TECHNICAL FIELD

This invention relates to a socket including jaws that are adjustable inwardly and outwardly in a radial direction with respect to a rotational axis of the soc- ° ket so as to permit gripping and rotational driving of nuts and bolt heads of different sizes.

BACKGROUND ART ♦ United States Patent 4,213,355 discloses an improve adjustable socket having jaws that are mounted for radial movement with respect to a rotational axis of the socket so as to permit gripping and driving of nuts and bolt heads of different sizes. A driver or jaw support member of this socket mounts the jaws for the radial movement and is received within a sleeve that engages the jaws to prevent outward radial movement of the jaws. Axial movement of the sleeve with respect to the jaw support member adjusts the jaws inwardly and outwardly in cooperation with a spring. A mount¬ ing end of the spring is secured to the jaw support member and legs of the spring respectively engage the jaws to provide outward biasing thereof into engagement with the sleeve. In one embodiment, a helical locking surface on the j support member is engaged by a helical locking surface on a rotatable adjuster to fix the rotational position therebetween in a manner that axially locates the sleeve to lock the jaws in any adjusted position. In another embodiment, a helical locking surface on the jaw support member and

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a helical locking surface on the sleeve are engaged with each other to axially position the sleeve and thereby axially fix the jaws in any adjusted position.

Other adjustable sockets and the like are disclosed by U.S. Patents: 810,288; 1,288,154; 1,498,040; 1,554,- 963; 2,580,247; 2,582,444; 2,669,896; 2,701,489; 2,850,- 931; 2,884,826; and 3,724,299.

DISCLOSURE OF INVENTION

An object of the present invention is to-provide an adjustable socket including an improved adjustment mechanism for radially adjusting jaws of the socket.

In carrying out the above object, an adjustable socket embodying the invention includes a jaw support member having a rotational axis about which the socket is rotatively driven and a plurality of jaws mounted on the support member for radial adjusting movement in¬ wardly and outwardly with respect to the rotational axis. An adjustment mechanism for radially positioning the jaws includes a seat positioned along the rotational axis and a plurality of helical springs respectively associated with the jaws. Each helical spring has an inner end engaged with the seat and an outer end en¬ gaged with the associated jaw such that the helical springs bias the jaws outwardly in a radial direction.

The spring seat preferably comprises a ball that engages the inner end of each helical spring. Each jaw includes a slide mounted for radial movement on the support member, and the slide of each jaw includes

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an inwardly facing opening that receives the outer end of the associated helical spring. Each jaw slide in¬ cludes an inwardly concave shape around the opening thereof in order to permit the ball to be received thereby upon inward jaw movement so as to permit far¬ ther inward movement of the jaws than would otherwise be possible.

In carrying out the above object in accordance with another aspect of the invention, the adjustable socket embodying the invention includes a jaw support member having a rotational axis about which the socket is ro- tatively driven and also having a plurality of slide- ways that extend radially from the rotational axis. A plurality of jaws respectively associated with the slideways of the support member each have a slide re¬ ceived by the associated slideway of the support mem- ber. The adjustment mechanism moves the jaws along the slideways radially in inward or outward directions with respect to the rotational axis to provide jaw adjustment. . Each jaw has an engagement surface that faces inwardly toward the rotational axis and extends with a slight inward inclination with respect to the rotational axis in an axial direction away from the- slide of the jaw. This construction allows the jaws to accommodate for clearance between the slides thereof and the associated slideways by tilting to position the engagement surfaces of the jaws in a parallel rela¬ tionship with the rotational axis to grip a nut or bolt head by surface-to-surface contact.

In carrying out the above object in accordance with another aspect of the invention, the adjustable

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socket includes a jaw support member having a rota¬ tional axis about which the socket is rotatively driven and a plurality of slideways that extend radially from the rotational axis with an inclination in one axial . direction. A plurality of jaws are respectively asso¬ ciated with the slideways of the support member and each has a slide received by the associated slideway of the support member such that each jaw is supported for radial movement along a path inwardly and outwardly with concomitant axial movement. Each jaw includes an inwardly facing engagement surface for applying torque during rotational driving of the socket and also in- eludes a camming surface that extends radially with an inclination in the opposite axial direction as the support member slideways. The camming surface of each jaw defines an angle greater than 90° with respect to the path of movement thereof and the adjustment mecha- nism engages the camming surfaces of the jaws in a slidable relationship to provide the inward and outward adjusting movement of the jaws.

