BACKGROUND INFORMATION

A cable tie is used for fastening, binding, bundling, and/or organizing cables/wires, pipes, pieces of wood, and/or any other items/load that can be tied with rope, tape, etc.

Different types of cable ties are made for use in different environments and applications. For example, some cable ties are made for outdoor use. Some cable ties are made for a specific industry, such as the food industry. Some are made for heavy-duty use (e.g., cable ties made of metal), for bundling large cables.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate one or more embodiments described herein and, together with the description, explain the embodiments. In the drawings:

FIG. 1A is an isometric perspective top/side view of an exemplary cable tie in an open configuration according to one implementation;

FIG. IB is an isometric perspective bottom/side view of the cable tie of FIG. 1 A in the open configuration;

FIG. 2 is an expanded isometric perspective top/side view of the cable tie of FIG. 1 A in the closed configuration;

FIG. 3 is an isometric cut-away perspective top/side view of the cable tie of FIG. 1 A in the closed configuration;

FIG. 4A is a cross-sectional side view of the cable tie before an end of the cable tie of FIG. 1A is inserted into a locking body of the cable tie;

FIG. 4B is a cross-sectional side view of the cable tie when the end of the cable tie of FIG. 1A is partially inserted into the locking body of the cable tie;

FIG. 4C is a cross-sectional side views of the cable tie after the end of the cable tie of

FIG. 1A is inserted into the locking body and the cable tie is in the closed configuration;

FIG. 5A is an isometric cut-away perspective top/side view of the cable tie according to another implementation;

FIG. 5B is an isometric cut-away perspective top/side view of the cable tie according to yet another implementation,

FIGS. 6A-6C are cross-sectional side views of the cable tie according to different implementations ; FIG. 7A is an isometric perspective top/side view of an exemplary cable tie in the open configuration according to another implementation;

FIGS. 7B and 7C are top and side views, respectively, of the cable tie of FIG. 7A;

FIG. 7D illustrates different forces that are applied to one of exemplary wave springs of FIGS. 7A-7C;

FIG. 7E and 7F illustrate different indentations on the wave springs of FIGS. 7A-7C;

FIG. 8A is an isometric perspective top/side view of an exemplary cable tie in the open configuration according to yet another implementation;

FIG. 8B is a cross-sectional side view of an exemplary ear clamp of the cable tie of FIG. 8A;

FIG. 8C is an expanded view of the ear clamp of the cable tie of FIG. 8A;

FIG. 8D is an isometric perspective top/side view of the cable tie of FIG. 8A after the cable tie is tightened by crushing the ear clamp;

FIG. 8E is a cross-sectional side view of the exemplary ear clamp of the cable tie of FIG. 8 A after the ear clamp has been crushed;

FIG. 9A is an isometric perspective top/side view of an ear clamp according to another exemplary implementation; and

FIG. 9B and 9C are cross-sectional side views of an ear clamp according to other implementations .

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

The following detailed description refers to the accompanying drawings. The same reference numbers in different drawings may identify the same or similar elements.

As used herein, the term "cable tie" may refer to a tie for binding different types of items, such as wires, cables, pipes, etc.

As described herein, a no-slip cable tie may provide for a small/minimum slack in binding, fastening or bundling cables. To tie/bundle cables using the no-slip cable tie, one end of a band, of the cable tie, that encircles the cables is inserted into the housing of a locking body of the cable tie. When the end of the band is inserted within the housing of the locking body, the band pushes a ball bearing within the housing toward an inner wall of the housing. Another ball within the housing, however, prevents the ball bearing from moving backwards beyond a point and bumping into the inner wall. When the band is pulled/tugged in the forward direction away from the inner wall, the ball bearing, being close to a front of the wall, prevents the end of the band from slipping and locks the band in place. Because the other ball prevents the ball bearing from moving about in the housing, the ball bearing continues to lock the band in place.

FIG. 1A shows an isometric perspective top/side view of an exemplary cable tie 100 in an open configuration according to one implementation, together with an xyz-axes 101. As shown, cable tie 100 includes locking body 102 and a band 104. In FIG. 1A, cable tie 100 is oriented such that band 104 extends along the x-axis of xyz-axes 101 and the unit normal vector of the flat surface of band 104 is parallel to the z-axis. Band 104 has an interior portion inside of housing 108.

When band 104 is wrapped about cables and an end of band 104 (e.g., section 116-3) is inserted within locking body 102, locking body 102 prevents the end from slipping back out of locking body 102 and the band from unwrapping about the cables.

