The present invention relates to a beam clamp for attachment to a flange of a structural building member and from which to support or brace a service component. The present invention also relates to a mounting assembly for attachment to a flange of a structural building member and from which to support or brace a service component.
It is known to attach service components to structural building members, such that the service component is supported by, or braced from the structural building member. Further, it is known to secure a beam clamp to a flange of the structural member, the beam clamp then providing an attachment point for use in supporting/bracing the service component.
For example, fluid distribution pipes can be supported by a joist or beam by attaching a beam clamp to a flange of the beam (or joist, purlin, etc.), and attaching the pipe to a ring (or a hanger, clamp, etc.), and securing a threaded rod (or wire rope, etc.) between the clamp and ring. In this way, a service component can be supported and/or braced, without the need to alter the structural member. The forces carried by the beam clamp can be static (for example, the mass of the service component, including any material conveyed within the service component, where appropriate), and/or dynamic (for example, forces induced by movement of the service component and/or structural building member).
Multiple beam clamps are commonly used to provide multiple connections of the service component to the structural member, and/or to multiple structural members. In this way, the load of the service component is distributed between multiple beam clamps, along the structural member, and/or across multiple structural members.
Each beam clamp will have a load rating to limit the likelihood of the beam clamp failing in service. As will be appreciated, the load rating of beam clamps is inversely proportional to the number of beam clamps required to support/brace a nominal service component. Further, the load rating of beam clamps is inversely proportional to the supply and installation cost. Thus, there is increased cost in supply and installation of beam clamps with low load ratings.
Common failure modes of beam clamps include deformation of the clamp body (caused by the load supported by the beam clamp exceeding the yield strength of the clamp body material), improper or inappropriate installation, and the beam clamp slipping from the flange of the structural member.
There is a need to address the above, and/or at least provide a useful alternative.
There is provided a beam clamp for attachment to a flange of a structural building member and from which to support or brace a service component, the beam clamp comprising:
a clamp body that includes:
whereby, in use of the clamp, the flange is secured within transverse opening between the tip of the at least one set screw and the contact surface.
In at least some embodiments, the surface irregularities are in the form of one or more sets of alternating ridges and furrows that are formed in the contact surface.
The ridges and furrows can be substantially parallel to one another. In some preferred embodiments, the ridges and furrows are formed so as to be substantially transverse to the direction of insertion of the flange into the transverse opening.
The entire contact surface can be provided with the surface irregularities. Alternatively or additionally, the at least one second jaw section has a pair of lateral faces and the contact surface forms vertices with the lateral faces, and wherein the surface irregularities extend the width of the contact surface between the vertices.
Preferably, the average amplitude of the surface irregularities is less than 1 mm (millimetre). More preferably, the average amplitude of the surface irregularities is between 2 μm (micrometre) and 100 μm.
In some embodiments, the ridges and furrows formed in the contact surface are substantially linear, and also parallel. In some alternative embodiments, the ridges and furrows may be non-parallel. In certain alternative embodiments, the ridges and furrows may be arcuate. Alternatively or additionally, the ridges and furrows can be concentric circular sectors.
Preferably, the ratio of the width of the second jaw section between the pair of lateral faces to the minimum separation of the first and second jaw sections is at least 1.25:1.
Preferably, the ratio of the depth of the second jaw section to the minimum separation of the first and second jaw sections is at least 1.5:1.
In some embodiments, the surface irregularities are created by a cutting tool that is used to form the transverse opening in the clamp body.
Preferably, the clamp body is made of a hardened steel. Alternatively or additionally, the clamp body is made of a material that has a minimum hardness of 150 BHN. Preferably, the clamp body is made of a material that has a minimum hardness of 170 BHN. More preferably, the clamp body is made of a material that has a minimum hardness of at least 200 BHN. In some embodiments, the clamp body is made of a material that has a hardness of approximately 235 BHN.
In at least some embodiments, at least a portion of the first and/or second jaw sections are tapered such that the thickness of the portion of the respective jaw section reduces in a direction away from the joining section.
In some embodiments, the second jaw section is tapered along its length such that the thickness of the second jaw section tapers in a direction away from the joining section.
In some embodiments, the first jaw section has an outer portion that is on the opposing side of the at least one mounting through hole to the joining section, and the outer portion has a thickness tapers in a direction away from the joining section. Preferably, the first jaw section has a central portion that defines the at least one mounting hole and an inner portion that is between the central portion and the joining section, and the inner and central portions have a substantially constant thickness.
