KR20170015282A - A framework structure - Google Patents

Abstract

A framework structure for providing a barricade or a support structure comprising a frame comprising a single pair of pivotally connected supports, the pair of supports including a first axis And wherein the footprint of the frame is larger in the deployed configuration than in the folded configuration, the connecting element is pivotally connected to the frame, releasably connected to the neighboring body or structure, Wherein the connecting element is rotatable about a second axis that is the same as or parallel to the first axis.

Description

Framework structure {A FRAMEWORK STRUCTURE}

The present invention relates to a framework structure, in particular a framework structure for providing a barricade or supporting structure.

The framework structure is used in many different environments. For example, the temporary framework structure is used as an obstacle to blocking or blocking or approaching the crowd, and the framework structure is used to support signs or advertisements or to provide means for partitioning the area.

Usually temporary obstacles are formed by individual "flat" fences or panels, which are much wider than their depth. These are usually assembled by aligning and connecting the ends of each individual fence unit to form a long obstacle. If such an obstacle is usually formed of a rigid material such as a steel fence, the obstacle is insufficient in depth to form a stable obstacle when facing a large number of crowd or forward forces. In addition, the assembly of these obstacles is labor intensive because each obstacle must be transported to that location and usually associated with neighboring obstacles on site. Moreover, when disrupting these obstacles, the obstacles again require a large amount of manpower and require a relatively large space for storage and transportation compared to the length of the obstacles. Moreover, it is difficult to provide controlled access through this type of obstacle without disassembling the obstacle in the field.

Even in situations where a " flat " fence structure is used to form obstacles with a certain depth, for example by providing a network of square sections, the obstacles can cause individual fence panels to be removed, Can be disassembled by someone. These obstacles also require significantly more manpower and time for assembly compared to standard fence structures.

Alternatively, there is an " expandable " obstacle, which is an expanded configuration that forms a substantially longer obstacle than a collapsed configuration occupying a relatively small amount of space, Lt; / RTI > This kind of obstacle is typically used in situations where it is structurally vulnerable when a force is applied to the front of the obstacle and thus is not likely to be accessed using force in the area delimited by the obstacle. The obstacle may be enhanced by an additional structure, but this increases the cost of the obstacle, the deployment time, and the required storage space. Moreover, conventional expandable obstacles typically have a complex pivotal network of cross-hatched trellis-like members. This type of expandable obstacle is limited to a limited length and additional additional obstacles connected to the first obstacle are required to apply the additional length. The means of connecting these obstacles often form vulnerabilities.

It is an object of the present invention to provide a framework structure, in particular a framework structure for providing a barricade or supporting structure.

According to the present invention, a framework structure as defined in the independent claims is provided.

A first aspect of the present invention provides a framework structure for providing a barricade or a support structure comprising a frame comprising a single pair of pivotally connected supports wherein a pair of supports is provided between the spread configuration and the fold configuration, Wherein the frame is rotatable relative to each other about a first axis to adjust the work structure and the footprint of the frame is larger in a spread configuration than in a fold configuration and the connecting element is pivotally connected to the frame, And the connecting element is rotatable about a second axis that is the same as the first axis or parallel to the first axis.

Accordingly, embodiments provide a structure or scaffold that can serve as a support structure or barricade that includes a frame having only a single pair of supports or subframes, wherein the supports or subframes The base of the supports can be rotated relative to each other to a position where the base of the supports is closer together than the spaced apart structure from a position where the base of the supports (i.e., the portion of the support closest to the ground) is spaced apart, have. Also, likewise, the support or subframe can be rotated in an opposite manner between spaced apart, extended configurations in the retracted configuration. The scaffold further comprises a connecting element or crossbar that rotates about an axis that is the same as, or about, an axis that is the center of rotation of the supports when they rotate relative to each other.

