KR20190052642A - Seismic clamp for non-structural components in a building - Google Patents

Abstract

An aseismic clamp for securing a utility pipe to a rigid rod includes a pipe holder that secures the utility pipe to the aseismic clamp. A rod fitting secures the rigid rod to the aseismic clamp so that the rigid rod extends transverse to the utility pipe. A spacer is disposed between the holder and the rod fitting. The spacer inhibits the rigid rod from contacting the utility pipe when the utility pipe is secured to the aseismic clamp, and the rigid rod is secured to the aseismic clamp.

Description

[0001] SEISMIC CLAMP FOR NON-STRUCTURAL COMPONENTS IN A BUILDING [0002]

The present invention relates generally to seismic clamps for non-structural components in buildings. This seismic clamp can be used, for example, as part of a seismic sway brace or restraint.

The earthquake-proof support system can be used to support non-structural components (e.g., pipes) within a building. These earthquake-resistant support systems include earthquake-resistant sway braces and restraints (e.g., branch line restraints). Seismic swath braces are used to minimize differential motion between non-structural components (eg, pipes) in the building and the building itself. Examples of non-structural components within a building include, but are not limited to, utility pipes, utility pipes, plastic pipes, conduits, round ducts, other pipe types, and the like. Properly installed swath braces limit damage to non-structural pipes by allowing buildings and non-structural pipes to move as a single unit in the event of an earthquake. The restraint fixes the non-structural component in place to a lesser extent than the earthquake swing brace. For example, the restraint itself prevents movement of the fire sprinkler branch line which may damage the structure or other non-structural systems nearby, such as air treatment ducts, piping or electrical systems. Building Code NFPA describes requirements for seismic swing braces and restraints. In addition to earthquake swing braces and restraints, other types of seismic support systems exist.

A conventional earthquake-resistant support system may include an earthquake-resistant clamp (e.g., a pipe clamp) attached to a bracing pipe or other bracing member. The earthquake-resistant clamp is attached to the non-structural pipe, and the bracing pipe is attached to a structural component (e.g., a beam) of the building.

In one aspect, an in-building braced utility assembly includes a utility pipe; A rigid rod; And a seismic clamp for securing the utility pipe to the rigid rod such that the rigid rod extends transversely to the utility pipe. The earthquake-resistant clamp includes a spacer disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe.

In another aspect, an in-building utility pipe bracing method generally includes securing the utility pipe to a seismic swab brace. The earthquake-resistant swivel brace includes a rigid rod and an earthquake-resistant clamp. The earthquake-resistant clamp fixes the utility pipe to the rigid rod. The rigid rods extend transversely to the utility pipe and the rigid rods and utility pipes do not contact each other when they are secured to the earthquake-resistant clamp.

In another aspect, an earthquake-resistant clamp for securing a utility pipe to a rigid rod generally includes a pipe holder configured to secure the utility pipe to the earthquake clamp so that the utility pipe extends in a first direction. The rod fitting is configured to fix the rigid rod to the seismic clamp so that the rigid rod extends in a second direction transverse to the first direction. A spacer is disposed between the pipe holder and the rod fitting. The spacer is configured to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the earthquake clamp and the rigid rod is secured to the earthquake clamp.

1 is a perspective view of a first embodiment of a seismic clamp for a seismic support system constructed in accordance with the teachings of the present invention.
2 is a front view of the earthquake-resistant clamp of Fig.
3 is a perspective view of a second embodiment of a seismic clamp constructed in accordance with the teachings of the present invention.
Fig. 4 is a front view of the earthquake-resistant clamp of Fig. 3;
5 is a perspective view of a third embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
6 is a front view of the earthquake swing brace of Fig.
7 is a perspective view of a fourth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
8 is a front view of the earthquake-resistant clamp of Fig.
9 is a perspective view of a fifth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
10 is a front view of the earthquake-resistant clamp of Fig.
11 is a perspective view of a sixth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
12 is a front view of the earthquake-resistant clamp of Fig.
Figure 13 is a perspective view of a seventh embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
14 is a front view of the earthquake-resistant clamp of Fig.
15 is a perspective view of an eighth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
16 is a front view of the earthquake-resistant clamp of Fig.
17 is a perspective view of a ninth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
18 is a front view of the earthquake-resistant clamp of Fig.
19 is a perspective view of a tenth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
20 is a front view of the earthquake-resistant clamp of Fig.
21 is a perspective view of an eleventh embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
22 is a front view of the earthquake-resistant clamp of Fig.
23 is a rear view of the earthquake-resistant clamp of Fig.
24 is a perspective view of a twelfth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
25 is a front view of the earthquake-resistant clamp of Fig.
26 is a perspective view of a thirteenth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
Fig. 27 is a front view of the earthquake-resistant clamp of Fig. 26;
28 is a perspective view of a fourteenth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
Fig. 29 is a front view of the earthquake-resistant brace of Fig. 28;
30 is a perspective view of a fifteenth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
31 is a front view of the earthquake-resistant brace of Fig. 30;
32 is a perspective view of a sixteenth embodiment of a vibration proof clamp constructed in accordance with the teachings of the present invention.
33 is a front view of the earthquake-resistant brace of FIG. 32;