The adjustment mechanism of the socket preferably includes a sleeve that receives the jaw support member in an axially movable relationship with respect there¬ to in opposite directions. The sleeve includes camming surfaces that engage the jaws at the camming surfaces thereof in a slidable relationship to provide inward and outward jaw movement upon axial movement between the jaw support member and the sleeve in a correspond¬ ing axial direction. An adjuster of a sleeve shape receives the jaw support member in a rotatable rela¬ tionship with respect to both the support member and the sleeve. The sleeve is movable axiallv uoon rota-

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tion of the adjuster to thereby adjust the jaws in¬ wardly or outwardly.

Both an adjusting ring and a retaining ring are also preferably provided with the socket. The adjust¬ ing ring is provided on the adjuster to facilitate gripping thereof for rotation that adjusts the jaws. The retaining ring is secured to the jaw support mem¬ ber after receipt thereof within the sleeve and within the adjuster and maintains the assembled condition of the ^• socket.

in its preferred construction, the jaw support mem¬ ber has an enlarged end on which the jaws are mounted and a smaller round end that is received within the ad¬ juster. An axial face on the enlarged end of the jaw support member includes radial grooves that respectively receive intermediate portions of the jaws. The radial grooves are respectively associated with the slideways extending parallel thereto in an axially inclined orien¬ tation. Axial slots connect the associated slideways and grooves, and each jaw has a web received within the associated axial slot and extending between the slide and intermediate portion thereof such that the slideways and grooves cooperate to mount the jaws on the enlarged end of the support member.

Economical manufacturing of the socket can be achieved by making the support member and jaws as investment castings, and for low volume production the sleeve and adjuster can also be made by invest¬ ment casting or for high volume production by hot or cold tube forming or by a powdered metal process.

In one disclosed embodiment, the jaw support member and the adjuster each include a helical locking surface. Engagement of the helical locking surfaces on the sup¬ port member and the adjuster adjustably positions the sleeve axially with respect to the support member and thereby adjustably positions the jaws. Each helical locking surface includes axially spaced ends so as to permit quick adjusting movement from the fully closed position of the jaws to the fully open position.

Another disclosed embodiment of the socket has the sleeve and adjuster provided with mated threads such that rotation therebetween provides axial movement of the sleeve with respect to the jaw support ^' member for adjusting the jaws.

In both of the disclosed embodiments, the sleeve has a plurality of openings respectively adjacent and axially aligned with the camming surfaces thereof which engage the camming surfaces of the jaws. These open¬ ings receive the intermediate portions of the jaws upon opening movement so as to permit increased out- ward jaw movement that permits a larger fully open position than would otherwise be possible.

Except for their mutually exclusive constructions, each embodiment of the adjustable socket preferably " includes all of the structural features discussed above.

Three of the jaws are preferably utilized so as to permit gripping of conventional six sided nuts and bolt heads. Of course, two or four jaws could also be used for gripping of four sided nuts and bolt heads. For

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special applications, any number of the jaws can be used to grip nuts or bolt heads of custom design with an unconventional number of sides.

The objects, features, and advantages of the pre¬ sent invention are readily apparent from the following detailed description of the best modes for carrying out the invention when taken in connection with the accompanying drawings.

BRIEF DESCRIPTION OF DRAWINGS

FIGURE 1 is a perspective view illustrating an adjustable socket constructed in accordance with the invention;

FIGURE 2 is an exploded perspective view of the adjustable socket illustrated in FIGURE 1;

FIGURE 3 is a schematic view illustrating helical locking surfaces that position jaws of the socket illustrated in FIGURE 2;

FIGURE 4 is a side view of a jaw support member of the adjustable socket illustrated in FIGURE 2;

FIGURE 5 is an axial end view of the jaw support member taken along line 5-5 of FIGURE 4;

FIGURE 6 is a side view of an adjuster of the ad¬ justable socket illustrated in FIGURE 2;

FIGURE 7 is an axial end view of the adjuster taken along line 7-7 of FIGURE 6;

FIGURE 8 is a side view of one of the jaws of the adjustable socket;

FIGURE 9 is a one-half sectional view of the sock¬ et of FIGURE 2 taken in a sideways direction and illu¬ strates the jaws thereof in a fully open position;

FIGURE 10 is a one-half sectional view of the sock¬ et of FIGURE 2 taken in a sideways direction ^' and illu¬ strates the jaws thereof in a fully closed position;

FIGURES 11 and 12 are angular cross-sectional views through the socket respectively taken along lines 11-11 and 12-12 of FIGURES 9 and 10 and illustrating helical springs that bias the jaws radially in an outward direction;

FIGURE 13 is an exploded perspective view of another embodiment of the adjustable socket; and

FIGURES 14 and 15 are one-half sectional views of the socket of FIGURE 13 taken in a sideways direction and respectively illustrating the jaws in fully open and fully closed positions.