In certain embodiments, the set screw has a shank with a waisted formation that acts as a stress concentrator such that the shank shears within the waisted formation when a predetermined torque is applied to the shank.
Preferably, the narrowest diameter of the waisted portion is less than the minor diameter of the external thread on the shank.
Preferably, the waisted formation is adjacent the head of the set screw. Alternatively or additionally, the waisted formation is between the head of the set screw and the externally threaded portion of the shank.
In some embodiments, the waisted formation has a one-sheet hyperboloid shape. In some alternative embodiments, the waisted formation has a first portion that is a convergent conical frustum, and a second portion that is a divergent conical frustum.
Preferably, the set screw has a tip with an end face with a surface area that is less than the cross sectional area of the shank of the set screw, the cross sectional area being in a plane that is transverse to the longitudinal direction of the shank.
Alternatively or additionally the set screw tip tapers in a direction away from the head of the screw. Preferably, the set screw tip tapers to a point. In some alternative embodiments, the set screw tip is at least partially domed shaped. In some further alternative embodiments, the set screw tip has a concave formation in the tip, such that the end of the tip defines an annulus.
The set screw tip can have an engagement surface that is formed with surface irregularities providing a roughness that enhances engagement of the set screw with the flange.
Preferably, the set screw is made of hardened steel. Alternatively or additionally, the set screw is made of a material that has a minimum hardness of 150 BHN. Preferably, the set screw is made of a material that has a minimum hardness of 170 BHN. More preferably, the set screw is made of a material that has a minimum hardness of at least 200 BHN. In some embodiments, the set screw is made of a material that has a hardness of approximately 235 BHN.
In at least some embodiments, the beam clamp further comprises a locking nut that is to locate on a portion of the shank of the set screw that projects from the first jaw section away from the transverse opening, wherein the service component is supported or braced by a component that includes an eyelet that, in use of the beam clamp, is captured between the locking nut and the clamp body.
Alternatively or additionally, the clamp body can include one or more mounting points, the service component is supported or braced by an attachment component that mounts to at least one of the mounting points, wherein the service component is attached to the beam clamp by the attachment component.
In some embodiments, the mounting points include any one or more of:
a secondary mounting hole for receiving the attachment component,
an internally threaded secondary mounting hole for engagement with an external thread of the attachment component,
an aperture that extends through the clamp body through which to pass an elongate portion of the attachment component,
a capturing formation that is formed in the clamp body, the capturing formation being shaped to receive a ferrule formation on the attachment component, and
a channel in the clamp body that extends between two co-planar faces of the clamp body, wherein the attachment component includes a elongate first connecting portion that is to be installed in the channel, and at least one second connecting portion that interconnects with the elongate first connecting portion, wherein the first and second connecting portions are interconnected when the first connecting portion is in the channel in a manner that places the first connecting portion in tension so as to resist removal of the first elongate connecting element from the channel, and wherein the service component can be supported or braced by the first elongate connecting element.
In embodiments in which the mounting points include an internally threaded secondary mounting hole, the internally threaded secondary mounting hole can be a blind hole.
Alternatively, the beam clamp installed on the flange forms a throughway within a part of the transverse opening, the throughway being bounded by the flange, the clamp body and the set screw, and wherein the service component can be supported or braced by a wire rope that is looped through the throughway.
In embodiments in which the mounting points include one or more channels that each extend between two opposing faces, each opposing face is preferably each part of a recessed formation in the clamp body that receives a portion of the first or second connection portion, whereby the recessed formations resists lateral movement of the elongate first connecting portion outwardly of the channel.
There is also provided a beam clamp for attachment to a flange of a structural building member and from which to support or brace a service component, the beam clamp comprising:
a clamp body that includes:
a set screw that is to be installed in the mounting through hole, the set screw having a shank with a waisted formation that acts as a stress concentrator such that the shank shears within the waisted formation when a predetermined torque is applied to the shank,
whereby, in use of the clamp, the flange is secured within transverse opening between the tip of the at least one set screw and the contact surface.
Preferably, the narrowest diameter of the waisted portion is less than the minor diameter of the external thread on the shank.
Preferably, the waisted formation is adjacent the head of the set screw.
