KR102221758B1 - Access structure integration assembly and integrated access systems and methods of using the same - Google Patents

Abstract

The present invention includes an access structure integration assembly 300 and an integrated system using the assembly 300. The access structure integration assembly 300 includes at least one channel structure 50 and at least one joist socket 60 that is slidingly coupled with the channel structure 50. The channel structure 50 is configured to be fixed to a foundation structure 100 such as a suspended work platform system, and the joist socket 60 is configured to be fixed to a second structure 200 such as a supported work platform system. The integrated system includes a foundation structure 100, a second structure 200, and at least two integrated assemblies 300, each assembly having a channel structure 50 fixed to the foundation structure 100, and a second structure. It is fixed to the structure 200 and includes a joist socket 60 slidingly coupled to the channel structure 50.

Description

Access structure integration assembly and integrated access system and method using the same {ACCESS STRUCTURE INTEGRATION ASSEMBLY AND INTEGRATED ACCESS SYSTEMS AND METHODS OF USING THE SAME}

Cross-reference to related applications

None

Statement regarding federally sponsored research or development

None

Technical field

The present invention relates generally to the field of construction, and to a hypothetical structure erected to access various parts of the various structures. In one aspect, the present invention relates to the integration of a supported work platform system and a suspended work platform system, and a structural assembly for achieving the same.

Work platforms and other access structures, including suspended work platform systems and scaffolding, allow workers to access hard-to-reach work places and can be assembled on site as needed. For example, when working on a structure such as a bridge, suitable for building a standard supported work platform or without a stable base, the suspended work platform allows workers to access the underside of this structure. The suspended working platform also eliminates the need to build a standard working platform and platform system to an impractical significant height. However, suspended working platforms are not always ideal for accessing some structures. Even after the suspended working platform is in place, the supported working platform can be advantageous in providing improved access to some structures. Accordingly, it may be advantageous to install a supported working platform on top of the suspended working platform.

Suspended working platforms use plywood panels that are fixed within a frame-like structure to form a platform that is suspended from an overhead structure. Legs used with existing supported work platforms put on a large concentrated load. Plywood panels used in suspended work platform systems cannot withstand the pressure exerted by the frame legs, and the load must be properly distributed over the structural members using a dunnage and/or beam. Installing a Dunage system or beam requires considerable equipment, effort, and time. In addition, the Dunage system only withstands downward loads and requires additional guy lines or bracing to withstand lateral, upward, or overturning forces. In other words, the Dunage system only prevents movement in a single direction, and requires a significant amount of extra equipment and materials to prevent movement or movement when a standard work platform system is installed on a suspended work platform system. Dunage is virtually unable to structurally integrate standard supported work platform systems with suspended work platform systems.

In summary, there is a need to overcome the deficiencies specified above and other deficiencies in the art of working platforms and working platform support systems. There is a need for an improved system that effectively integrates suspended and supported work platforms, and that adequately distributes the force exerted by the supported work platform system on the structural members of the suspended work platform system.

In order to overcome the aforementioned and other deficiencies, the present invention provides an apparatus for use with a work platform system, a work platform support system, a work platform system, and a method of manufacturing and installing the same.

In a first general aspect, the present invention provides an access structure integration assembly comprising at least one channel structure, which may be a C-shaped channel, and at least one joist socket, wherein the joist socket is slidingly engaged with the channel structure. In some embodiments, the channel structure is a C-shaped channel and includes a hard, flat bottom; Two flat sidewall portions extending upwardly from the bottom at approximately right angles, each sidewall portion ending at a flange, the flanges extending at a right angle from the sidewall portions so as to extend toward each other; And a linear gap having a width and extending the length of the C-shaped channel. In other embodiments, the joist socket is slidingly coupled with the channel structure using at least one T-bolt that slides with the linear gap of the C-shaped channel. The T-bolt includes a head with a width greater than the width of the linear gap. In other embodiments, the joist socket includes a hollow tubular body; And a base. In one embodiment of the integrated assembly, the C-shaped channel is configured to be fixed to the base structure, and the joist socket is configured to be fixed to the second structure. The foundation structure may be an articulatable suspended work platform system, and the second structure may be a supported work platform system. An access structure integration assembly according to embodiments described herein may include a deck retainer.

In a second general aspect, the present invention provides at least one substantially square channel structure, a rigid flat bottom comprising a plurality of holes corresponding to the holes of the deck retainer, two extending upwardly from the bottom at approximately right angles. A flat sidewall portion, each sidewall portion terminating at a flange, the flanges extending at right angles from the sidewall portions such that the flanges extend toward each other, and a linear gap extending the length of the channel structure and having a width Channel structure; At least one joist socket including a hollow tubular body and a base portion having a plurality of holes; A plurality of T-bolts having a head portion extending into the linear gap of the channel structure through the holes of the joist socket and having a head having a width greater than the width of the linear gap, the T-bolts are slidingly coupled with the channel structure, and each T -A plurality of T-bolts that the bolts are fixed with nuts; And optionally, at least one substantially linear deck retainer comprising a plurality of apertures corresponding to apertures of the channel structure, the deck retainer being parallel to the channel structure, each of the corresponding apertures of the channel structure and the deck retainer. A deck retainer is provided that is secured to the channel structure by a plurality of bolts extending through the set.

In a third general aspect, the present invention comprises at least one unit; A foundation structure fixed to at least one unit, each comprising at least two access structure integration assemblies including at least one channel structure and a joist socket slidingly coupled with the channel structure, each channel structure being fixed to the unit Provides.

In one embodiment, the channel structure is a C-shaped channel that is a substantially square tubular structure, and has a hard, flat bottom; Two flat sidewall portions extending upwardly from the bottom at approximately right angles, each sidewall portion ending at a flange, the flanges extending at a right angle from the sidewall portions so as to extend toward each other; And a linear gap having a width and extending the length of the C-shaped channel. The joist sockets are slidingly engaged with the C-shaped channels using at least one T-bolt that slides with the linear gap of the C-shaped channel.

In some implementations, the foundation structure further comprises a deck retainer secured between the unit and the C-shaped channel so as to be parallel to the C-shaped channel. The joist sockets in any embodiment provided are configured to be secured to a second structure, which may be a supported work platform system.

In one embodiment, at least one unit of the foundation structure comprises four joists interconnected with four hubs. In another embodiment, the unit includes at least two joists, each integrated assembly being secured to one of the joists. The joists may include a plurality of cage nuts, and the C-shaped channels may include a plurality of holes corresponding to the cage nuts, so that the integrated assemblies are each extending through the holes of the C-shaped channels and corresponding It may be fixed to the joists by a plurality of bolts coupled with the cage nut.

The foundation structure according to the embodiments described herein may comprise a plurality of units each defined by four joists interconnected with four hubs, wherein the joists and hubs are coplanar with respect to each other. So that they are interconnected. Each joist may include an upper element and a lower element. The foundation structure may also include a plurality of integrated assemblies, each secured to an upper element of the joist and parallel to the joist. Each joist may further include a plurality of cage nuts, and each channel structure may have a plurality of holes corresponding to the cage nuts, whereby the integrated assemblies extend through the holes of the channel structure and It is fixed to the joists using bolts that engage with the nuts.