Embodiments provide a frame structure with a frame movable in a compressed configuration or a folded configuration for storage or access, for example, in a deployed configuration providing a robust donor when used as an obstacle, And can be assembled easily and easily. As can be appreciated, the framework structure can provide a structure that can be efficiently stored in a compressed form with a relatively small footprint as compared to the configuration when "in use ". This means efficient use of space, saving storage and transportation costs compared to other obstacles. Specifically, the footprint of the frame in the folded configuration is substantially the same as the combined footprint of the first and second supports when the supports are oriented to be substantially upright, or the footprint of the combined first and second supports, 2 support. ≪ / RTI >

Moreover, the frame and the rotatable connection element can enable the scaffold to be quickly and easily assembled by positioning the scaffold at the desired location and, for example, by spreading one of the supports. This can form a sturdy triangular support frame and the width of the triangular support frame can be adjusted according to the needs of the user to provide additional height or support. In another embodiment, the height of the obstacle can be fixed. A coupling element means any structure capable of providing a compressive or tensile force to a neighboring structure, such as a rigid member, a compressible member, a chain, a strap, or any other suitable means. The connecting element may additionally provide means for reinforcing and supporting the frame structure, since such connecting elements may be anchored to a neighboring structure or body. The connecting element also serves as an obstacle supported by the frame to provide or prevent access to, for example, the mounting of a sign or billboard. Also, if the framework structure is used as an obstacle, the connection element can be used as an access point that allows a legitimate user to traverse the obstacle, because the connection element can be elevated without compromising the structure of the obstacle .

A single pair is meant to refer to a frame of each discrete structure comprising only a pair of pivotable supports or subframes. Accordingly, there may be additional features and components, but only two pivotally connected supports may be provided. For example, the support may comprise a plurality of legs and / or connecting means. In other words, a frame can consist of only two discrete subframes.

This configuration can provide a frame structure that can be easily manufactured and assembled and is easily customizable. Also, by having this configuration, manufacturing costs can be reduced as compared to a more complex configuration with a pair of supports per frame or framework structure. Also, when used as an obstacle or supporting structure, the obstruction or supporting structure can be easily extended by adding an additional additional framework structure unit. This may allow the support structure or obstacle to extend by a single frame width in length, unlike conventional conventional expandable structures. Additionally, the connection of these neighboring framework structures can improve the strength of the obstacle / support structure and does not create a vulnerability. In addition, not all framework structures need to be extended to make the structure exhibit stiffness. For example, a partially unfolded structure including some extended framework structure and some folded (or partially folded) framework structure provides a rigid structure.

The footprint means a two-dimensional area on the ground occupied by the object. In other words, if the projected contour of the object is drawn perpendicular to the surface on which the object is placed, then the footprint is the cross-sectional area of the contour formed by said contour.

As discussed above, this may enable the framework structure to move from the extended configuration to the folded configuration. In one embodiment, the unfolded configuration may be at least five times wider than in the folded configuration (in terms of the distance between the ends of the supports located furthest away from the pivot). In another embodiment, the distance between the ends of the supports that are furthest from the pivot in the unfolded configuration may be at least 10 times longer than the distance between the ends of the supports located furthest from the pivot in the folded configuration.

In one embodiment, the footprint of the frame in the folded configuration may be substantially the same as the footprint of either the first support portion or the second support portion. In this embodiment, the frame may be folded in a folded configuration, wherein the size of the space occupied by the frame is the same as the space occupied by the support of one of the first or second supports. In other words, the frame can be folded into a configuration in which one of the first or second supports is adjacent to or received by the other support, so that the space occupied by the frame is substantially limited by the dimensions of one of the frames. This can be an efficient way to make the framework structure compact and greatly reduces the storage space required for the framework structure. In another embodiment, the total footprint of the first and second supports in the folding configuration may be less than the sum of the footprint area of the first support and the footprint area of the second support, respectively.

In another embodiment, the coupling element may be adapted to engage another framework structure. In a further embodiment, the coupling element may comprise coupling means adapted to releasably connect a frame of another framework structure, and the frame may further comprise means for coupling to a coupling element of another framework structure have.