In some embodiments, the waisted formation has a one-sheet hyperboloid shape. In some alternative embodiments, the waisted formation has a first portion that is a convergent conical frustum, and a second portion that is a divergent conical frustum.
Preferably, the set screw has a tip with an end face with a surface area that is less than the cross sectional area of the shank of the set screw, the cross sectional area being in a plane that is transverse to the longitudinal direction of the shank.
Alternatively or additionally, the set screw tip tapers in a direction away from the head of the screw. Preferably, the set screw tip tapers to a point. In some alternative embodiments, the set screw tip is at least partially domed shaped. In some further alternative embodiments, the set screw tip has a concave formation in the tip, such that the end of the tip defines an annulus.
The set screw tip can have an engagement surface that is formed with surface irregularities providing a roughness that enhances engagement of the set screw with the flange.
Preferably, the set screw is made of hardened steel. Alternatively or additionally, the set screw is made of a material that has a minimum hardness of 150 BHN. Preferably, the set screw is made of a material that has a minimum hardness of 170 BHN. More preferably, the set screw is made of a material that has a minimum hardness of at least 200 BHN. In some embodiments, the set screw is made of a material that has a hardness of approximately 235 BHN.
In at least some embodiments, the beam clamp further comprises a locking nut that is to locate on a portion of the shank of the set screw that projects from the first jaw section away from the transverse opening, wherein the service component is supported by a component that includes an eyelet that, in use of the beam clamp, is captured between the locking nut and the clamp body.
The clamp body can include one or more secondary mounting holes for receiving an externally threaded component, wherein the service component is attached to the beam clamp by the externally threaded component.
Alternatively, the beam clamp installed on the flange forms a throughway within a part of the transverse opening, the throughway being bounded by the flange, the clamp body and the set screw, and wherein the service component can be supported or braced by a wire rope that is looped through the throughway.
There is also provided a mounting assembly for attachment to a flange of a structural building member and from which to support or brace a service component, the mounting assembly comprising:
a plurality of clamping members that each have:
an interconnecting member that is configured to interconnect with the clamping members, and that includes one or more mounting points from which to mount an attachment component,
whereby, in use of the mounting assembly:
In some embodiments, the interconnecting member is a connecting plate that has a plurality of primary apertures, and the mounting assembly further comprises a plurality of fasteners,
whereby, in use of the mounting assembly the connecting plate is mounted adjacent the clamping members with the shanks of the set screws extending through the primary apertures, and with the fasteners securing the connecting plate to the clamping members.
In some embodiments:
In some alternative embodiments:
In at least some preferred embodiments, the mounting assembly has four clamping members, and the connecting plate has four primary apertures, and the centres of the apertures are positioned at the vertices of a notional quadrilateral. In such embodiments, the structural member can be an I-beam, and the mounting assembly is mountable on one of the two flanges of the I-beam.
In some embodiments, the interconnecting member includes an elongate member that extends through throughways formed in the clamp bodies.
The clamp body of each clamping member can have any one or more of the features, characteristics and/or properties in accordance with clamp body of the beam clamp as described herein.
Alternatively or additionally, the set screws of each clamping member can have any one or more of the features, characteristics and/or properties in accordance with set screw of the beam clamp as described herein.
In order that the invention may be more easily understood, embodiments will now be described, by way of example only, with reference to the accompanying drawings, in which:
a: is an enlarged view of Region C in
The beam clamp 10 includes a clamp body 12 and a set screw 14. As particularly shown in
A transverse opening 24 is defined by the first and second jaw sections 16, 20 and the joining section 22. In use of the beam clamp 10, the flange of the structural component is located within the transverse opening 24. Further, in use of the beam clamp 10, the set screw 14 is installed in the mounting through hole 18, which extends through the first jaw section 16. As shown in
When the beam clamp 10 is installed on the flange F, the surface irregularities on the contact surface 26 can create a mechanical interference between the second jaw section 20 and the flange F that inhibits movement of the clamp body 12 relative to the flange F.
In at least some embodiments, the clamp body 12 is made of a material that is selected to have a hardness that exceeds the hardness of the structural member. In this way, with a sufficiently high pressure against the opposing surfaces of the flange F, the contact surface 26 deforms the material of the structural member, which enhances engagement of the clamp body 12 with the flange F. This provides the beneficial effect of decreasing the likelihood of the beam clamp 10 slipping from the flange F in service.
