NZ721895B2 - A swivelling joint - Google Patents
A swivelling joint Download PDFInfo
- Publication number
- NZ721895B2 NZ721895B2 NZ721895A NZ72189514A NZ721895B2 NZ 721895 B2 NZ721895 B2 NZ 721895B2 NZ 721895 A NZ721895 A NZ 721895A NZ 72189514 A NZ72189514 A NZ 72189514A NZ 721895 B2 NZ721895 B2 NZ 721895B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- swivelling joint
- bearing
- leg
- bearing surface
- relative
- Prior art date
Links
- 230000001154 acute Effects 0.000 claims description 23
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 12
- 239000011800 void material Substances 0.000 claims description 5
- 210000002414 Leg Anatomy 0.000 abstract 1
- 210000001699 lower leg Anatomy 0.000 abstract 1
- 210000000689 upper leg Anatomy 0.000 abstract 1
- 238000003466 welding Methods 0.000 description 10
- 230000000694 effects Effects 0.000 description 4
- 239000000428 dust Substances 0.000 description 3
- 238000004519 manufacturing process Methods 0.000 description 3
- 239000000356 contaminant Substances 0.000 description 2
- 210000001503 Joints Anatomy 0.000 description 1
- 230000003466 anti-cipated Effects 0.000 description 1
- 238000005266 casting Methods 0.000 description 1
- 238000009826 distribution Methods 0.000 description 1
- 238000003754 machining Methods 0.000 description 1
- 238000005065 mining Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000006011 modification reaction Methods 0.000 description 1
- 238000000926 separation method Methods 0.000 description 1
Classifications
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04H—BUILDINGS OR LIKE STRUCTURES FOR PARTICULAR PURPOSES; SWIMMING OR SPLASH BATHS OR POOLS; MASTS; FENCING; TENTS OR CANOPIES, IN GENERAL
- E04H12/00—Towers; Masts or poles; Chimney stacks; Water-towers; Methods of erecting such structures
- E04H12/18—Towers; Masts or poles; Chimney stacks; Water-towers; Methods of erecting such structures movable or with movable sections, e.g. rotatable or telescopic
- E04H12/187—Towers; Masts or poles; Chimney stacks; Water-towers; Methods of erecting such structures movable or with movable sections, e.g. rotatable or telescopic with hinged sections
-
- E—FIXED CONSTRUCTIONS
- E04—BUILDING
- E04H—BUILDINGS OR LIKE STRUCTURES FOR PARTICULAR PURPOSES; SWIMMING OR SPLASH BATHS OR POOLS; MASTS; FENCING; TENTS OR CANOPIES, IN GENERAL
- E04H12/00—Towers; Masts or poles; Chimney stacks; Water-towers; Methods of erecting such structures
- E04H12/32—Flagpoles
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F16—ENGINEERING ELEMENTS AND UNITS; GENERAL MEASURES FOR PRODUCING AND MAINTAINING EFFECTIVE FUNCTIONING OF MACHINES OR INSTALLATIONS; THERMAL INSULATION IN GENERAL
- F16L—PIPES; JOINTS OR FITTINGS FOR PIPES; SUPPORTS FOR PIPES, CABLES OR PROTECTIVE TUBING; MEANS FOR THERMAL INSULATION IN GENERAL
- F16L27/00—Adjustable joints, Joints allowing movement
- F16L27/02—Universal joints, i.e. with mechanical connection allowing angular movement or adjustment of the axes of the parts in any direction
Abstract
swivelling joint for use in a pole such as a light pole is disclosed. The swivelling joint connects a first member mounted to a lower leg of a pole with a second member mounted to an upper leg of the pole. The second leg has a skirt which sits around an annular portion of the first member, with a bearing member located between the first and second members. The bearing member can be moved from outside the second member between a locked position where the joint is fixed, and a released position where the joint can rotate. bearing member located between the first and second members. The bearing member can be moved from outside the second member between a locked position where the joint is fixed, and a released position where the joint can rotate.
Description
“A SWIVELLING JOINT”
Field of the Invention
The present invention relates to a swivelling joint for use in light
poles and similar structures. The swivelling joint is expected to be used in
light poles in excess of 2m in height, or light poles having a light located
outside of easy reach. It is anticipated that the swivelling joint may be used
in other poles such as flag poles, or in raised elongate structures such as
mountings for securing cameras.
Background to the Invention
The Swivelpole™ is described in the International Patent Application
published as WO0125687, the contents of which are incorporated herein by
reference. This product consists of a light pole which has a swivelling joint
along its length. The swivelling joint allows for safer and easier changing and
repair of lights than had previously been available.
The Swivelpole™ has proved highly successful, and has become an
important safety feature in many industrial, mining, and oil-and-gas
installations. Nonetheless, it is considered that improvements may be
possible in both the manufacture and use of the product.
The Swivelpole™ requires precise welding of flat plates onto tubing.
Such welding requires considerable expertise, in addition to costly
equipment. Inexpert welding can lead to distortion of the flat plates, resulting
in an underperforming joint. It is considered desirable to have a joint which
could be formed without welding, for instance by casting and machining. The
Swivelpole™ cannot be easily formed by such a method.
In addition, by the nature of its design, the Swivelpole™ includes an
open joint into which water and dust can locate. This is problematic in some
applications.
The present invention seeks to improve some features of the
previous Swivelpole™ design, particularly to allow for easier manufacture,
whilst retaining the key concept of the swivelling joint.
Summary of the Invention
According to one aspect of the present invention there is provided a
swivelling joint including a first member, a second member, and at least one
bearing member;
the first member being associated with a first leg, the first leg having a
longitudinal direction, the first member having an annular base which is
oriented at an acute angle relative to the longitudinal direction of the first leg,
the base having an outer periphery;
the second member being associated with a second leg, the second
leg having a longitudinal direction, the second member including an outer
wall arranged to locate around the annular base of the first member to define
an exterior surface of the swivelling joint;
the first member having a bearing surface located internally of the
exterior surface of the swivelling joint;
the bearing member being connected to the second member by an
adjustable connection means;
the bearing member locating within the outer wall of the second
member, with the bearing surface of the bearing member being opposed to
the bearing surface of the first member;
the adjustable connection means permitting relative movement of the
bearing member and the second member between:
a first configuration, wherein the bearing surface of the bearing
member and the bearing surface of the first member are in frictional
engagement restricting rotational movement of the first member relative to
the second member,
and a second configuration, wherein rotation of the second member
relative to the first member is permitted.