Locking body 102 includes a side wall 106-1, a top wall 106-2, a side wall 106-3, bottom walls 106-4 and 106-5 (shown in FIG. IB), and housing 108. Walls 106-1 through 106-5 (collectively referred to as "walls 106") extend along the x-axis from a side face 112-1 to a side face 112-2 (shown in FIG. IB). In one implementation, walls 106 may be made of one continuous strip of rigid material wrapped (e.g., loosely) about band 104, such that there is a gap/opening 114-1 and gap/opening 114-2 (FIG. IB) between walls 106 and band 104.

Housing 108 includes a side portion 110-1 (also referred to as a "stop 110-1"), a top portion 110-2, and a side portion 110-3 (collectively referred to as "portions 110"). As further described below, portions 110 are configured/shaped to enclose and interact with elements within housing 108, to prevent a portion of band 104 (which was inserted through opening 114-1 and 114-2) from sliding out from housing 108 when no-slip cable tie 100 is in the closed configuration. In FIG. 1A, housing 108 is in the shape of a dome, and may be made of steel, plastic, or another suitable material.

Band 104 includes an entrance section 116-1, a middle section 116-2, and an end section 116-3. Band 104 also includes edges, two of which are illustrated as a side edge 120- 1 and front edge 120-3. In one embodiment, side edge 120-1 and front edge 120-3 form an acute angle, such that, along the side edge 120-1 and parallel to the x-axis, the end of band 104 tapers to a tip 122 that can be more easily inserted into a gap/opening 114-2 (see FIG. IB) after band 104 is bound around cables/wires, to result in a closed (loop) configuration. The end of tip 122 may be rounded, so that a user may not easily and accidentally puncture oneself with tip 122. In one embodiment, when band 104 binds/bundles cables/wires, bottom surface 118-2 (FIG. IB) of band 104 may face the cables/wires and be in contact with the cables/wires. Band 104 may be made of flexible material, such as steel, or another material.

FIG. IB shows an isometric perspective bottom/side view of cable tie 100 in an open configuration, together with an xyz-axes 101. FIG. IB illustrates a number of features, of cable tie 100, that are not shown in FIG. 1A. For example, FIG. IB shows side edge 112-2 with gap/opening 114-2. FIG. IB also shows band 104 extending from entrance portion 116- 1 into locking body 102 (along the negative x-axis) and exiting from locking body 102 via opening 114-2 to form a clip 124 with a flap 126 that covers bottom walls 106-4 and 106-5. As shown, clip 124 and flap 126 are integrally formed with band 104. In a different implementation, clip 124 and flap 126 be constructed separately from band 104 and then affixed together via screws or another mechanism.

As shown in FIG. IB, flap 126 includes, in one embodiment, at about the middle of its surface, a tab 128 with a crease 130. Bottom walls 106-4 and 106-5 above tab 128 has a hole (e.g., a square hole whose front edge is aligned with a front edge of tab 128) (not shown in FIG. IB). Tab 128 is thrust upward in the direction of arrow 129 into the hole, bent about crease 130 (e.g., in the direction of the z-axis).

In this configuration, side walls 106-1 and 106-3 of locking body 102, clip 124, and tab 128 hold/affix a portion of locking body 102 to an interior portion of band 104, with the bottom surface 118-2 of band 104 being flush with an interior surface (the surface within locking body 102) of bottom walls 106-4 and 106-5 and the top surface of flap 126 being flush with the exterior surface (the surface in the -z direction) of bottom walls 106-4 and 106- 5. Side walls 106-1 and 106-3 prevent the interior portion of band 104 from moving laterally in the negative/positive y-direction with respect to locking body 102. Clip 124, which is integral to band 124, prevents locking body 102 from sliding in the negative/positive x- direction relative to the interior portion of band 104. Tab 128, having been pushed into the hole in bottom walls 106-4 and 106-5, catches an edge of the hole when an external force is applied to locking body 102 relative to the interior portion of band 104 in the positive x- direction. Tab 128 and the hole prevents locking body 102 from sliding in the x-direction relative to the interior portion of band 104.

FIG. 2 is an expanded isometric perspective top/side view of cable tie 100 in the closed configuration. In FIG. 2, end portion 116-3 of band 104 has been inserted into gap/hole 114-2 formed at side wall 112-2 of locking body 102, and passed through and out of locking body 102 via gap/hole 114-1, resulting in the closed configuration. In the configuration, a section/portion of band 104 (e.g., end section 116-3) overlaps with entrance portion 116-1 of band 104. In FIG. 2, bottom surface 118-2 of end section 116-3 would be in contact with the top surface 118-1 of entrance section 116-1.

