Tension-mounted strut frame

文档序号:1342468 发布日期:2020-07-17 浏览:24次 中文

阅读说明:本技术 张力安装的支杆架 (Tension-mounted strut frame ) 是由 康纳尔·P·麦克纳马拉 莫里斯·以利亚·伍德四世 吴灵修 琳娜·A·博登 马丁·马奇 于 2018-11-19 设计创作,主要内容包括:一种用于安装在两个基本平行的表面之间的张力安装杆,包括:中央管状体;第一伸缩管状体,其具有与所述中央管状体耦接的伸缩第一端和自由的第二端;以及第二管状体,其具有与所述中央管状体耦接的伸缩第一端和自由的第二端。延伸机构安装到中央管状体。延伸机构构造成被手动致动,并且具有齿条和小齿轮布置,该齿条和小齿轮布置构造成使第一管状体和第二管状体相对于中央管状体沿相反方向同时移动。(A tension mounting bar for mounting between two substantially parallel surfaces, comprising: a central tubular body; a first telescoping tubular body having a telescoping first end coupled with the central tubular body and a free second end; and a second tubular body having a telescoping first end coupled with the central tubular body and a free second end. The extension means is mounted to the central tubular body. The extension mechanism is configured to be manually actuated and has a rack and pinion arrangement configured to simultaneously move the first and second tubular bodies in opposite directions relative to the central tubular body.)

1. A tension mounting bar for mounting between two substantially parallel surfaces, the bar comprising:

a central tubular body;

a first telescoping tubular body having a telescoping first end coupled with the central tubular body and a free second end;

a second tubular body having a telescoping first end coupled with the central tubular body and a free second end; and

an extension mechanism mounted to the central tubular body, the extension mechanism configured to be manually actuated and having a rack and pinion arrangement configured to simultaneously move the first and second tubular bodies in opposite directions relative to the central tubular body.

2. The tension mounting bar of claim 1, wherein the extension mechanism comprises:

a first rack disposed within the central tubular body and having a first end section and a second end section connected to the telescoping first end of the first tubular body,

a second rack disposed within the central tubular body and having a first end section and a second end section connected to the telescoping first end of the second tubular body, an

A pinion gear meshed with each of the first and second racks.

3. The tension mounting bar of claim 2, wherein the extension mechanism comprises:

a locking member configured to move between engagement and disengagement with each of the first and second racks, an

An actuator coupled to the locking member, wherein manual actuation of the actuator disengages the locking member from each of the first and second racks.

4. The tension mounting bar of claim 3, wherein the actuator includes a bar projecting outwardly therefrom, and the locking member is secured to the bar of the actuator.

5. The tension mounting bar of claim 3, wherein the locking member is biased into engagement with the first and the second racks in a direction perpendicular to a length of each of the first and the second racks.

6. The tension mounting bar of claim 5, wherein the locking member includes a first portion having a first tooth engaging the first rack and a second portion spaced from the first arm and having a second tooth engaging the second rack.

7. The tension mounting bar of claim 3, wherein the first rack includes a first tooth and a second tooth separate from the first tooth, the locking member engages the first tooth, and the pinion gear engages the second tooth.

8. The tension mounting bar of claim 7, wherein the first rack includes a dividing wall extending along a longitudinal extent thereof, the first and second teeth being located on opposite sides of the wall.

9. The tension mounting bar of claim 7, wherein the second rack comprises a first tooth and a second tooth separate from the first tooth, the locking member engages the first tooth, and the pinion gear engages the second tooth.

10. The tension mounting bar of claim 9, wherein the second rack comprises a dividing wall extending along a longitudinal extent thereof, the first and second teeth being located on opposite sides of the wall.

11. The tension mount pole of claim 1, comprising an extension foot assembly, the extension foot assembly comprising:

a housing connected to the free second end of the first tubular body,

a lever mounted to the housing and including a lever contact surface, an

A foot mounted to the housing and including a foot contacting surface,

wherein the lever is configured to move between a retracted position and an outward position in which the lever contact surface engages the foot contact surface to extend the foot outwardly from the housing.

12. The tension mounting bar of claim 11, wherein the extension foot assembly further comprises a connecting member interconnecting the lever and the foot and configured to limit outward movement of the foot from the housing.

