That type of framework systems have been known for a long time, and used both in temporary and contemporary structures. The connectors connect bars to each other, producing connection nodes. In those framework systems, especially in temporary structures, like fair stands or booths, the connectors are preferably manufactured from a durable material, like stainless steel, that can withstand the load and weariness due to the numerous connection/disconnection routines, while the bars are preferred to be manufactured from lightweight and preferably extrudable materials, like aluminum, to benefit from customizable cross sections. Therefore, in most cases, the connectors are the preferred elements in the framework system that the framework components, including panels and especially diagonal braces, are connected to. The panels are flat elements, used mainly for separation purposes and diagonal braces comprise elongated elements in the form of a rod, wire or a profile element, used for improving the load bearing capacity of the framework system and bear compression or tension forces or both.
Because the connectors are used numerously in those framework systems, the excess weight of an oversized connector has a limiting effect on the load bearing capacity of the overall system. The oversized connectors have negative effects, also on manufacturing costs and on labor costs due to the increased time for setting the system numerously up and down especially in temporary structures, like fair stands or booths.
Connectors are generally polyhedron shaped elements with faces that receive bars. For reasons of not getting oversized and stabilization of the bars, the faces are shaped in relation with the cross section of the bar that is received, in such a way that, is covered by the bar substantially, if possible. The peripheral surface of the connector get covered substantially, when each of the faces receive at least one bar and especially in the cases of the bars with cross sections, shaped as a convex polygon, especially a regular convex polygon or a circle. That type of bars is among the most widely used types of bars in the framework systems, due to their high torsional resistance. The problem arises when to add framework components to their connectors. In known framework systems, the connectors fail to receive the framework components without being considered as oversized, especially for the cases in those systems, when those connectors are also used without the framework components, regarding that the components are used in the system only where needed. The additional faces, physical elements or surface area, dedicated for attaching the components, increase the overall size of those connectors and make them considered as over-sized. Furthermore, the over-sized connectors and their additional features dedicated for attaching components which usually remain useless for the cases without them, usually have negative effects on the ability of the framework's capability of attaching panels, by interfering with them and bringing out a problem of making undesirable arrangements especially at the corners of that panels.
Among those polyhedron shaped connectors of known systems, there are lightweight connectors with hollow forms that have advantageous shape on attaching framework components, as in the prior art document; WO 02/081837 A. With certain modifications, aiming to make use of the cavity inside the connector and to attach the framework components, that type of connectors can come out to be able to receive framework components without a disadvantage of over-sizing. Because of being composed of flat elements, they are relatively lighter than the connectors other than hollow formed ones, but most of them have significantly poor load bearing capacity, because of the relatively small contact surfaces between the flat elements. Another document; WO 0149950 A discloses another hollow formed connector, with relatively higher stability. But, however, that connector, together with the former one, has a limited capacity, when it comes to adding diagonal braces. Because, in the case of a diagonal brace, that is fixed to the plates and apply especially tensile forces thereto, the plates cannot withstand to the forces with a relatively high magnitude, without being ruptured. The option of increasing the thickness of the plates that those connectors are composed of, in most cases, gives away the other advantages of being hollow.
Most of the connectors other than hollow formed ones, generally don't have the disadvantage of poor loadability, but their problem is that, they attach the framework components, by means of certain modifications on the polyhedron shape, adding physical features, surface area or converting the polyhedron into another type of a polyhedron with additional faces to receive the framework components, when needed. So far, those solutions, failed to make their connectors to receive the framework components without getting oversized, especially for the cases with the same connectors in the system without that framework components. For example, in the prior art document, with the publication number US 2008/0175655 A, a cube shaped connector is suggested with a pair of extensions in the form of arms on a peripheral edge of each face of the connector, to form loops, wherein a diagonal connection with a hook-shaped end, is received and retained therein. But however, in order to locate the arms, the flat formed face elements are separated from each other and located at a distance at least the same as the length of the anus, increasing the overall size. The length of the anus must further be increased, for the cases the diagonal connection approaches to the surface of the bar, due to the angle therebetween, to prevent the end of the diagonal connection interfere with the surface of the bars. Furthermore, when a panel element with peripheral edges shaped in relation to the bars, is located in between a pair of bars, being surrounded thereby, the arms extend toward the panel element interfering therewith and brings a problem of making undesirable arrangements at the corners of that panels. That type of panel attachment is used frequently, especially in temporary framework systems like exhibition systems.
Therefore, the object of my invention is to produce a connection node, with a connector, connecting framework components and bars, especially bars with cross sections shaped circular or as a regular convex polygon, in a supporting framework system, substantially without being oversized, for both of the cases, the case with the framework components and the case, when those connectors are also used without the framework components.
For the purpose I stated above and in accordance with the invention, I suggest a supporting framework, having nodes and at least one framework component. The framework components are either panels or diagonal braces or a combination of them. At least one node has a connector and at least one bar. At least one connector has a plurality of bar receiving members that are located in a corresponding plurality of faces of an imaginary polyhedron and at least one bar has a first end, fixed to the one of the bar receiving members of the connector of a first node and a second end, fixed to the corresponding bar receiving member of the connector of another node.