BEST MODES FOR CARRYING OUT THE INVENTION

Referring to FIGURE 1 of the drawings, an adjust¬ able socket constructed in accordance with the present invention is indicated generally by reference numeral 10 and is illustrated in association with a ratchet wrench 12 for providing rotational driving of the sock- et about a central axis A. Adjustment of the socket . 10 as is hereinafter described permits gripping of a

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bolt head or a nut such as the nut 14 illustrated for driving rotation about axis A upon application of torque through the ratchet wrench 12.

With reference to FIGURE 2, one embodiment of the adjustable socket is indicated by 10a and includes a jaw support member 16 having a rotational axis along the central socket axis A about which the socket is rotatively driven. Jaws 18 are mounted on the support member 16 for radial adjusting movement inwardly and outwardly with respect to the rotational axis A so as to permit gripping of bolt heads and nuts of different sizes. An adjustment mechanism for radially position¬ ing the jaws 18 includes a seat embodied by a ball 20 and helical springs 22 respectively associated with the jaws. As seen by additional reference to FIGURES 11 and 12, the ball 20 is positioned along the rota- tional axis A of the jaw support member 16 and each of the helical springs 22 has an inner end engaged with the ball as well as an outer end engaged with the asso¬ ciated jaw 18. Helical springs 22 bias the jaws 18 outwardly in a radial direction with respect to the rotational axis A of the socket.

Provision of the ball 20 for seating the inner ends of the helical springs 22 provides an economical and efficient way of biasing the jaws 18 outwardly toward the fully open position as illustrated in FIGURES 9 and 11 from the fully closed position as illustrated in FIGURES 10 and 12. Each jaw 18 includes a slide 24 mounted for radial movement on the jaw support mem¬ ber 16 and ^' having an inwardly facing opening 26 that receives the outer end of the associated helical spring

22. As best seen in FIGURE 10, an inwardly concave shape 28 of each jaw slide 24 about the opening 26 thereof receives the ball 20 upon inward jaw movement so as to permit greater inward movement than would otherwise be possible.

With combined reference to FIGURES 2, 8, and 9 through 12, the jaw support member 16 having the ro¬ tational axis A about which the socket is rotatively driven has slideways 30 that extend radially from the rotational axis. The jaws 18 are respectively asso- ciated with the slideways 30 with the slide 24 of each jaw received by the associated slideway of the support member. The adjustment mechanism of the soc¬ ket moves the jaws 18 -along the slideways 30 radially in inward or outward directions with respect to the rotational axis A upon manually actuated adjustment. As seen in FIGURE 8, each jaw 18 has an engagement surface 32 that faces inwardly toward the rotational axis A and extends with a slight inward inclination with respect to the rotational axis in an axial direc¬ tion away from the slide 24 as illustrated by angle α - which is preferably on the order of about 2°. Such an inclination of each jaw engagement surface 32 al¬ lows the jaws to accommodate for clearance between the slides 24 thereof and the associated slideways 30 by tilting outwardly about the slide. This tilting of the jaws positions the engagement surfaces thereof in a parallel relationship with the rotational axis for gripping of a nut or bolt head by surface-to—surface contact. The inclination of each jaw engagement sur¬ face 32 allows the jaw slide 24 and support member slideway 30 to have an accummulated clearance on the

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order of about fifteen-thousandths of an inch and still function effectively in gripping with a surface-to-sur- 5 face contact during transmission of torque without re¬ quiring more expensive manufacturing operations to hold closer tolerances for the jaw slides and the support member slideways.

10 With combined reference to FIGURES 2, 8 and 10, the jaw support member 16 which is driven about the rota¬ tional axis A of the socket has the slideways 30 thereo extending radially from the rotational axis with an in¬ clination in one axial direction toward the socket end 15 at which the jaw gripping takes place. Each jaw 18 has its slide 24 received by the associated slideway 30 of the jaw support member 16 for radial movement along a path inwardly and outwardly with concomitant axial move¬ ment as illustrated by arrows 34 in FIGURES 8 and 10. 20 Each jaw 18 includes an inwardly facing engagement sur¬ face 32 for applying torque during rotational driving of the socket as previously discussed and also includes

\ a camming surface 36 that extends radially with an in- ι clination in the opposite axial direction as the sup-