13. The tension mounting bar of claim 12, wherein the lever includes a pair of cams and the foot includes a pair of spaced apart supports, at least one of the cams having the lever contact surface and at least one of the supports having the foot contact surface, the connecting member being mounted between the pair of cams and the pair of supports.

14. The tension mounting bar of claim 1, comprising a shelf support assembly mounted to the central tubular body, the shelf support assembly comprising:

a sleeve sized to slide over the central tubular body, an

A hook member mounted to the sleeve for mounting an associated shelf, the hook member frictionally engaging the central tubular body to secure the sleeve to the central tubular body.

15. The tension mounting bar of claim 14, wherein the hook member includes a recess for mounting a compressible pad for frictional engagement with the central tubular body.

16. A tension mounting bar for mounting between two substantially parallel surfaces, the tension mounting bar comprising:

a central tubular body;

a first telescoping tubular body having a telescoping first end coupled with the central tubular body and a free second end;

a second tubular body having a telescoping first end coupled with the central tubular body and a free second end; and

a manually actuated extension mechanism mounted to the central tubular body, the extension mechanism comprising:

a first rack disposed within the central tubular body and having a first end section and a second end section connected to the telescoping first end of the first tubular body,

a second rack disposed within the central tubular body and having a first end section and a second end section connected to the telescoping first end of the second tubular body, an

A pinion gear in mesh with each of the first and second racks, the pinion gear allowing the first tubular body and the second tubular body to move simultaneously in opposite directions relative to the central tubular body.

17. The tension mounting bar of claim 16, wherein the extension mechanism comprises:

a locking member biased into engagement with each of the first and second racks, an

An actuator coupled to the locking member, wherein manual actuation of the actuator disengages the locking member from each of the first and second racks.

18. The tension mount pole of claim 16, comprising an extension foot assembly, the extension foot assembly comprising:

a housing connected to the free second end of the first tubular body,

a lever mounted to the housing and including a lever contact surface,

a foot mounted to the housing and including a support having a support contact surface, an

A connecting member interconnecting the lever and the foot and configured to restrict movement of the foot relative to the housing,

wherein the lever is configured to move between a retracted position and an outward position in which the lever contact surface engages the support contact surface to extend the foot outwardly from the housing.

Background

Tension mounted strut mounts are commonly used support devices. In vertical use, they may support, for example, lighting fixtures, shelving units, etc., while horizontally mounted rods are used for clothing displays, curtains, shower curtains, etc. Tension mounted mast stands can be erected and secured with little mechanical capacity in a minimum of time and are versatile in that they can be located almost anywhere, spanning the distance between two surfaces, such as floors and ceilings. It is the tension of the device applied between the surfaces that provides stability in holding the rod in place.

At its most basic, a typical tension mounted strut tower includes a first rod having a foot to contact and grip a first lower surface, with a second, smaller diameter rod telescopically received in and extending from the first rod. The second bar has a foot for contacting the second upper surface. The two levers are normally spring biased outwardly relative to each other. One problem with this design is that the device is either adjustable over a small span and/or the expansion forces of the first and second rods may damage the support surface.

In operation, the rubber foot on the lower/first bar of the spring-biased prior art device is placed on the desired lower surface (e.g., floor). The user then pushes the upper/second rod against the spring force to temporarily fold and retract the second rod into the first rod. In the state where the second lever is held, the apparatus is tilted to a position as close to the vertical direction as possible. The second rod is then carefully released to allow the internal spring of the device to cause expansion until the rubber foot of the second rod contacts the upper surface (e.g., ceiling).

Because the telescoping secondary bar can be located at a relatively high position above the middle of the bar stock, short users experience considerable difficulty trying to orient the spring biasing means. Moreover, the strength with which it is held in the vertical position is directly dependent on the strength of the springs involved. However, the stronger the spring holding the strut cage in place, the more difficult the installation, since to perform the installation the spring is first manually compressed until selectively released. Thus, another problem with the spring-biased design is that installation is not always easy, as the user must attempt to compress both levers against the strong outward bias of the spring, and at the same time attempt to place the levers in a vertical orientation.