FIG. 3 is an isometric cut-away perspective top/side view of cable tie 100 in the closed configuration. FIG. 3 shows a number of features that are not visible in FIG. 1A through FIG. 2. As shown, housing 108 encloses space 302 in which a ball bearing 304 and sphere 306 are placed. In one implementation, ball bearing 304 may be made of metal (e.g., steel) and sphere 306 may be made of elastomeric or another material (e..g, plastic, rubber, sponge-like or spring-like material, stainless steel sponge, etc.). In the implementation illustrated in FIG. 3, ball bearing 304 and sphere 306 may have approximately the same diameter. In other implementations, the diameters may be different.

FIG. 3 also shows entrance portion 116-1 extending into housing 108 as an interior section/portion 308, which joins clip 124. In the closed configuration, interior section 308 is underneath end section 116-3 and above bottom walls 106-4 and 106-5. In FIG. 3, bottom wall 106-4 is illustrated as having front area 310-1 and a rear area 310-2. Between front area 310-1 and rear area 310-2 is a hole 312, into which tab 128 protrudes in the direction of arrow 129. Hole 312 may be in the shape of a rectangle, square, and/or another shape (e.g., circle, etc.) As explained above, an edge of tab 128 engages an edge of hole 312 if housing 108 is pushed/pulled in the x-direction relative to interior section 308, and prevents housing 108 from sliding in the x-direction relative to interior section 308 (e.g., prevents housing 108 from detaching from interior portion 308 of band 104).

FIGS. 4A through 4C are cross-sectional side views of cable tie 100 at different stages of closing cable tie 100 into a loop. FIG. 4A is a cross sectional side view of cable tie 100 before end section 116-3 of band 104 is inserted into locking body 102 via gap/opening 114-2 to be in the closed configuration. Like FIG. 3, FIG. 4 A shows ball bearing 304 and sphere 306 occupying space 302 of housing 108.

FIG. 4B is a cross sectional side view of cable tie 100 when end section 116-1 of band 104 is partially inserted into locking body 102 of cable tie 100. In FIG. 4B, after band 104 is wrapped about a bundle of cables/wires, end section 116-3 is pushed in the direction of arrow 406 via gap/opening 114-2 into housing 108. Consequently, end section 116-3 overlaps with interior section 308. As end section 116-3 moves further in the direction of arrow 406, section 116-3 pushes ball bearing 304, causing ball bearing 304 to move in the direction of arrow 408, such that section 116-3 may slide underneath ball bearing 304. In addition, section 116-3 also pushes ball bearing 304 in the direction of arrow 410, causing an area 412 on ball bearing 304 to contact an area 414 of sphere 306. Although the force on area 414 pushes sphere 306 in the direction of arrow 416, because area 418 of sphere 416 is in contact with stop 110-1 (or the interior surface of side portion 110-1) of housing 108, sphere 306 moves, in the direction of x-axis, little or no distance. Accordingly, sphere 306 prevents ball bearing 304 from moving further in the direction of arrow 410 and touching stop 110-1.

FIG. 4C is a cross sectional side view of cable tie 100 after end section 116-3 of band 104 is inserted into locking body 102 and cable tie 100 is in the closed configuration. In FIG. 4C, having been inserted fully into housing 108, end section 116-3 overlaps with entrance section 116-1. From this position, if band 104 is pulled in the direction of arrow 419, the frictional force between band 104 and ball bearing 304 causes ball bearing 304 to move in the direction of arrow 420 to the extent that there is space/clearance in space 302. Because space 302 within housing 108 is tapered in the negative x-direction, as ball bearing 304 is driven in the direction of arrow 420 until ball contacts the surface of portion 110-3 (also referred to as "stop 110-3"), area 424 and 422 of ball bearing 304 exert increasing force on the interior surface of portion 110-3 of housing 108 and on the top surface of end section 116-3 of band 104, respectively. The downward force exerted by area 422 of ball bearing 304 on end section 116-3 may pinch end section 116-3 between ball bearing 304 and interior section 308, and thus prevent end section 116-3 from retreating back in the direction of arrow 410 through gap/opening 114-2. That is, ball bearing 304 provides for the locking mechanism of cable tie 100.