In yet another embodiment, the foundation structure further includes a plurality of suspension connectors secured to the hubs.

According to a fourth general aspect, the present invention provides a plurality of joists each having an upper element and a lower element; A plurality of herbs; And a plurality of access structure integration assemblies; The plurality of joists includes at least 4 joists, and the plurality of hubs includes at least 4 hubs; The joists and hubs are interconnected so that the joists are coplanar with each other; Each integrated assembly comprises: a substantially linear deck retainer comprising a plurality of apertures; A substantially square channel structure parallel to the deck retainer, a hard and flat bottom comprising a plurality of holes corresponding to the holes of the deck retainer, two flat sidewall portions extending upwardly from the bottom at approximately right angles, each sidewall portion A channel structure including two flat sidewall portions ending at the flange, wherein the flanges extend at right angles from the sidewall portions such that the flanges extend toward each other, and a linear gap extending a length of the channel structure and having a width; A plurality of deck retainer bolts extending through the deck retainer and corresponding holes in the channel structure; A plurality of joist sockets including a hollow tubular body, and a base portion having a plurality of holes; And a plurality of T-bolts having a head portion extending into the linear gap of the channel structure through the holes of the joist socket and having a head having a width greater than that of the linear gap, wherein the T-bolts are slidingly coupled with the channel structure, and each The T-bolt comprises a plurality of T-bolts that are fixed with nuts; Each channel structure secures at least two joist sockets; Each integrated assembly is secured to an upper element of one of the joists, wherein the number of joists is greater than the number of integrated assemblies.

In one embodiment of the third aspect, the joists include a plurality of cage nuts coupled with deck retainer bolts to secure the deck retainer and channel structure to the joists.

The suspended work platform system may also include at least two suspension connectors each secured to one of the hubs. At least one of the hubs comprises a first surface having a set of openings; A second surface substantially parallel to the first surface and having a second set of openings, and a structural element connected between the first surface and the second surface, of the first set and the second set of openings At least one is coaxial to one of the second set of openings.

In another embodiment, the joist sockets of the suspended work platform system are configured to secure the second structure. The second structure may be a supported work platform system, and the suspended work platform system may be articulated.

According to a fifth general aspect, the present invention provides a foundation structure; A second structure; And at least two access structure integration assemblies including a channel structure, each of which may be a C-shaped channel, and at least one joist socket slidingly coupled with the channel structure; The foundation structure is fixed to the channel structure; The second structure provides an integrated system that is secured to the joist socket. The integrated system may also include a deck retainer. The foundation structure may be a work platform system such as a suspended work platform system or an articulated suspended work platform system. The foundation structure may include one or more units, at least one unit comprising at least four joists; And at least four hubs, each joist having an upper element and a lower element, and at least two of the joists include at least four cage nuts, and the joists and the hubs are coplanar with respect to each other. To be interconnected.

In one embodiment, each access structure integration assembly is secured to the joist so as to be parallel to the joist. Each joist may further include at least two cage nuts, and each integrated assembly may be secured to the joist using at least two bolts each of which is coupled with one cage nut.

In one embodiment of the integrated system, each channel structure is a rigid flat bottom, with two flat sidewall portions extending upwardly from the bottom at approximately a right angle, each sidewall portion ending at a flange, with the flanges extending towards each other. And two flat sidewall portions extending at right angles from and a linear gap having a width and extending a length of the channel structure. Accordingly, each joist socket may be slidingly coupled to the channel structure by a T-bolt slidingly coupled to the linear gap of the channel structure. In some implementations, each joist socket includes a hollow tubular body and a base. The integrated assembly may include two joist sockets.

In one embodiment, the second structure is at least one unit of the work platform system, and the second structure may additionally be a supported work platform system or shoring. The supported working platform according to one embodiment may have at least two layers. The second structure can also be fixed with a barrier.

In another embodiment, the integrated system further comprises a third structure comprising at least 4 hubs and at least 4 joists, each of the 4 joists configured to interconnect with at least 2 of the 4 hubs; The joists and hubs are configured such that (i) one of the joists-and two of the hubs-remain stationary; (ii) two of the joists are rotatable; (iii) two of the hubs-and one of the joists-are configured to be interconnected, such that they are translatable; The two stationary hubs are each connected to the second structure; When interconnected, two rotatable joists, two translatable hubs, and one translatable joist can be articulated from an initial position to a final position for the stationary joist and stationary hubs; At least four joists are substantially coplanar with each other in their initial and final positions; At least one of the joists is configured to be connected with at least one of the hubs using a pin to provide free rotation of the at least one joist with respect to the at least one hub about the pin; The free rotation includes: (i) an additional pin to be located near the outer periphery of the at least one hub; And (ii) at least one of at least a portion of the platform when the platform is positioned relative to the hubs and joists in the final position.

According to a sixth general aspect, the present invention provides an integrated working platform system for suspending from an overhead structure, comprising: a first structure; A plurality of integrated assemblies each fixed to the joist; And a second structure having a frame fixed to the joist sockets; The first structure comprises: at least two suspension connectors having a first end and a second end configured to be secured to the overhead structure; A plurality of joists each having an upper element and a lower element; And a plurality of hubs, wherein at least two of the hubs have a first surface having an opening configured to engage a first end of the suspension connectors; The plurality of joists includes at least 4 joists, and the plurality of hubs includes at least 4 hubs; The joists and hubs are interconnected such that the joists are coplanar with each other, each integral assembly comprising: a substantially linear deck retainer comprising a plurality of holes; A substantially square, tubular C-shaped channel parallel to the deck retainer, with (a) a rigid, flat bottom comprising a plurality of holes corresponding to the holes in the deck retainer, and (b) two extending upwardly from the bottom at approximately a right angle. Flat sidewall portions, each sidewall portion ending at a flange, wherein the flanges extend at right angles from the sidewall portions such that the flanges extend toward each other, and (c) extending the length of the C-shaped channel and having a width. A C-shaped channel comprising a linear gap; A plurality of deck retainer bolts extending through the deck retainer and corresponding holes in the C-shaped channel; A plurality of joist sockets including a hollow tubular body, and a base portion having a plurality of holes; And a plurality of T-bolts having a head portion extending into the linear gap of the C-shaped channel through the holes of the joist socket and having a head having a width greater than that of the linear gap, wherein the T-bolts are slidingly coupled with the C-shaped channels. , Each T-bolt comprises a plurality of T-bolts that are fixed with a nut; Each C-shaped channel provides an integral working platform system, securing at least two joist sockets.

The second structure may comprise a plurality of coplanar platforms, at least one additional platform parallel to the platforms but not coplanar, and/or at least three parallel non-coplanar platforms.

