The technical field relates generally to foldable structural trusses.
Structural trusses are used in a wide variety of situations and constructions. They can be used horizontally, vertically or in any other orientation. They include a plurality of rigid frame members interconnected to one another so as to create a skeletal open structure.
Some structural trusses are used in situations where they will be often moved from one location to another. An example of situation is when they are used in performance stages. Many performance stages are designed to be transported from site to site, for example when they are used as concert tour stages. They are thus assembled and disassembled frequently.
Each time a temporary construction must be assembled at a given site, it requires parts to be transported at the site, for instance using one or more truck trailers or the like. This often includes transporting large parts such as structural trusses. Since the space available on a truck trailer is inevitably limited and minimizing the total number of truck trailers is always desirable, minimizing the overall space of each part, especially the largest ones, can have a huge impact on the transportation costs.
Some structural trusses are made of a plurality of parts that are welded or otherwise permanently attached together. They cannot be folded or be completely disassembled into smaller parts. They are thus relatively large in size and they require a lot of space. Structural trusses made of a plurality of detachable parts can be stored and transported in considerably smaller spaces. However, they require that all the parts to be assembled before use and disassembled afterwards. This increases the assembly time and the labor costs.
Foldable structural truss arrangements have been suggested in the past. These arrangements often have parts hinged and/or otherwise operatively connected together to create a self forming assembly that can be collapsed to save space during storage and transportation, and deployed thereafter before use. Examples can be seen in U.S. Pat. No. 3,235,038 (Nesslinger) of 1966, U.S. Pat. No. 5,016,418 (Rhodes et al.) of 1991, U.S. Pat. No. 5,040,349 (Onoda et al.) of 1991, U.S. Pat. No. 7,716,897 (Merrifield) of 2010, U.S. Pat. No. 8,028,488 (Doff) of 2011, and US-2012/0110946 (Daas et al.) of 2012. However, the arrangements disclosed in these references are not always well adapted for use in a wide range of environments and purposes. Some of them also require complex constructions and can be difficult to implement. Still, while reducing the size of some structural truss arrangements when they are in their folded position would be highly desirable, this can be very challenging to achieve, if not impossible, using existing approaches, especially if this must be done without reducing the supported load and without significantly impairing one or more additional design factors, for instance weight, manufacturing costs, assembly time on a site and the associated labor costs, to name just a few.
Clearly, room for improvements still exists in this technical area.
In one aspect, there is provided an elongated double-fold foldable structural truss having a quadrilateral framework extending along a longitudinal direction, the structural truss being movable between a folded position and an unfolded position, and including: four chord beam units disposed parallel to one another, each chord beam unit being located at a corresponding corner of the quadrilateral framework and having four sides, two of the sides being inner sides and two of the sides being outer sides, each inner side facing a corresponding one of the inner sides of another one of the chord beam units of the structural truss, each chord beam unit including: two spaced-apart and juxtaposed beams running parallel to one another, the beams defining between them a first open channel extending substantially along an entire length of the structural truss, the first open channel being opened on one of the inner sides of the chord beam unit, the chord beam unit having a second open channel on the other one the inner sides of the chord beam unit, the second open channel extending substantially along the entire length of the structural truss; a plurality of first pivot joints extending transversally in-between the two spaced-apart beams and across the first open channel, the first pivot joints having first pivot axes that are parallel to one another and that are perpendicular to the longitudinal direction; and a plurality of second pivot joints extending perpendicularly across the second open channel, the second pivot joints having second pivot axes that are parallel to one another, that are perpendicular to the longitudinal direction and that are perpendicular to the first pivot axes of the chord beam unit; and four web units, each including a plurality of brace members interconnecting two corresponding ones of the chord beam units (110), the brace members of two of the web units having opposite ends that are pivotally connected to corresponding ones of the first pivot joints and the braces members of two of the web units having opposite ends that are pivotally connected to corresponding ones of the second pivot joints, the brace members of at least two of the web units being telescopic, each telescopic brace member including two sections in telescopic engagement with one another and being movable between a retracted position and an extended position, the telescopic brace members being all in their extended position when the structural truss is in its unfolded position and being all in their retracted position when the structural truss is in its folded position, all brace members extending at least partially inside a corresponding one of the open channels when the structural truss is in its folded position.