An example of an earthquake-resistant clamp for bracing non-structural components to a rigid rod in a building is disclosed herein. For example, an earthquake-resistant clamp may be suitably configured for use with a swing brace, restraint, or other non-structural earthquake-resistant support system. Thus, the described embodiments are not limited to seismic swath braces or restraints. Although in the illustrated embodiments each of the seismic clamps is suitably configured for use with a rigid rod (RR) having at least a circular cross-sectional shape, in other embodiments the seismic clamp may be configured for a rigid rod having a different shape have. The rigid rods may also include pipes, solid rods, threaded rods, bars, strut channels, or other types of rigid rods. As is generally known, a rigid rod may be secured to and extended from a structural component of a building, such as a beam, using an earthquake-proof clamp or other device. In the illustrated embodiments, each seismic clamp may be suitably configured to bracing a non-structural pipe, such as a utility pipe, which may include, but is not limited to, a pipe, a duct, a circular duct, do. For example, in a particular embodiment, the pipe for use with the brace may be a plastic pipe comprising CPVC (chlorinated polyvinyl chloride), or a plastic pipe including, but not limited to, a plastic pipe consisting essentially of CPVC, Other types of plastic pipes may be used. In another embodiment, the pipe to be braced may be a flexible metal pipe or a thin metal pipe. In each illustrated embodiment, the earthquake-resistant clamp includes a spacer disposed between the plastic utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe. In addition, in each illustrated embodiment, the brace limits the force exerted on the utility pipe such that the brace does not deform the utility pipe, particularly the plastic utility pipe (e.g., CPVC pipe), either elastically or elastically do.

Referring to Figures 1 and 2, a first embodiment of a seismic clamp for bracing a non-structural component, such as a utility pipe (UP), to a rigid rod (RR) in a building is shown generally at 10. The earthquake-proof clamp (10) comprises a pipe holder, generally designated 12, adapted to fix a utility pipe (UP) on an earthquake-proof clamp; A spacer, generally designated 14, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a rod fitting generally indicated at 16, which is configured to secure the earthquake-resistant clamp to the rigid rods. In this embodiment, although the spacer 14 and the rod fitting 16 are integrally formed as a single, integral component, they may be formed separately. For example, the spacer 14 and the rod fitting 16 may be formed of a metal piece, such as a flat metal sheet. The holder 12 is also formed separately from the spacer 14 and the rod fitting 16 and may include one or more fasteners 18 (e.g., bolts or screws The same threaded fastener) to the spacer / rod fitting component.

1 and 2, the pipe holder 12 includes a strap (not shown) including a substantially arcuate central portion 20 defining a bearing surface of a size and shape extending partially around the periphery of the utility pipe UP strap and first and second opposite ear portions 22 extending outwardly from opposing ends of the central portion. The strap may be formed of flat metal pieces or other materials. The spacer 14 includes a saddle 26 defining a bearing surface on which the utility pipe UP is supported and first and second opposite ear portions 26 extending outwardly from opposing ends of the saddle 28). The saddle 26 generally opposes the central portion 20 of the pipe holder 12 and the first and second ear portions 28 are generally located on the first and second ear portions of the pipe holder 12, Respectively. Fasteners 18 extend through aligned openings (e.g., threaded openings) that extend through each of the first and second ear portions 22, 28. When the fasteners 18 are tightened, the holder 12 is moved toward the spacer 14 to fix the utility pipe UP between the holder and the spacer. For the reasons described below, in the illustrated embodiment, the fastener 18 is a torque limiting bolt, and thus when the predetermined torque on the bolt head 30 is reached, the bolt head shears the rest of the bolt, To prevent further tightening of the bolt.