As briefly discussed above, in a different embodiment without sphere 306 in space 302, when end section 116-3 is inserted into housing 108, end section 116-3 may cause ball bearing 304 to move all the way (or significant portion of the way) to stop 110-1 of housing 108. With ball bearing 304 in such a position, if band 104 were pulled back in the direction of arrow 419 (e.g., due to the weight of cables that are bound by cable tie 100), as end section 116-3 moves in the same direction relative to housing 108, ball bearing 304 would also move from the stop 110-1 of housing 108 toward the interior surface of portion 110-3 of housing 108, until ball bearing 304 locks end section 116-3, and, therefore, band 104. The distance covered by ball bearing 304 until ball bearing 304 locks band 104 is approximately the amount of slippage of band 104 allowed by cable tie 100. The slippage may result in an undesirable amount of slack in band 104 when cable tie 100 is in the closed configuration, with band 104 wrapped about cables/wires. In contrast, with sphere 306 in place as illustrated in FIGS. 3, 4A, 4B, and 4C, ball bearing 304 cannot move in the direction of arrow 410 when end section 116-3 is inserted into housing 108 (or can only move a small amount). Hence, when band 104 is pulled in the direction of arrow 419 (e.g., by the weight of the cables that are wrapped by band 104), ball bearing 304 cannot travel as significant of a distance until ball bearing 304 locks band 104. In other words, sphere 306 may prevent band 104 from slipping, and helping to prevent unwanted slack between band 104 and the cables bundled by cable tie 100 (e.g., slipping distance < the distance occupied by sphere 306 (e.g., the diameter)).

FIG. 5 A is an isometric cut-away perspective top/side view of cable tie 100 according to another implementation. In this implementation, cable tie 100 includes, in place of sphere 306, a cylinder 502. Cylinder 502 may play a role similar to that of sphere 306 in the implementations described above.

FIG. 5B is an isometric cut-away perspective top/side view of cable tie 100 according to another implementation. In this implementation, cable 100 includes, in place of sphere 306, a block 504. Block 504 may prevent ball bearing 304 from allowing undesirable slippage of band 104 when band 104 is closed around cables/wires, in a manner similar to that described above for sphere 306 (e.g., by occupying a space between ball bearing 304 and stop 110-1 of housing 108.

FIGS. 6A-6C are cross-sectional side views of cable tie 100 according to other implementations. FIG. 6A shows the cross-sectional view of cable tie 100 according to one implementation. In this implementation, ball bearing 604, square/cube 606, and side portions 602-1 through 602-3 correspond to ball bearing 304, sphere 306, and side portions 110-1 through 110-3, respectively, illustrated in FIGS. 4A-4C. Furthermore, each of ball bearing 604, cube 606, side portions 602-1 through 602-3 has a functional role corresponding to the role of bearing 304, sphere 306, and side portions 110-1 through 110-3, respectively. In addition, cube 606 acts as a spring between bearing 604 and side portion 110-1. Cube 606 exerts a pressure on bearing 604 by pushing against side portion 602-1 and bearing 604. This prevents bearing 604 from moving away substantially from portion 602-3, and reducing the force on section 116-3 when section 116-3 is fully inserted in housing 108.

In a typical implementation, cube 606 may be made of resilient material, such as stainless steel or stainless steel wire mesh. Depending on the implementation, cube 606 may be replaced by a stainless steel mesh of another shape, such as a round ball, cylinder, rectangular box/prism, etc. In contrast to portions 110 in Fig. 4A-4C, portions 602 may be shorter or longer - that is, portions 602 may extend to properly accommodate cube 606.

FIG. 6B shows the cross-sectional view of cable tie 100 according to yet another implementation. In this implementation, ball bearing 608 and sphere 610 and side portions 612-1 through 612-3 correspond to ball bearing 304, sphere 306, and side portions 110-1 through 110-3, respectively, illustrated in FIGS. 4A-4C. Each of ball bearing 608, sphere 610, side portions 612-1 through 612-3 has a functional role similar to the role of bearing 304, sphere 306, and side portions 110-1 through 110-3, respectively. In this implementation, ball bearing 608 is smaller (i.e., has a smaller diameter) than sphere 610 such that ball bearing 608 occupies slack/room in housing 108. Ball bearing 608 and sphere 610 prevent each other from "sloshing" in housing 108 (by occupying the space in housing 108), and thus prevent reduction of the force exerted by bearing 608 and/or sphere 610 on section 116-3 when section 116-3 is fully inserted in housing 108.