Disclosure of Invention

According to one aspect, a tension-mounted strut mount for mounting between two substantially parallel surfaces comprises: a central tubular body; a first telescoping tubular body having a telescoping first end connected to the central tubular body and a free second end; and a second tubular body having a telescoping first end connected to the central tubular body and a free second end. The extension means is mounted to the central tubular body. The extension mechanism is configured to be manually actuated and has a rack and pinion arrangement configured to simultaneously move the first and second tubular bodies in opposite directions relative to the central tubular body.

According to another aspect, a tension-mounted pole for mounting between two substantially parallel surfaces comprises: a central tubular body; a first telescoping tubular body having a telescoping first end connected to the central tubular body and a free second end; and a second tubular body having a telescoping first end connected to the central tubular body and a free second end. A manually actuated extension mechanism is mounted to the central tubular body. The extension mechanism includes a first rack and a second rack, each rack disposed in the central tubular body. The first rack has a first end section and a second end section, the second end section being connected to the telescoping first end of the first tubular body. The second rack has a first end section and a second end section, the second end section being connected to the telescoping first end of the second tubular body. The extension mechanism further includes a pinion gear that meshes with each of the first and second racks. The pinion allows simultaneous movement of the first and second tubular bodies in opposite directions relative to the central tubular body.

Drawings

FIG. 1 is a perspective view of a tension mounted strut mount according to the present invention for mounting between two substantially parallel surfaces.

FIG. 2 is an enlarged perspective view of a portion of a tension mounted strut rack having an exemplary extension mechanism according to one aspect of the present invention.

Fig. 3 is a perspective view of the rack and pinion arrangement of the extension mechanism of fig. 2.

Fig. 4 and 5 are exploded perspective views of the extension mechanism of fig. 2.

FIG. 6 is an enlarged perspective view of an exemplary extension foot assembly for a tension mounted strut rack in accordance with an aspect of the present invention.

Fig. 7 is an exploded perspective view of the extension foot assembly of fig. 6.

Fig. 8 and 9 are cross-sectional views of the extension foot assembly of fig. 6.

Fig. 10 and 11 are exploded perspective views of an exemplary shelf support assembly for tension mounted strut racks in accordance with an aspect of the present invention.

FIG. 12 is a cross-sectional view of an exemplary extension mechanism according to another aspect of the present invention.

Fig. 13 and 14 are exploded perspective views of the extension mechanism of fig. 12.

FIG. 15 is an enlarged perspective view of an exemplary extension foot assembly for a tension mounted strut rack according to another aspect of the present invention.

Fig. 16 is an exploded perspective view of the extension foot assembly of fig. 16.

Fig. 17 and 18 are cross-sectional views of the extension foot assembly of fig. 15.

Fig. 19 and 20 are exploded perspective views of an exemplary shelf support assembly for tension mounted cradles according to another aspect of the present invention.

Fig. 21 is a cross-sectional view of the shelf support assembly of fig. 19 mounted to a tension mounted mast frame.

Detailed Description

It should be understood, of course, that the description and drawings herein are merely exemplary and that various modifications and changes may be made in the structures disclosed without departing from the disclosure. Fig. 1 and 2 illustrate an exemplary tension mounted strut tower according to the present invention, generally designated by the reference numeral 100. The brace rack 100 is typically mounted between two substantially parallel support surfaces by contacting the ends at the two surfaces using outward tension, thereby serving as a decorative support for a rack, clothing, window treatments, and the like. The support surface may be oriented horizontally, requiring vertical support, such as in a bathroom shower, or vertically, requiring horizontal support, such as in a closet or window box. The two support surfaces need not be perfectly parallel, so long as a properly mounted strut rack 100 can maintain its position when straddling between the two support surfaces.

In general, the example tension-mounted strut mount 100 includes a central tubular body 102 having a first end 104 and a second end 106; a first telescoping tubular body 110 having a telescoping first end 112 coupled to the first end 104 of the central tubular body 102 and a free second end 114; and a second tubular body 118 having a telescoping first end 120 coupled to the second end 106 of the central tubular body 102 and a free second end 122. The first and second tubular bodies 110, 118 are telescoping to allow for variation in the length/height of the strut rack 100. The free second ends 114, 122 of the first and second tubular bodies 110, 118, respectively, can each be provided with a padded surface member or foot 126, 128 for contacting one of the support surfaces without damaging the support surface in any way. The bottom region of each cushion surface member 126, 128 may comprise a material such as rubber to provide the necessary grip and cushioning at the contact between the free second end 114, 122 and the support surface.