The illustrated rod fitting 16 includes first and second opposing arms 32 extending from respective first and second ear portions 28 of the spacer 14 in the opposite direction of the holder 12 . The arms 32 define a rod receiving opening 34 that extends through the arm 32 from the front side of the arm toward the rear side of the arm so that the rigid rod RR is positioned on the front side of the arm To enter the rod receiving opening. The ends of the fasteners 18 extending through the ear portions 28 of the spacer 14 engage the rigid rods RR in the rod receiving openings 34. [ The arms 32 include bearing surfaces 38 that partially define rod receiving openings 34 that support a rigid rod RR. The fasteners 18 serve as set screws for pressing the rigid rod RR against the bearing surfaces 38 to secure the fitting 16 to the rigid rod RR. With this arrangement, the rigid rod RR and the utility pipe UP extend transversely (e.g., vertically) with respect to each other.

In the illustrated embodiment, the brace 10 is secured to the utility pipe (not shown) by a holder 12 so that the holder does not elastically or elastically deform a utility pipe, in particular a plastic utility pipe (e. G., A CPVC pipe) To limit the force applied to the UP. That is, the outside dimension of the utility pipe at the position fixed by the holder does not change during or after fixation. In the illustrated embodiment, the bolt head 30 of each fastener 18 is sheared during fastening after a predetermined torque has been reached on the bolt head. For example, when the ends of the fasteners 18 engage the rigid rod RR after a certain amount of tightening, additional torque applied to the bolt head 30 shears the bolt head of the bolt, Thereby preventing the additional holder 12 from being fastened on the utility pipe UP. In this way, the brace 10 is fixed to the rigid rod RR, and the holder does not deform the utility pipe UP either elastically or elastically.

4 and 5, a second embodiment of an earthquake-resistant clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is shown generally at 110. The earthquake-proof clamp 110 is a pipe holder schematically denoted by 112, which is configured to fix a utility pipe UP to an earthquake-proof clamp; A spacer generally designated 114 disposed to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally shown as 116, configured to secure the earthquake-resistant clamp to the rigid rods. The pipe holder 112, the spacers 114, and the rod fittings 116 are integrally formed as an integral component, such as from a metal (e.g., sheet metal). The pipe holder 112 has a substantially U-shape that partially surrounds the periphery of the utility pipe UP. The rod fitting 116 includes opposing channel shaped arms extending downwardly from opposing ends of the pipe holder 112. Each channel shaped arm has a first sidewall 117 connected to a corresponding end of the pipe holder, a bottom wall 119 extending inwardly from the first sidewall, and a bottom wall 119 extending upwardly from the bottom wall in opposed relationship with the first sidewall And a second side wall 121. Aligned rod receiving openings 123 extend through the first and second sidewalls 117, 119 and have a size and shape for receiving the rigid rod therethrough. The spacer 114 includes tabs 129 defining a bearing surface on which the utility pipe UP is supported. Taps 129 extend upwardly from the upper ends of the respective second sidewalls 121. As shown in Fig. The taps 129 extend outwardly away from each other and thereby define a substantially V-shaped bird.

In the illustrated embodiment, the central portion of the pipe holder 112 is bendable out-of-plane at a weak region (e.g., the notch 127) The taps 129 (and the rod fitting arms) are opened to allow the utility pipe UP to be received between the spacer and the center of the pipe holder. The pipe holder 112 can then be closed by bending the center of the pipe holder so that the taps 129 are moved toward each other. In this illustrated embodiment, the brace 110 limits the force exerted on the utility pipe UP by the holder 112 such that the holder is elastically or resiliently mounted on a utility pipe, in particular a plastic utility pipe , CPVC pipe). That is, the outside dimension of the utility pipe UP in a fixed position is not changed during or after fixation. In other embodiments, the pipe holder 112 may not be bendable out-of-plane, and instead, the pipe holder may be slidably received on the utility pipe UP. Threaded fasteners 118 extend through openings 123 (e.g., threaded openings) in bottom wall 119 to engage rigid rods RR. The sidewalls 117, 121 include bearing surfaces that partially define the rod receiving openings 123. The fasteners 118 serve as locking screws for pressing the rigid rod RR against the bearing surfaces to secure the fitting 116 to the rigid rod RR. With this arrangement, the rigid rod RR and the utility pipe UP extend transversely (e.g., vertically) with respect to each other. Fasteners 118 may be torque limiting bolts.

