The present invention is directed towards a hinge mechanism and a hinge system. In some embodiments, the hinge mechanism and the hinge system may be used in operation on a swinging barrier, such as a gate or door etc.
It is beneficial in many applications to provide swinging barriers that close automatically—such as a gate in a pool, playground or preschool fence. To provide the desired force, the barrier may be supported by a hinge that exerts a closing bias. However, in some previous hinge designs the extent to which barrier may rotate in a self-closing manner may be limited by the biasing arrangement incorporated in the hinge.
Various forms of hydraulic closers have been previously proposed such as WO20120495518A1 and WO2015015443A1.
WO20120495518A1 discloses a 90° bi-directional closer with two pistons that operate on a common shaft. However, such design is complex and the shaft may be subjected high bending forces.
WO2015015443A1 discloses a single piston hydraulic closer.
Whilst the two patent documents disclose development in hydraulic closers, there has been a requirement to offer a more cost effective solution that minimises the number of complex parts, and still provide a robust solution for 180° hydraulic closers.
The above references to the background art do not constitute an admission that the art forms a part of the common general knowledge of a person of ordinary skill in the art. The above references are also not intended to limit the application of the method and system as disclosed herein.
According to a first aspect, a hinge mechanism is provided comprising first and second members rotatable relative to one another about a hinge axis from a first to a second position; and a biasing arrangement operative to adopt an active mode to bias the first and second members into at least one relative position and operative to adopt an inactive mode where the biasing arrangement does not provide bias to the first or second members to undergo relative rotation, wherein the biasing arrangement remains in the inactive mode on relative rotation of the first and second members through a first selected angular displacement between the first position and the second position, and is in the active mode on relative rotation of the first and second members through a second selected angular displacement between the first position and the second position.
According to a second aspect, there is provided a hinge mechanism comprising first and second members rotatable relative to one another about a hinge axis from a first to a second position, and a biasing arrangement operative in an active mode to bias the first and second members into at least one relative position, the biasing arrangement comprises a cam surface disposed on the first member and the second member includes a drive arrangement, the drive arrangement comprising a biasing device and a drive member which is biased into an extended position by the biasing device and movable from the extended position against the bias of the biasing device, the drive member including an engagement surface which is operative to contact the cam surface during relative rotation of the first and second members and, during at least one selected angular displacement between the first and second positions, the contact between the cam surface and the engagement surface causes the drive member to move from the extended position, wherein when the drive member is in the extended position the biasing arrangement is in an inactive mode such that it does not provide bias to the first or second members to undergo relative rotation, wherein the engagement surface is profiled to include a recess to accommodate at least a portion of a cam having the cam surface to allow rotation of the cam relative to the engagement surface without biasing the drive member from the extended position such that the biasing arrangement remains in the inactive mode on relative rotation of the first and second members through a first selected angular displacement and is in the active mode to bias the first and second members into at least one relative position through a second selected angular displacement.
According to a third aspect, there is provided a hinge system comprising first and second hinge mechanisms for a barrier, each hinge mechanism comprising first and second members rotatable relative to one another about a hinge axis, one of the first or second members of each hinge mechanism being connected to the barrier and the other being connected to a supporting structure such that the barrier can rotate about the hinge axis, the hinge mechanisms each including a biasing arrangement operative in an active mode to bias their respective first and second members into a least one relative position and at least the first hinge mechanism is operative to adopt an inactive mode, where it does not provide bias to the first or second members to undergo relative rotation, through a selected angular displacement of the first and second members about the hinge axis, wherein the first and second hinge mechanisms are configured such that on rotation of the barrier about the hinge axis from the first position to the second position, at least one of the hinges mechanisms remain active to bias the barrier to return to the first position and wherein through a particular angular displacement between the first position and the second position at least the first hinge mechanism remains inactive.
Embodiments of the present disclosure will now be described with reference with the accompanying figures in which:
In the following description, functionally similar parts carry the same reference numerals between different embodiments. The drawings are intended to be schematic, and dimensions, scale and/or angles may not be determined accurately from them unless otherwise stated.