According to a seventh aspect, the present invention provides a method of incorporating a second structure with respect to a foundation structure, the method comprising: providing a foundation structure; Providing a second structure; Providing at least two integral assemblies, each integral assembly including a channel structure and a joist socket slidingly coupled with the channel structure; Fixing the channel structures of the integrated assemblies to the foundation structure; And securing the joist sockets of the integrated assemblies to the second structure.

The foundation structure may be a suspended working platform system or an articulated suspended working platform system. The second structure can be a work platform system.

According to an eighth aspect, the present invention provides a method of installing a supported working platform system to a suspended working platform system, comprising: providing a suspended working platform system suspended from the structure, the suspended working platform system comprising: Comprising a plurality of interconnected hubs and joists such that the joists are coplanar with each other; Aligning the plurality of deck retainers in parallel with the plurality of joists such that the number of deck retainers is smaller than the number of joists and the deck retainers are each parallel to each other; Aligning the deck retainers and the plurality of channel structures on the collinear, wherein the channel structures are a hard and flat bottom including a plurality of holes corresponding to the holes of the deck retainer, two flat bottoms extending upwardly from the bottom at approximately right angles. A sidewall portion, each sidewall portion comprising two flat sidewall portions extending at right angles from the sidewall portions such that the flanges terminate at a flange, the flanges extending toward each other, and a linear gap extending the length of the channel structure, each Wherein the flange has an inner surface and an outer surface; Fixing deck retainers and channel structures to the joists using a plurality of bolts; Providing a plurality of joist sockets including a tubular body, a base having at least two holes, one T-bolt protruding through each hole to face the tubular body, and a nut partially engaged with each T-bolt The step of doing; Sliding each joist socket along the outer surface of one of the flanges such that the T-bolts pass through the linear gap; Tightening the nuts such that the head of the T-bolts engage the inner surfaces of the flanges; And securing the first end of the supported work platform system frame member within each of the plurality of joist sockets.

In one implementation, the method further includes providing a work platform assembly on the second end of the supported work platform system frame members.

The method also includes providing an articulating work platform assembly comprising a plurality of hubs and a plurality of joists coupled to the plurality of hubs; And articulating a work platform assembly capable of articulating from an initial position to a final position, wherein the joint connection comprises at least one of rotating and translating at least one of the plurality of joists with respect to at least one of the plurality of hubs. It may further comprise the step of, wherein the plurality of joists are substantially coplanar with respect to each other in the initial and final positions.

The above-described and other features and advantages of the present invention will become apparent in the following more detailed description of embodiments of the present invention. It should be understood that the above general description and the detailed description to be described below are both illustrative and not limiting of the present invention.

The features of the invention will be best understood from the detailed description of the invention and the embodiments of the invention selected for purposes of illustration and shown in the accompanying drawings.
1 is a top perspective view of an exemplary unit for a foundation structure.
2 is a top perspective view of an exemplary foundation structure.
3 is an exemplary hub for use with the foundation structure of FIG. 2.
4 is a side view of a foundation structure suspended from an overhead structure.
5 is a top perspective view of the hub of FIG. 3 connected to the joist.
6 is a top perspective view of the base structure and unit frame before joint connection.
7 is a top perspective view of the embodiment of FIG. 6 undergoing joint connection.
Figure 8 is a top perspective view of the embodiment of Figure 7 undergoing another joint connection.
9 is a top perspective view of the embodiment of FIG. 8 undergoing different joint connections.
10 is a top perspective view of the embodiment of FIG. 6 in which the joint connection is completed.
11 is a top perspective view of an exemplary foundation unit with multiple integrated assemblies.
12 is a top perspective view of a joist receiving an access structure integration assembly.
13 is a detailed view of a joist socket.
14A and 14B are exploded views of an exemplary integrated assembly.
15 is an isometric view of a joist socket.
16 is an end elevational view of an integrated assembly.
17 is an exploded view of FIG. 16.
18 is an end elevational view of an integrated assembly secured to a joist.
19 is an exploded view of FIG. 18.
20 is an exemplary foundation structure in which a second structure is integrated using a plurality of integrated assemblies.
21-24 illustrate an exemplary integrated system.

While certain preferred embodiments of the invention will be shown and described in detail, it should be understood that many changes and modifications may be made without departing from the scope of the appended claims. The scope of the present invention will not be limited in any way to the number, material, shape, relative arrangement, etc. of components, but is disclosed only as an example of implementation. Features and advantages of the invention are shown in detail in the accompanying drawings, with like reference numerals designating like elements throughout the drawings.

As a prelude to the detailed description, as used in this specification and the appended claims, unless the context clearly dictates otherwise, the singular form ("a", "an", "the") includes a plurality of objects. It should be noted that. Moreover, as used herein, the term “overhead structure” refers to any physical structure on which a work platform can be suspended. Likewise, the term “structure” refers to any physical structure accessible using a suspended work platform system, whether or not a supported work platform system is integrated. In some implementations, the structure and overhead structure can be the same. Exemplary structures and overhead structures include, but are not limited to, bridges, offshore rigs, boilers, boiler pendants, elevated and suspended structures, and ships.

Referring now to the drawings, FIG. 1 shows an exemplary unit 120 of a foundation structure 100. In the illustrated exemplary embodiment, the unit 120, which is a unit of the first working platform system, has four hubs 150 such that the joists 140 are coplanar and fixed to the hubs 150 at approximately right angles. It includes four joists 140 connected by. The hubs 150 and joists 140, together with an optional intermediate support deck joist 52, provide a framework for supporting the platform 170. In the illustrated exemplary embodiment, the platform 170 is separated into two platforms 170A, 170B, with an intermediate support deck joist 52 providing structural support between the platforms 170A, 170B. In other example implementations, a single platform 170 may be used, or the platform 170 may be subdivided into two, three, or more platforms.

2 shows an exemplary foundation structure 100 comprising a plurality of units 120 connected together in hubs 150. In the illustrated exemplary embodiment, the foundation structure 100 is a work platform system comprising a plurality of work platform units. In other example implementations, the foundation structure 100 may be a single unit 120. In still other exemplary embodiments, the foundation structure 100 includes a single joist 140 or at least two coplanar joists 140 configured to have two coplanar portions that are not linear with respect to each other and are spaced apart by a predetermined distance. It can be any structure or system that provides a substantially flat surface.

Joist 140 is any elongate structural member configured to support or support a load, such as a bar joist, truss, section (ie, I-beam, C-beam, etc.), or the like. Hub 150 is an interconnect structure such as a node, hinge, pivot, post, column, center, shaft, spindle, or the like. Accordingly, one of ordinary skill in the art will understand that the size, shape, and arrangement of the hubs 150 and joists 140 may vary to provide the work platform unit 120 and system 100.