5 and 6, a third embodiment of a seismic clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is shown generally at 210. The earthquake-proof clamp 210 has a pipe holder, generally designated 212, configured to secure a utility pipe UP to an earthquake-proof clamp; A spacer, generally designated 214, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally shown as 216, configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-proof clamp 210 is similar to the second earthquake-proof clamp 110, except as described below. The pipe holder 212 of the earthquake-proof clamp 210 is bent so as not to open and close the pipe holder, and the pipe holder has a roughly arcuate bearing surface 220 for the utility pipe UP. The taps 229 of the spacers also extend downwardly toward each other from the second sidewall 221 of the rod fitting 216 to define approximately V-shaped saddles for the utility pipe UP. The rigid rods RR and utility pipes UP extend in a transverse direction (e.g., perpendicular) with respect to each other.

7 and 8, a fourth embodiment of an earthquake-resistant clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is shown generally at 310. The earthquake-proof clamp 310 is a pipe holder schematically shown as 312, which is configured to fix a utility pipe UP to an earthquake-proof clamp; A spacer generally designated 314, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And generally a load fitting generally designated 316, configured to secure an earthquake-resistant clamp to a rigid rod. This earthquake-proof clamp 310 is similar to the third earthquake-proof clamp 210, except as described below. The tabs 329 of the spacer 314 extend inwardly toward each other from the first sidewalls 317 of the arms of the rod fitting 316. Also, the second sidewalls 321 of the arms of the rod fitting 316 are not on the inside thereof but on the outside of the corresponding first sidewalls 317. The rigid rods RR and utility pipes UP extend in a transverse direction (e.g., perpendicular) with respect to each other.

9 and 10, a fifth embodiment of an earthquake-proof clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 410. The earthquake-proof clamp 410 comprises a pipe holder, generally designated 412, configured to secure the utility pipe UP to the earthquake-resistant clamp; A spacer generally designated 414, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally designated 416, configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-resistant clamp 410 is similar to the first earthquake-proof clamp 10 except as described below. The rod fitting 416 is in the form of a channel that includes opposed first and second sidewalls 432 and a bottom wall 433 interconnecting the first and second sidewalls. The upper ear portions 435 of the first and second sidewalls 432 are connected to the pipe holders 412 by fasteners 419 extending through aligned openings (e.g., unthreaded openings) ) And spacers 414, respectively. The capped nuts 441 are screwed into the fasteners 419 to prevent the holder from plastic or elastically deforming utility pipes, particularly plastic utility pipes (e.g., CPVC pipes) Thereby restricting the force applied to the utility pipe by the holder by restricting the tightening of the holder 412 on the utility pipe UP. The rod receiving openings 434 in the first and second sidewalls 432 receive a rigid rod (RR). The fastener 445 serves as a securing screw that secures the brace 410 to the rigid rod by engaging the threaded opening in the bottom wall 433 of the rod fitting 416 and engaging the rigid rod RR. The rigid rods RR and utility pipes UP extend in a transverse direction (e.g., perpendicular) with respect to each other.

Referring to Figures 11 and 12, a sixth embodiment of an earthquake-resistant clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is shown generally at 510. The earthquake-resistant clamp 510 is configured to fix the utility pipe UP to the earthquake-proof clamp, as shown generally at 512; A spacer generally designated 514, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally shown as 516, configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-resistant clamp 510 is similar to the first earthquake-proof clamp 10, except as described below. The pipe holder 512 has a keyed fitting 550 (e. G., ≪ RTI ID = 0.0 > e. G. For example, a T-shaped fitting. The keyed fitting 550 may be received in a slot 552 defined by one of the ear portions 528 of the spacer 514 when the keyed fitting is in the first orientation. After the keyed fitting 550 is inserted into the slot 552, the pipe holder 512 may be rotated 90 degrees so that the opposite ear 522 defined by the pipe holder with the through opening opens into the spacer 514, respectively. The fastener 518 is then used to securely hold the holder 512 in place to allow the holder 512 not to elastically or elastically deform the utility pipe, particularly a plastic utility pipe (e. G., A CPVC pipe) Can be tightened similarly to the description. The rigid rods RR and utility pipes UP extend in a transverse direction (e.g., perpendicular) with respect to each other.