In another aspect, there is provided a structural truss as shown, described and/or suggested herein.
In another aspect, there is provided a structural truss system as shown, described and/or suggested herein.
In another aspect, there is provided a method of folding and unfolding a structural truss as shown, described and/or suggested herein.
Further details on the various aspects of the proposed concept will be apparent from the following detailed description and the appended figures.
The structural truss 100 can be folded and unfolded repeatedly in two perpendicular directions. The folded position is for storage and transportation. It is thus very convenient for use in knockdown structures that must be transported, assembled and then disassembled at frequent occasions.
The parts of the structural truss 100 are made of a rigid material, for instance metallic material such as aluminum or an alloy thereof. Nevertheless, other materials are possible as well.
The structural truss 100 has a quadrilateral framework 102 extending along a longitudinal direction 104. It includes four chord beam units 110 disposed parallel to one another and extending along the entire length of the structural truss 100 when it is in its unfolded position. Each chord beam unit 110 is located on a corresponding corner of the quadrilateral framework 102. Each chord beam unit 110 has two inner sides and two outer sides. Each inner side faces a corresponding one of the inner side of another one of the chord beam units 110. Each of the outer sides are opposite one of the inner sides. Thus, the two inner sides are perpendicular with reference to one another. The four chord beam units 110 are identically in the illustrated example. Variants are possible as well.
The structural truss 100 is designed to be very compact in the folded position, as shown for instance in
Each chord beam unit 110 in the illustrated example includes two spaced-apart and oppositely-juxtaposed C-shaped beams 112 running parallel to one another. The two beams 112 of each chord beam unit 110 extend along the entire length of the structural truss 100. The back sides of these two beams 112 are rigidly interconnected using a plurality of longitudinally-spaced sets of beam holders 114, as best shown in
Four web units 120 are provided on the structural truss 100. Each web unit 120 includes a plurality of brace members 122 interconnecting two corresponding ones of the chord beam units 110. The brace members 122 are obliquely disposed with reference to the longitudinal direction 104 of the structural truss 100. Variants are possible as well.
At least two of the web units 120 include brace members 122 that are telescopic. Each telescopic brace member 122 includes two sections in telescopic engagement with one another. One section is large in size and the other fits therein. These sections are movable between a retracted position and an extended position. The telescopic brace members 122 are all in their extended position when the structural truss 100 is in its unfolded position and are all in their retracted position when the structural truss 100 is in its folded position. When only two of the web units 120 include telescopic brace members 122 and the other two web units 120 have non-telescopic brace members 122, the web units 120 with the telescopic brace members 122 are both extending parallel to one another while the web units 120 with the non-telescopic brace members 122 are both extending parallel to one another. In the example illustrated in
The brace members 122 of two of the web units 120 have opposite ends that are pivotally connected to first pivot joints 130. The brace members 122 of the other two of the web units 120 have opposite ends that are pivotally connected to second pivot joints 132. An example of a first pivot joint 130 and of a second pivot joint 132 are shown in
As can be seen in
The other inner side of each chord beam unit 110 has a second open channel 136 extending along the entire length of the structural truss 100. In the illustrated example, the second open channel 136 is created by the opposite flanges of the C-shaped beam 112. Both open channels 134, 136 are made larger than the width (or outer diameter) of the corresponding brace members 122. Variants are possible. In use, the ends of the brace members 122 remain connected to the corresponding pivot axes 130, 132 and the brace members 122 extend at least partially inside the corresponding open channels 134, 136 when the structural truss 100 is in its folded position. This maximizes the compactness of the folded structural truss 100.
As aforesaid,
Furthermore, in the illustrated example, the first pivot joint 130 is also used as a spacer. The first pivot joint 130 includes a pair of annular bushings 160 coaxially disposed with reference to the first pivot axis 140. A corresponding bolt 152 is inserted through a through-hole at the end of the corresponding brace members 122 and also through registered holes made across the beams 112. A nut and washer are also provided at the end of this bolt 152 and the assembly is tightened to firmly hold the parts together. The bushings 160 can be made of a material such as nylon or any other suitable material. They allow pivoting the corresponding brace members 122 even if the bolt 152 is tighten. Other configurations and arrangements are possible as well.