For example, the length of the joists 140 and the positions of the joists 140 and the hubs 150 may vary according to a desired size and configuration of the base structure 100. In the illustrated exemplary embodiments, the units 120 are rectangular, so that the joists 140 in one direction are longer than the joists 140 extending in the opposite direction, and the overall rectangular base structure 100 is formed. Although formed, the joists 140 may be of any length and may be connected to the hubs 150 at any angle allowed by the design of the hubs 150. The size and shape of the support platforms 170A and 170B may likewise vary according to the configuration of the joists 140 and the hubs 150.

In the exemplary implementations shown in FIGS. 1 and 2, the foundation structure 100 is shown as an access structure, such as a work platform system. Specifically, the foundation structure 100 is shown as a work platform system (ie, a suspended work platform system) designed to be suspended from an overhead structure. However, the foundation structure 100 may be any foundation structure, as discussed above, including any type of access structure (i.e., a suspended work platform system, a supported work platform system, scaffolding, earth guard). . In preferred exemplary embodiments, the foundation structure 100 is any structure with at least one unit 120 with two coplanar parallel joists 140. More preferably, the foundation structure 100 is a working platform system, even more preferably, a suspended working platform system. In the most preferred embodiment, the foundation structure 100 is an articulated suspended working platform system as described herein.

3 shows an exemplary hub 150 for use with the foundation structure 100, which is an articulated, suspended working platform system in the illustrated exemplary embodiment described. In the illustrated exemplary embodiment, the hub 150 is configured to allow articulation of both the hub 150 and the joist 140 when attached to the joist 140. Articulation as used herein is defined as the ability to swing and/or rotate around a pivot point or axis. The hub 150 also allows the unit 120 and then the foundation structure 100 to be suspended from the overhead structure. However, in other exemplary implementations, the hub 150 may only provide joint connection of the hub 150 or the joist 140, or may not allow joint connection. In yet other example implementations, the hub 150 may not allow the unit 120 or the underlying structure 100 to be suspended.

In the exemplary embodiment shown in FIG. 3 showing a hub 150 that allows joint connection of both the hub 150 and the joist 140 as well as the suspension of the unit 120 and the foundation structure 100, the hub 150 ) Comprises an upper element 11 and a lower element 12 spaced at the distal ends of the intermediate region 15. The upper element 11 and the lower element 12 can be of a substantially flat configuration as well as parallel to each other. The upper element 11 and the lower element 12 are octagonal in the illustrated embodiment. The intermediate zone 15 may be a cylindrical zone, the longitudinal axis of the intermediate zone 15 being perpendicular to the plane of the upper element 11 and the lower element 12. In the illustrated embodiment, the intermediate zone 15 is a staff post. In the illustrated exemplary embodiment, in order to show that the middle section 15 is hollow, the lower part of the middle section 15 has been removed for clarity.

A plurality of openings 13 and 14 extend through both the upper element 11 and the lower element 12 respectively. A plurality of openings 13 (e.g., 13A, 13B, 13C, 13D, 13E, 13F, 13G, 13H) are dotted on the upper element 11 to provide various locations for connection to one or more joists 140. have. A plurality of openings 14 (e.g., 14A, 14B, 14C, 14D, 14E, 14F, 14G, 14H) are likewise spaced apart on the lower element 12 so that the respective openings (e.g., 13A and 14A) are coaxial. have.

In the center of the upper element 11 is a central opening 16 configured to receive a suspension connector for securing the unit 120 and the foundation structure 100 to the overhead structure. The central opening 16 may be of a generally cross-shaped configuration, since four slots 17 (eg, 17A, 17B, 17C, 17D) extend from the central opening region 19 thereof. A series of cross slots 18A, 18B, 18C, 18D traverse and interconnect each of the four slots 17A, 17B, 17C, and 17D. As shown in FIG. 4, the slots 17 and 18 and the central opening region 19 interact with one end of the suspension connector 80 and fix it to the hub 150. The other end of the suspension connector 80 is fixed to the overhead structure 90 to suspend the foundation structure 100. One of ordinary skill in the art will readily appreciate that the slots 17 and 18 and the central opening region 19 may have different configurations and designs, as long as the suspension connector 80 can be coupled with the hub 150.

To improve strength, a second reinforcing plate 20 can be added to the underside of the upper element 11, but the openings of the reinforcing plate 20 consist of a central opening 16 and all auxiliary openings 17, 18, 19). A handle 22 is optionally added to the side of the intermediate section 15.

5 is a top perspective view of the interconnection between a single hub 150 and a single joist 140. The exemplary joist 140 shown in FIG. 5 includes an upper element 32 and a lower element 33. A plurality of diagonal support members 38 are interspersed between the elements 32 and 33. Each of the elements 32 and 33 consists of two L-shaped angled parts 39A and 39B called a joist chord. The elements 32, 33 can typically have the same configuration, except that the upper element 32 includes connecting holes 54A, 54B in the middle thereof. The joist 140 includes a first end 31A and a second end 31B. The upper connecting flange 35 and the lower connecting flange 36 extend at both ends 31A and 31B of both the upper element 32 and the lower element 33. The connecting holes 37 pass through both the upper and lower connecting flanges 35 and 36. Thus, there are four upper connection flanges 35A, 35B, 35C, 35D and four lower connection flanges 36A, 36B, 36C, 36D. Therefore, the upper connecting flange 35A and the lower connecting flange 36A through which the connecting hole 37A passes are at the first end 31A extending from the upper element 32. Likewise, the upper connecting flange 35B and the lower connecting flange 36B through which the connecting hole 37B passes are at the second end 31A of the upper element 32. Subsequently, the upper connecting flange 35D and the lower connecting flange 36D extend at the first end 31A of the lower element 33. The connecting hole 37D passes through these connecting flanges 35D and 36D. The upper connecting flange 35C and the lower connecting flange 36C through which the connecting hole 37C passes are at the second end 31B of the joist 30 extending from the lower element 33.

Additional locking holes 360A, 360B, 360C, 360D, which are also located on the connecting flanges 35A, 35B, 35C, 35D, are inside each of the connecting holes 37A, 37B, 37C, and 37D. A pin may be disposed through the connecting holes 37 and any two corresponding upper and lower openings 13, 14 of the hub 150. For example, the pin is through the upper connection flange 35A; Through the opening 13A; Through the lower connecting flange 36A (all of the first end 31A of the upper element 32); Through the upper connecting flange 35D; Through opening 14A; Then, it may be disposed through the lower connection flange 36D. In this situation, the pin is further screwed through the connecting holes 37A and 37D. The pin includes two roll pins at its upper end, and the lower roll pin of the two roll pins serves as a stop, thereby preventing the pin from sliding through the joist 140 and the hub 150 throughout. The upper roll pin can act as a finger catch to allow easy manipulation of the pin.

The design of these parts allows free rotation of both the joist 140 and the hub 150 while the joist 140 and the hub 150 are connected to each other. While the rotation arrow R ₁ represents the rotation of the joist 140, the rotation arrow R ₂ represents the rotation of the hub 150. This rotational capability provides, in part, the articulation capability of the joists 140 and the hubs 150.