13 and 14, a seventh embodiment of an earthquake-resistant clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 610. [ The earthquake-resistant clamp 610 comprises a pipe holder, generally designated 612, configured to secure the utility pipe UP to an earthquake-resistant clamp; A spacer generally designated 614, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally shown as 616, configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-resistant clamp 610 is similar to the fifth earthquake-proof clamp 410, except as described below. The rod openings 634 defined by the opposing first and second sidewalls 632 of the rod fittings 616 may have a circular cross section as shown in the previous embodiment for securing to the brace 610 , Or a rigid rod in the form of a strut channel (SC) as shown in Figs. 13 and 14. Each of the sidewalls 632 includes a retainer having two prongs 658 that extend into corresponding openings 634. When the strut channel is received in the opening 634 and occupies the strut channel in the opening, the retainer prongs 658 are received in the open interior of the strut channel to define an inturned lip ). The retainer prongs define a V-shaped space suitable for receiving and supporting a rigid rod having a circular cross section.

15 and 16, an eighth embodiment of an earthquake-proof clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 710. [ The earthquake-resistant clamp 710 comprises a pipe holder, generally designated 712, adapted to secure utility pipe UP to an earthquake-resistant clamp; A spacer generally designated 714, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And load fittings generally designated 716, which are configured to secure the earthquake-resistant clamp to the rigid rods.

15 and 16, the pipe holder 712 includes a strap including a substantially arcuate central portion 720 defining a bearing surface of a size and shape that partially extends around the periphery of the utility pipe UP And opposite first and second ear portions 722 extending outwardly from opposing ends of the midsection. The strap may be formed of flat metal pieces or other materials. The spacer 714 includes saddles 726 defining a bearing surface on which the utility pipe UP is supported and first and second opposite ear portions 728 extending outwardly from opposing ends of the saddle . The saddle 726 generally opposes the central portion 720 of the pipe holder 712. The first and second ear portions 728 of the spacer 714 are received in openings 729 (e.g., slot shaped openings) in the pipe holder 712 that are generally adjacent to the ear pieces 722 of the pipe holder To secure the utility pipe (UP) between the holder and the spacer. The pipe holder 712 is secured to the rod fitting 716 by fasteners 730 (e.g., bolts) extending through the first and second ear portions 722 and threaded into the rod fittings.

The illustrated load fittings 716 include opposing first and second opposing arms 732. In the illustrated embodiment, the first and second opposing arms 732 are generally configured such that the rigid rods RR extend generally transverse (e.g., perpendicular) to the utility pipe UP, Receiving openings 734 extending therethrough. ≪ / RTI > Fasteners 735 (e.g., bolts) extend through opposing arms 732 of rod fitting 716 to engage rigid rods (RR) in rod-receiving openings 734. Arms 732 include bearing surfaces that partially define rod receiving openings 734 that support a rigid rod (RR). The fasteners 735 serve as fixing screws for pressing the rigid rods RR against the bearing surfaces to secure the fittings 716 to the rigid rods RR. With this arrangement, the rigid rods RR and the utility pipes UP extend in a transverse direction (e.g., perpendicular) with respect to each other.

In this illustrated embodiment, the brace 710 is secured to the utility pipe 712 by a holder 712 to prevent the holder from elastically or elastically deforming utility pipes, particularly plastic utility pipes (e.g., CPVC pipes) To limit the force applied to the UP. That is, the outside dimension of the utility pipe at the position fixed by the holder does not change during or after fixation. In the illustrated embodiment, the pipe holder 720 and the spacers 714 are sized and shaped to fit a particular utility pipe having a selected size and shape to prevent the holder from deforming the utility pipe elastically or elastically Respectively.

17 and 18, a ninth embodiment of an earthquake-proof clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 810. The earthquake-resistant clamp 810 comprises a pipe holder, generally designated 812, configured to secure the utility pipe UP to an earthquake-resistant clamp; A spacer generally designated 814, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And load fittings generally designated 816, which are configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-proof clamp 810 is similar to the eighth earthquake-proof clamp 710, except as described below. Spacer 814 includes first and second taps 829 extending inwardly from adjacent first and second ear portions 822 of pipe holder 812. The tabs 829 define a bearing surface for supporting the utility pipe UP in spaced relation to the rigid rod RR.

