The present invention pertains to a novel construction for attaching a wear part to an excavator or the like.
The invention in this application is at times described in relative terms, such as “up” and “down,” for ease of explanation. These terms generally are to be understood in relation to the orientation of the wear assembly as illustrated in
Wear parts, such as teeth and shrouds, have long been secured along the digging edges of various excavators (e.g., the front lip of a bucket for a front end loader) to break up the earthen material to be collected and to protect the digging edge from premature wear. To facilitate replacement of the wear parts and reduce the amount of material needing frequent replacement, the wear parts are typically composed of multiple parts. As an example, the wear parts may include an adapter, a wear point or tip, and a lock to removably secure the wear member to the adapter.
An adapter is a base that is fixed to the digging edge of an excavator by welding, mechanical attachment or being cast as an integral portion of the bucket lip. The adapter itself may have multiple parts, particularly in larger sized teeth, but is commonly a single component. In any event, the adapter includes a forwardly projecting nose shaped to securely hold the wear member in place. In an excavating tooth, the wear member is a point or tip that has a generally wedge-shaped configuration with top and bottom walls that converge to a digging edge. The base end of the point includes a rearwardly opening socket to receive the adapter nose. The lock, typically in the form of a pin, is inserted into a passage formed by an opening in the adapter nose that aligns with openings in opposite walls of the point. The passage may extend through a central portion of the nose either vertically or horizontally, or be defined externally of the nose to receive an external lock, for example, as disclosed in U.S. Pat. No. 4,965,945, which is hereby incorporated by reference.
Although the passage receiving the lock may be linear or curved, the sides of the lock and the walls of the passage receiving the lock have in the past been defined by generally parallel surfaces. As a result, the sides of the lock slide against the walls of the passage in face-to-face contact as the lock is being inserted into or removed from the tooth. Moreover, it is important to maintain the lock in the defined passage so that the point is not lost. Loss of the point not only leads to premature wearing of the adapter, but may also damage downstream machinery intended to process the excavated material. Accordingly, the lock is fit tightly within the defined passage to inhibit its ejection or loss. As can be appreciated, this sliding action of the lock generates significant frictional resistance. In the past, a large hammer has been needed to force the lock into and out of the passage. This tends to be an onerous and time-consuming task for the operator in the field.
The present invention solves the difficulties of inserting and removing the lock via a novel construction that enables the lock to be inserted into and removed out of the wear assembly (e.g., a tooth) without the need for repeated hammer blows. More specifically, a tapered lock is received within a complementary opening whereby the lock can be inserted and removed by a prying tool. The use of such a cooperative lock and opening can be used to secure different types of wear members (e.g., points and shrouds) usable in excavating operations.
In one aspect of the invention, the wear assembly has a tapered opening that is adapted to receive a complementary shaped lock. In one construction, the opening is tapered such that the front and rear walls converge as they extend away from the opening's inlet end. In a preferred embodiment, the opening narrows in generally three perpendicular directions. The opening also preferably includes a stop to releaseably retain the lock in the opening and a notch to better help prevent twisting of the lock under load.
In another aspect of the invention, the lock includes a body that generally converges toward one end to define a tapered configuration. Due to the tapered shape of the lock, as opposed to a lock with generally parallel sidewalls, the lock does not slide in face-to-face contact with the sidewalls of the passage and generate high frictional resistance as it is being placed into and out of the passage. Accordingly, the lock can be pried into and out of the passage without the use of a hammer. In a preferred aspect of the invention, the prying tool is a member that rotates to release the latch of the lock and to pull the lock from the opening.
In one preferred embodiment of the invention, the wear member (e.g., a point) has an ear that projects rearwardly from the socket defined to receive the adapter nose. The ear includes a tapered slot or opening to receive and support the tapered lock when fully inserted, but without the frictional sliding against the sides of the slot when only partially fit into the slot. The full face-to-face engagement between the lock and the slot only occurs when the lock has been fully inserted. The lock has a latch that cooperates with a formation in the tooth to hold the lock in place during use of the tooth.