According to a second aspect of the present invention there is
provided a swivelling joint including a first member, a second member, and
at least one bearing member;
the first member being associated with a first leg, the first leg having a
longitudinal direction, the first member having an annular base which is
oriented at an acute angle relative to the longitudinal direction of the first leg,
the base having an outer periphery;
the second member being associated with a second leg, the second
leg having a longitudinal direction, the second member including an outer
wall arranged to locate around the annular base of the first member to define
an exterior surface of the swivelling joint;
the second member having a bearing surface located internally of the
exterior surface of the swivelling joint;
the bearing member being connected to the first member by an
adjustable connection means;
the bearing member locating within the outer wall of the second
member, with the bearing surface of the bearing member being opposed to
the bearing surface of the second member;
the adjustable connection means permitting relative movement of the
bearing member and the first member between:
a first configuration, wherein the bearing surface of the bearing
member and the bearing surface of the second member are in frictional
engagement restricting rotational movement of the first member relative to
the second member,
and a second configuration, wherein rotation of the second member
relative to the first member is permitted.
According to a third aspect of the present invention there is provided
a swivelling joint including a first member, a second member, and at least
one bearing member;
the first member being associated with a first leg, the first leg having a
longitudinal direction, the first member having a base, the base having an
outer periphery, the outer periphery being located in a plane, the plane being
perpendicular to an operating axis, the operating axis being angled with
respect to the longitudinal axis of the first leg at an offset angle;
the second member being associated with a second leg, the second
leg having a longitudinal direction, the second member including an outer
wall arranged to locate around the annular base of the first member to define
an exterior surface of the swivelling joint;
the first member having a bearing surface located internally of the
exterior surface of the swivelling joint;
the bearing member being connected to the second member by an
adjustable connection means;
the bearing member locating within the outer wall of the second
member, with the bearing surface of the bearing member being opposed to
the bearing surface of the first member;
the adjustable connection means permitting relative movement of the
bearing member and the first member between:
a first configuration, wherein the bearing surface of the bearing
member and the bearing surface of the first member are in frictional
engagement restricting rotational movement of the first member relative to
the second member,
and a second configuration, wherein rotation of the second member
relative to the first member is permitted.
Advantageously, the bearing connection, between the bearing
surface of the bearing member and the bearing surface of the first or second
member, is located internally of the joint and is protected from ingress of
water or dust.
Preferably, the outer wall or skirt of the second member and the
periphery of the annular base of the first member combine to define a
circular track about which the second member can rotate relative to the first
member when in the second configuration.
It is preferred that the bearing surface of the first or second member
be annular. In the most preferred embodiments, the bearing surface of the
first or second member is formed by an annular groove.
The annular groove may be formed from three surfaces: a cylindrical
centre surface and two frusto conical outer surfaces.
The adjustable connection means may include a threaded bolt, such
that threaded movement of the bolt causes movement between first and
second configurations.
In a most preferred embodiment, the bolt may be generally
tangential to the annular base. In an alternative embodiment, the bolt may
be generally radial relative to the annular base. In a further alternative
embodiment, the bolt may be axial to the annular base, or offset relative to
an axial direction.
It is preferred that the bearing member includes an internally
threaded body portion arranged to engage with threads on the bolt. It is
preferred that the body portion is integral with an engaging portion of the
bearing member, the engaging portion including the bearing surface.
The bearing member may include two engaging members, each of
which has a body portion and an engaging portion. In a preferred
embodiment, the body portion of only one engaging member is internally
threaded. The two engaging members may be separated by a resilient
biasing means such as a spring, which may act to bias the engaging
members away from each other.
Alternatively, the bearing member may be arranged to pivot between
the first configuration and the second configuration.
According to a fourth aspect of the present invention there is
provided a swivelling joint including a first member, a second member, and a
bearing member;
the first member being associated with a first leg, the first leg having a
longitudinal direction, the first member having a hollow body portion, the first
member having a bearing surface which is oriented at an acute angle
relative to the longitudinal direction of the first leg, the bearing surface facing
towards the hollow body portion;
the second member being associated with a second leg, the second
leg having a longitudinal direction;
the bearing member being connected to the second member by an
adjustable connection means, the bearing member having a bearing surface
which is oriented at an acute angle relative to the longitudinal direction of the
first leg;
the bearing member locating within the hollow body portion of the first
member, with the bearing surface of the bearing member being opposed to
the bearing surface of the first member;
the adjustable connection means permitting relative movement of the
bearing member and the second member between:
a first configuration, wherein the bearing surface of the bearing
member and the bearing surface of the first member are in frictional
engagement restricting rotational movement of the first member relative to
the second member,
and a second configuration, wherein rotation of the second member
relative to the first member is permitted.
The bearing surface of the first member may be annular. It may be
formed as an annular shoulder at an outer edge of the hollow body portion.
The bearing member may be annular. In one embodiment, the
bearing surface of the bearing member is an outer annular ring of the
bearing member. The bearing member may include connection means
receiving apertures located internally of the outer annular ring.
The connection means receiving apertures may be internally
threaded. The connection means may be formed by a plurality of externally
threaded bolts arranged to be received within the receiving apertures.
The bolts may be angularly spaced around the swivelling joint. In
one embodiment the connection means may be formed by three such bolts,
spaced apart by 120°.
The bolts may be perpendicular to the bearing surfaces. In one
embodiment, the bolts are off-set by an acute angle, preferably between 15°
and 30°, such as 22.5°, from the perpendicular. In this embodiment, the
bearing member may include an annular connection means receiving portion
having a face which is frusto conical, with an obtuse cone angle, such as
135°.
In a preferred form of this embodiment, one of the first member and
the second members has a circular recess, and the other of the first member
and the second member has a circular projection arranged to locate within
the circular recess, and the adjustable connection means passes within the
circular projection.
The swivelling joint may include secondary apertures in the first
member and the second member, arranged to receive a secondary locking
pin. The secondary apertures may be formed as recesses extending
inwardly from an outer periphery in at least one of the first and second
members.
According to a fifth aspect of the present invention there is provided
a swivelling joint including a first member, a second member, and a bearing
member;
the first member being associated with a longitudinally extending first
leg, the first leg having a longitudinal direction, the first member having a
hollow body portion, the first member having a bearing surface which is
oriented at an acute angle relative to the longitudinal direction of the first leg,
the bearing surface facing towards the first leg;
the second member being associated with a longitudinally extending
second leg, the second leg having a longitudinal direction;
the first member and the second member being arranged to meet
along a connection annulus,
the bearing member being connected to the second member by an
adjustable connection means, the bearing member having a bearing surface
which is oriented at an acute angle relative to the longitudinal direction of the
first leg;
the bearing member locating inside the connection annulus, with the
bearing surface of the bearing member being opposed to the bearing
surface of the first member;
the adjustable connection means permitting relative movement of the
bearing member and the second member between:
a first configuration, wherein the bearing surface of the bearing
member and the bearing surface of the first member are in frictional
engagement restricting rotational movement of the first member relative to
the second member,
and a second configuration, wherein rotation of the second member
relative to the first member is permitted.