The exemplary strut rack 100 also includes an extension mechanism 130 mounted on the central tubular body 102 for adjusting and locking the span of the strut rack. As described below, the extension mechanism 130 is configured to be manually actuated and has a rack and pinion arrangement configured to simultaneously move the first and second tubular bodies 110, 118 relative to the central tubular body 102.

Referring to fig. 3-6, according to one aspect, the extension mechanism 130 includes a housing 132 mounted at least partially within the central tubular body 102. The housing 132 may be defined by a first housing portion 136 and a second housing portion 138, and is at least partially assembled over first and second racks 140, 142, each disposed within the central tubular body 102. The first rack 140 has a first end section 146 and a second end section 148, the second end section 148 being attached to the telescoping first end 112 of the first tubular body 110. Similarly, the second rack 142 has a first end section 152 and a second end section 154, the second end section 154 being connected to the telescoping first end 120 of the second tubular body 118. To allow connection of each second end section 148, 154, a connector 156, 158 may be mounted to the respective second end section 148, 154. The connectors 156, 158 may be received and connected to the respective telescoping first ends 112, 120. According to one aspect of the present invention, the first rack 140 includes a first tooth 160 and a second tooth 162, the second tooth 162 being separated from the first tooth via a dividing wall 164 extending along a longitudinal direction of the first rack 140. The first and second teeth 160, 162 are located on opposite sides of the wall 164. The second rack 142 is similarly configured and includes a first tooth 170 and a second tooth 172, the second tooth 172 being separated from the first tooth via a dividing wall 174 extending longitudinally along the second rack 142. The first and second teeth 170, 172 are located on opposite sides of the wall 174. In the illustrated embodiment, the first teeth 160, 170 of each of the first and second racks 140, 142 have a first orientation and the second teeth 162, 172 have a different second orientation. For example, in the illustrated embodiment, the first teeth 160, 170 are disposed on the dividing walls 164, 174 and the second teeth 162, 172 are disposed transverse to the walls 164, 174. The pinion gear 178 is engaged with each of the first and second racks 140, 142, and more specifically, with the second teeth 162, 172 of each of the first and second racks 140, 142.

The example extension mechanism 130 also includes a locking member 180 configured to move between engagement and disengagement with each of the first and second racks 140, 142. In the illustrated embodiment, the locking member 180 includes a first arm 182 having a first tooth 184, and a second arm 186 spaced apart from the first arm and having a second tooth 188. The first and second teeth 184, 188 of the locking member 180 engage the first teeth 160, 170 of the first and second racks 140, 142, respectively. A bridge 196 interconnects the first arm 182 and the second arm 186. According to one aspect, the locking member 180 is pivotally mounted on the housing 132 via a bridge 196 and biased into engagement with the first and second racks 140, 142. As shown in fig. 4 and 5, the first housing portion 136 of the housing 132 includes a recessed portion 200 having a post 202 therein. The post 202 is provided with a cutout 204 sized to receive the bridge 196, and when installed in the cutout 204, the locking member 180 is connected to the first housing portion 136 and pivots about an axis defined by the bridge 196. Web 208 is positioned over bridge 196 of locking member 180, web 208 spanning between first arm 182 and second arm 186. A projection 212 is provided on the web 208. The mating protrusion 214 is located in the recessed portion 200 of the first housing portion 136. A first biasing member (e.g., a first spring 218) is mounted on the projections 212, 214. The first spring 218 biases the first and second teeth 184, 188 of the locking member 180 into engagement with the first teeth 160, 170 of the first and second racks 140, 142.