In another embodiment, the frame may include a locking device adapted to lock the coupling elements of the other framework structure relative to the frame. This may allow the coupling elements of the neighboring framework structures to lock in place so that the coupling elements can not be inadvertently removed or unintentionally removed without first unlocking the locking device . This may provide additional security, for example when the framework structure is used as an obstacle, because the framework structure, when used as a supporting structure, for example in an unassociated state, restrains access across the obstacle , Thereby preventing the obstacle from being disassembled.

In another embodiment, the first support may comprise at least two legs, and the second support may comprise at least two legs. In a further embodiment, at least two legs of the first support may be connected by a first connecting bar, and at least two legs of the second supporting part may be connected by a second connecting bar. The connecting element may be pivotally connected to the first connecting bar of the first support and / or the first connecting bar is adapted to engage with a connecting element of an additional framework structure.

In another embodiment, the framework structure further comprises connecting means adapted to connect the obstacle unit to another framework structure. Optionally, the connecting means is located on the first support and connects the obstacle unit to a second support of another framework structure. The connecting means may or may not be included in the footprint of the frame in the folded configuration. In one embodiment, the connecting means may be included in the footprint of two neighboring framework structures, thus not increasing the footprint occupied by the structure.

In another embodiment, the connecting element can extend beyond the footprint of the frame. In another embodiment, in the folded configuration, the connecting element does not extend beyond the footprint of the frame. This enables efficient storage of the framework structure.

In another embodiment, the frame may further comprise a removable panel adapted to prevent access to the obstacle unit from the first direction. Optionally, the panel is adapted to interlock with panels of other framework structures according to any of the foregoing.

In another embodiment, the framework structure may further comprise a second connecting element. In this embodiment, the second connecting element acts in the same manner as the first connecting element. The second coupling element further strengthens the framework structure and provides additional obstacles across the depth of the framework structure. Specifically, if the structure is used as an obstacle, the second connecting element may be positioned to prevent access to the face of the obstacle, and the first connecting element may prevent access to the second side of the obstacle do. In this case, an interval equal to the depth of the obstacle can be formed between the two connecting elements, which interferes with traversing the obstacle from one of the sides. In one embodiment, the spacing is at least 1 meter. In this embodiment, a person located on either side of the obstacle will not be able to reach beyond the obstacle.

In a further embodiment, the framework structure may be a temporary framework structure. In another embodiment, the framework structure may be an expandable obstacle unit.

In another embodiment, the connecting element is an obstruction arm.

A second aspect of the present invention provides a barricade comprising a first framework structure and a second framework structure, wherein each framework structure comprises a frame comprising a single pair of pivoted supports, The pair of supports are rotatable about one another about an axis A to adjust the framework structure between the unfolded configuration and the folded configuration and the footprint of the frame is larger in the unfolded configuration than in the folded configuration, Is pivotably connected to the frame and is releasably connected to an adjacent body or structure, the connecting element being rotatable about an axis parallel to the same axis as the axis (A).

In one embodiment, the first framework structure and the second framework structure are in an unfolded configuration, and the connecting elements of the first framework structure are connected to the second framework structure.

A third aspect of the present invention provides the use of the framework structure described above as an obstacle.

An example of the present invention will now be described with reference to the accompanying drawings.

1 shows a side view of an embodiment of the present invention.
Figure 2a shows a front view of an embodiment of the present invention.
Figure 2B shows a side view of an embodiment of the present invention.
Fig. 3A shows a front view of the first support portion.
3B is a front view of the second support portion.
Figure 4 shows a side view of an embodiment of the invention.
Figure 5a shows the components of the locking mechanism.
Figure 5b shows the components of the locking mechanism.
Figure 5c shows the components of the locking mechanism.
6A shows a front view of an embodiment of the present invention.
6B shows a side view of an embodiment of the present invention.
Figure 7 shows a side view of an embodiment of the present invention.
Figure 8 shows the locking mechanism.

A first embodiment of the present invention is shown in Figs. 1-5. Figure 1 illustrates a plurality of individual framework structures 12 joined together to form a single structure 10.