It is preferred that the joint can be rotated into a main orientation
wherein the respective longitudinal axes of the first and second legs are
parallel. It is further preferred that, in this orientation, a void is defined
around a central axis of the joint. Advantageously, this allow cables and
similar items to locate centrally along the central axis.
It is preferred that rotation of the first member relative to the second
member occurs about an axis of rotation which is disposed at an acute angle
relative to the longitudinal axis of the first leg.
The acute angle may be between 30° and 60°, and is most
preferably about 45°.
The swivelling joint may be usefully deployed in an elongate member
for locating articles remote from a base position. It is considered that it may
be useful in an elongate member having length of at least 1.5m, and
particularly if length exceeds 2m. The elongate member may be a light pole.
Brief Description of the Drawings
It will be convenient to further describe the invention with reference
to preferred embodiments of the present invention. Other embodiments are
possible, and consequently the particularity of the following discussion is not
to be understood as superseding the generality of the preceding description
of the invention. In the drawings:
Figure 1 is a perspective of a swivelling joint in accordance with a
first embodiment of the present invention, shown in a first position;
Figure 2 is a front exploded view of the swivelling joint of Figure 1;
Figure 3 is a rear exploded view of the swivelling joint of Figure 1;
Figure 4 is a side view of a first member within the swivelling joint of
Figure 1;
Figure 5 is a lower perspective of a second member within the
swivelling joint of Figure 1;
Figure 6 is an exploded view of a clamping member within the
swivelling joint of Figure 1;
Figure 7 is a cross sectional view taken through an angle of action of
the swivelling joint of Figure 1;
Figure 8 is a cross sectional view taken from the side of the
swivelling joint of Figure 1;
Figure 9 is a perspective of the swivelling joint of Figure 1, shown in
a second position;
Figure 10 is a cross sectional view taken from the side of the
swivelling joint in the position of Figure 9;
Figure 11 is a perspective of a swivelling joint in accordance with a
second embodiment of the present invention, shown in a first position;
Figure 12 is a front exploded view of the swivelling joint of Figure 11;
Figure 13 is a rear exploded view of the swivelling joint of Figure 11;
Figure 14 is a lower perspective of a second member within the
swivelling joint of Figure 11;
Figure 15 is a side cross sectional view of the swivelling joint of
Figure 11;
Figure 16 is a cross sectional view taken through an angle of action
of the swivelling joint of Figure 11, showing the joint in a locked
configuration;
Figure 17 is a cross sectional view taken through an angle of action
of the swivelling joint of Figure 11, showing the joint in a released
configuration;
Figure 18 is a perspective of a swivelling joint in accordance with a
third embodiment of the present invention, shown in a first position;
Figure 19 is a front exploded view of the swivelling joint of Figure 18;
Figure 20 is a rear exploded view of the swivelling joint of Figure 18;
Figure 21 is a perspective of a first member within the swivelling joint
of Figure 18;
Figure 22 is a perspective of the first member of Figure 21 with a
clamping member included;
Figure 23 is a lower perspective of a second member within the
swivelling joint of Figure 18;
Figure 24 is a side cross sectional view of the swivelling joint of
Figure 18;
Figure 25 is a cross sectional view taken through an angle of action
of the swivelling joint of Figure 18.
Detailed Description of Preferred Embodiments
A first embodiment of the present invention will be described with
reference to Figures 1 to 10, in which there is shown a swivelling joint 10
having three main components: a first member 12, a second member 14 and
a bearing member 16.
The first member 12 is associated with a first leg 18, which is
oriented in a longitudinal direction. The first leg 18 terminates at a pole
receiving aperture 20, which forms a cylindrical sleeve arranged to connect
to a pole (such as the base of a light pole) by suitable means such as
clamping or welding.
The second member 14 is associated with a second leg 24, which is
oriented in a longitudinal direction. The second leg 24 terminates at a pole
receiving aperture 26, which forms a cylindrical sleeve arranged to connect
to a pole (such as the top portion of a light pole) by suitable means such as
clamping or welding.
The arrangement is such that when the swivelling joint 10 is in a first
position, as shown in Figure 1, the first leg 18 and the second leg 24 can
both be vertical, and aligned along a common longitudinal axis.
The first member 12 has an annular base 22 which is connected to
the first leg 18 by means of a tapered connection portion 28.
The annular base 22 defines a plane oriented at an angle relative to
the longitudinal axis of the first leg 18. The angle of orientation may be
considered by defining an offset angle between the longitudinal axis of the
first leg 18, and a line perpendicular to the plane of the base 22. The offset
angle is an acute angle. In the embodiment shown, the offset angle is 45°.
The annular base 22 is circular, with a diameter nearly twice that of
the first leg 18. The annular base 22 is positioned such that a lower side 30
is close to a nominal cylinder defined by the first leg 18, and an upper side
32 is spaced from this nominal cylinder.
The first member 12 has an annular outer rim 34 which is parallel to,
and spaced from, the base 22. The outer rim 34 is circular, with a diameter
similar to that of the base 22. The base 22 and the outer rim 34 are aligned
along a common offset axis, which is oriented at the offset angle relative to
the longitudinal axis.
The arrangement is such that an upper side of the outer rim 34 is
close to the nominal cylinder defined by the first leg 18.
An annular groove 36 is located between the base 22 and the outer
rim 34. The annular groove 36 is ‘flat-bottomed-V’ shaped in cross section.
In other words, the annular groove 36 is formed by an inwardly tapering
lower frusto conical surface 38, a cylindrical inner surface 40, and an
outwardly tapering upper frusto conical surface 42. The lower frusto conical
surface 38 extends between the base 22 and the inner surface 40, and the
upper frusto conical surface 42 extends between the inner surface 40 and
the outer rim 34. The cylindrical inner surface 40 is aligned along the offset
axis, with a diameter about 90% that of the outer rim 34. The annular groove
may alternatively be ‘curve-bottomed-V’ shaped in cross section, with the
inner surface being partly toroidal rather than cylindrical.
The outer rim 34 has a plurality of recesses 44 spaced around its
upper periphery. In the embodiment shown there are 12 recesses equally
spaced around the outer rim 34.
The second member 14 has an upper face 46 extending away from
the second leg 24. The upper face 46 is broadly located in and around a
plane oriented at an offset angle relative to the longitudinal axis of the
second leg 24. The offset angle of the upper face 46 is similar to that of the
base 22; about 45° in this embodiment.