25 port member slideways 32. The camming surface 36 of each jaw 18 and the path of jaw movement as illustrated by arrows 34 define an angle β (FIGURE 8) greater than 90° and preferably on the order of about 95°. The adjust¬ ment mechanism of the socket engages the jaw camming

30 surfaces 36 in a manner which is hereinafter described and the angular relationship thereof with respect to the path of jaw movement as illustrated by arrows 34 prevents any binding during both inward and outward jaw movement. Along the path of jaw movement, both

35 the jaw slide 24 and the support member slideway 30

preferably have round cross sections so as to also faci¬ litate the adjusting movement of jaws 18. At their in- ner ends, the slideways 30 define a somewhat pointed junction with each other for receiving the ball 20 that seats the biasing springs 22

As seen in FIGURES 2, 9, and 10, the adjustment mechanism of the socket 10 includes a sleeve 38 that receives the jaw support member 16 by insertion of a small round end 40 thereof into the sleeve followed by insertion of an enlarged end 42 thereof on which the jaw slideways 30 are provided. The sleeve includes camming surfaces 44 that engage the camming surfaces 36 of the jaws 18 as illustrated in FIGURES 9 and 10 in a slidable relationship to provide inward and out¬ ward jaw movement upon axial movement between the jaw support member 16 and the sleeve. An adjuster 46 of the socket adjustment mechanism has a sleeve type con¬ struction as best seen in FIGURE 2 and receives the round end 40 of the jaw support member 16 in a rotatable relationship with respect thereto and with respect to the sleeve 38. The sleeve 38 is moved axially upon rotation of the adjuster 46 to thereby adjust the jaws inwardly or outwardly.

As seen in FIGURES 4, 5, 6, and 1 , the jaw support member 16 includes a helical locking surface 48 and the adjuster 46 includes a complementary helical lock¬ ing surface 50. Each of these helical locking surfaces extends about the axis of socket rotation for 360° as illustrated in FIGURE 3 and includes suitable locking projections 52 such that _. axial engagement of the lock- ing surfaces prevents undesired rotation between the jav

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support member 16 and the adjuster 46. The locking surface 48 on the jaw support member 16 faces away from its enlarged end 42 as illustrated in FIGURE 4 toward its smaller round end 40 whose axial extrem¬ ity is provided with a square driving hole 54 with sides that are each provided with an associated de¬ pression 56 for receiving a ball detent on the driver of an associated wrench. Adjuster 46 has an enlarged end 58 on which its helical locking surface 50 is disposed so as to face toward the helical locking sur¬ face 48 of the jaw support member with the smaller round end 40 thereof received within the adjuster. A small end 60 of the adjuster 46 extends away from an annular shoulder 62 that faces in the opposite axial direction as the locking surface 50 on the en¬ larged end 58. Helical locking surface 48 on the jaw support member 16 has axially spaced ends 48a and 48b connected by an axially extending surface 64, and the helical locking surface 50 on the adjuster 46 has axially spaced ends 50a and 50b connected by an axially extending surface 66.

Upon assembly of the socket, the adjuster 46 illu¬ strated in FIGURES 6 and 7 receives the small end 40 of .the jaw support member 16 illustrated in FIGURES 4 and 5 for insertion of both into the sleeve 38 illu¬ strated in FIGURE 2 with the jaws 18 received by the associated slideways 30 of the jaw support member in association with the seated springs 22 as previously described. The adjustment mechanism also includes an adjusting ring 68 that receives the smaller end 60 of the adjuster 46 after being received within the sleeve 38 and a lock screw 70 fixes the adjusting ring

with respect to the adjuster. The adjusting ring has a larger diameter than the small end 60 of the adjus- ter 46 and thereby facilitates manual gripping and rotation of the adjuster 46 with respect to the jaw support member 16 in order to position the helical locking surfaces 48 and 50 to adjust the axial posi¬ tion of the sleeve 38 and thereby radially adjust the jaws.

Helical springs 22 bias the jaws 18 outwardly away from the fully closed position illustrated in FIGURE 10 toward the fully open position illustrated in FIGURE 9 and the consequent sliding action between the jaw cam¬ ming surfaces 36 and the sleeve camming surfaces 44 biases the sleeve 38 axially toward the left so as to engage an inwardly extending annular flange 72 on the sleeve with the annular shoulder 62 on the adjuster 46. This biasing also axially engages the helical locking surfaces 48 and 50 so as to prevent rotation between the adjuster 46 and the jaw support member 16 such that the sleeve 38 is axially positioned to thereby adjust¬ ably fix the jaws in a locked relationship. Adjusting ring 68 is manually gripped with one hand and relative rotation thereof with respect to the sleeve 38 provides the adjustment of the jaws. Rotation of the ring 68 adjusts the rotational position at which the helical locking surface 50 thereof engages the helical locking surface 48 on the jaw support member 16 in order to axially adjust the position of the adjuster shoulder 62 and thereby adjust the position of the sleeve shoul¬ der 72 such that the sleeve and jaw camming surfaces 44 and 36 adjustably position the jaws 18 in cooperation with the helical springs 22. Rotation of the adjusting

