U.S. patent number 10,385,548 [Application Number 13/497,989] was granted by the patent office on 2019-08-20 for lock assembly for an excavator wear member.
This patent grant is currently assigned to CQMS PTY LTD. The grantee listed for this patent is Miguel Guimaraes, Bruce Lilley, Quintin Nienaber, Tony Young. Invention is credited to Miguel Guimaraes, Bruce Lilley, Quintin Nienaber, Tony Young.
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United States Patent |
10,385,548 |
Guimaraes , et al. |
August 20, 2019 |
Lock assembly for an excavator wear member
Abstract
A lock assembly for an excavator wear assembly, the lock
assembly a locking pin having at least one dowel extending
outwardly therefrom. The lock assembly also includes a retaining
member having a seat and a cavity and a biasing member located
within the cavity of the retaining member. The biasing member is
adapted to exert a biasing force on the dowel to releasably retain
the dowel within the seat of the retaining member.
Inventors: |
Guimaraes; Miguel (Mackay,
AU), Lilley; Bruce (Mackay, AU), Nienaber;
Quintin (Mackay, AU), Young; Tony (Mackay,
AU) |
Applicant: |
Name |
City |
State |
Country |
Type |
Guimaraes; Miguel
Lilley; Bruce
Nienaber; Quintin
Young; Tony |
Mackay
Mackay
Mackay
Mackay |
N/A
N/A
N/A
N/A |
AU
AU
AU
AU |
|
|
Assignee: |
CQMS PTY LTD
(AU)
|
Family
ID: |
44145019 |
Appl.
No.: |
13/497,989 |
Filed: |
November 19, 2010 |
PCT
Filed: |
November 19, 2010 |
PCT No.: |
PCT/AU2010/001556 |
371(c)(1),(2),(4) Date: |
June 28, 2012 |
PCT
Pub. No.: |
WO2011/069183 |
PCT
Pub. Date: |
June 16, 2011 |
Prior Publication Data
|
|
|
|
Document
Identifier |
Publication Date |
|
US 20120260539 A1 |
Oct 18, 2012 |
|
Foreign Application Priority Data
|
|
|
|
|
Dec 11, 2009 [AU] |
|
|
2009906064 |
|
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
E02F
9/2825 (20130101); E02F 9/2833 (20130101); E02F
9/2816 (20130101); E02F 3/32 (20130101) |
Current International
Class: |
E02F
9/28 (20060101); E02F 3/32 (20060101) |
References Cited
[Referenced By]
U.S. Patent Documents
Foreign Patent Documents
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|
|
|
|
|
|
2003264586 |
|
Jul 2004 |
|
AU |
|
2005203574 |
|
Mar 2007 |
|
AU |
|
2009238226 |
|
Oct 2009 |
|
AU |
|
2161505 |
|
Apr 1997 |
|
CA |
|
WO 2004/027272 |
|
Apr 2004 |
|
WO |
|
WO 2008/116942 |
|
Oct 2008 |
|
WO |
|
WO 2009/127016 |
|
Oct 2009 |
|
WO |
|
Other References
US. Appl. No. 13/497,892, filed Jun. 28, 2012. cited by
applicant.
|
Primary Examiner: Will; Thomas B
Assistant Examiner: Misa; Joan D
Attorney, Agent or Firm: Leydig, Voit & Mayer Ltd.
Augustyn; John
Claims
The invention claimed is:
1. A lock assembly for releasably securing an excavator wear member
to a separate spigot portion of an adapter, the lock assembly
comprising: a locking pin having at least one dowel extending
outwardly therefrom; a retaining member which is a separate part
from the wear member and the adapter and which has a body with a
seat and a cavity, the body being configured to be received into a
locking aperture of the excavator wear member, and the retaining
member also has a ramp extending from within the cavity of the
retaining member and terminating outwardly of an exterior surface
of the retaining member; and a biasing member located within the
cavity of the retaining member; wherein the biasing member is
adapted to exert a biasing force on the dowel to releasably retain
the dowel within the seat of the retaining member.
2. The lock assembly of claim 1, wherein a detent extends outwardly
from a body of the retaining member.
3. The lock assembly of claim 1, wherein at least one slot is
located through an exterior surface of the retaining member.
4. The lock assembly of claim 3, wherein the at least one slot is
adapted to receive the dowel of the locking pin.
5. The lock assembly of claim 1, wherein the biasing member is
releasably secured within the cavity of the retaining member.
6. The lock assembly of claim 1, wherein the seat is formed on an
underside of an exterior surface of the retaining member.
7. The lock assembly of claim 1, wherein the seat is axially offset
from a slot formed in an exterior surface of the retaining
member.
8. The lock assembly of claim 1, wherein a passage is formed
between an upper face of the biasing member and an underside of an
exterior surface of the retaining member.
9. The lock assembly of claim 8, wherein the seat forms part of the
passage.
10. The lock assembly of claim 8, wherein a land forms part of the
passage such that the distance between the land and the upper face
of the biasing member is smaller than a cross sectional dimension
of the dowel.
11. The lock assembly of claim 8, wherein an angled guide surface
forms part of the passage, the angled guide surface extending from
a slot formed in an exterior surface of the retaining member
towards the seat.
12. The lock assembly of claim 8, wherein the passage is adapted to
receive the dowel when the locking pin is axially rotated such that
the dowel is forced against a surface of the biasing member within
the passage prior to location of the dowel within the seat.
13. An excavator wear assembly comprising: an excavator wear member
having: a socket cavity that is configured to receive a spigot
portion of an adapter; and a locking aperture extending through a
side wall of the excavator wear member, the locking aperture having
a receiving passage and a retaining recess that are separate from
the spigot portion of the adapter; a lock assembly having: a
locking pin having at least one dowel extending outwardly
therefrom; a retaining member which is a separate part from the
excavator wear member and adapter but which is located within the
retaining recess of the locking aperture, the retaining member
having a body with a seat and a cavity and the retaining member
also having a ramp extending from within the cavity of the
retaining member and terminating outwardly of an exterior surface
of the retaining member; a biasing member located within the cavity
of the retaining member; and an adaptor having: a spigot portion
located within the socket cavity of the excavator wear member, and
a retaining passage; wherein the locking pin is located through the
locking aperture of the excavator wear member and the retaining
passage of the adaptor and wherein the biasing member is adapted to
exert a biasing force on the dowel of the locking pin to retain the
dowel within the seat of the retaining member to thereby releasably
retain the spigot portion of the adaptor within the socket cavity
of the excavator wear member.
Description
FIELD OF THE INVENTION
The invention relates to a lock assembly for an excavator wear
member. In particular, although not exclusively, the invention
relates to a lock assembly for releasably securing an excavator
tooth to a nose of an excavator.