The second pivot joint 132 also includes a pair of annular bushings 162 and the arrangement is similar to that of the first pivot joint 130 in the illustrated example. It uses a bolt 164. Variants are possible as well.
The quadrilateral framework 102 forms the basic components of the structural truss 100. However, in the example illustrated in
As can be seen in
Still, in the illustrated example, the ends of these cross brace members 168 are removably connected to the corresponding chord beam units 110 using brackets 170. The additional brace members 166 provided at right angles are connected to the chord beam units 110 inside a corresponding one of the open channels 134, 136. All these additional brace members 166 and cross brace members 168 can be completely removed from the structural truss 100 before it is folded. Other arrangements and configurations are also possible.
In the illustrated example, the telescopic brace members 122 each include a self-locking mechanism that automatically locks itself when the two sections of the corresponding brace member 122 reach the extended position. This facilitates the unfolding of the structural truss 100. Workers simply have to move the chord beam units 110 away from one another until the self-locking mechanisms of the brace members 122 are locked. The self-locking mechanisms can include, for instance, spring-biased buttons 180 extending radially out of a hole from the corresponding telescopic brace members 122 when the right position is reached. These buttons 180 can be manually depressed by the workers. Other configurations and arrangements are also possible.
Since the buttons 180 of the self-locking mechanisms have a relatively limited shear resistance, the corresponding sections of each telescopic bracing member 122 can be secured by one or more removable fasteners, for instance bolts, pins or the like. These fasteners are positioned substantially radially across corresponding aligned openings provided through the sections. These openings are configured and disposed to be registered when the self-locking mechanisms are in their locked position. The fasteners 182 are inserted and removed by the workers. Variants are possible as well.
To unfold the structural truss 100, the fasteners 182 must all be removed from the brace members 122 and the buttons 180 can be depressed by hand on each of the brace members 122 to release the self-locking mechanisms and be able to move the telescopic brace members 122 in their retracted position. Variants are possible as well.
It should be noted that the structural truss 100 can be designed to have with more than one unfolded position. One can include one or more additional possible positions where there is less than the maximum width of the structural truss 100 in one or even the two directions, for instance to fit in a small space. Accordingly, any possible working position of the structural truss 100 where it can be locked and secured for use in or as a framework structure is a position where the structural truss 100 can be considered as being completely unfolded. Variants are possible as well.
If desired, one can add more additional chord beam units 110 and a corresponding number of additional web units 120 to form a wider structural truss system 200.
If desired, one can add more additional chord beam units 110 and a corresponding number of additional web units 120 to the structural truss system 200 of
As can be appreciated, the foldable structural truss 100 is very compact in its folded position. The overall cross section area in the folded position is many times smaller than that the overall cross section area in the unfolded position. Moreover, the foldable structural truss 100 can still be manufactured using relatively simple and standard parts so as to minimize the manufacturing costs. The foldable structural truss 100 can be opened and closed relatively easily and quickly since many of the parts are preassembled, thereby minimizing the assembly time and labor costs.
The foldable structural truss 100 can be very useful in many applications. An example of application is a mobile performance stage for music concerts or other kinds of events. Other possible applications include roadways, gangways, bridges, cranes, roadways, catwalks, towers, masts, etc. Many other applications are possible as well.
The present detailed description and the appended figures are meant to be exemplary only, and a skilled person will recognize that many changes can be made while still remaining within the proposed concept.
The present case is a continuation of PCT Application No. PCT/CA2014/050487 filed on 23 May 2014. PCT/CA2014/050487 claims the benefit of U.S. patent application No. 61/826,976 filed on 23 May 2013. The entire contents of these previous patent applications are hereby incorporated by reference.
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Entry |
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Machine translation in English of EP-0733584 A1. |
Machine translation in English of EP-1079039 A1. |
Machine translation in English of RU-2136549 C1. |
Machine translation in English of RU-2137684 C1. |
Machine translation in English of WO-98/40579 A1. |
International Preliminary Report on Patentability (IPRP) under Chapter I of PCT/CA2014/050487 (report dated Dec. 3, 2015). |
Number | Date | Country | |
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20160090741 A1 | Mar 2016 | US |
Number | Date | Country | |
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61826976 | May 2013 | US |
Number | Date | Country | |
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Parent | PCT/CA2014/050487 | May 2014 | US |
Child | 14947769 | US |