Those of skill in the art will understand that the joists 140 can be of any length and positioned at any angle that can be received by the hub 150. As in the case of a single unit 120 or the foundation structure 100, when a plurality of hubs 150 and joists 140 are connected, the joists 140 are units 120 and the basic structure 100 accordingly. May be pivotable on the hubs 150 to form any configuration of the. Due to this joint connection, the frame of the units 120 may be assembled in a collapsed form while the base structure 100 is in place, and then may be unfolded from the base structure 100 to the outside. When the desired configuration is achieved, the unit 120 is fixed to prevent additional joint connections.

The “in-the-air” assembly of additional units 120 is shown in FIGS. 6-10. 6 shows an exemplary frame for a unit 120A that is assembled and connected to the existing foundation structure 100 in the unit 120B. The new unit 120A is in the initial position before the joint connection. As Figs. 7 to 9 clearly show through the motion arrow M by the combination or rotation of the joists 140D, 140E, 140F and the hubs 150D, 150E, the frame for the unit 120A is final It can be moved and rotated to the required position (Fig. 10). That is, the unit 120A is jointly connected in place.

Once in place, the unit 120A can be locked in its final position using a locking pin as described above. In other exemplary embodiments, by fixing the platform 170 (not shown) in the frame, it is possible to prevent the additional joint connection of the unit (120A).

In alternative implementations, the joist 140 and the hub 150 may be fixed to each other using other structures and methods well known in the art, and the joints of the joist 140 and the hub 150 relative to each other. You may not allow the connection. For example, in some implementations, the joist 140 and the hub 150 are rigidly connected to prevent joint connection and may be locked in place.

11 is a top perspective view of an exemplary foundation structure 100 as shown in FIG. 2 with access structure integration assemblies 300 secured to some joists 140. As discussed in more detail below, the access structure integration assemblies 300 include at least one joist socket 60 and a channel structure 50, but in the illustrated exemplary embodiment, these are intermediate support deck joists. It is fixed to the joists 140 extending perpendicular to the 52. The access structure integration assemblies 300 are used to integrate the second structure 200 or the unit 220 or the frame 210 of the second structure into the base structure 100 or the unit 120 of the base structure. .

In one implementation, the second structure 200 may be any structure that can be incorporated using the access structure integration assemblies 300, such as, for example, any access structure. Access structures include, for example, suspended work platform systems, supported work platform systems, scaffolds, and earth guards.

As shown, the joist sockets 60 are arranged on the channel structures 50 connected in parallel with the joists 140 and fixed thereto. Therefore, the size of the base structure 100 and the arrangement of the joists 140 in detail can determine the configuration of the joist sockets 60, and consequently, the configuration of the second structure 200 integrated with the base structure 100. Inevitably limit it. In the illustrated exemplary embodiment, the channel structures 50 are secured to joists perpendicular to the intermediate support deck joists 52. However, in other exemplary implementations, the channel structures 50 may be secured to joists parallel to the intermediate support deck joists 52 or both.

To save material and assembly time and cost, the channel structures 50 are typically unidirectional, such as joists 140 running perpendicular to the intermediate support deck joists 52 as shown in FIG. It is fixed to the joists 140 leading to. Therefore, the distance between the two joist sockets 60 on a given linear path of the joists 140 (such as the joist sockets 60A, 60C, 60D) is variable, while the (joist sockets 60A, 60B) and Likewise) the distance between the joist sockets 60 on the parallel joists remains the same. Typically, the length of the joists 140 extending perpendicular to the channel structures 50 corresponds to a desired length (or a multiple or multiple) of one dimension of the second structure 200.

In some example implementations, the second structure 200 is a work platform system, and the length of the joists 140 extending perpendicular to the channel structures 50 is the bay size of the work platform system or the work platform system. It corresponds to the length (or times or multiples) of the frame member for. In a preferred exemplary embodiment, the second structure 200 is a supported work platform system. The bay size of most supported work platform systems and hence the length of most frame members for supported work platform systems can be 3 feet, 42 inches, 4 feet, 5 feet, 7 feet, 8 feet, or 10 feet. have. Therefore, the length of the joists 140 of the foundation structure 100 to be integrated with the second structure 200, which is a supported work platform system, is preferably 3 feet, 42 inches, 4 feet, 5 feet, 7 feet, 8 feet. It can be feet, or 10 feet.

12 shows an exemplary joist 140 with an access structure integration assembly 300 comprising a single channel structure 50 and two joist sockets 60. 13 shows the connection between the channel structure 50 and the joist socket 60 in more detail. As described in more detail below, the joist sockets 60 may be positioned and fixed somewhere along the channel structures 50.

In the exemplary embodiments shown, the channel structure 50 is a substantially square tubular structure having a rigid flat bottom 51 and rigid flat sidewalls 54 extending upwardly from the bottom 51 at approximately right angles. Structure. Each side wall 54 ends at a flange 53, with the flanges 53 extending towards each other but from the side walls 54 so as not to physically contact each other to form a linear gap along the length of the channel structure. It faces inward approximately at a right angle, thereby forming a "C" shape. The inner and outer surfaces of the flanges 53 are substantially flat. In some implementations, the channel structure 50 is referred to as a C-shaped channel 50.

In the illustrated exemplary embodiments, the C-shaped channel 50 is secured to the joist 140, with the deck retainer 58 between the joist 140 and the C-shaped channel 50. The deck retainer 58 transmits and distributes force from the second structure 200 incorporated into the foundation structure 100 using the joist 140 and specifically the integrated assemblies 300 along the joist cord 144. It is a substantially linear, rigid structure. When the joist socket 60 is used on the end joist, a tow board may be used instead of the deck retainer 58.

In the exemplary embodiment shown in FIG. 12, while a single C-shaped channel 50 is used, two deck retainers 58 are required to cover the length of the joist 140. In other implementations, the deck retainers 58 as long as the respective holes are aligned with the cage nuts 142 of the joists 140 so that the integrated assemblies 300 can be secured to the joists 140. And the C-shaped channels 50 can have any length.

The joist socket 60 includes a base 62 and support posts 67 and a tubular body 65 that is structurally integrated into a single unit. The tubular body 65 is configured to receive the frame 210 from the second structure 200 to integrate the base structure 100 and the second structure 200. In the illustrated exemplary embodiments, the frame 210 is cylindrical to correspond to the tubular body 65 of the joist socket 60. However, it should be understood that the shape and size of the tubular body 65 may vary to accommodate any shape of the frame 210 for the second structure 200 or unit 220 of the second structure.

The T-bolts 70 fix the joist socket 60 in the C-shaped channel 50 while still allowing the joist socket 60 to slide with the C-shaped channel 50 together with the nuts 78. . As used herein, slidingly engaged means that the two components (ie, the joist socket and the C-shaped channel) are fixed to each other in a manner that allows sliding movement relative to each other. 16 and 17, the T-bolts 70 are T-bolts 70 so that the bolt head 72 slides within the C-shaped channel 50 and is shaped to engage the inner surface of the flanges 53. It has a shaped shape. When the joist socket 60 is in the desired location on the C-shaped channel 50, the nuts 78 are tightened to the T-bolts 70 to lock the joist socket 60 in place. When the nuts 78 are loosened, the T-bolts can slide freely within the linear gap of the C-shaped channels 50, so that the joist sockets 60 are slidingly engaged with the C-shaped channels 50. .