BACKGROUND TO THE INVENTION
Excavator tooth assemblies mounted to the digging edge of excavator
buckets and the like generally comprise a replaceable digging
tooth, an adaptor body and an adaptor nose which is secured by
welding or the like to the digging edge of a bucket or the like.
The tooth generally has a socket-like recess at its rear end to
receivably locate a front spigot portion of the adaptor nose and a
removable locking pin is generally employed to releasably secure
the tooth on the adaptor.
In use, excavator teeth are subjected to extensive load forces
along a longitudinal axis of a tooth as well as in vertical and
transverse directions. A snug fit is required between the digging
point and the front portion of the adaptor and also between the
adaptor socket and the nose spigot portion and their respective
mounting pins to avoid premature wear between the components. As
the various components wear, the locking pins can loosen thereby
increasing the risk of loss of a digging point or an entire
adaptor/tooth combination. This necessitates considerable downtime
to replace the lost wear members and where items such as locking
pins are not recovered, these can cause damage and/or further
downtime in downstream operations such as ore crushing and the
like.
The greatest loads experienced by excavator tooth assemblies are
vertical loads which tend to generate large moment forces capable
of rotating a tooth off the front of an adaptor and/or rotating the
adaptor off the adaptor nose. In addition, twisting or "yaw" loads
are frequently imposed on such tooth assemblies.
Despite many prior art attempts to improve the mounting of a wear
member to a nose of an excavator, most of these proposals suffer
from one or more deficiencies. As described hereinafter, many of
the prior art references relate to direct mounting of a tooth onto
a nose without an intermediate adaptor but in those assemblies, the
mounting systems for securing teeth directly onto excavator noses
is considered analogous to the mounting of a tooth onto an
adaptor.
U.S. Pat. No. 4,182,058 describes an excavator tooth having a
rearwardly divergent tapering socket to receive a nose having a
complementary-shaped front spigot portion. Resistance to rotational
moment forces is borne by a resilient steel cotter pin extending
through aligned vertical apertures in the socket and spigot
portions.
U.S. Pat. Nos. 3,774,324, 4,338,736, 4,481,728, 4,903,420,
5,469,648, 7,100,315 and 6,735,890 all describe nose and tooth
combinations wherein the nose has a generally convergently tapering
spigot portion with a forward tip having a box-like configuration
with at least the upper and lower surfaces thereof having faces
parallel to each other and to a longitudinal axis of the nose
portion. With the exception of U.S. Pat. No. 4,338,736, which
describes a transverse locking pin, each of the tooth mounting
arrangements is heavily reliant on a large vertical locking pin to
resist rotational moment forces tending to rotate the teeth off
respective noses.
U.S. Pat. No. 4,231,173 describes a tapered adaptor nose having a
box-like free end, which engages in a mating box-like socket cavity
to resist rotational moments. Opposed pairs of rearwardly extending
tongues engage in corresponding recesses in the outer surfaces of
the adaptor nose to resist rotational movements. Because the
tongues themselves are unsupported, they possess a limited capacity
to resist rotational moment forces.
U.S. Pat. No. 5,272,824 describes a structure similar to that of
U.S. Pat. No. 4,231,173 except that the side tongues are of more
robust dimensions and the upper and lower tongues are formed as
box-like members with apertures to receive a vertical mounting pin
passing through aligned apertures in the tooth and adaptor
nose.
U.S. Pat. No. 4,404,760 provides flat rail surfaces on the adaptor
nose to engage with mating grooves in the socket aperture of a
corresponding tooth wherein the mating rail and groove surfaces are
generally parallel to the longitudinal axis of the tooth.
U.S. Pat. No. 5,423,138 describes a generally tapered nose having a
box-like front end with upper and lower transverse surfaces
generally parallel to a longitudinal axis of a tooth which located
directly thereon. The parallel upper and lower transverse surfaces
are contiguous with upper and lower rail surfaces on each side of
the nose and parallel to the longitudinal axis of the tooth. A pair
of rearwardly extending side tongues locate in recesses formed in
the outer side faces of the nose, ostensibly to resist rotational
moment forces in the tooth. Because the side tongues are recessed
to accommodate the side rail portions, the robustness of the side
tongues is somewhat compromised.
U.S. Pat. No. 4,233,761 describes a fairly stubby tapered nose
having a box-like front portion with upper and lower surfaces
generally parallel to a longitudinal axis of an excavator tooth, an
intermediate rearwardly diverging tapered portion and a rear
portion having upper and lower surfaces extending generally
parallel to a longitudinal axis of the tooth. Formed on the upper
and lower surfaces of the front, intermediate and rear portions of
the nose are spaced parallel reinforcing ribs which are located in
mating grooves in the excavator tooth. A large vertical locking pin
extends through aligned apertures in the tooth and nose between the
reinforcing ribs. This structure is heavily reliant on the locking
pin to resist rotational moment forces however it is considered
that this configuration may be prone to failure in the rear portion
of the adaptor.
U.S. Pat. No. 5,709,043 describes a nose/adaptor combination
wherein the adaptor socket tapers convergently towards a box-like
front portion having upper and lower bearing surfaces generally
parallel to a longitudinal axis of the tooth, a front transverse
upright bearing surface and rearwardly divergent bearing surfaces
formed at obtuse angles between the converging upper and lower
walls and the side walls of the socket, ostensibly to avoid areas
of stress concentration.
U.S. Pat. No. 6,018,896 describes a pin/retainer system for locking
an excavation tooth onto an adaptor wherein the retainer is
inserted in the adaptor and a wedge-shaped pin is driven into
aligned apertures in the tooth and adaptor to resiliently engage
with the retainer.
United States Publication No US 2002/0000053A1 describes a
mechanism for releasably retaining an adaptor into the nose of a
bucket lip or the like wherein a tapered threaded socket is
non-rotatably located on the inside of an aperture in the side wall
of the adaptor. A threaded retaining pin extends through the
threaded socket and locates in an aligned aperture in the bucket
nose.
U.S. Pat. No. 5,337,495 describes a tooth assembly with a two-piece
telescopically engageable adaptor secured to a nose with a tapered
wedge pin assembly. A similar mounting system is described in U.S.
Pat. Nos. 5,172,501 and 6,052,927. Other retention systems for
digging points on adaptors or adaptors on noses are described in
U.S. Pat. Nos. 6,119,378, 6,467,204, and 6,467,203.
Other devices for removably securing replaceable wear elements on
earth working equipment such as a retaining pin, a bolt, a pin lock
and locking blocks engageable in a top aperture in a wear, member
are described in U.S. Pat. Nos. 3,839,805, 3,982,339, 4,587,751,
5,088,214 and 5,653,048 respectively.