Within the disclosure, unless otherwise stated, the term gate includes, for example, a movable barrier, hatch, gate, door, skylight or window, i.e. a member suitable for closing or opening an aperture, but not limited to the pivotal or direction of movement. For example, the member may pivot horizontally and/or vertically.
The hinge mechanism 10 has two hinge parts 12 and 14 which are rotatable relative to one another about a hinge axis A-A. In the illustrated embodiment, the one hinge part is in the form of a shaft 12 and the other hinge part is in the form of a housing 14. The shaft 12 and the housing 14 rotate relative to each other about the hinge axis A-A that extends longitudinally through the centre of the shaft 12.
The hinge 10 is designed to provide a bias to rotation of the shaft 12 within the housing 14. With reference to
The biasing arrangement 16 includes a cam 18 having a cam surface 20 which, in the illustrated form, forms part on the shaft 12, and the housing 14 includes a drive arrangement 22. In the illustrated embodiment, the drive arrangement 22 is mounted within the housing 14. In alternative embodiments, the drive arrangement may be mounted external the housing or mounted partially within the housing. The drive arrangement 22 as shown is in the form of a piston cylinder arrangement and includes a piston 24 that is disposed substantially perpendicular to the cam surface 20 (although it is to be appreciated that other orientations are possible). The drive arrangement 22 includes a biasing device 26 (in the form of a spring) and the piston 24 includes an engagement surface 28 at its distal end 30 that contacts the cam surface 20 during relative rotation of the shaft 12 and the housing 14.
The shaft 12 is shown in an enlarged perspective view
In general, the engagement surface 28 is arranged to be biased by the spring 26 into the cylindrical receptacle 34 so as to be able to contact the cam surface 20. However, the extent of the movement of the piston 24 towards the cam surface 20 is limited by engagement of a shoulder 40 of the piston 24 with a ledge 42 formed on the housing 14 (as shown in
As described above, the biasing arrangement 16 is arranged to operate in an active and an inactive mode. This is determined by the contact of the engagement surface 28 with the cam surface 20 and/or the relative position of the piston 24. In the illustrated embodiment, the engagement surface 28 is profiled to define a recessed portion 44. The recessed portion 44 may be formed between the engagement surface 28 and an internal wall of the cylinder 36. The recessed portion 44 which is shaped to receive the cam surface 20 when the shaft 12 is in a specific orientation and the piston 24 is in the extended position. Moreover, because of the recessed portion 44, the shaft 12 is able to freely rotate relative to the engagement surface 28 through an angular displacement α without the cam surface 20 contacting the engagement surface 28. In this way the biasing arrangement 16 remains inactive during that angular displacement α.
In the active mode, the piston 24 is moved from its extended position through contact of the engagement surface 28 with the cam surface 20 and the resulting biasing force applied to the cam surface 20 by the compression of the biasing device 26 is such that it induces a torsional force on the cam surface 20 to cause it to rotate. This occurs through a second angular displacement β of the shaft 12 relative to the housing 14. To create this torsional force, the point of loading being applied to the cam surface 20 by engagement with the engagement surface 28 needs to be offset from the hinge axis A-A. The operation of the biasing arrangement 16 in these active and inactive modes is best shown in relation to
Accordingly, the biasing arrangement 16 remains in the inactive mode on relative rotation of the shaft 12 and the housing 14 through the first selected angular displacement α between the first position to the intermediate position. The cam 18 is able to freely rotate in the inactive mode. Because of the shape of the cam surface 20 and the shape or profile of the engagement surface 28, the cam 18 is able to freely rotate during the first selected angular displacement α. The cam surface 20 and the engagement surface 28 may or may not be in contact when moving between the first position and the intermediate position and if the surfaces 20, 28 are in contact, there is no loading between the surfaces 20, 28. Once the shaft 12 and the housing 14 are in the intermediate position, the cam surface 20 and the engagement surface 28 are in contact. In some embodiments, the first selected angular displacement α may be greater than 10°, or less than 85°, and in some embodiments, may be in the range of about, 0 to 70°, 0 to 80°, 0 to 85°. In the illustrated embodiment, the first selected angular displacement is about 0 to 75°.