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ring for closing of the jaws moves the sleeve 38 to¬ ward the right with respect to the jaw support mem¬ ber 16 until the fully closed position is reached whereupon continued rotation moves the ends 48a and 50a of the locking surfaces past each other such that the sleeve moves axially under the spring bias to provide quick opening movement of the jaws.

Jaw support member 16 can be moved axially with respect to the sleeve 38 toward the left as illu¬ strated in FIGURES 9 and 10. The socket includes a retaining ring 74 that is received by a round groove 76 (FIGURE 4) in the small round end 40 of the jaw support member 16 after the assembly of the socket. Retaining ring 74 axially engages the small end 60 of the adjuster 46 to limit the relative axial move¬ ment of the jaw support member and thereby maintains the assembled condition of the socket.

A very economical socket can be manufactured by making the support member 16 and jaws 18 as investment castings, and for low volume production the sleeve 38 and adjuster 46 can also be made by investment casting or for high volume production by hot or cold tube form¬ ing or by a powdered metal process.

As seen in FIGURES 2, 4, 5, 8, and 9, the enlarged end 42 of the jav: support member 16 has an axial face including radial grooves 78 that extend with an angular inclination parallel to the slideways 30 and slidably support intermediate jaw portions 80 in cooperation with the slides 24 and the associated slideways. Each groove 78 has side surfaces 82 as seen in FIGURE 4

as well as inclined axial surfaces 84 respectively ad¬ jacent the side surfaces. Each slideway 32 and its associated groove 78 are axially aligned and connected by an associated axial slot 86 as best seen in FIGURE 4 and each jaw has an angular intermediate web 88 that is received by the associated axial slot. The support member grooves 78 and intermediate jaw portion 80 co- operate with the slides 24 and slideways 32 to provide support of the jaws in any adjusted position. Also, openings 90 in the sleeve 38 respectively adjacent the camming surfaces 44 in axial alignment therewith allow the intermediate jaw portions 80 to move outwardly through the sleeve upon outward jaw movement so as to permit a larger size fully open position than would otherwise be possible. Each jaw web 88 has an inwardly facing pointed shape as best ^' seen in FIGURES 11 and 12 such that the jaws can move inwardly to provide a smaller fully closed position than would other-wise be possible.

With reference to FIGURES 13, 14, and 15, another embodiment of the adjustable socket indicated at 10b is the same as the previously described embodiment except as will be noted such that like reference nu¬ merals are shown and much of the previous description is applicable and thus will not be repeated. Adjust¬ able socket 10b has a sleeve 38 whose flange 72 includes internal threads 92 and also has an adjuster 46 having a sleeve end 94 including external threads 96 that mate with the internal threads on the sleeve. An annular shoulder 98 of the jaw support member 16 faces away from the enlarged end 42 thereof toward the smaller round end 40 and engages the axial end of the adjuster

sleeve 94 under the bias of springs 22 in the assembled condition of the socket. Adjusting ring 68 is unitary with the adjuster 46 to facilitate gripping thereof and rotation of the adjuster with respect to the sleeve 38 and the jaw support member 16 so as to move the sleeve axially and thereby adjustably position the jaws 18. Rotation of the adjuster 46 in one direction moves the sleeves 38 toward the right such that the camming sur¬ faces 36 and 44 move the jaws 18 against the bias of springs 22 in an inward direction away from the fully open position shown in FIGURE 14 toward the fully closed position shown in FIGURE 15. Rotation of the adjuster 46 in the opposite direction moves the sleeves 38 toward the left such that the cooperation of the cam¬ ming surfaces 36 and 44 and the bias of the springs 22 moves the jaws in a direction from the fully closed • position toward the fully open position.

Both embodiments of the socket are illustrated with three jaws 18 spaced circumferentially from each other at 120° positions so as to permit gripping and torquing of six sided nuts and bolt heads.

While the best modes for carrying out the invention have been described in detail, those familiar with the art to which this invention relates will reconize various alternative designs and embodiment for prac- ticing the invention as defined by the following claims.

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