U.S. Pat. No. 5,937,550 describes a lock assembly for releasably
securing an adaptor to a nose of an excavator support structure.
The lock assembly comprises a body and a base coupled together and
adapted for insertion, while coupled together, in a hole in the
nose of the support structure. The length of the lock assembly is
extended to secure the adaptor and is retracted to release the
adaptor. While adequate for securing an adaptor to a nose of an
excavator support structure, the lock described in this patent is
relatively complex in design and operation leading to high costs
and labour intensive extraction procedures in the field.
Canadian Patent Application No 2,161,505 describes a system for
removably retaining an excavation point on an adaptor with at least
one flanged sleeve having a screw-threaded aperture therein, the
flanged sleeve being non-rotatably locatable in a transverse bore
in the adaptor before fitment of the point onto the adaptor. A
screw-threaded pin is inserted into the sleeve via an aperture in
the point whereby portion of the head of the pin retains the point
on the adaptor.
Australian Patent Application No. 2003264586 describes a locking
pin assembly comprising a body member having a non-circular
cross-sectional shape locatable in a bore of complementary shape
extending laterally between opposite sides of an excavator lip
mounting nose. After locating the body member in the nose aperture,
an adaptor can be engaged over the nose with apertures in opposite
side walls aligned with the body member. Threaded bolts engage in
threaded apertures in opposite ends of the body member, the bolts
each having a tapered shank portion with an enlarged boss at a free
end thereof, the boss being locatable in a respective aperture in a
side wall of said adaptor to prevent the adaptor from disengaging
with the nose.
While generally satisfactory for their intended purpose, the
abovementioned prior art all suffer from one or more shortcomings
or disadvantages in terms of inadequate resistance to rotation of a
tooth off a nose or an adaptor under the influence of vertical
loads applying a rotational moment to the tooth, a predisposition
to premature wear, difficulties in retention of the teeth on noses
or adaptors, inadequate locking systems and unduly complicated
configurations giving rise to increased fabrication costs.
Furthermore, the prior art all generally rely on lock assemblies
that require threaded components. Thread components in lock
assemblies are generally disadvantageous as dirt and fines can
infiltrate the threaded assembly thereby causing cementation and
resulting in difficulties in removal.
OBJECT OF THE INVENTION
It is an object of the invention to overcome or at least alleviate
one or more of the above problems and/or provide the consumer with
a useful or commercial choice.
DISCLOSURE OF THE INVENTION
In one form, although it need not be the only or indeed the
broadest form, the invention resides in a lock assembly for an
excavator wear assembly, the lock assembly comprising:
a locking pin having at least one dowel extending outwardly
therefrom;
a retaining member having a seat and a cavity; and
a biasing member located within the cavity of the retaining
member;
wherein the biasing member is adapted to exert a biasing force on
the dowel to releasably retain the dowel within the seat of the
retaining member.
Preferably, the retaining member has a ramp extending from within
the cavity of the retaining member and terminating outwardly of an
exterior surface of the retaining member.
Suitably, a detent extends outwardly from a body of the retaining
member.
Preferably, at least one slot is located through an exterior
surface of the retaining member.
Suitably, the at least one slot is adapted to receive the dowel of
the locking pin.
Suitably, the biasing member is releasably secured within the
cavity of the retaining member.
Preferably, wherein the seat is formed on an underside of an
exterior surface of the retaining member.
Preferably, the seat is axially offset from a slot formed in an
exterior surface of the retaining member.
Preferably, a passage is formed between an upper face of the
biasing member and an underside of an exterior surface of the
retaining member.
Suitably, the seat forms part of the passage.
In a preferred form, a land forms part of the passage such that the
distance between the land and the upper face of the biasing member
is smaller than a cross sectional dimension of the dowel.
Optionally, an angled guide surface forms part of the passage, the
angled guide surface extending from a slot formed in an exterior
surface of the retaining member towards the seat.
Suitably, the passage is adapted to receive the dowel when the
locking pin is axially rotated such that the dowel is forced
against a surface of the biasing member within the passage prior to
location of the dowel within the seat.
In a further form, the invention resides in an excavator wear
member comprising:
a locking aperture extending through a side wall of the excavator
wear member, the locking aperture having a receiving passage and a
retaining recess;
wherein, the receiving passage extends inwardly from an outer face
of the side wall and the retaining recess is located on an inner
face of mounting ear such that the receiving passage terminates at
retaining recess.
Preferably, the excavator wear member further comprises a body and
a mounting ear extending rearwardly of the body, the locking
aperture extending through the mounting ear.
Suitably, a locking face is located at an inner end of the
retaining recess.
Optionally, a pair of slots extend outwardly from diametrically
opposed sides of the receiving passage.
Optionally, a ramp extends about an inner face of receiving
passage.
Suitably, the ramp commences adjacent an outer end of the receiving
passage and extends circumferentially about an inner face of
receiving passage to terminate adjacent the retaining recess.
Conveniently, two ramps extend about an inner face of the receiving
passage from diametrically opposing sides thereof.
Preferably, a blind slot extends outwardly of a main portion of the
retaining recess.
In a preferred form, the receiving passage has a generally circular
main portion and the retaining recess has a generally circular main
portion, wherein the generally circular main portion of the
receiving passage is concentric with the generally circular main
portion of the retaining recess.
Suitably, the generally circular main portion of the retaining
recess has a larger diameter than the generally circular main
portion of the receiving recess.
In still a further form, the invention resides in an excavator wear
assembly comprising:
an excavator wear member having a socket cavity and locking
aperture extending through a side wall of the excavator wear
member, the locking aperture having a receiving passage and a
retaining recess;
a locking pin having at least one dowel extending outwardly
therefrom;
a retaining member located within the retaining recess of the
locking aperture, the retaining member having a seat and a
cavity;
a biasing member located within the cavity of the retaining member;
and
an adaptor having a spigot portion located within the socket cavity
of the excavator wear member and a retaining passage;
wherein the locking pin is located through the locking aperture of
the excavator wear member and the retaining passage of the adaptor
and wherein the biasing member is adapted to exert a biasing force
on the dowel of the locking in to retain the dowel within the seat
of the retaining member to thereby releasably retain the spigot
portion of the adaptor within the socket cavity of the excavator
wear member.
Further features of the present invention will become apparent from
the following detailed description.
BRIEF DESCRIPTION OF THE DRAWINGS
To assist in understanding the invention and to enable a person
skilled in the art to put the invention into practical effect
preferred embodiments of the invention will be described by way of
example only with reference to the accompanying drawings,
wherein:
FIG. 1A shows a perspective view of an excavator wear assembly
according to an embodiment of the invention;
FIG. 1B shows an exploded perspective view of the excavator wear
assembly shown in FIG. 1A;
FIG. 2A shows a reverse perspective view of a tooth forming part of
the excavator wear assembly shown in FIG. 1A;
FIG. 2B shows a rear perspective view of the tooth shown in FIG.