19 and 20, a tenth embodiment of an earthquake-resistant clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 910. The earthquake-proof clamp 910 includes a pipe holder, generally designated 912, configured to secure the utility pipe UP to an earthquake-resistant clamp; A spacer generally designated 914, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally designated 916, configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-proof clamp 910 is similar to the eighth earthquake-proof clamp 710, except as described below. The rod fitting 916 is formed as a single elongate block having a top surface that faces the pipe holder 912 and defines a spacer 914, particularly a bearing surface of the spacer. Accordingly, the spacer 914 and the rod fitting 916 are integrally formed as an integral component.

21 to 23, an eleventh embodiment of an earthquake-proof clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 1010. [ The earthquake-proof clamp 1010 includes a pipe holder, generally designated 1012, configured to secure the utility pipe UP to an earthquake-resistant clamp; A spacer generally designated 1014, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the earthquake-resistant clamp; And generally a load fitting generally designated 1016, configured to secure an earthquake-resistant clamp to a rigid rod.

21-23, the pipe holder 1012 includes a strap including a generally arcuate central portion 1020 defining a bearing surface of a size and shape that partially extends around the periphery of the utility pipe UP . The strap may be formed of flat metal pieces or other materials. The spacer 1014 includes a sleeve 1026 defining a bearing surface on which the utility pipe UP is supported. The sleeve 1026 is fixed to the rigid rod RR by a fastener 1027 functioning as a setscrew. Sleeve 1026 generally opposes central portion 1020 of pipe holder 1012.

The illustrated load fitting 1016 includes opposed first and second arms 1032 extending from opposing ends of the pipe holder 1012 and integrally formed therewith. First and second arm rod receiving openings 1034 extend through arms 1032 to allow the rigid rod RR to extend approximately transversely (e.g., vertically) to the utility pipe UP do. Fasteners 1035 (e.g., bolts) extend through the first and second ear portions 1033 of the rod fitting 1016 to engage the rigid rods (RR) in the rod receiving openings 1034. Arms 1032 include bearing surfaces that partially define load receiving openings 1034 that support a rigid rod (RR). Fasteners 1035 function as fastening screws that press the rigid rod RR against the bearing surfaces to secure the fitting 1016 to the rigid rod RR. With this arrangement, the rigid rods RR and utility pipes UP extend in a transverse direction (e.g., perpendicular) with respect to each other.

In the illustrated embodiment, the brace 1010 is secured to the utility pipe 1012 by a holder 1012 to prevent the holder from elastically or elastically deforming utility pipes, particularly plastic utility pipes (e.g., CPVC pipes) To limit the force applied to the UP. That is, the outside dimension of the utility pipe UP at the position fixed by the holder 1012 does not change during or after fixation. In the illustrated embodiment, the pipe holder 1020 and the spacer 1014 are sized and shaped to fit a particular utility pipe having a selected size and shape to prevent the holder from deforming the utility pipe elastically or elastically Respectively.

24 and 25, a twelfth embodiment of an earthquake-resistant clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 1110. [ The earthquake-proof clamp 1110 comprises a pipe holder, generally designated 1112, configured to secure the utility pipe UP to an earthquake-resistant clamp; Which is configured to be disposed between the utility pipe UP and the rigid load RR to prevent the rigid load RR from contacting the utility pipe UP when the utility pipe UP is secured to the earthquake clamp, Spacers as outlined; And a load fitting generally shown as 1116, configured to secure the earthquake-resistant clamp to the rigid load (RR).

24 and 25, the pipe holder 1112 defines a bearing surface of a size and shape that partially extends around the periphery of the utility pipe UP and includes an outer upper member 1113 having an arcuate shape, (1115). The strap 1115 is inside the upper member 1113. The fastener 1118 is threadedly received in the upper member 1113 and connected to the strap 1115 so that the strap 1115 is moved toward and away from the upper member as the fastener 1118 is tightened do. The spacer 1114 includes a sleeve 1126 defining a bearing surface on which the utility pipe UP is supported. Sleeve 1126 is received on rigid pipe RR and at least partially surrounds the periphery of rigid rod RR. Sleeve 1026 generally opposes central portion 1120 of pipe holder 1112.

The illustrated load fittings 1116 include opposing first and second arms 1132 extending from opposite ends of the upper member 1113 of the pipe holder 1112 and integrally formed therewith do. The first and second arm load receiving openings 1134 extend through the arms 1132 such that the rigid rod RR extends generally transverse (e.g., perpendicular) to the utility pipe UP . With this arrangement, the rigid rods RR and utility pipes UP extend in a transverse direction (e.g., perpendicular) with respect to each other.

