rear position side from the circumferential outer groove portion 11 of the outer socket 310 so as to approach the outer peripheral surface of the inner socket 220 from the front position toward the rear position. As a result, the inner socket 220 can smoothly move from the front position to the rear position. However, from the viewpoint of the reliability of fixing the inner socket 220 at the front position, it is a preferable aspect that the tool socket 200 of the second embodiment in which the tapered portion 313 is not formed is employed. In each of the above-described embodiments, a known material is appropriately selected and used. A typical example is chromium molybdenum steel.

  As described above, the modifications existing within the scope of the present invention including other combinations of the embodiments are also included in the scope of the utility model registration request.

  The present invention can be widely used as a tool socket including an inner socket and an outer socket.

10, 210, 310, 1010 Outer socket 11 Outer socket end surface 12, 212 Circumferential outer side groove portion 14 Outer side front restricting portion 15 Outer side rear restricting portion 16, 1016 Outer socket socket hole 20, 220, 1020 Inner socket 20a, 220a Inner socket body 20b, 220b Restriction member 21 End surface of inner socket 22, 222 Circumferential inner side groove 23 Tapered portion 24 Inner side forward restriction portion 25 Inner side rear restriction portion 26, 1026 Inner socket socket hole 27 Fixing Groove 30 Coil spring 40, 240 Lock mechanism 41, 241 Elliptical spring 41a, 241a Outer part 41b, 241b Inner part 41c, 241c Opening part 50 Fixing ring 51 Opening part 52 Inner peripheral part 60 Chat Member 100,200,1100 tool socket 313 tapered portion 1000 work object 1030 spring

Claims (8)

An outer socket,
In the outer socket, an inner socket that is movable back and forth in the direction of the rotation axis with respect to the outer socket, and that engages with the outer socket so as not to rotate relative to the outer socket;
The inner socket is located between the inner socket and the outer socket, and the end surface of the inner socket is at a rear position deeper than the end surface of the outer socket from the front position where the end surface of the inner socket protrudes from the end surface of the outer socket. A coil spring for urging the inner socket in the direction of heading;
The outer socket has an outer peripheral portion that is partly held by the circumferential outer groove on the inner peripheral surface and an inner peripheral portion that engages with the circumferential inner groove on the outer peripheral surface of the inner socket. An opening is formed so as to include one of the apexes of the shaft, and an elliptical spring biasing in a direction of reducing the width of the opening is engaged with the circumferential inner side groove, thereby the inner A tool including a lock mechanism in which the socket is fixed at the front position, and the inner socket is released from the front position by disengaging the elliptical spring and the circumferential inner groove. Socket. The taper part is formed in the said front position side from the said circumferential inner side groove part of the said inner socket so that it may leave | separate from the internal peripheral surface of the said outer socket toward the said front position from the said back position. Tool socket. An outer socket,
In the outer socket, an inner socket that is movable back and forth in the direction of the rotation axis with respect to the outer socket, and that engages with the outer socket so as not to rotate relative to the outer socket;
The inner socket is located between the inner socket and the outer socket, and the end surface of the inner socket is at a rear position deeper than the end surface of the outer socket from the front position where the end surface of the inner socket protrudes from the end surface of the outer socket. A coil spring for urging the inner socket in the direction of heading;
The inner socket has an inner circumferential portion that is partly held in the circumferential inner groove portion on the outer circumferential surface and an outer circumferential portion that engages with the circumferential outer groove portion on the inner circumferential surface of the outer socket. An opening is formed so as to include one of the vertices of the shaft, and an elliptical spring biasing in a direction of expanding the width of the opening engages with the circumferential outer groove, whereby the inner A tool including a lock mechanism in which the socket is fixed at the front position, and the inner socket is released from the front position by disengaging the elliptical spring and the circumferential outer groove. Socket. The taper part is formed so that the outer peripheral surface of the said inner socket may be approached from the said front position toward the said back position in the said back position side from the said circumferential outer side groove part of the said outer socket. Tool socket. An outer socket,
In the outer socket, an inner socket that is movable back and forth in the direction of the rotation axis with respect to the outer socket, and that engages with the outer socket so as not to rotate relative to the outer socket;
The inner socket is located between the inner socket and the outer socket, and the end surface of the inner socket is at a rear position deeper than the end surface of the outer socket from the front position where the end surface of the inner socket protrudes from the end surface of the outer socket. A coil spring for urging the inner socket in the direction of heading;
The outer socket has an outer peripheral portion that is partly held by the circumferential outer groove on the inner peripheral surface and an inner peripheral portion that engages with the circumferential inner groove on the outer peripheral surface of the inner socket. An opening is formed so as to include one of the apexes of the shaft, and an elliptical spring biasing in a direction of reducing the width of the opening is engaged with the circumferential inner side groove, thereby the inner A tool having a lock mechanism in which the socket is fixed at the front position, and the inner socket is released from the front position by disengaging the elliptical spring and the circumferential inner groove. A socket,
The inner socket is composed of an inner socket body and a regulating member fitted to the outer periphery of the inner socket body and provided with the circumferential inner side groove portion,
The tool socket is
The outer socket and the elliptical spring are combined,
The inner socket body is inserted into the outer socket combined with the elliptical spring in a direction from the front position toward the rear position;
The coil spring is inserted into the outer peripheral side of the inner socket body inserted into the outer socket and the inner peripheral side of the outer socket in the direction from the rear position toward the front position,
The socket for tools comprised by the said limitation member being inserted in the direction which goes to the said front position from the said back position with respect to the said inner socket main body in which the said coil spring was inserted. The taper part is formed in the said front position side from the said circumferential inner side groove part of the said control member so that it may leave | separate from the internal peripheral surface of the said outer socket toward the said front position from the said back position. Tool socket. An outer socket,
In the outer socket, an inner socket that is movable back and forth in the direction of the rotation axis with respect to the outer socket, and that engages with the outer socket so as not to rotate relative to the outer socket;
The inner socket is located between the inner socket and the outer socket, and the end surface of the inner socket is at a rear position deeper than the end surface of the outer socket from the front position where the end surface of the inner socket protrudes from the end surface of the outer socket. A coil spring for urging the inner socket in the direction of heading;
The inner socket has an inner circumferential portion that is partly held in the circumferential inner groove portion on the outer circumferential surface and an outer circumferential portion that engages with the circumferential outer groove portion on the inner circumferential surface of the outer socket. An opening is formed so as to include one of the vertices of the shaft, and an elliptical spring biasing in a direction of expanding the width of the opening engages with the circumferential outer groove, whereby the inner A tool having a lock mechanism in which the socket is fixed at the front position and the inner socket is released from the front position by releasing the engagement between the elliptical spring and the circumferential outer groove. A socket,
The inner socket is composed of an inner socket body and a regulating member fitted to the outer periphery of the inner socket body and provided with the circumferential inner side groove portion,
The tool socket is
The outer socket and the elliptical spring are combined,
The inner socket body is inserted into the outer socket combined with the elliptical spring in a direction from the front position toward the rear position;
The coil spring is inserted into the outer peripheral side of the inner socket body inserted into the outer socket and the inner peripheral side of the outer socket in the direction from the rear position toward the front position,
The socket for tools comprised by the said limitation member being inserted in the direction which goes to the said front position from the said back position with respect to the said inner socket main body in which the said coil spring was inserted. The taper part is formed in the said back position side from the said circumferential outer side groove part of the said outer socket so that it may approach the outer peripheral surface of the said inner socket toward the said back position from the said front position. Tool socket.

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