By way of example only, the beam clamp 10 can be intended for use with structural members made of medium strength structural steel with a nominal yield strength of 300 MPa, and a typical hardness in the range of 130 to 170 BHN. In such an example, the clamp body 12 may be made of a steel with a nominal hardness of 235 BHN, and with a guaranteed minimum of 200 BHN.
By virtue of the surface irregularities, the total surface area of the contact surface 20 on the second jaw section 20 is greater than the planar surface area defined by the peripheral edges of the contact surface 20.
As shown in
As shown in
In the illustrated example, the ridges and furrows of the contact surface 26 are substantially linear, and also parallel.
In this particular example, the ratio of the width D3 of the second jaw section 20 (between the pair of lateral faces 28, 30) to the minimum separation DI of the first and second jaw sections 16, 20 (that is; D3:D1) is approximately 1.33:1. The ratio of the depth D2 of the second jaw section 20 to the minimum separation DI of the first and second jaw sections 16, 20 (that is; D2:D1) is approximately 1.6:1.
Preferably, the average amplitude of the surface irregularities is less than 1 mm (millimetre). More preferably, the average amplitude of the surface irregularities is between 2 μm (micrometre) and 100 μm. For the purposes of this specification, the amplitude of the surface irregularities will be understood to me the geometric separation of adjacent peak and trough formations of the surface irregularities, measured in a direction that is orthogonal to a common plane of the contact surface 26. It will be appreciated that there may be variation in the amplitude of the surface irregularities.
In this embodiment, the surface irregularities are created by a cutting tool that is used to form the transverse opening 24 in the clamp body 12.
As shown most clearly in
In the example of
The waisted formation 42 is shaped so as to have a first portion that is a convergent conical frustum, and a second portion that is a divergent conical frustum. The tip 40 of the set screw 14 tapers so as to narrow in a direction away from the head 38 of the set screw to a point. Accordingly, the taper of the tip 40 is also in a direction away from the waisted formation 42.
The beam clamp 10 includes a locking nut 44 and washer 46 that locate on the shank 36, externally of the transverse opening 24. In the example of
In the example illustrated in
perpendicular to the contact surface 26 and extend in a direction that is generally away from the transverse opening 24,
in a plane that is parallel to the contact surface 24, or
at any angle therebetween.
Further, in some instances the beam clamp can be used for supporting/bracing loads that are applied in directions that are upward with respect to the first jaw section 16.
As indicated in
As indicated in
As indicated in
As indicated in
As indicated in
As will be appreciated, the beam clamp 10 when installed by either the first or second described method can have the advantage of enabling the eyelet Y to be removed and replaced/reinstalled without interfering with clamping force of the clamping body 12 and set screw 14 on the flange F.
A transverse opening 324 is defined by the first and second jaw sections 316, 320 and the joining section 322. In use of a beam clamp that includes the clamp body 312, the flange of the structural component is located within the transverse opening 324. Further, in use of the beam clamp 310, the set screw 14 is installed in the mounting through hole 318, which extends through the first jaw section 316.
In this embodiment, the clamp body 312 includes a mounting point, which in this embodiment is in the form of a secondary mounting hole 350 for receiving an externally threaded component. In this particular example, the secondary mounting hole 350 is a blind hole that is formed in the joining section 322. The service component is attached to the beam clamp by the externally threaded component. As will be appreciated, in this example, the externally threaded component can be a screw, or may be a threaded rod.
In the embodiments illustrated in
The surface irregularities formed on the contact surface 26a of the clamp body 12a illustrated in
The surface irregularities formed on the contact surface 26b of the clamp body 12b illustrated in
The surface irregularities formed on the contact surface 26c of the clamp body 12c illustrated in
The surface irregularities formed on the contact surface 26d of the clamp body 12d illustrated in
The clamp body 12e shown in
In the clamp body 12e, the three mounting through holes 18e are arranged in the first jaw section 16e such that the centres of the holes 18e are arranged linearly.
The clamp body 12f shown in
With respect to the claim bodies 12e, 12f shown in
The clamp body 12g shown in
The clamp body 12g additionally includes a mounting point, which in this embodiment is in the form of an internally threaded through hole 23 that extends through the joining section 22g. The hole 23 is able to receive a component with an external threaded. Accordingly, the hole 23 provides an additional mounting point for use in a securing and/or bracing function for a service component.