The actuator 230 is coupled to the locking member 180, and manual actuation of the actuator 230 disengages the locking member 180 from each of the first and second racks 140, 142, as described below. In the illustrated aspect, the actuator 230 is mounted within an opening 232 provided in the first housing portion 136 by a support ring 238. The support ring 238 includes locking tabs 240 on an outer surface 242 thereof, the locking tabs 240 being received in corresponding cutouts 246 located at least partially around an inner surface 248 of the first housing portion 136 defining the opening 232. The support ring 238 also includes guide channels 260 sized to slidably receive corresponding guide tabs 262 provided on the actuator 230. It will be appreciated that each guide channel 260 has a closed end that limits sliding of the actuator 230 to the exterior of the housing 132. The rod 266 projects outwardly from the actuator 230 and extends through a hole 268 formed in the post 202. A second biasing member (e.g., a second spring 270) is mounted on the rod 266 and biases the actuator 230 away from the locking member 180. With continued reference to fig. 4 and 5, the second housing portion 138 includes a post 276 having a stepped configuration that allows the post 276 to be at least partially positioned between the first and second racks 140, 142. In the illustrated embodiment, the post 276 includes a hole 278, the hole 278 being sized to receive the end of the rod 266, the hole securing the second spring 270 between the actuator 230 and the post 276 when assembled. The post 276 also includes a cutout 280, and a stem 282 projects outwardly from the cutout 280. The pinion gear 178 is mounted on a rod 282 and is rotatably received in the cutout 280. This allows the pinion gear 178 to engage the second teeth 162, 172 of the first and second racks 140, 142. As shown, one end of the rod 282 may be configured to engage the bridge 196 of the locking member 180, thereby further securing the locking member 180 within the housing 132.

In use, the locking member 180 is normally biased into engagement with the first teeth 160, 170 of the first and second racks 140, 142 via the first spring 218. This prevents movement of the first and second tubular bodies 110, 118 relative to the central tubular body 102. Manual depression of the actuator 230 pivots the locking member 180 out of engagement with the first and second racks 140, 142. This allows the first and second tubular bodies 110, 118 to move simultaneously relative to the central tubular body 102 via engagement of the pinion gears 178 with the second teeth 162, 172 of the first and second racks 140, 142. When the actuator 230 is released, the second spring 270 biases the actuator 230 outward of the housing 132, and the first spring 218 pivots the locking member 180 back into engagement with the first and second racks 140, 142 again, thereby maintaining the position of the first and second tubular bodies 110 relative to the central tubular body 102.

The example strut tower 100 further includes an extension foot assembly 300 that provides fine tension on the strut tower 100. As shown in fig. 6-9, the extension foot assembly 300 includes a housing 302 coupled to the free second end 114 of the first tubular body 110. The shell 302 may have a flared open end 304 through which the cushion surface member 126 is movably received and a connecting end 306 having spaced apart connecting members 310 extending therefrom. Each of the attachment members 310 includes teeth 312 adapted to engage an inner surface of the first tubular body 110. To connect the shell 302 to the free second end 114, the wedge 316 is loosely connected to the connecting end 306 by a fastener 320, the fastener 320 threadably engaging an insert 322 secured in a bore 324 of the wedge member 316. The wedge member 316 is provided with outwardly inclined surfaces 328 which engage the inner surfaces of the connecting members 310 and which have projections 330, the projections 330 being located between the connecting members 310. The connecting end 306 is inserted into the first tubular body 110 with the wedge 316. The fastener 320 can then be tightened, which pulls the wedge member 316 axially toward the connecting end 306, causing the angled surfaces 328 to press the teeth 312 of the connecting member 310 into engagement with the inner surface of the first tubular body 110.

The extension foot assembly 300 further includes a lever 340 operatively coupled to the cushion surface member 126. As shown, the lever 340 includes an upper cam feature 342 having at least one cam defining a contact surface. According to one aspect, the cam feature 342 has first and second spaced apart cams 344, 346, each having a contact surface. The cam feature 342 is pivotally mounted to the housing 302 by a pivot pin 350, the pivot pin 350 extending through an opening 352 in the cam feature 342 and a corresponding opening 354 in the housing 302. The lever 340 is preferably configured to conform to the shape and contour of the flared open end 304. The pad surface member 126 is connected to a foot support 360 having a contact surface that will engage the cam feature contact surface. In the illustrated embodiment, the foot support 360 includes a base 362 and a pair of spaced apart arm supports 364, 366 extending from the base 362, each arm support including a contact surface. In use, the lever 340 is configured to move between a retracted position and an outward position in which the lever contact surface engages the foot support contact surface to extend the foot support 360 (and the cushion surface member 126 mounted to the base 362) outward from the housing 302. According to one aspect, the extension foot assembly 300 further includes a connecting member 370, the connecting member 370 interconnecting the lever 340 and the foot support 360 and configured to limit travel movement of the foot support 360 outward from the housing 302. The connecting member 370 may be in the form of a link mounted between the cams 344, 346 and the arm supports 364, 366. The first end of the connecting member 370 includes an opening 372, the opening 372 sized to receive a pin 374, the pin 374 also extending through an opening 376 in the cam feature 342. The second end of the connecting member 370 includes an elongated slot 380. The pin 380 is positioned in the slot 382 and passes through an opening 386 in the foot support 360. With this arrangement, rotation of the lever 340 causes the connecting member 370 to move axially toward the first tubular body 110, while the lever contact surface causes the foot support 360 to move outwardly from the housing 302. The distance of travel of the foot support 360 is dependent upon the length of the elongated slot 380 of the connecting member 370.