The present invention pertains to a wear assembly for an excavator, and in particular to a coupling construction for securing a wear member to the digging edge of the excavator. In a preferred construction, the inventive coupling comprises an adapter 12, a wear member 14 and a lock to hold the wear member to the adapter. Several variations of the lock are disclosed below for use with essentially the same adapter 12 and wear member 14 (although some minor variations will be noted for some of the embodiments). Many variations in the adapter and wear member are possible. For convenience, the wear member below will be described as a tip or point for an excavating tooth, though the invention pertains to other wear members, such as shrouds, as well.
In a first embodiment, tooth 10 includes an adapter 12, a point or tip 14 and a lock 16 (
While an external locking assembly is preferred for securing a tooth point to an adapter, the opening for receiving the tapered locks of the invention could extend through central portions of the nose and point either vertically or horizontally. In this case, the tapered shape of the opening would be formed primarily in the adapter nose rather than in point. Moreover, the opening could be formed in other constructions such as a mounting portion of a shroud or other wear member fit over a boss or the like fixed to an excavator. In this type of assembly, the opening could have a broader construction (i.e., not adapted to receive a pin-shaped lock) and/or have an open inlet end on various portions of the wear member by which to receive the lock.
In accordance with one construction of the invention, the point 14 has a generally wedge-shaped configuration with top and bottom walls 24, 26 that converge to a digging edge 27 (see, e.g.,
In one preferred construction, slit 42 opens along the top side 44 of ear 38 to define an inlet end 45 to receive the lock. The slot then converges or tapers toward the ear's bottom end 46 (
In the preferred construction, slot or opening 42 is tapered in three directions to receive a comparably shaped lock in order to provide easy insertion and removal for lock 16, and a greater bearing surface with which to resist loads (
Second, the widths of front and rear walls 50, 52 each widen as they extend from the bottom wall 56 to the open top end of the slot, so that the front and rear walls 50, 52 are wider at the top than the bottom of slot 42. In other words, sidewall 54 is inclined to the vertical axis 57 so that the sidewall 54 and vertical axis 57 converge toward bottom wall 56. In this arrangement, the sidewall 54 of the slot is inclined relative to a central plane of the socket 30 that bisects side walls 28, 29 of the point and extends along the longitudinal axis of the socket (i.e., the axis of insertion of the nose in the socket), such that the sidewall 54 of the slot converges toward the central plane of the socket as the sidewall 54 extends away from the inlet end 45 of the slot. While a snug engagement is preferred when the lock is fully fitted into passage 41, sidewall 54 could extend substantially parallel to axis 57 provided the lock is not tightly held between sidewall 54 and the side 43 of adapter 12 such that the lock could not be pried into and out of passage 41.
Finally, slot 42 also preferably widens from the front wall 50 to the rear wall 52 such that bottom wall 56 expands in the rearward direction and the portions of the rear wall 52 are wider than the corresponding portions of the front wall 50. The widening of slot 42 from front to back creates a rear wall 52 that is wider than the front wall 50 to provide a larger surface area with which to resist the greater forces that are ordinarily applied to this surface in holding the point to the adapter. Front wall 50 is preferably narrower than rear wall 52 to provide greater strength to the coupling of ear 38 to body 58 of point 14. While the widening of the slot from front wall 50 to the rear wall 52 is preferred, it could be eliminated if desired.
A notch 60 is preferably provided in the upper rear corner of slot 42 to increase the bearing surface of rear wall 52 without unduly weakening the strength of ear 38 and to prevent rotation of the lock, particularly under heavy loading. Since the ear is laterally offset from ledge 22, a forwardly directed force on point 14 can generate a torque on the lock, which is resisted by the generally rectangular cross section of the lock and a protrusion received in notch 60, as described more fully below. As with slot 42, notch 60 is also preferably tapered in three directions such that (1) the front and rear faces 62, 64 diverge as they extend toward the open top end 44 of slot 42, (2) the front and rear faces 62, 64 widen as they extend toward the open end of the slot, and (3) the rear face 64 is wider than opposing portions of front face 62. Nevertheless, other arrangements for the notch are possible. Rear wall 52 is also preferably provided with an additional inward extension 66 at its top end to further increase the surface area of the rear wall and provide a portion more directly opposed to ledge 22 without hindering the mounting of the point on the adapter. While the use of notch 60 is preferred, it could be eliminated for some uses or replaced by other means for preventing rotation of the lock.