2A
FIG. 2C shows a sectional perspective view of the tooth shown in
FIG. 2A;
FIG. 3A shows a perspective view of a lock assembly shown in FIG.
1A;
FIG. 3B shows an exploded perspective view of the lock assembly
shown in FIG. 3A;
FIG. 4A shows an underside perspective view of a retaining member
forming part of the lock assembly shown in FIG. 3A;
FIG. 4B shows a topside perspective view of the retaining member
shown in FIG. 4A;
FIG. 5 shows a perspective view of a keeper forming part of the
lock assembly shown in FIG. 3A;
FIG. 6A shows a sectional perspective view of components of the
lock assembly shown in FIG. 3A;
FIG. 6B shows a transverse sectional perspective view of components
of the lock assembly shown in FIG. 3A;
FIG. 7A shows a side perspective view of components of the locking
assembly shown in FIG. 3A located within a tooth;
FIG. 7B shows a rear perspective view of the view shown in FIG.
7A;
FIG. 7C shows a top sectional view of the view shown in FIG.
7A;
FIG. 8A shows a sectional perspective view of the tooth located on
the adaptor;
FIG. 8B shows a sectional top view of the tooth located on the
adaptor;
FIG. 9A shows locking pin forming part of the lock assembly located
through aligned apertures in the tooth and passage in the adaptor,
the locking pin positioned in the locked position;
FIG. 9B shows a sectional view of the lock assembly in the locked
position;
FIG. 10A shows a sectional top view of the lock assembling in the
locked position with a keeper associated therewith;
FIG. 10B shows a perspective view of the excavator wear assembly
shown in FIG. 1A;
FIG. 11A shows a perspective view of a lock assembly according to a
further embodiment of the invention;
FIG. 11B shows an exploded perspective view of the lock assembly
shown in FIG. 11A
FIG. 12A shows a topside perspective view of a retaining member
forming part of the lock assembly shown in FIG. 11A;
FIG. 12B shows a further topside perspective view of the retaining
member shown in FIG. 12A;
FIG. 12C shows an underside perspective view of the retaining
member shown in FIG. 12A;
FIG. 12D shows a further underside perspective view of the
retaining member shown in FIG. 12A;
FIG. 13 shows a topside perspective view of a biasing member
forming part of the lock assembly shown in FIG. 11A;
FIG. 14A shows a sectional side view of the retaining member and
biasing member forming part of the lock assembly shown in FIG.
11A;
FIG. 14B shows an orthogonal sectional side of the retaining member
and biasing member shown in FIG. 14A;
FIG. 15A shows an underside perspective view of a keeper member
forming part of the lock assembly shown in FIG. 11A;
FIG. 15B shows a perspective view of the keeper member shown in
FIG. 15A;
FIG. 16A shows a perspective view of a tooth according to a further
embodiment of the invention;
FIG. 16B shows a further perspective view of the tooth shown in
FIG. 16A;
FIG. 16C shows a further perspective view of the tooth shown in
FIG. 16A;
FIG. 17A shows an internal perspective view of components of the
locking assembly shown in FIG. 14A located within a tooth;
FIG. 17B shows a reverse front perspective view of the components
shown in FIG. 17A;
FIG. 17C shows a forward front perspective view of the components
shown in FIG. 17A;
FIG. 17D shows a sectional top view of the components shown in FIG.
17A;
FIG. 18A shows a sectional top view of the lock assembly in the
locked position with a keeper associated therewith; and
FIG. 18B shows an internal perspective view of the keep shown in
FIG. 18A.
DETAILED DESCRIPTION OF THE INVENTION
The excavator wear assembly and lock assembly therefore are
described with reference to an excavator wear member in the form of
a tooth releasably secured to an adaptor. The adaptor is in turn
secured to a nose of an excavator bucket or the like. A skilled
addressee will appreciate that the invention may be employed to
releasably secure an adaptor to a nose or a tooth directly to a
nose of an excavator bucket lip.
Furthermore, the lock assembly may be utilized in other
applications such as a retaining pin for components in dragline
excavator rigging and the like.
FIG. 1A shows a perspective view of an excavator wear assembly 1000
according to an embodiment of the invention. FIG. 1B shows an
exploded perspective view of the excavator wear assembly 1000.
Excavator wear assembly 1000 comprises a wear member in the form of
a tooth 1100 mountable on an adaptor 1200 and a lock assembly 1300
adapted to releasably secure tooth 1100 on adaptor 1200 as will be
discussed in greater detail below.
Adaptor 1200 is suitably configured for mounting on a digging edge
of an excavator by way of an adaptor socket 1210. Adaptor socket
1210 is formed in a shape complimentary with a nose of an excavator
digging edge (not shown).
Adaptor 1200 has aligned transverse apertures 1221 each extending
through a respective opposed side wall 1220. Aligned transverse
apertures 1221 are adapted to receive an adaptor retaining pin (not
shown) which extends through aligned transverse apertures 1221 and
an adaptor retaining pin passage in the complimentary shaped nose
(not shown) to thereby retain the adaptor 1200 on the excavator
digging edge.
Additionally, adaptor 1200 has a pair of side wall mounting
recesses 1203 and 1204 located in a forward portion of respective
opposed side wall 1220.
Adaptor 1200 further includes a spigot portion 1230 extending from
a forward portion thereof. Spigot portion 1230 has converging upper
and lower rear bearing surfaces 1231, 1232 which terminate at
substantially parallel upper and lower forward bearing surfaces
1233, 1234 respectively. A front bearing face 1235 is disposed
between upper forward bearing surface 1233 and lower forward
bearing surface 1234.
Spigot portion 1230 also has a retaining passage 1237 extending
therethrough between opposed side walls 1236 thereof.
FIG. 2A shows a reverse perspective view of wear member in the form
of tooth 1100. FIG. 2B shows a rear perspective view of the tooth
1100 and FIG. 2C shows a sectional perspective view of the tooth
1100.
Tooth 1100 has a forwardly projecting working end 1101 and a socket
cavity 1110 formed from converging upper and lower rear bearing
surfaces 1111 and 1112 respectively. Each of upper and lower
bearing surfaces 1111 and 1112 terminate at substantially parallel
upper and lower forward bearing surfaces 1113 and 1114
respectively. A front bearing face 1115 is disposed between upper
forward bearing surface 1113 and lower forward bearing surface
1114.