Accessories such as shelves 400 may be selectively connected along the length of the strut rack 100. One embodiment of the holder rack 100 is used in a shower enclosure or the like to provide support space for items such as shampoos, conditioners, shavers, soaps, brushes, and any other desired product. Thus, the accent shelf is specifically configured with hooks, slots, rails, etc. to hold such products and is provided with a perforated base to facilitate drainage (and other liquids). The illustrated shelf 400 includes an exemplary g shelf support assembly 402 mounted to the central tubular body 102. The shelf support assembly 402 includes a sleeve 406 sized to slide over the central tubular body 102, and a tongue member 410 mounted on the sleeve. The sleeve 406 includes a hook 408 for mounting a shelf. The tongue member 410 fits in the mounting portion 412 of the sleeve 406 such that the base 414 of the tongue member 410 abuts an internal flange 418 defined by the mounting portion 412 and the extension 422 of the tongue member 410 fits in the sleeve opening 424. A compressible pad 430 (e.g., a silicone pad) may then be positioned between the central tubular body 102 and the extension 422, and a silicone strip (not shown) may be adhered to the central tubular body 102 under the base 414. With this arrangement, the tongue members 410 frictionally engage the central tubular body 102 to secure the sleeve 406 to the central tubular body. The shelf mount 440 is connected to the sleeve 406 by a hook 408 extending through an opening 442 defined in the shelf mount 440. As shown, the shelf mount 440 may be a two-part structure having a first mounting portion 444 and a second mounting portion 446, the second mounting portion 446 being secured to the first sleeve portion by fasteners 448, the fasteners 448 extending through openings 450 in the first mounting portion 444 and being in threaded engagement with bosses 452 on the second mounting portion 446. The first mounting portion 444 includes a recessed portion 460 sized to receive the mounting portion 412 of the sleeve 406, and upper and lower wire holder receiving features 464, 466. The second mounting member 446 includes respective upper and lower wire holder receiving features 474, 476. In use, the shelf 400 is first attached to the shelf mount 440, and then this assembly is connected to the sleeve hook 408. It should be appreciated that the sleeve 406 may be molded plastic or coated to avoid damaging the outer surface of the central tubular body 102.

Fig. 12-14 illustrate another aspect of an extension mechanism 500 mounted to the central tubular body 102, the extension mechanism 500 being used to adjust and lock the span of the strut rack 100. Similar to the extension mechanism 130, the extension mechanism 500 is configured to be manually actuated and has a rack and pinion arrangement configured to simultaneously move the first and second tubular bodies 110, 118 relative to the central tubular body 102. The extension mechanism 500 includes a housing 502 mounted at least partially within the central tubular body 102. The housing 502 is defined by a first housing portion 506 and a second housing portion 508, and is at least partially assembled over the first and second racks 140, 142. The pinion 510 is meshed with each of the first and second racks 140, 142, and more specifically, with the second teeth 162, 172 of each of the first and second racks 140, 142.