Each framework structure 12 is connected to the first support frame 20 by two coupling elements in the form of an obstacle arm 40 and by a first support frame 20 and a pair of hinges 26. [ And a second support frame (30) on which the second support frame (30) is mounted. All of the framework structures 12 are arranged such that the base portion of the first support frame 20 (with the wheel 48 attached) and the base portion of the second support frame 30 (with the connecting means 36 attached) It is a unfolded configuration that is spaced from each other. This is different from the folded or nested configuration shown in Figures 2a and 2b in which the first support frame 20 and the second support frame 30 are joined together in a substantially flat arrangement The second support frame 30 is received in the first support frame 20 to form the second support frame 30.

As can be seen in the plan view of Figures 2a, 3a and 3b, the first support frame 20 has two legs 22, 23, an upper end of two legs 22, 23 An upper connecting bar 21 connecting the ends of the legs 22 and 23 to the pair of wheels 48 and opposite ends of the legs adjacent to the wheel 48, And includes a sub-connection bar 24 for connection. The lower connecting bar 24 is affixed with a pair of lockable wheels 48 that enable the framework structure 12, and in some embodiments, the structure 10, to be easily relocated. Two barriers 40 are provided on the upper connecting bar 21 of the first support frame 20. [ The first support frame 20 comprises connecting means in the form of two connecting plates 36 which are connected to the second supporting frame or terminating wheel 49 of the neighboring framework structure 12 .

The second support frame 30 also includes two legs 32 and 33 wherein the upper connecting bar 31 connects the upper (upper end) of the legs 32 and 33 and the lower connecting bar 34, Connects the bases of the legs 32, 33.

The two support frames 20 and 30 of one framework structure 12 are supported by a pair of hinges 26 located on the upper connecting bar 31 of the second support member 30 And the second supporting member is engaged with the upper connecting bar 21 of the first supporting frame 20. [ This enables the first support frame 20 and the second support frame 30 to rotate relative to each other. In this embodiment, the first support frame 20 and the second support frame 30 rotate in opposite directions to move from a position substantially perpendicular to the folding configuration (Figs. 2A, 2B, and 4) (Fig. 1) about an axis defined by the upper connecting bar 21 of the support frame 20. [0035] This arrangement allows the framework structure in a state of being assembled to the framework structure 12 or the large structure 10 to move easily and quickly in a folded configuration, thereby facilitating easy folding and storage of the framework structure Allow. It also provides a means for quickly and efficiently removing the structure 10. [

As shown in plan view in FIG. 2A and in side view in FIG. 2B and FIG. 4, the folding configuration significantly reduces the footprint of the structure, thereby reducing the frame structure 12 or structure 10 Thereby reducing the space required for storage. The second support structure 30 can be rotated to be received in the first support structure 20 in a seated manner since the dimension of the second support structure 30 is less than the inner dimension of the first support structure 20. [ (See Figs. 2A and 2B). In this embodiment, the obstacle arm 40 can not be received in the first support means 20 due to the position of the hinge at least in part. Accordingly, in the present embodiment, the obstacle arm 40 can be rotated upward, so that the obstacle arm 40 does not interfere with the folding of the frame, as shown in Fig. As can be appreciated, in this embodiment, the obstacle arm 40 may have a locking mechanism to hold the obstacle arm 40 in the upright position. This can be any locking mechanism known in the art. This can also be achieved by using a pivot that provides a sufficient level of resistance to keep the obstacle arm 40 in the upright position. This also means that the obstacle arm 40 is supported by the neighboring obstacle arm 40 (see FIG. 4) (e.g., the obstacle arms 40 are seated against each other) The obstacle arm 40 may be seated in the seating portion on the neighboring framework structure 12. The preference for storage depends on the user's requirements.