Portions 612 may be dimensioned to properly accommodate ball bearing 608 and sphere 610. In some implementations, both ball bearing 608 and sphere 610 may be composed of the same or similar materials (e.g., stainless steel).

FIG. 6C shows the cross-sectional view of cable tie 100 according to yet another implementation. In this implementation, sphere 614 corresponds to ball bearing 304 and sphere 306, and portions 616-1 through 616-3 correspond to portions 110-1 through 110-3 illustrated in FIGS. 4A-4C. In FIG. 6C, portions 616-1, 616-2, and 616-3 are shaped/cut such that portions 616-1 and/or 616-2 ("housing 108" or buckle) act as backstop against sphere 614. Once inserted into housing 108, section 116-3 acts as a leaf spring on sphere 614 and pushes sphere 614 against portions 616-1 through 616-3. That is, when section 116-3 of cable tie 100 is inserted in housing/buckle 108, sphere 614 is pressed against portions 616 (e.g., especially portions 616-1 and 616-2) by section 116-3. When section 116-3 is being pulled back out of housing 108, sphere 614 is pulled toward portion 616-3, which increases the force applied by section 116-3 against sphere 614. This causes sphere 614 to increase its force on portion 616-3 and section 116-3, preventing section 116-3 from being pulled out of housing 108. In this implementation, section 116-3's leaf-spring action against sphere 614 and the shape of portions 616 prevent sphere 614 from moving substantially away from portion 616-3. This causes sphere 614 to maintain constant pressure on section 116-3 and not allow section 116-3 to slip away from within housing 108. In some implementations, interior portion 308 may include a "dimple" or a hole. In other implementations, interior portion 308 excludes (i.e., is without) a dimple or a hole. If a hole or a dimple exists on interior portion 308, when section 116-3 is fully inserted into housing 108, bearing/sphere (e.g., any one of bearing 304, sphere 306, cylinder 502, cube 606, bearing 608, sphere 610, or sphere 614) may drive the area (of section 116-3) on which the bearing sits into the hole (on interior portion 308) underneath section 116-3. In this way, the dimple or hole on interior portion 308 may further stabilize the bearing/sphere, when section 116-3 is locked by the bearing/sphere.

FIG. 7A is an isometric perspective top/side view of an exemplary cable tie 700 in the open configuration according to another implementation. FIGS. 7B and 7C are top and side views, respectively, of the cable tie of FIG. 7A. As shown in FIGS. 7A-7C, cable tie 700 may include a locking body 702 and a band 704.

Locking body 702 includes similar components as locking body 102 and is made of the same material as locking body 102. In addition, locking body 702 may operate similarly as locking body 102.

Band 704 includes similar components and is made of the same material as band 104. Band 704 also operates similarly to band 104. In contrast to band 104, however, band 704 includes front section 716-1, spring section 716-2, and end section 716-3.

As further shown, spring section 716-2 includes five wave springs, 722, 726, 730, 734, and 738. Each of wave springs 722, 726, 730, and 734 includes downward arcs, an upward arc, and an end piece. For example, wave spring 722 includes downward arcs 722-1 and 722-3, upward arc 722-2, and end piece 724. As shown, each of wave springs 726, 730, and 734 include similar components as wave spring 722. Wave spring 738 is slightly different from other wave springs 722, 726, 730, and 734 in that wave spring 738 does not include an end piece.

A downward arc may include a strip that is curved convex relative to the bottom surface of band 704 (the downward arc is also curved concave relative to the top surface of band 704). Conversely, an upward arc may include a strip that is curved convex relative to the top surface of band 704 (the upward arc is also curved concave relative to the bottom surface of band 704). For wave spring 722, one end of downward arc 722-1 is attached to a piece that precedes wave spring 722 (i.e.., front section 716 in this case) and the other end of downward arc 722-1 is attached to end piece 724. Similarly, one end of downward arc 722-3 is attached to a piece that precedes wave spring 722 (i.e., front section 716) and the other end of downward arc 722-3 is attached to end piece 724. Upward arc 722-2 is similarly configured. The arcs of other wave springs 726, 730, and 734 are arranged similarly as those of wave spring 722. For wave spring 738, one ends of downward arcs 738-1 and 738-3 and upward arc 738-2 are attached to end section 716-3 (since there is no end piece for wave spring 738).