An outer wall or skirt 48 depends from the upper face 46 in a
direction generally perpendicular to the upper face 46. The skirt 48 includes
an approximately part-cylindrical portion 50 extending around approximately
280°, and a flattened edge 52 at a lower end of the skirt 48, spaced from the
second leg 24.
The skirt 48 is sized to locate around the annular base 22 of the first
member 12.
The interior of the second member 14 can be seen in Figures 3 and
. The skirt 48 includes two inwardly extending projections 54, located near
the second leg 24. The two inwardly extending projections 54 have centres
spaced from each other by about 90° around the part-cylindrical portion 50,
with each about 45° from an upper end of the skirt 48. The inwardly
extending projections are each aligned circumferentially around the part-
cylindrical portion 50, with each projection 54 extending along about 45°.
The skirt 48 also includes a bearing member receiving portion 56
located internally of the flattened edge 52. The bearing member receiving
portion 56 is broadly rectangular in shape, oriented tangentially to a nominal
cylinder defined by the part-cylindrical portion 50. The bearing member
receiving portion 56 has bolt receiving apertures 58 at outer ends thereof.
The bearing member 16 is sized and shaped to locate within the
bearing member receiving portion 56. The bearing member 16 includes a
bolt 60, sized to extend through the bearing member receiving portion in a
direction parallel to the flattened edge 52; a retaining clip 62 arranged to
locate in a groove around a distal end of the bolt 60; a first engaging
member 64, a second engaging member 66, and a separating spring 68.
The first engaging member 64 has a body portion 70 through which
an internally threaded aperture 72 extends in a longitudinal direction. The
body portion 70 has a length approximately one-third that of the bearing
member receiving portion 56. The internally threaded aperture is arranged to
engage with external threads on the bolt 60.
The first engaging member 64 has an engaging portion 74 located
on an inner side of the body portion. The engaging portion 74 is concave in
shape, with a radius of curvature similar to that of the inner surface 40 of the
annular groove 36 of the first member 12. The engaging portion 74 is
arranged to locate within the annular groove 36 as will be described below.
The second engaging member 66 is similar to the first engaging
member 64, with the principal difference being that the aperture 72
extending through the body portion 70 of the second engaging member is
not internally threaded.
The bolt 60 has a head 76 at a proximal end thereof.
For ease of explanation, assembly of the bearing member 16 will be
described with reference to the second member 14 only. The bearing
member 16 can be assembled directly within the second member 14 as
follows. The first engaging member 64 is positioned within the bearing
member receiving portion 56, with its aperture 72 aligned with the apertures
58 of the bearing member receiving portion 56, and its engaging portion 74
oriented to generally follow the curvature of the part cylindrical portion of the
skirt 48. The first engaging member 64 is located towards one side of the
bearing member receiving portion 56.
The second engaging member 66 is located within the bearing
member receiving portion 56, in a mirror-image position to the first engaging
member 64. The second engaging member 66 is located towards the other
side of the bearing member receiving portion 56.
The separating spring 68 is positioned between the first and second
engaging members 64, 66.
The bolt 60 is passed sequentially through a first bolt receiving
aperture 58, the aperture 72 of the second engaging member 66, the
separating spring 68, the aperture 72 of the first engaging member 64
(through which it must be threaded), and the second bolt receiving aperture
58. The retaining clip is then placed onto the bolt 60 outside the second bolt
receiving aperture 58, preventing inadvertent withdrawal of the bolt 60 back
through the second bolt receiving aperture 58. The head 76 of the bolt
remains outside the first bolt receiving aperture 58.
It will be appreciated that the action of the spring 68 is to urge the
second engaging member 66 towards a side wall of the bearing member
receiving portion 56, adjacent the first bolt receiving aperture 58. The axial
position of the first engaging member 64, and thus the distance between the
first and second engaging members 64, 66, is altered by rotation of the bolt
The swivelling joint 10 is assembled by location of the second
member 14 and bearing member 16 about the first member 12. The ultimate
arrangement is such that the skirt 48 of the second member 14 sits over the
first member 12, with the inward projections 54 and the engaging portions 74
of the bearing member 16 locating within the annular groove 36. In other
words, the skirt 48 seats over the base 22 of the first member in a sliding fit,
defining an exterior surface of the swivelling joint 10. Other than the head 76
of the bolt 60, and the retaining clip 62, the working parts of the bearing
member 16 are located internally of the swivelling joint 10. In particular, it will
be appreciated that the bearing surfaces, being the engaging portions 74
and the annular groove 36, sit internally of the exterior surface and are
generally protected from water and dust ingress.
This arrangement can be seen in cross section in Figure 7.
In order to assemble the swivelling joint 10, it is first necessary to
place the first and second engaging members 64, 66 and separating spring
68 within the annular groove 36 of the first member 12, at the lower side 30
thereof. The first and second engaging members 64, 66 and separating
spring 68 can be held there manually, or by use of a suitable removable clip.
The second member 14 can then be placed over the first member 12
by locating the inward projections 54 within the groove 36 at the upper side
32 thereof, and using these as hinges then closing the second member 14
over the first member 12, with the flattened edge 52 of the skirt 48 lowering
over the first and second engaging members 64, 66.
Once the second member 14 has been lowered into position, the
bolt 60 can be placed into position to effectively mount the first and second
engaging members 64, 66 to the second member 14.
Once the swivelling joint has been thus assembled, rotation of the
second member 14 relative to the first member 12 can be selectively
permitted or prevented by rotation of the bolt 60.
When the bolt 60 is tightened, the first engaging member 64 is
brought towards the second engaging member 66. This acts to reduce the
effective radius of curvature, and urges the engaging portions 74 into
engagement with the annular groove 36. Tightening of the bolt 60 provides a
wedging effect, with the engaging portions 74 clamping against the annular
groove 36 and the annular groove 36 being forced in turn against the inward
projections 54. The resulting friction is sufficient to maintain the swivelling
joint 10 in a desired position, with rotation substantially prevented. This can
be seen in cross section in Figure 8.
When the bolt 60 is loosened, the opposite effect takes place. The
engaging portions 74 are released from active engagement with the annular
groove 36, and the annular groove 36 is no longer forced against the inward
projections 54. Rotation of the second member 14 relative to the first
member 12 about the offset axis is now permitted. The engaging portions 74
and inward projections 54 remain located within the annular groove 36,
preventing complete disconnection of the second member 14 from the first
member 12. The swivelling joint can be rotated from its first position, where
the first leg 18 and the second leg 24 are substantially parallel as shown in
Figures 1 and 8, to a second position, where the first leg 18 and the second
leg 24 are substantially perpendicular as shown in Figures 9 and 10. It will
be appreciated that the joint can be rotated into any intermediate position
between the first and second positions. During rotation the skirt 48 of the
second member 14 stays surrounding an outer periphery of the annular
base 22 of the first member 12. In this way, the skirt 48 and the base 22
combine to form a generally circular track about which rotation occurs.