Bearing surfaces 1111, 1112, 1113, and 1114 and front bearing face
1115 of tooth socket 1110 are configured to be complimentary with
bearing surfaces 1231, 1232, 1233 and 1234 and front bearing face
1235 respectively of spigot portion 1230 of adaptor 1200. Socket
cavity 1110 is adapted to receive spigot portion 1230 of adaptor
1200.
Tooth 1100 further includes mounting ears 1103 and 1104 extending
rearwardly of tooth body 1102 from opposed sides thereof. In use
mounting ears 1103 and 1104 are adapted to be located within
mounting recesses 1203 and 1204 respectively of adaptor 1200.
Additionally, a toe aperture 1130 extends through mounting ear 1103
and a locking aperture 1120 extends through opposed mounting ear
1104 as shown. In use, toe aperture 1130 and locking aperture 1120
are adapted to at least partially align with retaining passage 1237
of adaptor 1200.
Toe aperture 1130 is generally circular in cross section and
extends through mounting ear 1103 as shown.
Locking aperture 1120 extends through mounting ear 1104 and is
formed from a receiving passage 1121 and a retaining recess 1125.
Optionally, locking aperture 1120 may extend through any wall of
the tooth 1100
Receiving passage 1121 extends inwardly from an outer face of tooth
1100 and terminates at retaining recess 1125 located on an inner
face of mounting ear 1104.
Receiving passage 1121 has a generally circular main portion 1122
and a pair of slots 1123 extending outwardly from diametrically
opposed sides thereof.
Retaining recess 1125 has a generally circular main portion 1126
and a blind slot 1127 extending outwardly from circular main
portion 1126. Circular main portion 1126 of retaining recess 1125
is concentric with circular main portion 1122 of receiving passage
1121 with circular main portion 1126 having a relatively larger
diameter thereby forming a locking face 1128 at an inner end of
retaining recess 1125.
Similarly, blind slot 1127 generally corresponds with one of slots
1123 of receiving passage 1123 with blind slot 1127 having a
relatively larger cross sectional area than each of slots 1123.
FIG. 3A shows a perspective view of lock assembly 1300 in a locked
position and FIG. 3B shows an exploded perspective view of lock
assembly 1300.
Lock assembly 1300 comprises a locking pin 1310, a biasing member
1320, a retaining member 1330, a keeper 1340 and a compression
washer 1350. Lock assembly further comprises a pair of washers
1301,1302 adapted to locate against opposed faces of biasing member
1320.
Locking pin 1310 has a main portion 1312 and a pair of dowels 1311
extending outwardly from main portion 1312 and an end thereof from
diametrically opposed sides thereof. Dowels 1311 are adapted to be
received through respective slots 1123 of receiving passage 1121 as
will be discussed in greater detail below.
Locking pin 1310 also has a toe portion 1313 extending from an end
of main portion 1312 distal dowels 1311. Locking pin 1310 further
comprises a recess 1314 (not shown in FIG. 3A or 3B) located in an
end thereof adjacent dowels 1311.
Compression washer 1350 is securely located about toe portion 1313
adjacent main portion 1312.
Toe portion 1313 is adapted to be located in toe aperture 1130 of
tooth 1100 as will be discussed in greater detail below.
Biasing member 1320 is generally circular in shape and has an
aperture 1321 extending therethrough. Biasing member 1320 is formed
from a resiliently deformable plastic or the like and is adapted to
be located about main portion 1312 of locking pin 1310. Biasing
member 1320 further includes an annular ridge 1322 extending
circumferentially about an outer surface thereof.
In use, washers 1301, 1302 adapted to locate against opposed faces
of biasing member 1320 such that washer 1302 bears against an inner
surface of each dowel 1311 when locking assembly is in the locked
position.
FIG. 4A shows an underside perspective view of retaining member
1330 and FIG. 4B shows a topside perspective view of retaining
member 1330.
Retaining member has a body 1331 formed from a generally planar
circular top surface 1332 having an aperture 1332A and an annular
wall 1333 extending downwardly from top surface 1332 thereby
forming a cavity 1334 adapted to locate biasing member 1320 therein
as will be discussed further below. A detent 1335 extends outwardly
from body 1331 as shown. Body 1331 is adapted to be received in
circular main portion 1126 of retaining recess 1125 and detent 1335
is adapted to be received in blind slot 1127 of retaining recess
1125.
Retaining member 1330 further includes an annular valley 1337
extending circumferentially about an inner face of annular wall
1333 as shown.
A pair of slots 1336 are located on top surface 1332 such that
slots are 1336 are diametrically opposed about top surface 1332.
Slots 1336 are adapted to receive dowels 1311 of locking pin
1310.
A pair of seats 1338 are located on diametrically opposing sides of
an underside of top surface 1332 as shown. Each seat 1338 is
adapted to locate a dowel 1311 of locking pin 1310 when locking
assembly 1300 is in the locked position.
Retaining member 1330 further includes a number of angled guide
surfaces 1339 on an underside of top surface 1332 with each angled
guide surface 1339 extending from a respective slot 1336 to a land
1339A such that each land 1339A is disposed between a respective
angled guide surface 1339 and a seat 1338.
Suitably, each seat 1338 is axially offset from a slot 1336.
Preferably, each seat is axially offset by 90 degrees from each
slot 1336.
FIG. 5 shows a perspective view of keeper 1340 forming part of
locking assembly 1300.
Keeper 1340 has a generally circular top portion 1341 and a pair of
legs 1342 extending from diametrically opposed sides of top portion
1341. Each leg 1342 is adapted to be received through a slot 1123
of receiving passage 1121 of tooth 1100 and terminate in a
respective slot 1335 of retaining member 1330 when lock assembly
1300 is in the locked position.
Keeper 1340 further includes a plug 1343 extending from a central
region of an underside of top portion 1341. Plug 1343 is adapted to
be securely located within recess 1314 of locking pin 1310.
Lock assembly 1300 is adapted to releasably secure tooth 1100 on
adaptor 1200.
FIG. 6A shows a sectional view of washers 1301, 1302 and biasing
member 1320 located within cavity 1334 of retaining member 1330 and
FIG. 6B shows a transverse sectional view of this arrangement.
As shown, annular ridge 1322 of biasing member 1320 is located
within annular valley 1337 of retaining member 1330 such that
biasing member 1320 is securely located within cavity 1334.
In a preferred embodiment, washers 1301, 1302 are non-removably
secured to opposing faces of biasing member 1320 by means of an
adhesive or the like.
In an optional embodiment, the biasing member 1320 may be
permanently secured within cavity 1334 of retaining member 1330 by
means of a chemical fastener or the like.