The clamp body 12h shown in
The set screw 14a illustrated in
The set screw 14b illustrated in
The set screw 14c illustrated in
In one further variant of the set screw, the tip can include an annular concave formation, with a central conical formation and an annular ring surrounding the annular concave formation. The annular ring can taper in a direction away from the head of the set screw. Alternatively or additionally, the leading end of the central conical formation can project longitudinally beyond the leading edge of the annular ring.
Embodiments may incorporate one or more set screws that have different tip forms and/or features from those illustrated. By way of example, set screws may have features that combine features of set screws illustrated herein.
The clamp body 412 includes a mounting point, which in this embodiment is in the form of a capturing formation 450 that is formed in the joining section 422. As illustrated in
The capturing formation 450 includes a slot 452 that opens onto the external surface of the joining section 422 of the clamp body 214, and an insertion opening 454 that opens onto the transverse opening 424. The insertion opening 454 is dimensioned so as to be larger than the width of the slot 452. In this way, a stepped shoulder is formed internally within the joining section 422 and the intersection of the insertion aperture 454 with the slot 452.
In addition, the insertion opening 454 is dimensioned so as to be larger than the diameter of the ferrule formation U. Thus, the wire rope R can pass through both the insertion opening 454 and the slot 452. The ferrule formation U can pass through the insertion opening 454 but is obstructed by the stepped shoulder from entering the slot 452. Accordingly, the capturing formation 450 captures the ferrule formation U, such that the end of the wire rope
R is retained within the clamping body 412.
In this example, the slot 452 is elongate, which enables the wire rope R to extend from the clamping body 412 at a range of angles. It will be appreciated that in some alternative embodiments, the slot 452 could be substituted with a circular hole that intersects the insertion hole 454. Similarly, the insertion opening 454 can be circular, or an elongate slot.
The beam clamp 510 of this embodiment is particularly suitable for mounting on a flange F of a structural member such as an I-beam (as illustrated in
The beam clamp 510 also has a load support, which in this particular example includes a hooking member 502. At one end of the hooking member 502 is a hole through which the shank 536 of the set screw 514 extends, and the hooking member 502 is captured between the washer and locking nut pair 544, 546 and the clamp body 512. In this way, the hooking member 502 is connected to the clamp body 512. At the opposing end, the hooking member 502 includes a hook portion 504 that hooks around opposing edge of the flange F.
In the illustrated embodiment, the load support includes, and an optional fastener 503. The fastener 503 extends through another hole in the hooking member 502 that is adjacent hook portion 504. The opposing edge of the flange F is captured between the end of the hook portion 504 and the fastener 503.
Loads applied to the beam clamp 510 are distributed between the clamp body 512 and the hooking member 502. As will be appreciated, the direction of the applied load will dictate the manner in which the load is distributed.
The clamp body 612 has two mounting through holes 618 in the first jaw section 616, and two mounting holes 619 in the second jaw section 620. Further, the first jaw section 618 includes a contact surface 27 that is substantially similar in form and function to the contact surface on the second jaw section 620.
The clamp body 612 has three mounting points. Two of the mounting points are in the form of internally threaded through holes 623 that both extend through the joining section 622.
The third mounting point is located between the two through holes 623. In this example, the third mounting point is a channel 660 in the joining section 622. The clamp body 612 has two opposing faces between which the channel 660 extends. In this particular embodiment, the clamp body 612 includes two recessed formations 661, one at each end of the channel 660. At the base of each recessed formation 661 is a C-shaped planar surface. The two C-shaped planar surfaces form the two opposing faces between which the channel 660 extends. As shown particularly in
As illustrated in
The mounting assembly 705 includes four clamping members 710, and an interconnecting member 756. As will be discerned from the Figures, each clamping member 710 is substantially similar to the beam clamp 10 shown in
The interconnecting member, which in this embodiment is in the form of a plate 756, interconnects with the four clamping members 710, and includes a mounting point 760 from which to mount an attachment component that, in service, is mounted to the mounting point and supports and/or braces the service component. In the illustrated example, the attachment component is a bolt 706 and eyelet nut 707 pair.
The mounting assembly 705 is secured to the flange F by securing each clamping member 710 to the flange F. This is done in the same manner in which the beam clamp 10 is attached to a flange F.
The plate 756 is configured to interconnect with the clamping members 710. In this example, the plate 756 has a set of four apertures 758, and the set screw 714 of each of the four clamping members 710 is passed through a respective aperture 758. Further, each set screw 714 is installed in the mounting through hole 718 of the corresponding clamp body 712.