As shown, the holes 69 of the joist socket 60 are provided with holes in the supported work platform system component, such as legs, to secure the supported work platform system to the suspended work platform system 100. Are aligned.

In the illustrated exemplary embodiment, the joist socket base 62 has a width slightly greater than the width of the C-shaped channel 50 and a length sufficient to support a single tubular body 65. However, the joist socket base 62 may have any length to include one or more tubular bodies 65, and the diameter of the tubular body 65 is a leg, or a supportive operation to be coupled with the joist socket 60. It can be understood that it depends on the dimensions of the other components of the platform system. In addition, the width of the joist socket base 62 may vary permissibly depending on the diameter of the tubular body 65, keeping in mind that the T-bolt 70 must still be fully engaged with the base 62.

One of ordinary skill in the art will understand that when integrating the base structure 100 and the second structure 200, the frame 210, such as the legs of the second structure, needs to distribute the weight to the joists 140. The strongest portions of the joists 140 are the panel points 144 where the diagonal support members 38 intersect (more clearly shown in Figs. 14A and 14B). Traditionally, a Dunage, such as an I-beam or other support material, is placed on the joists 140 to transfer the load of the second structure to the panel points 144. However, as discussed above, such a Dunage system prevents downward movement and provides little resistance to horizontal, vertical, and rotational movement. Accordingly, additional fastening devices (ie, tie downs, struts, branch lines, etc.) are used to more firmly support the second structure on the foundation structure.

By fixing the deck retainer 58 and the channel structure 50 directly on the top thereof in parallel with the joists 140, the load of the supported work platform system is concentrated on the joist sockets 60 and the channel structures 50 It is transmitted to the panel points 144 by. In addition, since the joist sockets 60 completely surround the ends of the frame members for the supported working platform system, movement in all directions (including rotational movement) is prevented.

In the illustrated exemplary implementations, the access structure integration assembly 300 secures the second structure 200 to prevent or limit further downward movement. For example, in the illustrated exemplary embodiment described, when the joist socket 60 is secured within the channel structure 50, the joist socket 60 is in each axis for a total of six potential types of movement relative to the joist 140. Including rotational movement, movement of the frame 210 fixed therein in all directions along the x-axis, y-axis, and z-axis will be prevented. However, in other exemplary embodiments, the integrated assembly 300 may limit or prevent movement in at least one of the directions, preferably at least two directions, and more preferably at least three directions. However, in the most preferred embodiment, the integrated assembly 300 comprises all six of the frame members 210 (and hence the second structure 200) to the joist 140 (and hence the foundation structure 100). Restrict or prevent tangible movement.

14A and 14B show an exploded view of the joist 140 with the access structure integration assembly 300. In the illustrated exemplary embodiment, the integrated assembly 300 includes a joist socket 60 and a channel structure 50 that is a C-shaped channel in the illustrated exemplary embodiment. 14A and 14B, square brackets representing the integrated assembly 300 as shown in FIGS. 14A and 14B encompass nuts 78, T-bolts 70, and deck retainer bolts 57, but these components It is understood that it does not form the essential components of the integrated assembly 300 as described in FIG. Other fastening components and mechanisms can be used to secure the C-shaped channel 50 (and deck retainer 58 when used) to the joist 140, and the joist sockets 60 are T-bolts 70. It may be slidingly coupled with the C-shaped channels 50 using other structures and components.

The holes 56 (not shown) of the lower portion 51 of the C-shaped channel 50 are aligned with the holes 59 of the deck retainer 58 (or tow board). The deck retainer bolts 57 are coupled with cage nuts 142 installed in the joist 140 to fix the C-shaped channel 50 to the deck retainer 58 and the joist 140.

The T-bolts 70 may be inserted through the holes 64 of the base 62 of the joist socket 60 to partially engage the nuts 78. With the T-bolts 70 sliding loosely in the holes 64, the joist socket 60 is C-shaped so that the head 72 of the T-bolts 70 is in the C-shaped channel 50. It can be slid on the end of the channel 50. The head 72 of the T-bolts 70 is wider than the opening of the C-shaped channel 50 so that the T-bolt head 72 engages the inner surfaces of the flanges 53. Accordingly, upward movement of the joist socket 60 with respect to the C-shaped channel 50 is prevented. When the joist socket 60 is in the desired position along the C-shaped channel 50, the nuts 78 are tightened to the T-bolts 70 to fix the joist sockets 60 in place using compression force. .

15 is an isometric view of a joist socket 60 showing a tubular body 65 with holes 69 for engagement with structural elements of a supported work platform system. The base 62 includes holes 64 for receiving the T-bolts 70, and support posts 67 for structural integrity. In some example implementations, the base 62 may include additional holes 64 for the T-bolts 70 and the struts 67 may have a different size or configuration.

16 is an end elevational view of the assembled integrated assembly 300. The tubular body 65 is hollow, and the holes 69 are open to the hollow tubular body 65. The T-bolt 70 extends through the base 62 and the opening of the channel structure 50, which is a C-shaped channel in the illustrated exemplary embodiment. The bolt head 72 is wider than the opening of the C-shaped channel 50 and thus engages the flanges 53 when tightened in place by the nut 78. 17 is an exploded view of the integrated assembly 300 of FIG. 16.

18 is a side view of the integrated assembly 300 fixed to the joist 140. To secure the C-shaped channel 50 to the joist 140, the deck retainer bolt 57 is a joist 140 through the channel structure 50 and deck retainer 58, which is a C-shaped channel in the illustrated exemplary embodiment. ) In the cage nut 142 extends inside. 19 is an exploded view of the integrated assembly 300 with the deck retainer 58 of FIG. 18. 19 shows the hole 59 of the deck retainer 58 as having a protrusion around the bottom of the hole 59. As more clearly shown in FIG. 18, the protrusion around the hole 59 fits between the two L-shaped angular parts 39A, 39B of the elements 32, 33 to provide additional stability.

FIG. 20 shows an exemplary second structure 200 integrated with the foundation structure 100 shown in FIG. 11 using access structure integration assemblies 300. In the illustrated exemplary embodiment, the frame 210 of the second structure 200 includes interconnected legs that are fixed within the joist sockets 60. Preferably and as shown in FIG. 20, the second structure is a work platform system, such as a supported work platform system, comprising a plurality of individual units 220.

In the illustrated exemplary embodiment, the foundation structure 100 includes a plurality of units 120, the frame 210 of the second structure includes a plurality of interconnected legs, and includes a plurality of individual units 220. Is configured to qualify. In other exemplary implementations, the foundation structure 100 may be only a single unit 120 or two or more units 120. In other exemplary implementations, the second structure 200 may be a single unit 220 or may be configured to have a frame 210 defining a single unit 220. In other exemplary implementations, the frame 210 of the second structure 200 may fix the platforms.