The locking member 520 of the extension mechanism 500 is configured to move between engagement and disengagement with the first and second racks 140, 142. In the illustrated embodiment, the locking member 520 includes a first portion 522 having first teeth and a second portion 526 spaced from the first portion and having second teeth 528. The first and second teeth 524, 528 of the locking member 520 engage the first teeth 160, 170 of the respective first and second racks 140, 142. According to one aspect, the locking member 520 is biased into engagement with the first and second racks 140, 142, e.g., via a biasing member 530 (e.g., a spring) in a direction perpendicular to the length of each of the first and second racks 140, 142. The spring 530 is mounted on or around a protrusion 532 located in a recess 534 on the second housing portion 508 and on or around a mating protrusion 536 on the locking member 520. The spring 530 normally biases the first and second teeth 524, 528 of the locking member 520 into engagement with the first teeth 160, 170 of the first and second racks 140, 142. The recessed portion 534 is sized to receive the locking member 520 when moved out of engagement with the first and second racks 140, 142. Also shown is an opening 540 in the tab 532, the opening 540 extending through the second housing portion 508. As the locking member 520 moves into the recessed portion 534, the protrusion 536 of the locking member 520 may be at least partially received in the opening 540.

As shown, the first housing portion 506 of the housing 502 includes a recessed portion 550, the recessed portion 550 having an opening 552 therethrough. The second housing portion 508 includes a post 556 having a stepped configuration that allows the post 556 to be at least partially positioned between the first and second racks 140, 142. A rod 558 extends from the post 556 of the second housing portion 508. Pinion 510 is mounted on rod 558 and is rotatably received in recess 550, with the end of rod 558 being at least partially received in opening 552. This allows the pinion 510 to engage the second teeth 162, 172 of the first and second racks 140, 142 flanking the post 556. As shown, an end of the rod 558 may be configured to engage a portion of the actuator support 560 mounted on the first housing portion 506.

The actuator support 560 includes a first portion 562 and a second portion 564 depending therefrom. The first portion 562 includes an opening 568 sized to receive the actuator 570. The post 572 bisects the opening 568 and has an opening 574 extending therethrough. The posts 572 are received in corresponding channels 578 provided in the first housing portion 506. The wall 580 of the first housing portion 506 at least partially defines the passage 578, and the wall 580 includes an opening 584 such that the opening 584 is axially aligned with the opening 574 when the actuator support 560 is properly mounted to the first housing portion 506. In the depicted aspect, the second portion 564 of the actuator support 560 includes an angled portion or locking tab 586, which angled portion or locking tab 586 is received in another recessed portion 588 located on the first housing portion 506 in the illustrated embodiment. The end of the rod 558 engages the angled portion 588.

The actuator 570 is coupled to the locking member 520, and similar to the embodiments described above, manual actuation of the actuator 570 disengages the locking member 520 from each of the first and second racks 140, 142. In the depicted aspect, the actuator 570 fits within an opening 568 provided in the actuator support 560. The actuator 570 includes a stem 590 projecting outwardly therefrom. The shaft 590 includes an enlarged head 592 at a distal end thereof and at least one guide 594. In the aspect shown, a pair of guides 594 are located on the rod 590, which may be radially spaced on the rod 590. The rod 590 extends through the opening 574 of the respective actuator support 560 and the opening 584 of the first housing portion 506, the head 592 of the rod is secured in the projection 536 of the locking member 520, and the guide 594 abuts the locking member 520. Thus, the locking member 520 is fixed to the rod 590 of the actuator 570. It should be appreciated that the openings 574, 584 are configured to slidably receive the guide 594.

In use, the locking member 520 is normally biased into engagement with the first teeth 160, 170 of the first and second racks 140, 142 via the first spring 218. This prevents movement of the first and second tubular bodies 110, 118 relative to the central tubular body 102. Manually depressing the actuator 570 moves the locking member 520 out of engagement with the first and second racks 140, 142 and into the recessed portion 534 of the second housing portion 508. This allows the first and second tubular bodies 110, 118 to move simultaneously relative to the central tubular body 102 via the engagement of the pinion gear 510 with the second teeth 162, 172 of the first and second racks 140, 142. When the actuator 570 is released, the spring 530 moves the locking member 520 back into engagement with the first and second racks 140, 142, thereby maintaining the position of the first and second tubular bodies 110 relative to the central tubular body 102.