The retaining member 1330 is then located within retaining recess
1125 of locking aperture 1120 of tooth 1100 as shown in FIGS. 7A,
7B and 7C.
In this position, detent 1335 is located within blind slot 1127
thereby non-rotatably locating retaining member 1330 within
retaining recess 1125. Furthermore, top surface 1332 of retaining
member 1330 abuts locking face 1128 as shown.
Furthermore, slots 1336 of retaining member 1330 align with and
correspond to slots 1123 of receiving passage 1121 of tooth 1100 as
shown.
In an optional embodiment, retaining member 1330 may be permanently
secured within retaining recess of locking aperture 1120 of tooth
by means of a chemical fastener or the like such that tooth 1100 is
provided in the arrangement as shown in FIGS. 7A-7C. Alternatively,
retaining member 1330 may be integrally formed with tooth 1100.
The tooth 1100 is then slidably mounted onto adaptor 1200 such that
spigot portion 1230 is located within socket cavity 1110 of tooth
1100 as previously discussed and as shown in FIG. 8A and FIG.
8B.
In this position, the retaining member 1330 is captively retained
in retaining recess 1124 of tooth 1100 in view of retaining recess
1124 being coaxial with retaining passage 1237 of adaptor 1200. In
this way, an outer face of washer 1301 and a lower face of annular
wall 1333 of retaining member 1330 both contact an outer face of
side wall 1236 of spigot portion 1230 to thereby captively retain
retaining member 1330 in retaining recess 1124 a shown.
Retaining pin 1310 of lock assembly 1300 is then located through at
least partially aligned locking aperture 1120, retaining passage
1237 and toe aperture 1120 as shown in FIG. 9A in order to place
the lock assembly 1300 in the locked position to releasably retain
tooth 1100 on adaptor 1200. FIG. 9B shows a section perspective
view of locking assembly 1300 in the locked position with the
adaptor 1200 and tooth 1100 removed from the view for clarity.
Toe portion 1313 of locking pin 1310 is first located through
locking aperture 1120 of tooth 1100. Toe portion 1313 travels
through receiving passage 1121 of locking aperture 1120, aligned
aperture 1332A of retaining member and 1321 of biasing member 1320
and into retaining passage 1237 of spigot portion 1230 of adaptor
1200.
In this position, or prior to insertion, locking pin is rotated
axially about a longitudinal axis thereof such that dowels 1311 are
generally coplanar with a plane formed by aligned slots 1336 of
retaining member 1330 and slots 1123 of receiving passage 1121 of
tooth 1100.
In this orientation of locking pin 1310, dowels 1311 are received
through respective aligned slots 1336 and 1123 as locking pin 1310
is further translated within retaining passage until a face of each
dowel contacts 1311 contacts an outer face of washer 1302. At this
stage of insertion, toe portion 1313 is located within toe aperture
1130 of tooth 1100 as shown.
In this position, lock assembly 1300 is in the insertion position.
In order to move lock assembly to the locked position as shown in
FIGS. 9A and 9B, locking pin 1310 is rotated axially about a
longitudinal axis thereof in order to move each dowel 1311 away
from a respective slot 1336 into a respective seat 1338 of
retaining member 1300.
Each dowel 1311 has a diameter that is greater in length than a
length between an outer face of washer 1302 and an inner surface of
land 1339A. As such, as locking pin 1310 is axially rotated, a face
of each dowel 1311 is urged into abutment with a face of a
respective angled guide surface 1339 whilst an opposing face of
each dowel 1311 remains in contact with an outer face of washer
1302.
As previously discussed, biasing member 1200 is formed from a
resiliently deformable material such that as the locking pin 1310
is axially rotated and each dowel 1311 travels against a respective
angled guide surface 1339, biasing member 1320 is thereby
compressed.
When a face of each dowel 1311 bears against a face of a respective
land 1339A, biasing member is at full compression. As the locking
pin 1310 continues to be axially rotated, a face of each dowel 1311
is urged by the compressive force of biasing member 1320 into a
respective seat 1338.
In this position, a face of each dowel 1311 is held in firm
abutment with a face of seat 1338 by a biasing force supplied by
biasing member 1320 in order to captively retain locking pin 1310
within partially aligned locking aperture 1120, retaining passage
1237 and toe aperture 1120 as shown.
Suitably, a power tool is used to axially rotate locking pin 1310
such that a sufficient force is used to overcome the biasing force
of biasing member 1320. Furthermore, locking pin may be rotated in
either axial direction in order to move lock assembly 1300 into the
locked position from the insertion position.
In the locked position, compression washer 1350 extends about toe
portion 1313 within retaining passage 1237 or adaptor 1200 adjacent
toe aperture 1130 in order to prevent the ingress of fines and the
like therein.
Keeper 1340 is then located within locking aperture 1120 as shown
in FIG. 10A and FIG. 10B. Plug 1343 is located within recess 1314
by way of an interference fit in order that keeper 1340 is secured
to locking pin 1310. Furthermore, legs 1342 extend through slots
1123 from an outer extent thereof and terminate within cavity 1334
of retaining member 1330.
In this way, the location of legs 1342 ensure that locking pin 1310
cannot rotate to a position such that dowels are in alignment with
slots 1336 in the event that the locking pin 1310 is subjected to
large rotational loads during use. Keeper 1340 also prevents
ingress of fines and the like into locking aperture 1120.
In order to move lock assembly 1300 to the insertion position, the
keeper 1340 is removed and the locking pin 1310 is suitably rotated
in order that dowels 1311 align with respective aligned slots 1336
and 1123 in order that locking pin 1310 may be withdrawn to remove
tooth 1100 from adaptor 1200.
FIG. 11A shows a perspective view of a lock assembly 2300 according
to a further embodiment of the invention. FIG. 11B shows an
exploded perspective view of lock assembly 2300.
Lock assembly 2300 has a locking pin 1310 as previously described.
Lock assembly 2300 also comprises a biasing member 2320, a
retaining member 2330 and a keeper 2340 as discussed in greater
below.
As shown most clearly in FIG. 11A, when biasing member 2320,
retaining member 2330 and keeper 2340 are fitted to locking pin
1310, a channel 1315 is formed between keeper 2340 and retaining
member 2330.
FIG. 12A and FIG. 12B show top side perspective views of retaining
member 2330 forming part of the lock assembly 2300. FIG. 12C and
FIG. 12D show underside perspective views of retaining member
2330.
Retaining member 2330 has a body 2331 having an aperture 2332A
extending through a top surface 2332 thereof. An annular wall 2333
extends downwardly from top surface 2332 thereby forming a cavity
2334 adapted to locate biasing member 2320 therein as will be
discussed in further detail below. A detent extends 2335 extends
outwardly from body 2331 as shown.