It will be appreciated that the first position of the joint 10, where the
first leg 18 and the second leg 24 are substantially parallel, represents the
main orientation of the joint 10. As seen in Figure 8, in this orientation there
is a generally cylindrical hollow void passing through the centre of the joint
in this orientation. In practice, this void is likely to have electrical cabling
passing through it. It is considered a significant advantage of the present
invention that this cabling is not obstructed by any mechanical linkages
passing though the void.
The swivelling joint 10 includes a secondary locking means,
provided by a locking pin 80 mounted to the upper face 46 of the second
member 14. The locking pin 80 is moveable by operation of a lever 82
between a first position in which the locking pin 80 extends, in use, into a
recess 44 in the outer rim 34 of the first member 12; and a second position
in which the locking pin 80 is retracted towards the upper face 46, and is not
in engagement with the first member 12.
A second embodiment of the present invention will be described with
reference to Figures 11 to 17, in which there is shown a swivelling joint 110
having three main components: a first member 112, a second member 114
and a bearing arrangement formed by three bearing members 116.
The first member 112 is associated with a first leg 118, which is
oriented in a longitudinal direction. The first leg 118 terminates at a pole
receiving aperture 120, which forms a cylindrical sleeve arranged to connect
to a pole (such as the base of a light pole) by suitable means such as
clamping or welding.
The second member 114 is associated with a second leg 124, which
is oriented in a longitudinal direction. The second leg 124 terminates at a
pole receiving aperture 126, which forms a cylindrical sleeve arranged to
connect to a pole (such as the top portion of a light pole) by suitable means
such as clamping or welding.
The arrangement is such that when the swivelling joint 110 is in a
first position, as shown in Figure 11, the first leg 118 and the second leg
124 can both be vertical, and aligned along a common longitudinal axis.
The first member 112 has an annular base 122 which is connected
to the first leg 118 by means of a tapered connection portion 128.
The annular base 122 defines a plane oriented at an offset angle
relative to the longitudinal axis of the first leg 118. The offset angle is an
acute angle. In the embodiment shown, the offset angle is 45°.
The annular base 122 is circular, with a diameter nearly twice that of
the first leg 118. The annular base 122 is positioned such that a lower side
130 is close to a nominal cylinder defined by the first leg 118, and an upper
side 132 is spaced from the nominal cylinder.
The first member 112 has an annular outer rim 134 which is parallel
to, and spaced from, the base 122. The outer rim 134 is circular, with a
diameter similar to that of the base 122. The base 122 and the outer rim 134
are aligned along a common offset axis, which is oriented at the offset angle
relative to the longitudinal axis.
The arrangement is such that an upper side of the outer rim 134 is
close to the nominal cylinder defined by the first leg 118.
An annular groove 136 is located between the base 122 and the
outer rim 134. The annular groove 136 is ‘flat-bottomed-V’ shaped in cross
section. In other words, the annular groove 136 is formed by an inwardly
tapering lower frusto conical surface 138, a cylindrical inner surface 140,
and an outwardly tapering upper frusto conical surface 142. The lower frusto
conical surface 138 extends between the base 122 and the inner surface
140, and the upper frusto conical surface 142 extends between the inner
surface 140 and the outer rim 134. The cylindrical inner surface 140 is
aligned along the offset axis, with a diameter about 90% that of the outer rim
134.
The second member 114 has an upper face 146 extending away
from the second leg 124. The upper face 146 is broadly located in and
around a plane oriented at an offset angle relative to the longitudinal axis of
the second leg 124. The offset angle of the upper face 146 is similar to that
of the base 122; about 45° in this embodiment.
An outer wall or skirt 148 depends from the upper face 146 in a
direction generally perpendicular to upper face 146. The skirt 148 is
generally cylindrical in shape.
The skirt 148 is sized to locate around the annular base 122 of the
first member 112.
The interior of the second member 114 can be seen in Figure 14.
The skirt 114 has a generally cylindrical inner surface, with three bolt
receiving apertures 158 spaced at equal distances about the circumference
of the skirt 148. The bolt receiving apertures 158 are counter sunk.
Each bearing member 116 is sized and shaped to locate within the
annular groove 136. Each bearing member 116 includes a bolt 160, sized to
extend through the bearing member 116, a body portion 170 through which
an internally threaded aperture 172 extends, an engaging portion 174
spaced from the internally threaded aperture 172, and a raised portion 178
adjacent the internally threaded aperture 172. The engaging portion 174 and
the raised portion 178 are on opposite sides of the body portion 170. The
internally threaded aperture 172 is arranged to engage with external threads
on the bolt 160.
Each bolt 160 has a head 176 arranged to locate within the outer
part of a bolt receiving aperture 158.
The swivelling joint 110 is assembled by location of the second
member 114 and bearing members 116 about the first member 112. The
ultimate arrangement is such that the skirt 148 of the second member 114
sits over the first member 112, with the engaging portions 174 of the bearing
members 116 locating within the annular groove 136.
This arrangement can be seen in cross section in Figure 15.
In order to assemble the swivelling joint 110, it is first necessary to
place the body portions 170 of the three bearing members116 at appropriate
locations within the annular groove 136 of the first member 112. The body
portions 170 can be held there manually, or by use of a suitable removable
clip.
The second member 114 can then be placed over the first member
112.
Once the second member 114 has been lowered into position, the
bolts 160 can be placed into position to effectively mount the body portions
170 of the bearing members 116 to the second member 114.
Once the swivelling joint has been thus assembled, rotation of the
second member 114 relative to the first member 112 can be selectively
permitted or prevented by rotation of the bolts 160.
When each bolt 160 is turned in a first direction, the body portion
170 adjacent the aperture 172 is urged towards the bolt receiving aperture
158. The raised portion 178 acts as a pivot against the inside of the skirt
148, urging the engaging portion 174 into engagement with the annular
groove 136. Further tightening of the bolt 160 in this direction provides a
wedging effect, with the engaging portions 174 clamping against the annular
groove 136. The resulting friction is sufficient to lock the swivelling joint 110
into a desired position, with rotation prevented. This is shown in Figure 16.
When the bolts 160 are turned in the other direction, the opposite
effect takes place. The engaging portions 174 are released from active
engagement with the annular groove 136, and are pulled outwardly as the
body portion 170 adjacent the aperture 172 moves inwardly. Rotation of the
second member 114 relative to the first member 112 about the offset axis is
now permitted. The body portions 170 remain located within the annular
groove 136, preventing complete disconnection of the second member 114
from the first member 112. This is shown in Figure 17.