For each of the wave springs 722, 726, 730, and 734, its end piece interconnects its upward and downward arcs, (e.g., arcs 722 are connected to one other via end piece 724). Hence, each end piece allows the corresponding wave spring to function as a single unit and provides necessary rigidity to the wave spring. Without the end piece, for example, downward arc 722-1 of wave spring 722 would be directly attached to arc 726-1 of the next wave spring 726, and thus form a continuous series of arcs. The series of arcs 722-1 and 726- 1 would be free to move relative to another series of upward arcs (i.e., 722-2 and 726-2) parallel to downward arcs 722-1 and 726-1.

As illustrated in FIG. 7C, to wrap cable tie 700 about a load (e.g., bundle of cables, pipes, beams, wires, pencils, etc.) (not shown) under tie 700, end section 716-3 of tie 700 may be to bent in the direction of arrow 740. Once wrapped about the load, end section 716- 3 may be inserted into locking body 702 and tightened (e.g., by pulling on end section 716- 3). Tightening cable tie 700 may exert different force components on each of the wave springs.

FIG. 7D illustrates different forces that are applied to wave spring 722 of cable tie 700 when cable tie 700 is in use and tightened. FIG. 7D shows the original shape of arcs 722-1 through 722-3 in dotted lines and the final shape of the arcs in solid lines after the forces act on the arcs.

As shown, as the result of tightening cable tie 700, pulling forces are applied to the ends of arcs 722-1 through 722-3 in the directions of arrows 750 and 754, by front section 716-1 and end piece 724. The forces widen (or spread apart) arcs 722-1 through 722-3 in the same directions as the arrows. As the arcs widen, the arcs exert restorative forces (spring's force) in the directions opposite to those the arrows, to front section 716-1 and end piece 724. The restorative forces from each of the wave springs 722, 726, 730, 734, and 738 are transmitted throughout band 704, keeping tie 700 tight around the load and in equilibrium against the pulling forces. The constant tension in cable tie 700 may keep end section 716-3 in locking body 702 from sliding further into body 702 (e.g., due to vibration or other disturbances) and may prevent locking mechanisms within locking body 702 (e.g., square/cube 606, ball bearing 608, sphere 610, etc.) from moving and providing slack to cable tie 700. That is, the tension allows cable tie 700 to absorb any vibrations that may cause, without the wave springs, over time, locking body 702 to disengage band 704 or tie 700 from becoming loose.

When tie 700 is wrapped around a load, a portion(s) on the underside of arc 702-1 (as shown by arrow 752) may contact the load. The portion in contact with the load may experience a force applied by the load, as the result of tie 700 being wrapped about the load. For example, assume that the load contacts the portion of arc 722-1 at the point of arrow 752. The portion would experience a force in the direction of arrow 752. The force would result in further widening of lower arc 722-1. The restorative forces due to upper arc 722-2 may aid in counteracting the widening. That is, upper arc 722-2 provides reinforcement to lower arcs 722-1 and 722-3.

In FIG. 7B, each arc in a wave spring is approximately 1/3 of the width of tie 700. In a different implementation, the width of each arc in a wave spring may be wider or narrower than those of other arcs in the spring. Each arc may be made longer/shorter (i.e., in the lengthwise direction of tie 700) taller/less tall (in the direction of arrow H in FIG. 7D). Such changes may provide more flexibility or rigidity to tie 700. For example, increasing the lengths of upper/lower arcs 722-1 through 722-3 may increase the flexibility of wave spring 722. The size of the end pieces (e.g., pieces 724, 728, 732, and 736) in the lengthwise direction of band 704 may also be increased or decreased (e.g., decreased to zero length).

FIGS. 7 A or 7B show the surfaces of the arcs as being relatively smooth and without markings. In some implementations, as illustrated in FIG. 7E, for some of the arcs (e.g., upper arcs), a deep, lengthwise indentation/groove 760 may be placed on the top surface of each arc. This may increase the rigidity or tensile strength of the arcs. In other

implementations, as illustrated in FIG. 7F, a groove/indentation 762 that extends from approximately a portion of an arc to a portion of end piece may be placed on each of the wave springs (e.g., upper arcs 722-2, 726-2, etc.). This may bolster and provide further strength to the portion of the arc that attaches to the end piece. Although FIGS. 7E and 7F illustrate the indentations/grooves on the top surface of the upper arcs, in other implementations, the indentations/ grooves may also be made on the lower arcs, on the bottom surface of tie 700.