In an alternative embodiment the cam surface and the engagement surface may be a different shape entirely, for example, the cam surface may be in the form of a segment. In this alternative embodiment, the selected angular displacement in the inactive mode may be through a middle range of the 0 to 180° rotation, for example, the selection angular displacement may be anywhere in the range of about 40° to 130°. In a further embodiment, the engagement surface may be flat, and used in combination with a cam surface that has a small radius positioned towards the edge of the shaft circumference. Alternatively, the profile and/or cross section of the cam 18 may be reduced such that the area of the recessed portion 44 of the piston 24 may also be reduced accordingly, or vice versa. Further still, the hinge mechanism may also be inverted, the bias would be provided in the counter-clockwise direction rather than the clockwise direction as shown. In this alternative embodiment, the inactive mode would be through a selected angular displace of about 105° to 180°.
Whilst the above arrangement has the first and second positions angularly displaced by 180° it is to be appreciated that sweep of the hinge may be greater or less depending on design requirements.
A benefit of the hinge mechanism 10 as described above that can operate in an active and inactive mode is that it can be used in conjunction with similar type hinge mechanisms 100 (including a similar biasing arrangement but which does not allow for an inactive mode) so as to extend the sweep of the combined hinges to bias a barrier utilising the hinges into a specific position whilst maintaining a desired resistance loading on the gate (i.e. not providing too much force on the barrier at any one angular displacement). Such an arrangement is disclosed with reference to
The hinge mechanism 10 also includes a hydraulic damping system (as shown best in
During return rotation of the shaft 12 in relation to the housing 14 upon closing of the gate, the piston 24 is biased to the expanded position and the volume in the first chamber 46 increases. The fluid then travels from the second chamber 48 about the cam 18 back to the first chamber 46 through the second fluid channel 54.
In the illustrated embodiment, the second fluid channel 54 includes a flow restrictor 56 to adjust (e.g. to reduce) the rate of flow of the fluid from the second chamber 48 to the first chamber 46. However, in alternative embodiments, the size (e.g., cross-section) of the first and/or the second fluid channel 52, 54 may be adjusted to control (e.g., reduce) the rate of flow of the fluid through the channel(s) 52, 54.
The first hinge mechanism 10 is the same as the hinge mechanism 10 illustrated in
Each of the hinge members 12, 112 and 14, 114 have a respective bracket for fixing the members to the respective structure. The first member 12, 112 of each hinge mechanism 10, 100 is fixed to the gate frame 102 (moveable) and the second member 14, 114 of each hinge 10, 100 is typically fixed to the post frame 104 (supporting structure). In operation, each of the first 12, 112 and second 14, 114 members are mounted to the gate 102 and post 104 to cooperate to control the pivotal movement of the gate 102 about the hinge axis A-A during both opening and closing of the gate 102.
The top hinge mechanism 10 operates as discussed above in relation to
In
In
Simultaneously, in
In
During rotation from about 90° to 180°, the biasing arrangement 126 of the second hinge mechanism 100 has adopted a passive mode. In the passive mode, the piston 124 is moved from its extended position and the piston 124 imparts a force to the cam surface 120 that is substantially aligned with the hinge axis such that it does not induce a sufficient moment on the cam surface 120 to bias the first 112 and second 114 members into relative rotation. Simultaneously, the biasing arrangement 126 of the first hinge mechanism 10 is active from 90° to 180°.
Specific features of the torque profile shown by the combined hinge mechanisms 10, 100 are as follows:
According to one embodiment, there is provided a hinge mechanism comprising:
A hinge mechanism according to embodiment 1, wherein the biasing arrangement remains in the inactive mode on relative rotation of the first and second members through a first angular displacement from the first position to an intermediate position and becomes active to bias the first and second members to the intermediate position on continued relative rotation of the first and second members through a second angular displacement from the intermediate position towards the second position.