In one version (not shown), this embodiment includes an encircling
spring around the bearing members 116, acting to urge the engaging
portions towards the annular groove 136. This spring assists in tightening of
the engaging portions 174.
Although not shown in the drawings, it is considered that a
secondary locking means similar to that shown in the first embodiment could
be readily added to the second embodiment.
A third embodiment of the present invention will be described with
reference to Figures 18 to 25, in which there is shown a swivelling joint 210
having three main components: a first member 212, a second member 214
and a bearing member 216.
The first member 212 is associated with a first leg 218, which is
oriented in a longitudinal direction. The first leg 218 terminates at a pole
receiving aperture 220, which forms a cylindrical sleeve arranged to connect
to a pole (such as the base of a light pole) by suitable means such as
clamping or welding.
The second member 214 is associated with a second leg 224, which
is oriented in a longitudinal direction. The second leg 224 terminates at a
pole receiving aperture 226, which forms a cylindrical sleeve arranged to
connect to a pole (such as the top portion of a light pole) by suitable means
such as clamping or welding.
The arrangement is such that when the swivelling joint 210 is in a
first position, as shown in Figure 18, the first leg 218 and the second leg
224 can both be vertical, and aligned along a common longitudinal axis.
The first member 212 is generally hollow, and has a lower face 228,
a generally cylindrical side wall 230, an upper shoulder 222, and an
upwardly extending cylindrical projection 234. The first member 212 has a
hollow body portion defined generally by the lower face 228 and the side
wall 230.
The side wall 230 has a thickness of around 10% of its internal
diameter. In the embodiment shown in the drawings, the side wall has an
outer diameter of 175mm and an internal diameter of 140mm. The side wall
230 separates the lower face 228 and the upper shoulder 222. The upper
shoulder 222 includes a number of ‘cut out’ portions or recesses 244.
The upper shoulder 222 extends internally of the side wall 230 and is
opposed to the lower face 228. The upper shoulder 222 is generally annular,
with an inner diameter equal to about 70% of the outer diameter of the side
wall 230. In the embodiment shown, the upper shoulder has an internal
diameter of about 125mm.
The upper shoulder 222 has an outer face 236, on the outside of the
first member 212, and an inner face 238, inside the first member 212 and
facing the lower face 228. The inner face 238 is generally annular. In the
preferred embodiment shown, the inner face 238 is frusto conical, with a
cone angle of about 135°, and oriented such that the distance from the lower
face 228 to the inner face 238 increases away from the side wall 230.
The inner face 238 is a bearing surface, oriented towards the hollow
body portion.
The cylindrical projection 234 extends upwardly from the outer face
236 of the upper shoulder 222. The cylindrical projection 234 has an
external diameter which is about 85% of the external diameter of the side
wall 230. In the embodiment shown, the cylindrical projection 234 has an
external diameter equal to about 147mm.
The cylindrical projection may have a frusto conical internal shape,
with an internal diameter increasing from the inner edge of the upper
shoulder 222 to the upper edge of the cylindrical projection. The cone angle
of this shape is about 45°.
The second member 214 has a generally frusto conical top surface
246 and a generally cylindrical skirt 248. The skirt 248 depends downwardly
from the periphery of the top surface 246, and has an internal diameter
equal to the external diameter of the cylindrical projection 234 of the first
member 212. The skirt 248 of the second member 214 thus defines a
circular recess within which the cylindrical projection 234 of the first member
212 can locate.
The second member 214 includes three bolt-receiving apertures 258
spaced at 120° intervals near the periphery of the top surface 246. The bolt
receiving apertures 258 are located radially internally of the skirt 248 by a
short distance. The bolt receiving apertures 258 are normal to the top
surface 246; that is, are at an angle of about 22.5° relative to the longitudinal
direction of the second leg 224, and are oriented towards a central axis of
the second member 214 such that the distance from the skirt 248 to each of
the bolt receiving apertures 258 increases away from the top surface 246.
The bearing member 216 is generally frusto conical, with a cone
angle of 135°. It is also generally annular in shape, with an external diameter
similar to the internal diameter of the side wall 230 of the first member 212,
and an internal diameter about one third of its outer diameter. The bearing
member 216 shown in the drawings has a height of about 12mm. It is sized
so as to locate in the hollow body portion of the first member 212, with an
outer rim of the bearing member 216 locating under the shoulder 222 of the
first member 212.
The bearing member 216 does not have a circular outer periphery.
Instead, its outer periphery is shaped in such a fashion that the bearing
member 216 can be inserted into the hollow body portion of the first member
212.
The bearing member 216 has three internally threaded bolt receiving
apertures 256 spaced at 120° intervals near the periphery of the bearing
member 216. The bolt receiving apertures 256 are perpendicular to an upper
surface of the bearing member 216; that is, they are inclined at 22.5° relative
to a central axis of the bearing member 216. The radial position of the bolt
receiving apertures 256 is matched to that of the bolt receiving apertures
258 of the second member 214 as described below.
The swivelling joint 210 is assembled by manoeuvring the bearing
member 216 into the hollow body portion of the first member 212, such that
an outer rim of the conical upper surface of the bearing member 216 abuts
the inner face 238 of the shoulder 222 of the first member 212. The second
member 214 can then be located over the first member 212, with the
cylindrical projection 234 of the first member 212 locating within the circular
recess defined by the skirt 248 of the second member 214. The upper edge
of the cylindrical projection 234 of the first member 212 is in contact with the
circular recess of the second member 214 along a connection annulus.
During this stage of assembly, the second member 214 can rotate
freely about the cylindrical projection 234. It can therefore be rotated until
the bolt receiving apertures 258 of the second member 214 align with the
bolt receiving apertures 256 of the bearing member 216. It will be
appreciated that these bolt receiving apertures are all aligned at 22.5° to a
central axis of the swivelling joint 210, and that their respective radial
positions allow the bolt receiving apertures 256, 258 to be axially aligned
when the second member 214 is rotated to the correct position.
Adjustable connection means in the form of bolts 260 can be
inserted through the bolt receiving apertures 258, and received in the
threads of the bolt receiving apertures 256. This arrangement is shown in
cross-section in Figure 24.
Tightening of the bolts 260 causes the outer rim of the bearing
member 216, which acts as an annular outer bearing surface, to bear
upwardly against the inner face 238 of the shoulder 222 of the first member
212.
The swivelling joint 210 is thus moveable between two
configurations: a first configuration in which the bolts 260 are tight, and a
second configuration in which the bolts 260 are loose.
In the first configuration the bearing surface of the bearing member
216 is held tightly against the bearing surface of the first member 212. The
resulting friction prevents relative rotation of the bearing member 216 and
the first member 212, and thus prevents relative rotation of the first member
212 and the second member 214.