Fig. 15-18 illustrate an extension foot assembly 600 that provides fine tension on the strut rack 100 according to another aspect of the present disclosure. Similar to the extension foot assembly 300, the extension foot assembly 600 includes a housing 602 coupled to the free second end 114 of the first tubular body 110. The housing 602 may have a flared open end 604 through which a liner surface member 606 is removably received and a connection end 608 adapted to engage an inner surface of the first tubular body 110. For example, crush ribs can be located on the connection end 608 that at least partially deform when the connection end 608 is inserted into the first tubular body 110. It will be appreciated that the use of crush ribs can ensure a secure connection with the first tubular body 110.

The extension foot assembly 600 also includes a lever 620 operatively coupled to the padded surface member 606. As shown, lever 620 includes an upper cam component 622 having at least one cam defining a contact surface. According to one aspect, cam feature 622 has first and second spaced apart cams 624 and 626, each having a contact surface. The cam feature 622 is pivotally mounted to the housing 602 via a pivot pin 630 that extends through an opening 632 in the cam feature 622 and a corresponding opening (not shown) in the housing 602. The lever 620 is preferably configured to conform to the shape and contour of the flared open end 604 for aesthetic purposes. The pad surface member 606 is connected to a foot support 640 having a contact surface to be engaged by the cam feature contact surface. In the illustrated embodiment, the foot support 640 includes a base 642 and a pair of spaced apart arm supports 644, 646 extending from the base 642, each arm support including a contact surface. In use, the lever 620 is configured to move between a retracted position and an outward position in which the lever contact surface engages the foot support contact surface to extend the foot support 640 (and the cushion surface member 606 mounted to the base 642) outward from the housing 602. According to one aspect, the extension foot assembly 600 further includes a connecting member 650 interconnecting the lever 620 and the foot support 640 and configured to limit travel movement of the foot support 640 outward from the housing 602. The connecting member 650 may be in the form of a link that fits between the cams 624, 626 and the arm supports 644, 646. The first end of the connecting member 650 includes an opening 652 sized to receive a pin 654 that also extends through an opening 656 in the cam feature 622. The second end of the connection member 650 includes an opening 660. Pin 662 is positioned in opening 660 and passes through opening 664 in foot support 640. With this arrangement, rotation of the lever 620 causes the connecting member 650 to move axially toward the first tubular body 110 while the lever contact surface moves the foot supports 640 outward out of the housing 602. And the travel distance of the foot supports 640 is limited by the connection members 650.

Fig. 19-21 illustrate an exemplary shelf support assembly 670 mounted on the central tubular body 102 in accordance with another aspect of the present invention. The shelf support assembly 670 includes a sleeve 672 sized to slide over the central tubular body 102 and a hook assembly 676 mounted on the sleeve having a hook 678 for mounting a shelf. The hook assembly 676 is fitted into the mounting portion 680 of the sleeve 672 in a manner that allows the first and second engagement portions 684, 686 of the hook assembly 676 to engage the central tubular body 102. In the depicted aspect, the first and second engagement portions 684, 686 of the hook assembly 676 at least partially define first and second channels 690, 692. The first and second channels 690, 692 are adapted to receive the first and second elongated guides 696, 698 located on the mounting portion 680. A compressible pad 700 (e.g., a silicone pad) may be positioned between the central tubular body 102 and the hook member 676, and the hook member 676 may include a seat 702 sized to receive the compressible pad 700. With this arrangement, the hook members 676 frictionally engage the central tubular body 102 to secure the sleeve 672 to the central tubular body. The shelf mount 710 is connected to the sleeve 672 via a hook 678 that extends through an opening 712 defined in the sleeve 672. As shown, similar to the shelf mount 440, the shelf mount 710 may be a two-part structure having a first mount 714 and a second mount 716 secured to the first mount by a fastener that extends through an opening 720 in the first mount 714 and threadingly engages a boss 722 on the second mount 716. The first mounting member 714 includes a recessed portion 730 sized to receive a portion of the hook 678, wherein the hook 678 is received through a cutout 732 in the recessed portion. The second mounting portion 716 further comprises a cutout 738 for a hook 678. The shelf mount 710 also has upper and lower wire rack receiving features. In use, the shelf 400 may be first attached to the shelf mount 710, and then the assembly may be connected to the hook 678 of the hook assembly 676. It should be appreciated that the sleeve 672 may be molded plastic or coated to avoid damaging the outer surface of the central tubular body 102.

It will be appreciated that various of the above-disclosed and other features and functions, or alternatives or variations thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.

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