The first support means 20 and the second support means 30 are spaced apart so that the first support means 20 and the second support means 30 Donations are separate. This deployed arrangement provides a framework structure 12 with a rigid base and rigid structure. Thus, the connection of a plurality of framework structures 12, as shown in Fig. 1, results in a long structure 10 having a strong and rigid structure as a result. The strength and stiffness of such a structure 10 can be further improved through the use of the obstacle arm 40 of the framework structure 12. [ In this embodiment, the obstacle arm 40 is rotated about the upper connecting bar 21 of the first supporting frame 20 (and hence accordingly about the same axis as the first supporting frame and the second supporting frame) And is coupled to the upper connecting bar of the first support structure of the neighboring framework structure 12. [ As can be appreciated, this further stabilizes the structure 10 and improves the resistance of the structure 10 to impact. In a variant, there may be only one obstacle arm, or there may be more than two obstacle arms.

In this embodiment, the obstacle arm 40 is coupled to the upper connecting bar of the first support frame 20 via the locking mechanism. In this embodiment, the features of the locking mechanism are shown in Figures 5A-5C. The locking mechanism consists of three components: an upper connecting bar 21, an inner locking plate 50 and a locking clip 46, which are located on the ends of each of the obstacle arms 40 1).

The locking clip 46 includes a head 57 sized to receive the upper connecting bar 21 therein. Inside the head 57, there is a mushroom-shaped head pin 56 extending toward the outside of the head 57.

The inner lock plate 50, shown in greater detail in FIG. 5B, is an elongated strip extending through the hollow in the center of the upper connecting bar 21. In this embodiment, the inner locking plate 50 is slightly longer than the upper connecting bar 21 and therefore can extend outwardly of the upper connecting bar 21 (see FIG. 5A). The inner lock plate 50 has two slots 51 with a narrow elongated portion and a wide circular cutout located in the center of the elongated portion (two obstacle arms 40 are present) . The slot (51) extends through the inner lock plate (50). There is also a third slot 55 in the middle of the plate with the elongated portion terminating at the end in the wide circular portion. The slots 51 of the inner lock plate 50 are aligned with the two holes 54 in the upper connecting bar 21. [ The center slot 55 is sized such that it does not extend into the elongated portion of the central slot 55 but is positioned at a position where one of the wide circular portions of the inner lock plate 50 is aligned with the spring loaded pin 52 The mushroom-shaped head portion, which is sized so that when the inner lock plate 50 is moved along the first direction, the mushroom head-shaped portion is deflected for engagement with the wider circular portion to prevent further movement of the upper link bar Shaped pin 52 having a spring-loaded shape. To release this coupling, the user may have to pull the pin 52 out. Alternatively, the elongated slot may be tapered to create less resistance by moving the inner connecting bar 50 in the opposite direction (i.e., the opposite direction to the first direction).

In this configuration, when the obstacle arm 40 of the neighboring framework structure is moved downward, the mushroom-shaped head pin 56 of the lock piece 46 of the neighboring framework structure is engaged with the pin- Extends into the hole 54 and extends through the slot 51, wherein the mushroom-shaped portion of the pin extends beyond the slot 51. The inner locking plate 50 may then slide in any direction along the length of the upper connecting bar 21. [ The removal of the pin 56 (and hence the removal of the obstacle arm 40) is facilitated by the fact that the inner lock plate 50 is positioned at the center of the slot 51, . In this embodiment, the inner lock plate 50 is configured such that when the inner lock plate 50 is moved to the locked position, the inner lock plate 50 is moved only toward the outside of one of the ends of the upper connecting bar 21 The size is determined to be extended. Thus, once the obstacle arm 40 is locked in place, in this embodiment the inner lock plate 50 can only be accessed from one side of the framework structure 12, It will be inaccessible to the user 50. Thus, if used as an obstacle, the defender can easily move the inner lock plate 50, so that the obstacle arm 40 can be raised to allow access to the obstacle and / or disrupt the obstacle, This is particularly important, for example, in the case of a fire or an emergency, while the obstacle arm 40 can not be unlocked by a person on the opposite side of the obstacle. This provides both security and ease of use without compromising stability.