In a first embodiment, lock 16 includes a body 70, a latch 72 and a resilient member 74 (FIGS. 1 and 5-7). Body 70 has front and rear surfaces 76, 78 that are preferably shaped to correspond with and abut against front and rear walls 50, 52 of slot 42 when the lock is fully inserted into the slot, i.e., the front surface 76 of lock 16 abuts front wall 50 and rear surface 78 abuts rear wall 52. While front and rear surfaces 76, 78 and front and rear walls 50, 52 could be only partially engaged, they are preferably in substantially full bearing engagement with each other along the length of slot 42. In this way, the lock is stably supported in the ear of the point when under duress, and when looseness and wear develops in the tooth assembly.
In the preferred construction, lock 16 is shaped to be matingly received in slot 42. Accordingly, lock 16 is preferably tapered in three directions. First, front and rear surfaces 76, 78 converge as they extend toward the bottom surface 80 of the lock. Second, side surfaces 82, 84 of body 70 also converge as they extend toward bottom surface 80. Third, side surfaces 82, 84 converge as they extend toward front surface 76. With this tapered construction, the lock can be easily placed into and out of the tooth without hammering. In particular, unlike conventional lock pins with parallel sides where substantial friction is encountered between the pin and the sides of the passage, the surfaces 76, 78, 80, 82 of lock 16 are not pressed into face-to-face frictional sliding contact with opposing walls 50, 52 and 43, 54 until the lock is fully set in slot 42. The taper of front and rear surfaces 76, 78 is important because it provides a good fit between the lock and the slot in the longitudinal direction (i.e., in the direction of greatest loading) when the lock is fully fitted, but avoids the face to face sliding frictional contact during insertion. While the tapering of the lock in the other two orthogonal directions is preferred, the side surfaces 82, 84 can be substantially parallel in a vertical direction (i.e., without tapering toward button surface 80), if the lock is not too tightly received between sidewall 54 and side 43 so as to prevent the lock from being pried into and out of the opening. Moreover, side surfaces 82, 84 can also be substantially parallel in the longitudinal direction (i.e., without side surfaces 82, 84 tapering toward front surface 76) provided sufficient surface area contact exists between rear wall 52 and rear surface 78 for the expected loads.
A protrusion 86 is provided on the top end of side surface 82 to fit within notch 60. Preferably, protrusion 86 matingly fits within notch 60 when lock 16 is fully fitted within slot 42. Body 70 is laterally wider than slot 42 so that the lock extends inward from ear 38 to engage ledge 22 of adapter 12. As noted above, the offset construction of ear 38 and ledge 22 places a torque on the lock that is resisted by the generally rectangular cross-section of body 70 and the receipt of protrusion 86 in notch 60.
In the preferred construction, body 70 further includes a front support 87 that extends forward, above slot 42, to abut rear wall 32 of point 14. This additional engagement between the lock and the point helps to stabilize the mounting of the lock in slot 42. Then, if looseness develops in the tooth on account of wear or because of other reasons, the lock is stably held to the point the reduce the likelihood of losing the lock.
Latch 72 and resilient member 74 are each received within a recess 90 defined in an upper portion of body 70. The latch 72 includes a pivot pin 92 at its lower end that is received within a hole 93 to define a pivot axis 97. Accordingly, the latch moves about axis 97 between a latched condition where the lock is held within slot 42 and an unlatched condition where the lock can be removed from the slot. A shoulder 94 is preferably formed along a mid portion of the latch 72 to engage stop 48 in the latched condition. An opening 95 is defined above shoulder 94 to accommodate receipt of stop 48.