In the illustrated embodiment, the brace 1110 is secured to the utility pipe 1112 by a holder 1112 to prevent the holder from elastically or elastically deforming utility pipes, particularly plastic utility pipes (e.g., CPVC pipes) To limit the force applied to the UP. That is, the outside dimension of the utility pipe UP at the position fixed by the holder 1112 does not change during or after fixation. In the illustrated embodiment, a stop in the form of a sleeve 1150 is received on the bolt 1118 between the bolt head and the upper member 1113 to limit the movement of the strap 1115 towards the spacer 1114, Thus limiting the force exerted on the utility pipe (UP) located between the strap and the spacer.

Referring to Figures 26 and 27, a thirteenth embodiment of a seismic clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 1210. [ The earthquake-proof clamp 1210 includes a pipe holder, generally designated 1212, configured to secure the utility pipe UP to an earthquake-resistant clamp; A spacer generally designated 1214, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally designated 1216, configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-proof clamp 1210 is similar to the eighth earthquake-proof clamp 710, except as described below. The spacer 1214 includes a plate that is fixed between the first and second ear portions 1222 of the pipe holder 1212 and the first and second opposing arms 1232 by fasteners 1230.

28 and 29, a fourteenth embodiment of an earthquake-resistant clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 1310. [ The earthquake-proof clamp 1310 has a pipe holder, generally designated 1312, configured to secure the utility pipe UP to an earthquake-resistant clamp; A spacer generally designated 1314, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally designated 1316, configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-resistant clamp 1310 is similar to the eighth earthquake-clamp 710, except as described below. The spacer 1314 includes a sleeve that is received on the rigid rod RR and at least partially surrounds the periphery of the rigid rod.

Referring to Figures 30 and 31, a fifteenth embodiment of a seismic clamp for bracing a non-structural component, such as a utility pipe (UP), to a rigid rod (RR) in a building is outlined by reference numeral 1410. [ The earthquake-proof clamp 1410 includes a pipe holder, generally designated 1412, configured to secure a utility pipe UP to an earthquake-proof clamp; A spacer generally designated 1414, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And a load fitting generally designated 1416, which is configured to secure an earthquake-resistant clamp to a rigid rod. This earthquake-proof clamp 1410 is similar to the fifth earthquake-proof clamp 410 except as described below. The center portions 1420 of each of the pipe holders 1412 and the spacers 1414 are approximately arcuate. Ear portions 1435 of the rod fitting 1416 also extend inward toward each other at the tops of the first and second sidewalls 1432. The bottom wall 1433 also includes two threaded openings, similar to the fifth embodiment, in which the fasteners 1445 are threadedly received and function as fastening screws for the rod fitting 1416.

As with the teachings of all other illustrated embodiments, the holder 1412 does not deform a utility pipe, particularly a plastic utility pipe (e. G., A CPVC pipe), either elastically or resiliently. As in the fifth embodiment, the cap nuts 1441 threaded on the fasteners 1419 (e.g., bolts) allow the holder to be attached to a utility pipe, especially a plastic utility pipe (e. G., A CPVC pipe) Limits the force exerted on the utility pipe by the holder by restricting the tightening of the holder 1412 on the utility pipe UP, so as not to deform it elastically or elastically. In addition, the rigid load RR and the utility pipe UP extend in a transverse direction (e.g., perpendicular) with respect to each other.

32 and 33, a sixteenth embodiment of an earthquake-resistant clamp for bracing a non-structural component, such as a utility pipe UP, to a rigid rod (RR) in a building is outlined by reference numeral 1510. [ The earthquake-proof clamp 1510 comprises a pipe holder, generally designated 1512, adapted to secure the utility pipe UP to an earthquake-resistant clamp; A spacer generally designated 1514, configured to be disposed between the utility pipe and the rigid rod to prevent the rigid rod from contacting the utility pipe when the utility pipe is secured to the seismic clamp; And load fittings generally designated 1516, which are configured to secure the earthquake-resistant clamp to the rigid rods. This earthquake-proof clamp 1510 is similar to the first earthquake-proof clamp 10 except as described below. Arms 1532 define rod receiving openings 1534 that extend through arms 1532. The ends of the fasteners 1518 extending through the ear portions 1528 of the spacer 1514 engage the rigid rod RR in the rod receiving openings 1534. [

Modifications and variations of the embodiments disclosed herein are possible without departing from the scope of the invention as defined in the appended claims.