In the second configuration the action of the bearing member 216
against the shoulder 222 prevents the separation of the first member 212
from the second member 214. The absence of pressure – and significant
friction – between the bearing member 216 and the shoulder 222 allows free
rotation of the bearing member 216 and thus the second member 214
relative to the first member 212. The swivelling joint can therefore act in a
similar fashion to the Swivelpole joint of PCT publication number
WO0125687.
It will be appreciated that the interplay between the cylindrical
projection 234 of the first member 212 and the circular recess of the second
member 214 not only provides a ‘track’ about which rotation can occur, but
also acts as a water impeding ring to prevent the ingress of water into the
hollow body portion of the first member 212. The bolts 260 are all located
radially internally of this water impeding ring, and therefore are kept
relatively free from water and other contaminants.
The angling of the bolts 260 at 22.5° to a central axis of the
swivelling joints 210, and the matching use of angled and frusto conical
surfaces, assists in locating the bolts 260 as far away from the central axis
as possible, while keeping the bolts 260 within the water impeding ring. This
assists both in force distribution and in ease of operation of the bolts 260. It
will noted, however, that this angling is not essential to the operation of the
invention, and although an angle of 22.5° is considered the easiest for
manufacturing purposes it is by no means the only useful angle at which the
bolts 260 can be inclined. Similarly, although the bolt 260 acts through
surfaces generally perpendicular to it, this is not essential to the operation of
the invention.
The swivelling joint 210 includes a secondary locking means, to
enable the swivelling joint 210 to be secured in a desired rotational position
during tightening or loosening of the bolts 260. This secondary locking
means is formed by the use of a secondary locking pin 280 within aligned
secondary apertures 284 of the second member 214 and recesses 244 of
the first member 212.
The secondary apertures 284 of the second member 214 are located
near a periphery of the second member 214; that is, within the skirt 248 and
therefore outside of the water impeding ring.
The recesses 244 of the first member 212 are formed as axially
aligned recesses extending inwardly from the outer periphery of the side wall
230 of the first member 212.
In the embodiment shown the secondary locking pin 280 is U-
shaped, with one arm of the pin 280 secured within a pin holding aperture
286 adjacent a secondary aperture 284 of the second member 214.
When the second member 214 is in a desired rotational position
relative to the first member 212, at least one secondary aperture 284 of the
second member 214 will be aligned with a recess 244 of the first member
212. The secondary locking pin 280 can be located within the aligned
secondary aperture 284 and recess 244 to maintain the swivelling joint 210
in this desired position.
It will be appreciated that the secondary apertures 284 and recesses
244 are designed to be free-draining, so that any water or other
contaminants can readily drain away.
Modifications and variations as would be apparent to a skilled
addressee are deemed to be within the scope of the present invention.
Claims (47)
1. A swivelling joint including a first member, a second member, and at least one bearing member; the first member being associated with a first leg, the first leg having a longitudinal direction, the first member having an annular base which is oriented at an acute angle relative to the longitudinal direction of the first leg, the base having an outer periphery; the second member being associated with a second leg, the second leg having a longitudinal direction, the second member including an outer wall arranged to locate around the annular base of the first member to define an exterior surface of the swivelling joint; the first member having a bearing surface located internally of the exterior surface of the swivelling joint; the bearing member being connected to the second member by an adjustable connection means; the bearing member locating within the outer wall of the second member, with the bearing surface of the bearing member being opposed to the bearing surface of the first member; the adjustable connection means permitting relative movement of the bearing member and the second member between: a first configuration, wherein the bearing surface of the bearing member and the bearing surface of the first member are in frictional engagement restricting rotational movement of the first member relative to the second member, and a second configuration, wherein rotation of the second member relative to the first member is permitted.
2. A swivelling joint including a first member, a second member, and at least one bearing member; the first member being associated with a first leg, the first leg having a longitudinal direction, the first member having an annular base which is oriented at an acute angle relative to the longitudinal direction of the first leg, the base having an outer periphery; the second member being associated with a second leg, the second leg having a longitudinal direction, the second member including an outer wall arranged to locate around the annular base of the first member to define an exterior surface of the swivelling joint; the second member having a bearing surface located internally of the exterior surface of the swivelling joint; the bearing member being connected to the first member by an adjustable connection means; the bearing member locating within the outer wall of the second member, with the bearing surface of the bearing member being opposed to the bearing surface of the second member; the adjustable connection means permitting relative movement of the bearing member and the first member between: a first configuration, wherein the bearing surface of the bearing member and the bearing surface of the second member are in frictional engagement restricting rotational movement of the first member relative to the second member, and a second configuration, wherein rotation of the second member relative to the first member is permitted.
3. A swivelling joint including a first member, a second member, and at least one bearing member; the first member being associated with a first leg, the first leg having a longitudinal direction, the first member having an annular base, the base having an outer periphery, the outer periphery being located in a plane, the plane being perpendicular to an operating axis, the operating axis being angled with respect to the longitudinal axis of the first leg at an offset angle; the second member being associated with a second leg, the second leg having a longitudinal direction, the second member including an outer wall arranged to locate around the annular base of the first member to define an exterior surface of the swivelling joint; the first member having a bearing surface located internally of the exterior surface of the swivelling joint; the bearing member being connected to the second member by an adjustable connection means; the bearing member locating within the outer wall of the second member, with the bearing surface of the bearing member being opposed to the bearing surface of the first member; the adjustable connection means permitting relative movement of the bearing member and the first member between: a first configuration, wherein the bearing surface of the bearing member and the bearing surface of the first member are in frictional engagement restricting rotational movement of the first member relative to the second member, and a second configuration, wherein rotation of the second member relative to the first member is permitted.
4. A swivelling joint as claimed in any preceding claim, wherein the outer wall of the second member and the periphery of the annular base of the first member combine to define a circular track about which the second member can rotate relative to the first member when in the second configuration.
5. A swivelling joint as claimed in claim 1 or claim 3, wherein the bearing surface of the first member is annular.
6. A swivelling joint as claimed in claim 5, wherein the bearing surface of the first member is formed by an annular groove.
7. A swivelling joint as claimed in claim 2, wherein the bearing surface of the first member is annular.
8. A swivelling joint as claimed in claim 7, wherein the bearing surface of the first member is formed by an annular groove.
9. A swivelling joint as claimed in claim 6 or claim 8, wherein the annular groove is formed from three surfaces: a cylindrical centre surface and two frusto conical outer surfaces.
10. A swivelling joint as claimed in any preceding claim, wherein the adjustable connection means includes a threaded bolt, such that threaded movement of the bolt causes movement between first and second configurations.