The upper portion 101 of latch 72 preferably extends laterally over the top of body 70. The front face 103 defines a pry surface whereby latch 72 can be moved to the unlatched condition. A guide rail 105, formed along the top of body 70, is received in a complementary groove 107 in the lower face 109 of upper portion 101. This rail and groove 105, 107 construction stabilizes the movement of the latch on the body, prevents the latch from moving laterally out of recess 90, and maintains pivot pin 92 in hole 93. The rear end of the groove 107 includes a rear wall (not shown) that contacts abutment 111 at the rear end of guide rail 105 to limit the outward pivoting of the latch and thereby define the latched condition. Preferably, the upper portion 101 is spaced slightly rearward of front support 87 in the locked condition so that contact with the rear wall 32 does not push on the latch.
Resilient member 74 is sandwiched between latch 72 and support surface 96 of recess 90 to normally bias the latch into the latched condition. Resilient member 74 is preferably an elastomer, such as neoprene or rubber, but could be composed of other resilient materials or involve other springs (not shown). The resilient member is preferably held in place by the compression forces applied by the latch 72 and support surface 96, i.e., abutment 111 is preferably set to stop latch 72 so that resilient member 74 is always under a compressive load. Nonetheless, resilient member 74 could be secured to latch 72 and/or support surface 96 by an adhesive or by molding the elastomer to one of these components. The latch 72 further preferably includes a finger 106 that overlies at least a portion of resilient member 74 to protect it and prevent its release upward, particularly when the resilient member is retained only by compressive forces. To remove lock 16 from slot 42, the latch is moved toward support surface 96, against the bias of resilient member 74, to the unlatched condition, i.e., where shoulder 94 releases stop 48.
In use, point 14 is fit onto adapter 12 such that nose 20 is received into socket 30 (
Lock 16 is wider than slot 42 such that the lock extends laterally out of the slot to engage ledge 22 of adapter 12. In most assemblies, the insertion of the lock causes the front surface 76 of lock 16 to press against ledge 22 of adapter 12 and the rear surface 78 to press against rear wall 52 of slot 42 to pull point 14 farther onto adapter 12. Once in a fully inserted position, the front surface 76 opposes ledge 22 and rear surface 78 opposes rear wall 52 to hold the point to the adapter. Since the lock is received in slot 42 and retained by the engagement of stop 48 and latch 72, the lock will stay in slot 42 and still hold the point to the adapter even if wearing of the components creates a looseness or gaps between the front surface 76 and ledge 22.
Lock 16 is preferably also pried out of slot 42 by prying tool T when it is desired to remove the point from the adapter. The free end of the prying tool is inserted between the prying face 103 of latch 72 and rear wall 32. The top end of the pry tool is then pushed forward and downward (generally in the direction of arrow 104), with the rear of point 14 forming the fulcrum, so that the free end F is rotated rearward and upward. This movement of the pry tool first pushes latch 72 rearward to its unlatched condition, and then pushes the lock upward at least partially and out of the slot. The interconnection of the pivot pin 92 in hole 93 enables the lock to be pried out of the slot through engagement with the latch. Although prying is the preferred method of removing lock 16, the lock could be removed by hammering if slot 42 included a portion that extended entirely through ear 38, provided the latch is first released by a tool.
While the latch assemblies for lock 16 and the other below described locks are preferably used in tapered locks, the latch constructions described for the various locks herein could be used in locks that have non-tapering bodies and/or that are intended to be inserted into and removed from a tooth assembly by hammering.
Moreover, the latches could also be used to secure a lock within an excavating wear assembly wherein the lock body has a shape other than an elongated pin configuration (e.g., a block shape). As an example only, the latch constructions described herein could be incorporated into a block-shaped lock such as described in U.S. Pat. No. 5,653,048, hereby incorporated by reference, in lieu of the latch arrangement disclosed therein to retain the lock in the opening. Using lock 16 as an example, a recess and hole, like the recess 96 and hole 93 in lock 16, could be formed in the block-shaped lock body to receive a similar latch and resilient member. The latch would then move in essentially the same way between a latched condition in engagement with a keeper and an unlatched condition to permit removal of the lock. The other latch constructions disclosed herein could also be similarly configured with a block-like body as opposed to a pin-shaped body.