Although FIGS. 7A-7C, 7E, and 7F show front section 716-1 as being shorter than spring section 716-2, which is shown as shorter than end section 716-3, in other

implementations, the relative lengths of the sections may vary. Furthermore, although FIGS. 7A-7C, 7E and 7F show only one spring section 716-2, other implementations may include additional spring sections. In such an implementation, each of the wave springs may or may not include two lower arcs and a single upper arc. For example, a wave spring may include two upper arcs and one lower arc, or alternatively, three lower arcs and two upper arcs. The number of arc(s) in one wave spring also may be the same or different from those of another wave spring.

FIG. 8A is an isometric perspective top/side view of an exemplary cable tie 800 in the open configuration according to yet another implementation. In this implementation, tie 800 includes a locking body (not shown) and band 804.

The locking body for tie 800 includes similar components as locking body 102 or 702 and is made of the same material as locking body 102 or 702. In addition, the locking body for cable tie 800 may operate similarly as locking body 102 or 702.

Band 804 includes similar components and is made of the same material as band 104 or 702. Band 804 also operates similarly to band 104 or 704. In contrast to bands 104 and 704, however, band 804 includes front section 816-1, ear clamp 816-2 and end section 816-3. In contrast to front section 116-1 or 716-1, front section 816-1 is illustrated as extending all the way to the clip (a component corresponding to clip 124 of tie 100). Furthermore, tie 800 includes ear clamp 816-2 instead of spring section 716-2, which is in an undamped configuration. In some implementations, band 804 may include not just one ear clamp, but multiple ear clamps arranged in series.

As further shown, clamp 816-2 includes a front wall 870, a top panel 872, and a rear wall 874. Front wall 870 is adjoined perpendicularly to top panel 872 via a front corner 876- 1, and top panel 872 is adjoined perpendicularly to rear wall 874 via rear corner 876-2. Ear clamp 816-2 is adjoined to: front section 816-1 at front wall 870, which forms a 90 degree angle with the front section 816-1; and end section 816-3 at rear wall 874, which forms a 90 degree angle with end section 816-3. As shown, front wall 870, front corner 876-1, top panel 872, rear corner 876-2, and rear wall 874 may form an "n" shape, as a continuous strip (e.g., from stamping out a length of steel band), with front wall 87- and rear wall 874

corresponding to the vertical strokes of the letter "n." In some implementations, the angle between front wall 870 and front section 816-1 (and rear wall 874 and end section 816-3) may be less (or greater) than 90 degrees.

FIG. 8B is a cross-sectional side view of an exemplary ear clamp 816-2 of cable tie 800. FIG. 8B illustrates a number of features not illustrated in FIG. 8A. For example, FIG. 8B shows h2, which specifies the depth of dimple 876-2 (from dimple floor 880 to top panel 878). In addition, FIG. 8B shows front wall 870 as including upper wall 870-1 and lower wall 870-2; and shows rear wall 874 as including upper wall 874-1 and lower wall 874-2. The height of lower walls 870-2 and 874-2 is shown as hi.

FIG. 8C is an expanded view of ear clamp 816-2. As shown, dimple 878 includes side walls 878-1 and 878-2 and dimple floor 880.

When implementing tie 800, dimple 878 may be placed on the top surface of band 804 prior to forming ear clamp 816-2. The side walls of dimple 878 may reinforce top panel 878, and prevent top panel 878 from bending at unwanted places during the manufacture of band 804.

FIG. 8D is an isometric perspective top/side view of cable tie 800 after cable tie 800 is tightened by crushing ear clamp 816-2. During its use, cable tie 800 may be wrapped about a load (e.g., bundle of cables, pipes, beams, wires, pencils, etc.) (not shown) under tie 800. Once wrapped about the load, end section 816-3 may be inserted into locking body (not shown) of cable tie 800 and tightened (e.g., by pulling on end section 816-3).

At this point, ear clamp 816-2 may be crushed to increase the tension on cable tie 800. To crush ear clamp 816-2, forces may be applied on front wall 870 and rear wall 874 in the directions of arrows 880-1 and 880-2, respectively, for example, by using a pair of pliers. Applying the forces bring front wall 870 and rear wall 874 toward one another, pulling band 804 around the load. If there is no slack, then bringing front wall 870 and rear wall 874 toward one another would stretch band 804. In such a case, the restorative force of band 800 would provide additional tension on band 804 around the load.