11. A swivelling joint as claimed in claim 10, wherein the bolt is generally tangential to the annular base.
12. A swivelling joint as claimed in claim 10, wherein the bolt is generally radial relative to the annular base.
13. A swivelling joint as claimed in claim 10, wherein the bolt is axial to the annular base, or offset relative to an axial direction.
14. A swivelling joint as claimed in any one of claims 10 to 13, wherein the bearing member includes an internally threaded body portion arranged to engage with threads on the bolt.
15. A swivelling joint as claimed in claim 14, wherein the body portion is integral with an engaging portion of the bearing member, the engaging portion including the bearing surface.
16. A swivelling joint as claimed in claim 15, wherein the bearing member includes two engaging members, each of which have a body portion and an engaging portion.
17. A swivelling joint as claimed in claim 16, wherein the body portion of only one engaging member is internally threaded.
18. A swivelling joint as claimed in claim 16 or claim 17, wherein the two engaging members are separated by a resilient biasing means.
19. A swivelling joint as claimed in claim 18, wherein the resilient biasing means acts to bias the engaging members away from each other.
20. A swivelling joint as claimed in claim 14 or claim 15, wherein the bearing member is arranged to pivot between the first configuration and the second configuration.
21. A swivelling joint including a first member, a second member, and a bearing member; the first member being associated with a first leg, the first leg having a longitudinal direction, the first member having a hollow body portion, the first member having a bearing surface which is oriented at an acute angle relative to the longitudinal direction of the first leg, the bearing surface facing towards the hollow body portion; the second member being associated with a second leg, the second leg having a longitudinal direction; the bearing member being connected to the second member by an adjustable connection means, the bearing member having a bearing surface which is oriented at an acute angle relative to the longitudinal direction of the first leg; the bearing member locating within the hollow body portion of the first member, with the bearing surface of the bearing member being opposed to the bearing surface of the first member; the adjustable connection means permitting relative movement of the bearing member and the second member between: a first configuration, wherein the bearing surface of the bearing member and the bearing surface of the first member are in frictional engagement restricting rotational movement of the first member relative to the second member, and a second configuration, wherein rotation of the second member relative to the first member is permitted.
22. A swivelling joint as claimed in claim 21, wherein the bearing surface of the first member is annular.
23. A swivelling joint as claimed in claim 22, wherein the bearing surface of the first member is formed as an annular shoulder at an outer edge of the hollow body portion.
24. A swivelling joint as claimed in any one of claims 21 to 23, wherein the bearing member is annular.
25. A swivelling joint as claimed in claim 24, wherein the bearing surface of the bearing member is an outer annular ring of the bearing member.
26. A swivelling joint as claimed in claim 25, wherein the bearing member includes connection means receiving apertures located internally of the outer annular ring.
27. A swivelling joint as claimed in claim 26, wherein the connection means receiving apertures are internally threaded.
28. A swivelling joint as claimed in claim 27, wherein the connection means is formed by a plurality of externally threaded bolts arranged to be received within the receiving apertures.
29. A swivelling joint as claimed in claim 28, wherein the bolts are angularly spaced around the swivelling joint.
30. A swivelling joint as claimed in claim 28 or claim 29, wherein the bolts are perpendicular to the bearing surfaces.
31. A swivelling joint as claimed in any one of claim 28 to 30, wherein the bolts are off-set by an acute angle relative to a central axis of the swivelling joint.
32. A swivelling joint as claimed in claim 31, wherein the acute angle is between 15° and 30°
33. A swivelling joint as claimed in claim 32, wherein the acute angle is around 22.5°.
34. A swivelling joint as claimed in any one of claims 31 to 33, wherein the bearing member includes an annular connection means receiving portion having a face which is frusto conical.
35. A swivelling joint as claimed in any one of claims 21 to 34, wherein one of the first member and the second members has a circular recess, and the other of the first member and the second member has a circular projection arranged to locate within the circular recess, the outer diameter of the circular projection defining a water impeding ring, and the adjustable connection means passes within the water impeding ring.
36. A swivelling joint as claimed in any preceding claim, wherein the swivelling joint includes secondary apertures in the first member and the second member, arranged to receive a secondary locking pin.
37. A swivelling joint as claimed in claim 36, wherein the secondary apertures are formed as recesses extending inwardly from an outer periphery in at least one of the first and second members.
38. A swivelling joint including a first member, a second member, and a bearing member; the first member being associated with a longitudinally extending first leg, the first leg having a longitudinal direction, the first member having a hollow body portion, the first member having a bearing surface which is oriented at an acute angle relative to the longitudinal direction of the first leg, the bearing surface facing towards the first leg; the second member being associated with a longitudinally extending second leg, the second leg having a longitudinal direction; the first member and the second member being arranged to meet along a connection annulus, the bearing member being connected to the second member by an adjustable connection means, the bearing member having a bearing surface which is oriented at an acute angle relative to the longitudinal direction of the first leg; the bearing member locating inside the connection annulus, with the bearing surface of the bearing member being opposed to the bearing surface of the first member; the adjustable connection means permitting relative movement of the bearing member and the second member between: a first configuration, wherein the bearing surface of the bearing member and the bearing surface of the first member are in frictional engagement restricting relative movement of the first member and the second member, and a second configuration, wherein rotation of the second member relative to the first member is permitted.
39. A swivelling joint as claimed in any preceding claim, wherein the joint can be rotated into a main orientation wherein the longitudinal axes of the first and second legs are parallel.
40. A swivelling joint as claimed in claim 39, wherein in the main orientation a void is defined around a central axis of the joint.
41. A swivelling joint as claimed in any preceding claim, wherein rotation of the first member relative to the second member occurs about an axis of rotation which is disposed at an acute angle relative to the longitudinal axis of the first leg.
42. A swivelling joint as claimed in claim 41, wherein the acute angle is between 30° and 60°.
43. A swivelling joint as claimed in claim 42, wherein the acute angle is about 45°.
44. A swivelling joint as claimed in any preceding claim when deployed in an elongate member for locating articles remote from a base position.
45. A swivelling joint as claimed in claim 44 wherein the elongate member has a length of at least 1.5m
46. A swivelling joint as claimed in claim 45, wherein the elongate member has a length of at least 2m.
47. A swivelling joint as claimed in any preceding claim, wherein the elongate member is a light pole.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
AU2013904795 | 2013-12-10 | ||
AU2013904795A AU2013904795A0 (en) | 2013-12-10 | A Swivelling joint | |
PCT/AU2014/050412 WO2015085366A1 (en) | 2013-12-10 | 2014-12-10 | A swivelling joint |
Publications (2)
Publication Number | Publication Date |
---|---|
NZ721895A NZ721895A (en) | 2020-09-25 |
NZ721895B2 true NZ721895B2 (en) | 2021-01-06 |
Family
ID=
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