In another embodiment of the invention, lock 125 is inserted into passage 41 to hold the point to the adapter (
Body 127 has a front surface 133, a rear surface 135 and side surfaces 137, 139. As with lock 16, lock 125 preferably tapers in three directions: (1) front and rear surfaces 133, 135 converge as they extend toward bottom surface 141; (2) side surfaces 137, 139 converge as they extend toward bottom surface 141; and (3) side surfaces 137, 139 converge as they extend toward front surface 133. Nevertheless, the alternative structural variations discussed in regard to the body of lock 16 are also applicable to the body 127 of lock 125.
A recess 141 is formed in an upper portion of body 127 to receive latch 129 and resilient member 131. A generally L-shaped hood 143 is formed to extend with one leg 145 over recess 141 and the other leg 147 along the rear side of the recess. The lower end of leg 147 is preferably shaped to be received in notch 44 to provide a greater surface area to abut rear wall 52 of slot 42 and to resist rotation of the lock under loading. Leg 145 protects resilient member 131 from wearing and provides support to lift lock 125 from passage 41. Further, front support 148 projects beyond leg 145 to contact the rear wall 32 of point 14 to help stabilize the mounting of the lock in the point.
Resilient member 131 is preferably an elastomer composed of neoprene, rubber or the like. The resilient member is preferably molded into the recess, although it could be secured with adhesive or the lock configured to mechanically retain the elastomer in place. Latch 129 is preferably adhered to the front surface 149 of resilient member 131. Latch 129 includes a recess 151 and a shoulder 153 for receiving and engaging stop 48 of point 14 to hold lock 125 in slot 42. A prying protrusion 155 with a prying surface 157 is formed on the top end of latch 129.
In use, lock 125 is inserted into; slot 42 when the point has been placed onto adapter nose 20 (
To remove lock 125 from slot 42, the prying tool is again inserted between rear wall 32 of point 14 and lock 125. The prying tool is rotated forward and downward so that the free end of the prying tool engages prying surface 157 of latch 129 to retract shoulder 153 from stop 48 and to pull lock 125 at least partially out of passage 41. The tool presses on prying surface 157a or 157b. Although there is no pivot pin for the latch in this embodiment, latch 125 essentially moves in a similar pivoting movement about its bottom end as it is pushed rearward at its top end by the prying tool. The top surface 159 of latch 129 abuts leg 145 of body 127 to provide support for removal of lock 125 from slot 42.
Lock 125a (
Like lock 16, latch 129a includes a lower pivot pin 92a that fits within hole 93a defined in body 127a. The latch 129a includes a shoulder 94a that is biased forward by resilient member 131a into a latched condition with stop 48 when the lock is in the fully inserted position. As with resilient member 131, resilient member 131a is formed with holes 132a to accommodate compression of the assembly When the latch 129a is pressed rearward. The holes 132a are preferably filled with compressible foam to prevent fines from compacting into them during use. Body 129a is shown with an expansion port 134a in its rear face 135a (
In this embodiment, top leg 145a defines a groove 146a extending along sidewall 148a of recess 141a. As seen in
In another alternative similar to locks 16 and 125, lock 125b includes a body 127b that preferably tapers in three directions. Body 127b defines a recess 141b that is adapted to receive a resilient member 131b and latch 129b. In this embodiment, the latch 129b is composed of a sheet metal material that is shaped to conform to the outer edge of resilient member 131b. Although the strength of the latch 129b is generally less than these in the other embodiments, this latch is easy and economical to make and does not require the latch and resilient member to be adhered together by adhesive or being molded together. The bottom pivot 132b is formed by shaping the bottom portion of the latch and resilient member into a rounded configuration that fits into a rounded cavity 134b in body 127b. The front of pivot 132b includes a flat 136b that abuts against a stop surface 138b on body 127b to limit the forward pivoting of the latch.
Body 127b includes a hood 153b with a top leg 145b and a lower leg 147b. Top leg 145b overlies and protects the resilient member, and overlies the latch 129b when the latch is retracted to its release position to provide support for removing the lock from the excavating tooth. The lower leg 147b wraps around the top of the resilient member to provide extra support to better maintain the shape of the resilient member and latch. The bottom of the lower leg 147b is intended for receipt in the notch of the point, but is illustrated with a different configuration to show another alternative. As with lock 125a, front support 148b projects forward of latch 129b and top leg 145b.