The supporting framework is characterized in that; the bar receiving members are in plate form and at least one connector further has an inner core, located in between the bar receiving members and the inner core has projections, each projecting toward one of the bar receiving members and connected to the back faces of them, the corresponding connector, further has at least one receiving plate, having a receiving member and each of the receiving plates is located between an adjacent couple of the projections of the inner core, and connected thereto, substantially, on an imaginary plane that passes through the longitudinal axes of each of the projections of the adjacent couple thereof, projecting toward the back faces of a corresponding adjacent couple of the bar receiving members and being connected thereto, whereby the receiving plates, the inner core and the bar receiving members, together, define a cavity, inside the imaginary polyhedron, at substantially at least one side of the receiving plate and the corresponding node further comprises at least one component holder having at least one supporting face and at least one projection and the component holder is located substantially in between the proximal portions of a first bar and a second bar, the second bar is adjacent to the first bar and the proximal portions of the bars are facing each other and the supporting face is located contacting with and substantially enclosing the proximal portion of at least of the one of the corresponding adjacent couple of the bars and the projection of the component holder projects inward the cavity, reaches the receiving member of at least one receiving plate and is releasably connected thereto and at least one framework component is connected to the component holder of the connector of at least two of the nodes, whereby a supporting framework is produced, wherein, the load of the framework components that is transferred to the node, is not taken and the stabilization of the framework components is not enabled, by the connector directly, but, shared between the connector and the surface of the bars. That collaboration decreases the share of the connector and the receiving plates, on load bearing and stabilizing the framework components 102, in accordance with the component holder and its projection, and a component holder, substantially as described and in accordance with the invention, is used with a preferable connector, having disc shaped bar receiving members that are located substantially at a tangential position to others, in a corresponding plurality of faces of an imaginary cube, the connector receiving cylindrical bars, with diameters substantially the same as the imaginary cube edges. Thus, a connector is produced, which is not over-sized, yet having the ability of being connected to framework components in a supporting framework system.
For the purposes stated above and in accordance with the invention, I suggest another supporting framework, having nodes and at least one framework component. The framework components are either panels or diagonal braces or a combination of them. At least one node has a connector and at least one bar. At least one connector has a plurality of bar receiving members that are located in a corresponding plurality of faces of an imaginary polyhedron and at least one bar has a first end, fixed to one of the bar receiving members of the connector of a first node and a second end, fixed to the corresponding bar receiving member of the connector of another node.
The supporting framework is characterized in that; the bar receiving members are in plate form and at least one connector further has an inner core, located in between the bar receiving members and the inner core has projections, each projecting toward one of the bar receiving members and connected reversibly to the back faces of them, the corresponding connector, further has at least one receiving plate, having a receiving member and each of the receiving plates, is located between an adjacent couple of the projections of the inner core, and connected thereto, substantially, on an imaginary plane that passes through the longitudinal axes of each of the projections of the adjacent couple thereof, projecting toward the back faces of a corresponding adjacent couple of the bar receiving members and being connected thereto, whereby the receiving plates, the inner core and the bar receiving members, together, define a cavity, enlarging towards inside of the imaginary polyhedron, at substantially at least one side of the receiving plate, the corresponding node further comprises at least one holder, having a first portion located in the cavity, substantially in between at least three adjacent receiving plates and the holder is shaped such that, the first portion can be placed in the cavity with a removal of at least one of the corresponding bar receiving members and is retained therein when the bar receiving members are replaced, the first portion extends towards the receiving member of at least one receiving plate and is releasably connected thereto and a second portion of the holder extends outward the connector and at least one framework component is connected to the holder of the connector of at least two of the nodes. The movability of the bar receiving members enable the holder to use the cavity, inside the imaginary polyhedron, more effectively and to be able to be connected to a plurality of receiving plates when necessary. Thus, a framework node is produced wherein; the connector's capacity of attaching framework components, especially diagonal braces, is improved with regard to the capacity of a polyhedron shaped connector, of the same overall size and with faces immovable. In accordance with the invention, this improvement enables, a preferable connector, to be produced, having disc shaped bar receiving members that are located substantially at a tangential position to others, in a corresponding plurality of faces of an imaginary cube, receiving cylindrical bars, with diameters substantially the same as the imaginary cube edges, the connector, yet, having the ability of being connected to framework components.