Four locking nuts 744 and washers 746 are located on the shanks of the set screws 714, with the plate 756 between the locking nuts and washers 744, 746, and the clamp bodies 712. The locking nuts 744 are tightened to secure the plate 756 against the clamp bodies 712. Thus, the clamping members 710 are interconnected by the plate 756.
In this example, the mounting point 760 is a central aperture in the plate 756 through which the shank of the bolt 706 is passed. The eyelet nut 707 is threaded onto the shank of the bolt 706, and when so installed establishes the attachment component. A wire rope (or similar) to which the service component is attached can be passed through the eye of the eyelet nut 707.
The centres of the apertures 758 are positioned at the vertices of a notional quadrilateral. The mounting point 760 is positioned inwardly of the edges of that notional quadrilateral. In addition, the mounting point 760 is equidistant from each of the apertures 758, such that forces applied to the mounting assembly 705 via the mounting point 760 are substantially evenly dispersed between the clamping members 710.
The mounting assembly 805 includes two clamping members 810, and an interconnecting member. As will be discerned from the Figures, each clamping member 810 is substantially similar to the beam clamp 10 shown in
It will be noted that the clamp bodies 812 have minor differences in shape and configuration to the clamp body 12. These differences enable each clamp body 812 to have a throughway 870 that extends through the second jaw section 820.
The interconnecting member, which in this embodiment is in the form of a length of threaded rod 866 that engages with a pair of internally threaded eyelet nuts 868, interconnects with the two clamping members 810. Thus, the interconnecting member is supported by the clamping members 810. Each eyelet nut 868 provides a mounting point 860 from which to mount an attachment component that, in service, is mounted to the mounting point and supports and/or braces the service component.
The two clamping members 810 are installed in the manner of the beam clamp 10 as previously described. The threaded rod 866 is then passed through the throughways 870.
The minor differences in shape and configuration of the clamp bodies 812 compared with the clamp body 12 also enable each clamp body 812 to have a secondary throughway 872 that extends through the joining section 822. Each secondary throughway 872 is orthogonal to the respective throughway 870 in the second jaw section 820. As will be appreciated, the secondary throughways 872 can provide additional mounting points for the mounting assembly 805.
In this example, each throughway 870 has a diameter sufficient to provide clearance for the treaded rod 866. Further, each secondary throughway 872 can also have a diameter sufficient to provide clearance for the treaded rod 866.
In some alternative installations, the mounting assembly 805 can be installed with the two clamping members 810 secured to two spaced apart flanges of a common structural member (such as an I-beam), and the threaded rod 866 passed through the secondary throughways 872, and the eyelet nuts 868 engaged with the threaded rod 866. In this way, the threaded rod 866 and eyelet nuts 868 are supported by the clamping members 810, with the longitudinal direction of the threaded rod 866 being transverse to the longitudinal direction of the structural member, and transverse to the plane of the flanges.
In some alternative embodiments, the mounting assembly can use clamping members with a transverse through hole, in a manner similar to the clamping body 12h illustrated in
It will be appreciated that in some alternative embodiments and/or installations of mounting assemblies, the clamping members can be secured to opposing edges of a flange of a structural member, to a common edge of a flange of a structural member, two spaced apart flanges of a structural member (such that the interconnecting member is generally parallel with a web of the structural member), or to two flanges of separate and spaced apart structural members (such that the interconnecting member “bridges” those structural members).
It will be understood that in this specification and the claims which follow, the order of recitation of aspects of an installed component, device or assembly does not imply an order of installation or procedure.
Throughout this specification and the claims which follow, unless the context requires otherwise, the word “comprise”, and variations such as “comprises” and “comprising”, will be understood to imply the inclusion of a stated integer or step or group of integers or steps but not the exclusion of any other integer or step or group of integers or steps.
The reference in this specification to any prior publication (or information derived from it), or to any matter which is known, is not, and should not be taken as an acknowledgment or admission or any form of suggestion that that prior publication (or information derived from it) or known matter forms part of the common general knowledge in the field of endeavour to which this specification relates.
Number | Date | Country | Kind |
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2019902556 | Jul 2019 | AU | national |
Number | Date | Country | |
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Parent | 17627859 | Jan 2022 | US |
Child | 18738060 | US |