Lock 125c is similar to lock 125b in construction of the body 127c and resilient member 131c. The latch 129c is similar to latch 129b but instead of being fabricated of sheet metal is a part that is formed by casting, forging or the like.
In lock 125c, a catch 132c is formed at the top of the hood 143c to temporarily hold the latch in a release or unlocked condition. In particular, a pry tool is inserted between the rear face 32 of point 14 and lock 125c and rotated forward so as to push latch 129c rearward. This prying motion pushed the latch rearward and upward so that the top of the latch hooks onto the catch 132c. Then the pry tool can be used to pry the lock at least partially out of slot 42.
In another embodiment of the invention, lock 166 is inserted into passage 41 to hold the point to the adapter (
Body 168 includes a front surface 174, a rear surface 176 and side surfaces 178, 180. As with the above-described locks, lock 166 preferably tapers in three directions. Front and rear surfaces 174, 176 of body 168 converge as they extend toward bottom surface 182. Likewise, side surfaces 178, 180 of body 168 also converge as they extend toward bottom surface 186. Finally, side surfaces 178, 180 converge as they extend toward front surface 174 to provide a rear surface 176 that is wider than front surface 174. In this way, side surface 178 generally parallels sidewall 54 of slot 42. As with the above lock 16, the front, Tear and side surfaces 174, 176, 178, 180 could be varied in their shapes and orientations. A protrusion 184 extends laterally from side surface 178 to fit in notch 60, and a front support 185 projects forwardly to abut rear face 32.
A recess defined as a channel 186 is formed in an upper portion of lock 166. Channel 186 is defined by top and bottom surfaces 187, 188 and is preferably curved with a concave-up configuration; nevertheless, the channel could have a linear configuration if desired. The channel extends through the lock body 168 and opens in both the front and rear surfaces 174, 176. The channel is oriented to swing upward in a rearward direction such that the channel opening in rear surface 176 is closer to top surface 189 of body 168 than the channel opening in front surface 174. In the preferred embodiment, the upper surface 190 of protrusion 184 is an extension of the bottom wall 192 of the channel.
Latch 170 has an arcuate configuration to slide in channel 186. More specifically, latch 170 includes a front portion 194 and a rear portion 198. The front portion has a free end 196, which is adapted to engage stop 48 of point 14 in a forwardly protruding latched condition. Rear portion 198 is preferably wider than front portion 194 to take advantage of the wider bottom surface 188 of channel 186 provided by protrusion 184. The top surface 187 of channel 186 has generally the same width as rear portion 198. A flange-like base element 201 is provided at the intersection of front and rear portions 194, 198 to define a support for resilient member 172.
Resilient member 172, as with the above locks, is preferably an elastomer composed of neoprene, rubber or the like. In the preferred construction, resilient member 172 is a short curved segment set between the upper face 203 of rear portion 198 of latch 170 and top surface 187 of channel 186, and between the pushing surface 205 of base element 201 and the bottom surface 209 of cover element 211 of body 168. In this way, resilient member 172 pushes against pushing surface 205 to bias latch 172 forward to the latched condition so that the free end 196 normally protrudes beyond front surface 174 to engage stop 48 and hold lock 166 in slot 42. A stop element 213 is preferably formed at the free end of top surface 187 to abut the front end 215 of base element 201 to limit the forward motion of latch 170. The latch and resilient member are preferably held to body 168 by always maintaining the resilient member under a compressive force. Nevertheless, resilient member 172 may be provided with an adhesive to secure the ends 217, 219 to base element 201 and cover element 211, or secured by mechanical means.