Retaining member 2330 further includes an annular valley 2337
extending circumferentially about an inner face of annular wall
2333 as shown.
A pair of slots 2336 are located on top surface 2332 such that
slots 2336 are diametrically opposed about top surface 2332. Slots
2336 are adapted to receive dowels 1311 of locking pin 1310.
A pair of seats 2338 are located on diametrically opposing sides of
an underside of top surface 2332 as shown. Each seat 2338 is
adapted to locate a dowel 1311 of locking pin 1310 when locking
assembly 1300 is in the locked position.
Retaining member 2330 further includes a number of angled guide
surfaces 2339 on an underside of top surface 2332 with each angled
guide surface 2339 extending from a respective slot 2336 to a land
2339A such that each land 2339A is disposed between a respective
angled guide surface 2339 and a seat 2338.
As shown each seat 2338 is axially offset from a slot 2336.
Preferably, each seat is axially offset by 90 degrees from each
slot 2336.
Retaining member 2330 further includes a pair of ramps 2360 each
having a guide surface 2361 that extends from within cavity 2334
about an inner face of annular wall 2333 and terminates outwardly
of an exterior surface in the form of top surface 2332 as
shown.
Guide surface 2361 is adapted to guide a respective dowel 1311 of
locking pin 1310 when locking pin 1310 is being removed from
excavator wear assembly as will be discussed in greater detail
below.
Each ramp 2360 has an abutment face 2362 extending outwardly from
top surface 2332 and terminating at guide surface 2361.
Furthermore, a locating corner 2363 is located on an underside of
each ramp 2360 adjacent a respective seat 2338. Each ramp 2360 also
includes an abutment surface 2364 adapted to engage with a surface
of biasing member 2320 as will be discussed below.
FIG. 13 shows a topside perspective view of biasing member 2320
forming part of the lock assembly 2300. Biasing member 2320 is
adapted to be located within cavity 2334 of retaining member 2330
as will be discussed in greater detail below.
Biasing member 2320 is generally annular in shape and has an
aperture 2321 extending therethrough. Biasing member 2320 is formed
from a resiliently deformable plastic or the like and is adapted to
be located about main portion 1312 of locking pin 1310.
Biasing member 2320 includes an annular ridge 2322 extending
circumferentially about an outer surface thereof. Annular ridge
2322 is adapted to be located within annular valley 2237 of
retaining member 2330.
Biasing member 2320 further includes a locating surface 2323 and a
pair of abutment portions 2327 extending outwardly from locating
surface 2323 as shown. Locating surface 2323 is adapted to oppose
and engage abutment surface 2364 of retaining member 2330.
Each abutment portion has a seat 2324, a retaining surface 2325 and
a tapered surface 2326. The seat is adapted to be located within a
respective locating corner 2363 of retaining member 2330.
FIG. 14A shows a sectional side view of biasing member 2320 located
within aperture 2334 of retaining member 2330 and FIG. 14B shows an
orthogonal sectional side view.
As shown, annular ridge 2322 of biasing member 2320 is located
within annular valley 2337 of retaining member 2330. Furthermore,
each locating surface 2323 opposes and engages abutment surface
2364 of retaining member 2330. In this way, biasing member 1320 is
securely located within cavity 1334. Furthermore, each seat 2324 is
located within a respective locating corner 2363.
In an optional embodiment, the biasing member 2320 may be
permanently secured within cavity 2334 of retaining member 2330 by
means of a chemical fastener or the like.
FIG. 15A shows an underside perspective view of a keeper member
2340 forming part of lock assembly 2300 and FIG. 15B shows a
perspective view of the keeper member 2340.
Keeper 2340 has a generally circular top portion 2341 and a pair of
legs 2342 extending from diametrically opposed sides of top portion
2341.
Each leg 2342 has a tapered face 2344 and a locating face 2345
creating a arcuate cutout 2346 between adjacent legs 2342 as shown.
Each tapered edge 2344 and each locating edge 2345 are adapted to
abut complementary faces located within a locking aperture of a
tooth as discussed in greater detail below.
Keeper 2340 further includes a plug 2343 extending from a central
region of an underside of top portion 2341. Plug 2343 is adapted to
be securely located within recess 1314 of locking pin 1310.
FIG. 16A shows a perspective view of a tooth 2100 according to a
further embodiment of the invention. FIG. 16B shows a reverse
perspective view of tooth 2100 and FIG. 16C shows a further
perspective view of tooth 2100.
As in the previous embodiment, locking aperture 2120 extends
through mounting ear 1104 and is formed from a receiving passage
2121 and a retaining recess 2125.
Receiving passage 2121 extends inwardly from an outer face of tooth
2100 and terminates at retaining recess 2125 located on an inner
face of mounting ear 1104.
Receiving passage 2121 has a generally circular main portion 2122
and a pair of ramps 2124 extending about an inner face of receiving
passage 2121 such that each ramp starts from diametrically opposite
sides of receiving passage 2121 adjacent an outer end thereof and
traverse a half circumferential path about inner face of receiving
passage to terminate adjacent retaining recess 2125.
Each ramp 2124 defines an outwardly facing insertion face 2124A and
an inwardly face withdrawal face 2124B.
Slots 2123 are formed on diametrically opposed sides of an inner
face of receiving passage 2121 between a head portion 2124C of one
ramp 2124 and a tail portion 2124D of the opposed ramp 2124 as
shown. Slots 2123 are adapted to receive dowels 1311 of locking pin
1310.
Retaining recess 2125 has a generally circular main portion 2126
and a blind slot 2127 extending outwardly from circular main
portion 1126. Circular main portion 2126 of retaining recess 2125
is concentric with circular main portion 2122 of receiving passage
2121 with circular main portion 2126 having a relatively larger
diameter thereby forming a locking face 2128 at an inner end of
retaining recess 2125.
As in the previous embodiment, lock assembly 2300 is adapted to
releasably secure a wear member in the form of tooth 2100 on
adaptor 1200.
After locating biasing member 2320 within cavity 2334 of retaining
member 2330 as previously discussed, retaining member 2320 is
located within retaining recess 2125 of locking aperture 2120 of
tooth 2100 as shown in FIG. 17A-FIG. 17D.
As shown, in this position detent 2335 is located within blind slot
2127 thereby non-rotatably locating retaining member 2330 within
retaining recess 2125.
Furthermore, top surface 2332 of retaining member 2330 abuts
locking face 2128 as shown.
Abutment face 2362 of each ramp 2360 of retaining member 2330
engages a face of toe portion 2124D of a respective ramp 2124 in
receiving passage 2121 thereby aligning each guide surface 2361 of
retaining member 2330 with a respective outwardly facing insertion
face 2124A of each ramp 2124 as shown.