The terms " work ", " the ", and " the " are intended to mean that there is more than one element when introducing elements of the invention or the embodiment (s) thereof. The terms "comprising", "comprises" and "having" are intended to be inclusive and mean that there may be additional elements other than the listed elements.

Since various changes may be made in the structures, products, and methods without departing from the scope of the present invention, all matters included in the above description and shown in the accompanying drawings are to be interpreted as illustrative rather than restrictive .

Claims (20)

As a braced utility assembly within a building,
Utility pipe;
A rigid rod; And
A seismic clamp for securing the utility pipe to the rigid rod such that the rigid rod extends transversely to the utility pipe, the seismic clamp being disposed between the utility pipe and the rigid rod, Wherein said spacer comprises a spacer that prevents said utility pipe from contacting said utility pipe. ≪ RTI ID = 0.0 >< / RTI > The method according to claim 1,
Wherein the rigid rod extends perpendicular to the utility pipe. The method according to claim 1,
Wherein said earthquake-resistant clamp comprises a pipe holder for securing said utility pipe to said earthquake-resistant clamp. The method of claim 3,
Wherein the utility pipe is a plastic utility pipe and the pipe holder secures the plastic utility pipe to the seismic clamp without deforming the plastic utility pipe. The method according to claim 1,
Wherein the spacer comprises a bearing surface on which the utility pipe is supported. 6. The method of claim 5,
Wherein the spacer comprises a saddle defining the bearing surface. ≪ Desc / Clms Page number 13 > 6. The method of claim 5,
Wherein the spacer comprises opposing tabs defining the bearing surface. ≪ RTI ID = 0.0 >< / RTI > 6. The method of claim 5,
Wherein the spacer includes a sleeve that at least partially surrounds the rigid rod and defines the bearing surface. 6. The method of claim 5,
Wherein the earthquake-resistant clamp comprises a rod fitting fixed to the rigid rod. 10. The method of claim 9,
Wherein the load fitting defines a bearing surface that supports the rigid rod and the seismic clamp includes a securing screw that urges the rigid rod against the bearing surface. A method for in-building utility pipe bracing,
Securing the utility pipe to a seismic sway brace, the seismic swing brace comprising a rigid rod and a seismic clamp, the seismic clamp securing the utility pipe to the rigid rod,
Wherein the rigid rods extend in a transverse direction relative to the utility pipe and the rigid rods and the utility pipes do not contact each other when secured to the earthquake clamp. 12. The method of claim 11,
Wherein said seismic clamp comprises a spacer disposed between said utility pipe and said rigid rod to prevent said rigid rod from contacting said utility pipe. 13. The method of claim 12,
Wherein said utility pipe is a plastic utility pipe. 14. The method of claim 13,
Wherein securing the utility pipe to the earthquake-resistant clamp does not deform the plastic utility pipe. An earthquake-resistant clamp for securing a utility pipe to a rigid rod,
A pipe holder configured to secure the utility pipe to the seismic clamp so that the utility pipe extends in a first direction;
A load fitting configured to fix the rigid rod to the seismic clamp so that the rigid rod extends in a second direction transverse to the first direction; And
And a spacer disposed between the pipe holder and the load fitting, the spacer being configured to prevent the rigid rod from contacting the utility pipe when the utility pipe is fixed to the earthquake-proof clamp and the rigid rod is fixed to the earthquake- Wherein said spacer is configured to secure said utility pipe to a rigid rod. 16. The method of claim 15,
Wherein the pipe holder is configured to secure the utility pipe to the seismic clamp without deforming the utility pipe if the utility pipe is a plastic utility pipe. 16. The method of claim 15,
Wherein the spacer comprises a bearing surface configured to support the utility pipe. 16. The method of claim 15,
Wherein the spacer comprises saddles defining the bearing surface. ≪ Desc / Clms Page number 13 > 16. The method of claim 15,
Wherein the spacer comprises opposing tabs defining the bearing surface. ≪ RTI ID = 0.0 > 11. < / RTI > 16. The method of claim 15,
Wherein the spacer comprises a sleeve configured to at least partially surround the rigid rod and define the bearing surface.

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