Lock 166 is inserted into slot 42 in the same manner as lock 16 (
In another embodiment, lock 235 is inserted into slot 42 to hold point 14 to adapter 12 (
Body 237 includes front and rear surfaces 243, 245, side surfaces 247, 249, and a bottom surface 251. As with the above locks, the lock body preferably tapers in three different directions—namely, the front and rear surfaces 243, 245 converge as they extend toward bottom surface 251, and the side surfaces 247, 249 converge as they extend toward the bottom surface 251 and as they extend toward front surface 243. Also, as noted above, front, rear and side surfaces 243, 245, 247, 249 can be varied in the ways as discussed above for the corresponding surfaces of lock 16. Side surface 247 includes a protrusion 250 to fit in notch 44. Front support 252 projects forward to abut rear face 32.
An upper portion of body 237 includes a recess 253. The bottom of the recess is defined as a concave, curved guide wall 255. Guide wall 255 is a circular segment that generally slopes downward toward front surface 243. Latch 239 is movably secured to body 237 by a pivot pin (not shown) that fits within hole 259. The bottom surface 261 is curved to correspond to guide wall 255 such that they slide along each other as the latch swings about pin. Shoulder 263 normally projects forwardly to engage stop 48 of point 14. Resilient member 241 is preferably an elastomer, such as neoprene or rubber, and shaped as a short curved segment that fits between a stop member 265 on body 237 and a rear pushing wall 267 of latch 239. The pushing wall 267 is defined in an indent 269 formed to receive the resilient member in recess 253. The latch preferably continually holds the resilient member under a compressive load, which holds the components together. An adhesive can be applied to hold resilient member 241 to one or both of stop member 265 and pushing wall 267, the resilient member may be molded to one of the components, or the components may be held together by mechanical means.
A finger 271 extends rearwardly from the top of the latch and over stop member 265. In this way, finger 271 abuts stop member 265 to limit the forward movement of shoulder 263. In addition, a pry tool can be inserted between the mounting end 18 of adapter 12 and lock 235 such that the free end of the pry tool engages the end of pry finger 271 (
Lock 280 is also similar to lock 235 in construction (
More specifically, latch 296 has a compact configuration with four rounded sides. Pivot pin 298 projects from an inner surface 306 in the upper, front corner of the latch. The bottom side 308 is curved to correspond to guide wall 310 of body 282, much like guide wall 255 of lock 235. A slot 312 extends from the front side 314 to a central portion of the latch to receive fastener 304. In this way, the fastener may simply be loosened, and not removed, to permit the latch to be manually moved between the latched and unlatched conditions. Since the top portion of the latch is exposed even when the point is on the adapter, the latch can be moved manually once the fastener is loosened. A notch 316 is provided on the rear side 318 of the latch for moving the latch between the latched and unlatched conditions, and for prying the lock from slot 42.
The central portion of latch 296 is recessed to define a clamping surface 320 against which the head 322 of fastener 304 bears when the screw is tightened into threaded bore 324. A shoulder 326 projects from the front side 314 below the open end of slot 312 to engage stop 48 when in the latched condition. Body 282 includes fore and aft stops 328, 330 for limiting the swinging of the latch. In the preferred construction, fore stop 328 is in the form of a flange that is aligned with the open end of slot 312. Bearing surface 332 abuts the lower end of the stop 328 when the latch reaches the latched condition. The fore stop further acts as a shield to inhibit fines from entering the slot and blocking the movement of the latch. The aft stop 330 is preferably formed as a bump in the upper rear corner of the boss. The rear side 318 abuts the aft stop when the latch swings to the unlatched condition where shoulder 326 disengages stop 48 of point 14. The threaded stem of fastener 304 is also preferably secured in threaded bore 324 with a lock tight coating, such as 262, from Loctite Corporation of Rocky Hill, Conn., to prevent premature loosening of the screw during use of the tooth. The fastener is preferably composed of metal, but could also be polymeric.