In this arrangement, twin helical slots 2800 are formed to enable
passage within a helical slot 2800 of a respective dowel 1311 of
locking pin 1310 to a respective seat 2338 of retaining member 2330
as will be discussed in greater detail below.
Each helical slot 2800 is formed by the passage between guide
surface 2361 and withdrawal face 2124B of a respective ramp 2124.
The helical slot 2800 then extends to slot 2336 of retaining member
2330, continues between retaining surface 2325 of biasing member
2320 and angled guide surface 2339 of retaining member 2330,
traverses between retaining surface 2325 of biasing member 2320 and
land 2339A of retaining member 2330 before terminating at seat 2338
of retaining member 2330.
In an optional embodiment, retaining member 2330 may be permanently
secured within retaining recess of locking aperture 2120 of tooth
2100 by means of a chemical fastener or the like such that tooth
2100 is provided in the arrangement as shown in FIGS. 17A-17D.
Alternatively, retaining member 2330 alone may be integrally formed
with tooth 2100.
The tooth 2100 is then slidably mounted onto adaptor 1200 such that
spigot portion 1230 is located within socket cavity 1110 of tooth
1100 as previously discussed and locking pin 1310 of lock assembly
2300 is then located through at least partially aligned locking
aperture 2120, retaining passage 1237 and toe aperture 2130, as
shown in FIG. 18A, in order to place the lock assembly 1300 in the
locked position to releasably retain tooth 2100 on adaptor
1200.
In this position, the retaining member 2330 is captively retained
in retaining recess 2124 of tooth 2100 in view of retaining recess
2124 being coaxial with retaining passage 1237 of adaptor 1200 as
previously discussed.
In order to move the lock assembly 2300 to a locked position
thereby releasably securing 2100 on adaptor 1220, toe portion 1313
of locking pin 1310 is first located through locking aperture 2120
of tooth 2100. Toe portion 1313 travels through receiving passage
2121 of locking aperture 2120, aligned aperture 2332A of retaining
member and aperture 2321 of biasing member 2320 and into retaining
passage 1237 of spigot portion 1230 of adaptor 1200.
Dowels 1311 traverse within helical slots 2800 commencing travel
from the portion of a respective helical slot 2800 formed by
opposing faces of the guide surface 2361 of ramp 2360 and the
withdrawal face 2124B of a respective ramp 2124.
The travel of each dowel 1311 within a respective helical slot 2800
causes locking pin 1310 to locate within the aligned apertures and
also urges rotation of the locking pin 1310 about a longitudinal
axis thereof.
This translation continues until a face of each dowel 1311 contacts
retaining surface 2325 of biasing member 2320. At this stage of
insertion, toe portion 1313 is located within toe aperture 2130 of
tooth 2100 as shown.
In order to completely translate lock assembly 2300 to the locked
position as shown in FIG. 18A, locking pin 1310 is rotated axially
about a longitudinal axis thereof in order to move each dowel 1311
into a respective seat 2338 of retaining member 2300.
Each dowel 1311 has a diameter that is greater in length than a
width of helical slot 2800 formed at that point between retaining
surface 2325 and an inner surface of land 1339A. As such, as
locking pin 1310 is axially rotated, a face of each dowel 1311 is
urged into abutment with a face of a respective angled guide
surface. 2339 whilst an opposing face of each dowel 1311 remains in
contact with retaining surface 2325.
As previously discussed, biasing member 2320 is formed from a
resiliently deformable material such that as the locking pin 1310
is axially rotated and each dowel 1311 travels against a respective
angled guide surface 2339, biasing member 2320 is thereby
compressed.
When a face of each dowel 1311 bears against a face of a respective
land 2339A, biasing member 2320 is at full compression. As the
locking pin 1310 continues to be axially rotated, a face of each
dowel 1311 is urged by the compressive force of biasing member 2320
into a respective seat 2338.
Suitably, a power tool is used to axially rotate locking pin 1310
and urge each dowel 1311 to traverse a respective helical slot 2800
such that a sufficient force is used to overcome the biasing force
of biasing member 2320.
In this position, a face of each dowel 1311 is held in firm
abutment with a face of seat 2338 by the biasing force supplied by
biasing member 2320 in order to captively retain locking pin 1310
within partially aligned locking aperture 2120, retaining passage
1237 and toe aperture 2130 as shown. As such, wear member in the
form of tooth 2100 is releasably secured to adaptor 1200 by lock
assembly 2300.
Keeper 2340 is then located within locking aperture 1120 as shown
in FIG. 18B. Plug 2343 is located within recess 1314 by way of an
interference fit in order that keeper 2340 is secured to locking
pin 1310. Furthermore, legs 2342 extend between the ramps 2124 of
receiving passage 2121.
Keeper 2340 prevents ingress of fines and the like into locking
aperture 2120.
The embodiment of the locking pin 2300 and tooth 2100 discussed
above has particular advantages when it is time to replace tooth
2100 due to wear.
The keeper member 2340 is first removed. A power tool is then used
to axially rotate locking pin 1310 and urge each dowel 1311 to
traverse a respective helical slot 2800 out from a respective seat
2800 against the biasing force of biasing member 2320. Each dowel
1311 travels along a respective helical slot 2800 and that
translation urges locking pin 1310 to begin to eject outwardly of
locking aperture 2120.
An outward end of locking pin 1310 is then available, in order to
draw the locking pin entirely from the aligned apertures and thus
remove tooth 2100 from adaptor 1200.
The ejection of locking pin 1310 from locking aperture 2120 as a
consequence of a power tool axially rotating locking pin 1310 as
described above is particularly advantageous in circumstances where
the locking pin 1310 becomes cemented within retaining passage 1237
of spigot portion 1230 of adaptor 1200 through ingress of fines and
moisture. The powered axial rotation is sufficient to overcome the
force of the cementation and partially eject the pin 1310 to
provide purchase for further withdrawal.
The excavator wear assembly of the invention and the lock assembly
for securing the wear member in the form of a tooth to an adaptor
avoids the need for threaded components and complex parts.
Furthermore, the lock assembly avoids the need for heavy hammers
and the like for mounting within the respective retaining apertures
and retaining cavities. In this way, the invention provides for an
effective method of releasably securing the tooth to the
adaptor.
Throughout the specification the aim has been to describe the
invention without limiting the invention to any one embodiment or
specific collection of features. Persons skilled in the relevant
art may realize variations from the specific embodiments that will
nonetheless fall within the scope of the invention.
It will be appreciated that various other changes and modifications
may be made to the embodiment described without departing from the
spirit and scope of the invention.
In this specification, where different embodiments share identical
features, common reference numbers are used to identify those
identical features.
* * * * *