In an alternative embodiment, the upper connecting bar 21 may have a hollow cylindrical shape and may have a slot sized to receive the inner locking bar 50, Lt; / RTI > Thus, the plug supports the inner connecting bar 50 within the upper connecting bar 21, and the inner connecting bar 50 at the locking position can be coplanar with the plug at one side, Thereby preventing access to the plate 50.

In another embodiment, the inner lock plate 50 may also be secured by a padlock that extends through the inner lock plate 50 at one end when, for example, a locked configuration (not shown) . In an alternative embodiment, the inner locking plate 50 may be shorter in length than the upper connecting bar 21, so that the inner locking plate 50, either in the locked position or in the unlocked position, Do not extend outwardly of the end and can be actuated by a key device instead of the pin 52. [ In this configuration, the obstacle arm 40 can be downwardly coupled and can be coupled in the same manner as in the embodiment of Figs. 5A-5C, but once engaged, the inner lock plate 50 can be locked Can slide along the inside of the bar (21). The key can then be removed and the locking mechanism can not be unlocked on either side of the framework structure without the use of a key. In a further variation, an automatic clip mechanism may be employed.

In use, framework structure 12 ("first framework structure") can be used to form structure 10, e.g., structure 10 shown in FIG. The initial assembly of the structure 10 entails providing a folded framework structure unit 12 (since the folded framework structure unit must be viewed or transported to the site), which is illustrated in Figures 2a and 2b Lt; / RTI > The framework structure 12 may now be deployed in an extended configuration wherein the first support frame 20 and the second support frame 30 are rotated away from one another to form a substantially triangular configuration ). The chain 47 is further attached to the first support frame 20 and the second support frame 30 to prevent the first support frame 20 and the second support frame 30 from rotating to a wider open position And the above-described configuration can be strengthened. The obstacle arm 40 can be held in the upright position until the unit is correctly positioned. The second framework structure 12 may now be located next to the first framework structure 12 and may be deployed in a similar manner. The second support frame 30 of the second framework structure 12 can now be connected to the bracket 36 of the first framework structure 12 and the first and second framework structures 12, Can be fixedly connected. The obstacle arm 40 of the first framework structure 12 can be downward and can be engaged with the upper connecting bar 21 of the first support frame of the second framework structure 12. [ If necessary, they can be locked in place. As a result, two robust framework structures are formed whose sizes are determined by a structure showing both stability and rigidity. The two barrier arms 40 of the second framework structure 12 may also be attached to either an external body or an additional framework structure 12, such as a coupling mechanism on the wall. Likewise, the additional framework structure 12 may be attached to the first framework structure 12 in the manner described above. In addition, the terminating wheel 49 may be attached to the second support frame 30 of the framework structure 12 at the end of the structure 10 (if the second support frame 30 is not attached to the structure adjacent thereto or the body) Lt; / RTI > This provides a robust structure 10 that is movable through the wheels 48, 49 to the required position. The wheels 48,49 may have a locking mechanism on the wheels so that they can be fixed when they are in place or a brake (not shown) can be applied.

Once the framework structure 12 is assembled to the structure 10, the framework structure 12 can still be moved into the unfolded configuration and into the folded configuration. For example, the structure 10 of FIG. 1 can be made compact with the folding configuration of FIG. In order to do this, the obstacle arm 40 of the folded framework structure 12 is moved away from the structure or body to which the obstacle arm has been attached, and the neighboring framework structure 12 has a framework structure 12 The obstructive arms 40 of the neighboring structure will fall away from the framework structure 12 being folded. As can be appreciated, if the entire structure 10 is being folded, then all the obstacle arms 40 of all the framework structures 12 will fall off. Once folded, this results in the folding structure in FIG. The obstacle arm 40 can now be rotated away from the frame, so that the obstacle arm does not interfere with the folding of the frame and thus the framework structure 12. Once folded, the result is the structure shown in FIG.