To insert lock 280, latch 296 is fixed by fastener 304 in the unlatched condition. Lock 280 is pried into slot 42 in the same manner as described above for lock 16. Once the lock is inserted fully in slot 42, the latch is moved to its latched condition and secured by fastener 304. The lock is removed by first loosening fastener 304. As seen in
As a further alternative, lock 280′ can be provided with a resilient take-up member 334′ in the lower portion of body 282′ (
Lock 340 is another embodiment that is, in general, similar to lock 280. In particular, lock 340 includes a body-342, a latch 344, a resilient member 346 and a secondary latch 348. The body 342 defines a recess 350 for receiving latch 344 that swings about pivot axis 352. The axis is preferably defined by a fastener 354 that is received through hole 356 and is engaged with a threaded bore (not shown) in the latch. Like the latch in lock 280, latch 344 is free swinging and not biased into the latched condition by the resilient member. Rather, resilient member 346 biases the secondary latch 348 into a latched condition to secured the latch in the locked position.
More specifically, the secondary latch 348 and resilient member 346 are made as a unitary member by being molded together or alternatively being secured by adhesive or other means. The resilient member 346 is configured to fit and be confined with a hollow portion (not shown) in latch 344. The secondary latch is normally biased rearward into an opening 358 defined in a rear portion of latch 344. The secondary latch includes a shoulder 360 that is adapted to engage a projection 362 formed on body 342. In this position, the secondary latch 348 overlies the lower edge 364 of opening 358 such that the lower edge abuts the secondary latch if the latch begins to turn from the latched toward the unlatched condition. The shoulder 360, then, abuts projection 362 and prevents movement of the latch to the unlocked condition.
To remove the lock, a pry tool is inserted into the opening 358 to push the secondary latch 348 forward and inside of latch 344 so that it releases projection 362. With the secondary latch pushed inward, the pry tool is used to turn the latch counter-clockwise such that the secondary latch abuts the front face 366 of projection 362. The operator continues to turn the latch until the finger 368 releases stop 48 of point 14. The latch preferably includes a protrusion 370 on the front end to aid in turning the latch if needed. Expansion ports 372, 373 are also preferably provided to accommodate the expansion of resilient member 346 as the secondary latch is pushed forward.
A rotatable pry tool 400 can be used to release the latch and pull the lock upward from the slot. As seen in
The rear end of the body includes a formation to attach to a driver for rotating the tool. The formation is preferably a socket 411 with flats (e.g., a square socket) that is adapted to engage a driving tool (powered or manual) for facilitating rotation of the tool. In this embodiment, the pry tool 400 is adapted to fit on the end of a shank of a torque wrench or the like. As an alternative, the pry tool 400 for removing the lock can be formed as part of a single assembly with a pry tool T for inserting the lock. For instance, a shank having a dogleg bend could be used to connect the two pry tools for manual operation.
In use, pry tool 400 is preferably used in conjunction with a tapered lock having a body and a latch. As an example, the tool is shown in
Tool 400 is then rotated (clockwise as shown in
As noted earlier, the aspects of the present invention are usable with wear members other than tooth points. For instance, the wear member may be a shroud similar to that disclosed in U.S. Pat. No. 5,088,214 (hereby incorporated by reference) or an adapter similar to that disclosed in U.S. Pat. No. 5,653,048 (hereby incorporated by reference). In either case, the lock and opening could be formed with the aspects as taught above for the point. The lock could be inserted into the opening from the top of the wear member (such as disclosed in the noted '214 and '048 patents) or laterally from a side of the wear member. Further, in this type of assembly, the support structure secured to the excavating equipment would be a boss as opposed to an adapter, and the support cavity receiving the support structure would be a slot in the wear member instead of a socket. Other such assembled support structures and wear members can also be formed to utilize the advantageous aspects of the present invention.
This application is a divisional application of U.S. patent application Ser. No. 10/187,446, filed Jul. 2, 2002 now U.S. Pat. No. 6,993,861, which is a continuation-in-part of U.S. provisional application Ser. No. 60/369,846, filed Apr. 5, 2002, and U.S. patent application Ser. No. 09/899,535, filed Jul. 6, 2001, now U.S. Pat. No. 6,735,890.
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Number | Date | Country | |
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20060117613 A1 | Jun 2006 | US |
Number | Date | Country | |
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60369846 | Apr 2002 | US |
Number | Date | Country | |
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Parent | 10187446 | Jul 2002 | US |
Child | 11324944 | US |
Number | Date | Country | |
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Parent | 09899535 | Jul 2001 | US |
Child | 10187446 | US |