Preferably at least one holder, further comprises at least one supporting face and the second portion of the holder, extends outward the cavity towards a location substantially in between a proximal portion of a couple of the adjacent bars, and the supporting face thereof, is located contacting with and enclosing the proximal portion of at least one of the corresponding couple of the adjacent bars, whereby the load of the framework components is transferred both, to the receiving plates and to the surface of the bars but not directly to the bar receiving members.
a is a side elevation of the connector, and
a and 3b are perspective views of the framework node with the component holder.
a is a perspective view of the connector and illustrates the connection of the component holder to the connector,
a is a perspective view of the modular connector,
a is a perspective view of the holder and
With reference to the embodiment shown in
The node 101 further has at least one component holder 149 as shown in
a shows diagonal tension braces 104 connected to the connector 108 as framework components 102 and
The component holder 149 can be produced in various different versions. The component holder 149 that is shown in
The
The node 201 further has at least one holder 241 as shown in
Preferably, the holder 241, further comprises at least one supporting face 256 as shown in the
The bar receiving members 213 are connected to the inner core 220 by means of the plate connector 217. The plate connector 217 has a mating bore 218 at the first end, extending radially toward a second end 274 and the projections 222 of the inner core 220, comprise a mounting bore 221 at the distal end 223, extending radially inward. The bar receiving members 213 comprise an opening 215. The bar receiving members 213 are mounted on the distal end 223 of the respective projection 222 of the inner core 220 by means of the plate connector 217, inserted through the openings 215 of the bar receiving members 213 into the corresponding mounting bores 221 of the projections 222 of the inner core 220. The second end 274 of the plate connector 217, can be shaped, such that a simple fastener can be inserted into the mating bore 218, and easily fasten the plate connector 217. The bars 210 comprise a bar end 211 preferably at each end of them. The bar end 211 is a protrusion, sized in relation to the mating bore 218 and the bar ends 211 of each bar 210 are inserted into the mating bore 218 of the corresponding connector 208.
Each of the bar receiving members 213, have preferably have passages 216. In a preferred connector 208, with the imaginary polyhedron 219 that is a cube, there are basically four passages 216. Each of the passages 216 are superposed to one of the receiving plates 224 and each of the receiving plates 224 has a protrusion 227, that protrudes toward the corresponding passage 216 and the protrusion 227 is received and retained therein, whereby any rotative motion of the bar receiving members 213, with regard to the longitudinal axis of the corresponding bars 210, is restrained. That restraining provides additional protection against an undesired dislocation of the bar receiving members 213.
In another preferred embodiment the bars 210 comprise slots 212 on their periphery, extending along the longitudinal axis of the bars 210. There are basically four slots 212 for each bar 210. Each one of the slots 212 is superposed to one of the protrusions 227 of the receiving plates 224, and the protrusion 227 of those receiving plates 224, protrude through the corresponding passages 216 of the bar receiving member 213 toward the corresponding slots 212 of the bars 210, the protrusions 227 are received and retained in the slots 212, whereby the rotative motion of the bars 210 with regard to their longitudinal axis, is restrained. That restraining provides additional protection against an undesired dislocation of the bars 210 and gives further resistance against the torsional movement of the bars 210, providing a positive effect on the load bearing capacity of the framework node 201. By means of the receiving plates 224 and especially that, they have protrusions 227, protruding through the passages 216 of the bar receiving members 213, the supporting role of the bar receiving members 213 is minimized and that can enable us to produce the bar receiving members 213 relatively thin and even from different materials like aluminum or plastic.
Preferably, the framework components 202 like diagonal braces 203 are located in between a two adjacent holders 241 and connected to the second portions 246 of them as shown in
As I mentioned before, a framework component 202 can either be a diagonal brace 203 or a panel 265. Each of the diagonal braces 203 preferably has a brace eye 207 at one end and the second portion 246 of the holder 241 preferably has an eye 260. The brace eye 207 is aligned to the eye 260 of the holder 241 and the diagonal brace 203 is connected pivotally to the second portion 246 of the holder 241 by means of a bolt 269 and a nut 270. Other types of fasteners can also be used like a pin and an external retaining ring (not shown). The panel 265 can be connected directly to the holder 241, but preferably the panels 265 are connected to the holder 241 by means of a panel arm 266, that is connected to the holder 241 as shown in the
As shown in
All of the connectors and the connection elements can be produced with high quality stainless steel casting. Panel arms can be produced easily and economically with a conventional punch and bending process. The diagonal braces can be produced with conventional machining process. The bars can be made of aluminum and aluminum extrusion process can be used to produce the bars with custom cross sections, like bars with slots.
This is a divisional application of application Ser. No. 14/383,108 filed on Sep. 5, 2014 which relates to a supporting framework, having connection nodes, the connection nodes having connectors, bars, and framework components, including panels and diagonal braces.
Number | Name | Date | Kind |
---|---|---|---|
4480418 | Ventrella | Nov 1984 | A |
4922669 | De Pas | May 1990 | A |
8820025 | Rochas | Sep 2014 | B1 |
20050040312 | Tsai | Feb 2005 | A1 |
20080175655 | Daubner | Jul 2008 | A1 |
20140331591 | Ohlson | Nov 2014 | A1 |
20150021285 | Pacaci | Jan 2015 | A1 |
Number | Date | Country | |
---|---|---|---|
Parent | 14383108 | Sep 2014 | US |
Child | 14716903 | US |