A hinge mechanism according to embodiment 1 or 2, wherein the biasing arrangement comprises a cam surface and a drive arrangement, the cam surface being disposed on the first member and the second member including the drive arrangement, the drive arrangement comprising a biasing device and a drive member which is biased into an extended position by the biasing device and movable from the extended position against the bias of the biasing device, the drive member including an engagement surface which is operative to contact the cam surface during relative rotation of the first and second members and, during at least one selected angular displacement between the first and second positions, the contact between the cam surface and the engagement surface causes the drive member to move from extended position,
wherein when the drive member is in the extended position the biasing arrangement is in an inactive mode such that it does not provide bias to the first or second members to undergo relative rotation.
A hinge mechanism according to embodiment 3, wherein, when in the active mode, the drive member is moved from its extended position and imparts a force to the cam surface that is offset from the hinge axis so as to induce a moment on the cam surface to bias the first and second members into relative rotation.
A hinge mechanism according to embodiment 3 or 4, wherein the engagement surface is profiled to include a recess to accommodate at least a portion of the cam to allow rotation of the cam relative to the engagement surface without biasing the drive member from the extended position during said first angular displacement of said first and second members.
A hinge mechanism according to any preceding embodiment, wherein the first member is in the form of a shaft and the second member is in the form of a housing, the shaft being disposed in the housing and rotatable relative thereto about the hinge axis.
A hinge mechanism according to any one of embodiments 3 to 6, wherein the drive arrangement is in the form of a piston cylinder arrangement, the piston forming the drive member and being movable within the cylinder along a piston axis which is arranged to be transverse to the hinge axis.
A hinge mechanism according to embodiment 7, wherein the biasing device is in the form of a compression spring disposed in the cylinder.
A hinge mechanism according to embodiment 7 or 8, wherein a stop arrangement is provided to prevent movement of the piston in the cylinder beyond the extended position.
A hinge mechanism according to embodiment 1, wherein when the biasing arrangement is in the inactive mode, a portion of the first member is received by a recess provided in the second member
A hinge mechanism according to any preceding embodiment, wherein the first angular displacement is less than 85°
A hinge mechanism according to embodiment 11, wherein the first angular displacement is in the range of about 0 to 75°.
A hinge mechanism according to any preceding embodiment, wherein the second angular displacement is greater than 70°.
A hinge mechanism according to embodiment 13, wherein the second angular displacement is in the range of about 75° to 180°.
According to another embodiment, there is provided a hinge mechanism comprising:
According to a further embodiment, there is provided a hinge system comprising:
A hinge system according to embodiment 16, wherein the second member of the first hinge mechanism comprises a recess for receiving a portion of the first member of the first hinge mechanism when the first hinge mechanism is in the inactive mode.
A hinge system according to embodiment 16 or 17, wherein the first and second hinge mechanisms are configured such that on rotation of the barrier about the hinge axis from a first position through a first angular displacement, the first hinge mechanism remains inactive whilst the second hinge mechanism is active to bias the barrier to return to the first position, whereas on continued rotation of the barrier through a second angular displacement, the first hinge mechanism is active to bias the barrier towards the first position.
A hinge mechanism according to any preceding embodiment, wherein the first angular displacement is less than 85°
A hinge mechanism according to embodiment 19, wherein the first angular displacement is in the range of about 0 to 75°.
A hinge mechanism according to any preceding embodiment, wherein the second angular displacement is greater than 70°.
A hinge mechanism according to embodiment 21, wherein the second angular displacement is in the range of about 75° to 180°.
A hinge system according to any one of embodiments 16 to 22 wherein the first hinge mechanism is as defined by any one of c embodiments 1 to 15.
In the claims which follow and in the preceding description, except where the context requires otherwise due to express language or necessary implication, the word “comprise” or variations such as “comprises” or “comprising” is used in an inclusive sense, i.e., to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments of the hinge mechanism and hinge system.
From the foregoing, it will be appreciated that various embodiments of the present disclosure have been described herein for purposes of illustration, and that various modifications may be made without departing from the scope and spirit of the present disclosure. Accordingly, the various embodiments disclosed herein are not intended to be limiting, with the true scope being indicated by the following claims.
Number | Date | Country | Kind |
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2016902515 | Jun 2016 | AU | national |
Filing Document | Filing Date | Country | Kind |
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PCT/AU2017/050655 | 6/27/2017 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/000029 | 1/4/2018 | WO | A |
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Number | Date | Country | |
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