As the legs of the frame 210 are fixed in the joist sockets 60, the movement of the second structure 200 along the x-axis, y-axis, and z-axis with respect to the joist sockets 60 and each axis Rotating movement is prevented. When the joist sockets 60 are fixed on the C-shaped channels 50 (i.e., when fastened on the C-shaped channels to be immovable), for the base structure 100, the x-axis, y-axis, Movement along the z-axis and rotational movement around each axis are prevented. Therefore, the access structure integration assemblies 300 effectively integrate the base structure 100 and the second structure 200. The term "integrated" as used herein with reference to a suspended working platform or platform system supporting a supported working platform or platform system means a total of six forms of movement of a supported working platform or platform system. (That is, linear movement along the x-axis, y-axis, and z-axis and rotational movement around the x-axis, y-axis, and z-axis) is prevented.

However, since the joist sockets 60 are movable along the C-shaped channels 50 when not fixed in place, the second structure 200 is built in a convenient place on the foundation structure 100, and after assembly It can be slid to the final position. Likewise, the second structure can be built and slid in different locations on the foundation structure 100 to access the various structures at different points along the foundation structure 100 if necessary.

Since the access structure integration assembly 300 transmits the pressure applied by the frame 210 of the second structure 200 to the panel points 144, the size of the second structure 200 is a suspended work platform system. It is limited by the amount of weight that the joists 140 of 100 can support. For example, when the foundation structure 100 is a suspended work platform system and the second structure 200 is a supported work platform system, if the joists 140 continue to support the weight and pressure exerted by the supported work platform system, , The supported work platform system may comprise a single layer or multiple layers.

FIG. 21 shows exemplary foundation structures 100 which are suspended work platform systems, incorporating second structures 200 which are supported work platform systems. In the illustrated embodiment, the foundation structures 100 are suspended from a structure 90 that is a diagonal beam. As shown, in order to provide access to the underside of the structure 90 as well as the sides of the structure 90 between the suspended work platforms, the second structure 200 is based using the integrated system 300. It is integrated with the structure 100.

FIG. 21 also shows that the foundation structure 100 is integrated with the second structure 200 and may depend on the second structure 200. For example, as shown in FIG. 21, the foundation structure 100 may be an articulated suspension-type work platform system, but as described in connection with FIGS. 6 to 10, the suspension-type work platform system 100b is It is built from the supported work platform system 200a, and the suspended work platform system 100c is built from the supported work platform system 200b. Thus, in order to continue accessing the structure 90 above the supported work platform 200c, the workers assemble additional suspended work platforms, as described in FIGS. 6-10, from the supported work platform 200c. Afterwards, it is possible to assemble additional supported working platforms that are integrated with the newly suspended platform system as described herein.

22 shows another exemplary implementation of a foundation structure 100 that is integrated with a second structure 200 using access structure integration assemblies 300. In the illustrated exemplary embodiment, the foundation structure 100 is a suspended work platform assembly and the second structure 200 is a supported work platform assembly. The foundation structure 100 is suspended from an overhead structure (not shown) and is used, for example, to access the substructures 91.

As shown in FIG. 22, the foundation structure 100 is suspended from the overhead structure, but the second structure 200, which is a supported work platform system, is built upward from the foundation structure 100. In the exemplary embodiment shown in FIG. 22, a six-story supported working platform is secured over the foundation structure 100. As shown in Fig. 22, the layers of the supported work platform system are parallel to each other but not coplanar. As described above, the number of floors of the support structure 200 integrated with the foundation structure 100 will vary depending on the work to be performed and the maximum amount of weight that the joists 140 can support.

23 shows an exemplary embodiment of the foundation structure 100 with the access structure integration assemblies 300 incorporating the second structure 200, wherein the foundation structure 100 is a suspended work platform system, 2 Structure 200 is a supported work structure system. The supported work platform system is built upwards from a suspended work platform system that is fixed under a structure 90, which is a two-point structure, such as a bridge or part of an offshore rig in the illustrated embodiment. As shown, the foundation structure 100 is suspended below the structure 90 and also extends out of the footprint of the overhead structure 90. The second structure 200 is built upward from a portion of the foundation structure 100 that is not directly below the structure 90 to access the sides of the structure 90.

In other implementations, as shown in FIG. 24, the second structure may be integrated with the foundation structure to provide support for an object such as a tarp or barrier. In FIG. 24, the second structure 200 is integrated with the foundation structure 100 using integrated assemblies 300, and the second structure is used to fix the barrier 95, which is a tarpaulin. For example, when painting the structure 90, the barrier 95 prevents debris (eg, soil, dust, water, pollen) from entering the work area and damaging or interfering with the painting or drying process. The barrier 95 also prevents contaminants (eg, smoke, vapors, particles) from exiting the work area and entering the environment. Therefore, the second structure 200 is used to create factory-like conditions in the field.

The drawings and description provided herein illustrate the foundation structure 100 which is a suspended or articulated suspended work platform system that is integrated with a second structure that is a supported work platform system, but the integrated assembly 300 includes various foundation structures and It goes without saying that it can be used to integrate the second structures.

The foregoing description of the present invention has been provided for purposes of illustration and description. This is not intended to be exhaustive or to limit the present invention to the precise form disclosed or to a material capable of implementing this form, and a number of modifications and changes may be made in consideration of the above teaching.

Specifically, the present invention is not limited to the embodiments and illustrations contained herein, but modified forms of embodiments, including some of the embodiments, and elements of different embodiments that fall within the scope of the following claims. It is intended to include combinations of.

Claims (65)