FIG. 8E is a cross-sectional side view of ear clamp 816-2 after ear clamp 816-2 has been crushed. Comparing FIG. 8E to FIG. 8B shows how front wall 870 and real wall 874 bend when ear clamp 816-2 is crushed. In FIG. 8B, upper wall 870-1 of front wall 870 and upper wall 874- 1 of rear wall 874 are vertical (perpendicular) relative to a surface of top panel 872. As ear clamp 816-2 is crushed, upper wall 870-1 bends about front corner 876-1 such that upper wall 870-1 's flat surface becomes positioned underneath and parallel to top panel 872. Upper wall 874-1 is similarly configured after ear clamp 876-2 is crushed. In FIG. 8E, because upper walls 870-1 and 874-1 are parallel to top panel 872, upper walls 870-1 and 874-1 do not contribute significantly to the overall height of ear clamp 816-2 (i.e., the distance between top panel 878 and the plane on which the top surface of front and end sections 816-1 and 816-2 lie). In FIG. 8E, after ear clamp 816-2 has been crushed/collapsed, front corner 876-1, top panel 872, rear corner 876-2, upper walls 870-1 and 874-1 of (front wall 870, and rear wall 874, respectively) form a "head" of ear clamp 816-2. Lower walls 870-2 and 874-2 (of front and rear walls 870 and 874, respectively) form the "neck" of ear clamp 816-2.

FIG. 9A is an isometric perspective top/side view of an ear clamp 916-2 according to another exemplary implementation. In FIG. 8E, as described above, after ear clamp 816-2 has been crushed/collapsed, ear clamp 816-2 includes a head (formed by front corner 876-1, top panel 872, rear corner 876-2, upper walls 870-1 and 874-1 of (front wall 870, and rear wall 874, respectively) and a neck (formed by lower walls 870-2 and 874-2 (of front and rear walls 870 and 874, respectively)). In contrast, in FIG. 8E, after ear clamp 916-2 has been crushed/collapsed, ear clamp 916-2 includes a very short or no neck.

FIG. 9B and 9C are cross-sectional side views of an ear clamp according to other implementations. In FIG. 8B, prior to being crushed, the cross-sectional side view of ear clamp 816-2 is in the shape of the letter "n" (or arguably the upside down letter "U"). In contrast, in FIG. 9B, prior to being crushed, the cross-sectional side-view of ear clamp 926-2 is in the shape of the letter "M." In FIG. 9C, prior to being crushed, the cross-sectional side- view of ear clamp 936-2 is in the shape of a the Greek letter lambda "Λ." When ear clamp 926-2 or 936-2 are collapsed, the front section (e.g., 816-1) and the end section (816-3) of the cablie tie are brought closer together, tightening the cable tie about its load. Depending on the implementation, the ear clamp for cable tie 100 or 8000, may take other shapes, as long as crushing the ear clamp brings front and end sections closer together and tightens the cable tie.

The foregoing description of implementations provides illustration, but is not intended to be exhaustive or to limit the implementations to the precise form disclosed. Modifications and variations are possible in light of the above teachings or may be acquired from practice of the teachings. For example, in some implementations, housing 108 may be shaped differently than that illustrated in FIGS. 1-6C. Furthermore, in some implementations, more than a single sphere 306, cylinder 502, or block 504 may be placed within housing 108 to prevent ball bearing 304 from "sloshing" and allowing slippage of band 104 in the closed

configuration. In some implementations, in place of sphere 306 or cylinder 502, or block 504, a spring or spring-like component may be placed in housing 108 to prevent slippage. Furthermore, depending on the implementation, a different type of band 104 may be used in place of band 104 (e.g., thicker band, narrower band, etc.). In still other implementations, top surface 118-1 of band 104, the interior surfaces of housing 108, and/or ball bearing 304 may include ridges to increase the friction between top surface 118-1 of band 104, the interior surfaces of housing 108, and/or ball bearing 304.

Although different implementations have been described above, it is expressly understood that it will be apparent to persons skilled in the relevant art that the

implementations may be modified without departing from the spirit of the invention. Various changes of form, design, or arrangement may be made to the invention without departing from the spirit and scope of the invention. Therefore, the above mentioned description is to be considered exemplary, rather than limiting, and the true scope of the invention is that defined in the following claims.

It should be emphasized that the term "comprises/comprising" when used in this specification is taken to specify the presence of stated features, integers, steps or components but does not preclude the presence or addition of one or more other features, integers, steps, components, or groups thereof.

No element, act, or instruction used in the present application should be construed as critical or essential to the implementations described herein unless explicitly described as such. Also, as used herein, the article "a" is intended to include one or more items. Further, the phrase "based on" is intended to mean "based, at least in part, on" unless explicitly stated otherwise.