It has a linear gap, a hard and flat lower portion and two flat sidewall portions extending upward from the lower portion, each sidewall portion ending at a flange, the flange extending from the sidewall portions so that the flanges extend toward each other, the linear gap At least one channeled structure to create a; And
At least one socket connected to a rigid base at a first end and comprising a hollow tubular body having a second open end,
The socket is slidingly coupled with the channel structure using at least one T-bolt slidingly coupled with the linear gap. The method of claim 1,
Wherein the two flat sidewall portions extend upwardly from the bottom at approximately right angles, and the flanges extend at right angles from the sidewall portions. The method of claim 1,
The at least one channel structure,
Is a substantially square tubular C-shaped channel,
Flat lower part;
The two flat sidewall portions, the sidewall portions extending upwardly from the lower portion at an approximately right angle; And
Including the linear gap,
Wherein the linear gap has a width. The method of claim 1,
An access structure integration assembly comprising at least two sockets. The method of claim 1,
Wherein the channel structure is configured to be secured to a base structure, and the socket is configured to be secured to a second structure. The method of claim 5,
Wherein the foundation structure is a suspended work platform system. The method of claim 6,
The suspended working platform is articulated, access structure integrated assembly. The method of claim 5,
The second structure is a supported work platform system. The method according to any one of claims 5 to 8,
And a deck retainer secured between the channel structure and the foundation structure. At least one unit comprising at least two elongate structural members; And
Each access structure integration assembly comprises at least two access structure integration assemblies according to any one of claims 1 to 8,
Each channel structure is fixed to one of the elongate structural members and is parallel to any of the elongate structural members. The method of claim 10,
Wherein the access structure integration assemblies each include a deck retainer, the deck retainers being secured between the unit and a lower portion of the channel structure so as to be parallel to the channel structure. The method of claim 10,
The at least one unit comprises four elongate structural members interconnected with four hubs. The method of claim 12,
The elongate structural members include a plurality of cage nuts, lower portions of each channel structure include a plurality of holes corresponding to the cage nuts, and the access structure integration assemblies are formed by a plurality of bolts. A foundation structure fixed to the structural members, each bolt extending through the hole of the channel structures and engaging a corresponding cage nut. The method of claim 10,
The foundation structure is a suspended work platform system,
The above suspended working platform system:
A plurality of elongate structural members each having an upper element and a lower element; And
Including; a plurality of herbs;
The plurality of elongate structural members comprises at least four elongate structural members, and the plurality of hubs comprises at least four hubs;
The elongate structural members and hubs are interconnected such that the plurality of elongate structural members are coplanar with each other;
The foundation structure further comprises a plurality of access structure integration assemblies, each access structure integration assembly:
A substantially linear deck retainer comprising a plurality of holes, wherein the channel structure is a substantially square tubular channel structure parallel to the deck retainer, and the hard and flat lower portion is a plurality of corresponding to the holes of the deck retainer. Deck retainer, including the holes of the;
A plurality of deck retainer bolts extending through the corresponding holes of the channel structure and the deck retainer;
A plurality of sockets including a hollow tubular body, and a base having a plurality of holes; And
A plurality of T-bolts extending into the linear gap of the channel structure through the holes of the socket and having a head portion having a width greater than that of the linear gap, the T-bolts sliding with the channel structure A plurality of T-bolts, each T-bolt being fixed with a nut;
Each channel structure fixes at least two sockets,
Each access structure integration assembly is secured to an upper element of one of the elongate structural members,
Wherein the number of elongate structural members is greater than the number of access structure integration assemblies. The method of claim 14,
At least one of the hubs is:
A first surface having a first set of openings;
A second surface substantially parallel to the first surface and having a second set of openings; And
A structural element connected between the first and second surfaces,
At least one of the first set and the second set of openings is co-axial with respect to one of the second set of openings. A foundation structure, each of which is a suspended work platform system comprising an upper element, a lower element and at least two elongated structural members having a plurality of cage nuts positioned along the upper element;
At least one unit of a supported work platform system; And
Comprising at least two access structure integration assemblies according to claim 1;
Each access structure integration assembly is secured to one of the elongate structural members so as to be parallel with each elongate structural member,
The integrated system, wherein a second structure is secured to the suspended work platform system by engagement with the sockets. The method of claim 16,
The foundation structure includes at least one unit,
The at least one unit is:
At least four elongate structural members each having an upper element, a lower element and a plurality of diagonal support members interspersed between the upper and lower elements, wherein at least two of the elongate structural members are at least two At least four elongate structural members, including cage nuts; And
Contains at least 4 herbs,
The elongate structural members and hubs are interconnected such that the elongate structural members are coplanar with each other. The method of claim 17,
Each access structure integration assembly is secured to the elongate structural member using at least two bolts, each of which engages with one cage nut. In the integrated work platform system for suspension from an overhead structure,
A first structure;
A plurality of access structure integration assemblies according to claim 3 each fixed to the elongate structural member; And
And a second structure having a frame fixed to the sockets;
The first structure is:
At least two suspension connectors, having a first end and a second end configured to be secured to the overhead structure;
A plurality of elongate structural members each having an upper element and a lower element; And
A plurality of hubs, at least two of the hubs having a first surface having an opening configured to engage the first end of the suspension connectors;
The plurality of elongate structural members comprises at least four elongate structural members, and the plurality of hubs comprises at least four hubs;
The elongate structural members and hubs are interconnected such that the elongate structural members are coplanar with each other;
Each access structure integration assembly:
A substantially linear deck retainer comprising a plurality of holes, the plurality of holes of the deck retainer corresponding to a plurality of holes included in the hard and flat bottom of the C-shaped channel;
A plurality of deck retainer bolts extending through the deck retainer and the corresponding holes of the C-shaped channel;
A plurality of sockets including a hollow tubular body, and a base portion having a plurality of holes; And
A plurality of T-bolts extending into the linear gap of the C-shaped channel through the holes of the socket and having a head portion having a width greater than that of the linear gap, the T-bolts being the C-shaped channel And a plurality of T-bolts that are slidingly coupled to each other, and each T-bolt is fixed with a nut;
Each C-shaped channel secures at least two sockets. In the method of installing a supported working platform system for a suspended working platform system,
Providing a suspended work platform system suspended from a structure, the suspended work platform system comprising a plurality of interconnected hubs and elongate structural members such that the elongate structural members are coplanar with each other. , step;
Aligning the plurality of deck retainers in parallel with the plurality of elongate structural members such that the number of deck retainers is less than the number of elongate structural members and the deck retainers are each parallel to each other;
Aligning the deck retainers and a plurality of C-shaped channels collinearly, wherein the C-shaped channels are formed at a hard and flat bottom, approximately at a right angle, including a plurality of holes corresponding to the holes of the deck retainer. As two flat sidewall portions extending upward from the lower portion, each sidewall portion ends at a flange, and the flanges extend at a right angle from the sidewall portions so as to extend toward each other, two flat sidewall portions, and the C shape Comprising a linear gap extending the length of the channel, each flange having an inner surface and an outer surface;
Fixing the deck retainers and C-shaped channels to the elongated structural members using a plurality of bolts;
A tubular body connected at a first end to a rigid base having at least two holes and having a second open end, one T-bolt protruding through each hole to face the tubular body, and each T -Providing a plurality of sockets, comprising a nut partially engaged with the bolt;
Sliding each socket along the outer surface of one of the flanges such that T-bolts pass through the linear gap;
Tightening nuts such that the heads of the T-bolts engage the inner surfaces of the flanges; And
Securing the first end of the supported work platform system frame member within each of the plurality of sockets. The method of claim 20,
And providing a work platform assembly on the second end of the supported work platform system frame members. The method of claim 21,
Providing an articulating work platform assembly comprising a plurality of hubs and a plurality of elongate structural members connected to the plurality of hubs; And
Articulating the jointly connectable working platform assembly from an initial position to a final position, wherein the jointly connecting step rotates one or more of the plurality of elongated structural members with respect to one or more of the plurality of hubs. Comprising at least one of the step and the step of translating, further comprising a step,
Wherein the plurality of elongate structural members are substantially coplanar with each other in the initial and final positions.
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