The first support frame 20 and the second support frame 30 can now be assembled by folding down the respective frames individually [still attached to the neighboring framework structure 12] 21, 31), by folding all of the frames using a pushing action that acts in a direction substantially perpendicular to the first, second, third, As can be appreciated, this action leads to the frame and thus the framework structure 12 to be, for example, the folded or adjacent configuration shown in Fig. This allows the structure 10 to be easily stored or transported, wherein the footprint of the structure 10 in the folded configuration is significantly smaller than the footprint in the expanded configuration.

In a further embodiment, the structure 10 may be used as a rapidly deployable obstacle or barricade. In this embodiment, there may be a structure 10 comprising a plurality of individual framework structures 12 that are stored in the configuration shown in Fig. If desired, the framework structure 12 at one of the distal ends of the structure 10 may be pulled by the user in a direction substantially perpendicular to the upper connecting bars 21, 31. This causes the frame to move from the folded configuration to the unfolded configuration because the first support frame 20 of the neighboring framework structure 12 is connected to the second support frame 30 The first support frame 20 and the second support frame 30 are pulled away from their bases when the framework structure 12 is pulled, The rotation about the pivot connecting the first support frame 20 and the second support frame 30 is caused. If the structure 10 is stored in the configuration shown in FIG. 4 (e.g., the obstacle arm 40 is rotated upward), the obstacle arm 40 may be brought down when the frame is moved in the deployed configuration. Alternatively, the obstacle arm 40 may be lowered in place as the structure is unfolded and downwardly to automatically engage with the neighboring framework structure 12. This can be accomplished by any means known in the art. This can be achieved, for example, by using a pivot that exhibits less resistance, or an additional chain that pulls on the obstacle arm 40 when the frame of the framework structure 12 is unfolded.

In a further embodiment, the structure may be deployed as an obstacle using the vehicle. This can be accomplished by connecting the framework structure 12 located at one of the ends of the folded structure 10 to the vehicle and using the vehicle to unfold the structure 10 in the manner described above. In one embodiment of this, there may be additional locks or straps that prevent the structure 10 from unfolding, so that the structure 10 can be moved using the vehicle until it is in the desired position, At this point, the lock or strap can be disengaged, and additional movement of the vehicle will result in the deployment of the structure 10 (e.g., movement to the extended configuration). This enables flexible and rapidly deployable expandable obstacles.

A further embodiment of the invention is shown in Figures 6a and 6b. The framework structure 12 of this embodiment has a similar structure to the framework structure 12 of the previous embodiment. The framework structure 112 includes two obstacle arms 140 and a second support frame 130 connected to the first support frame 120 by a first support frame 120 and a pair of hinges 126 ≪ / RTI > The framework structure 112 is shown in a folded configuration or in an adjacent configuration wherein the first support frame 120 and the second support frame 130 together define a second support frame 130 Are accommodated in the first support frame 120. 2A and 2B, the obstacle arm 140 and the support frames 120 and 130 are configured such that the obstacle arms 140 are received within the larger first frame 120 The size is determined to be. The first support frame 120 includes a pair of wheels 148 and a pair of connecting means 136 is attached to the second support frame 130.

In an additional embodiment, the obstacle arm 40. 140 may be at least partially retractable along its length, such that when the obstacle arm 40, 140 is disconnected from a neighboring entity, At least partially contract. This enables the longer obstacle arms to contract to a length that allows them to nestle within the folding configuration of the frame (e.g., within the footprint of the folded frame). Also, accordingly, it may be permitted to contract when the obstacle arm is connected to a neighboring unit. This is particularly advantageous in the apparatus of FIGS. 6A and 8, wherein the mushroom-shaped head fins 146 are located on the end of the obstacle arm 140 and thus are connected to the neighboring framework structure in a horizontal manner.

In a further embodiment of the invention in which the structure is used as an obstacle, additional features may also be presented. For example, in one embodiment shown in FIG. 7, an additional panel 60 may be attached to the structure 10,110 to prevent access to obstacles or to provide additional obstacles or separate walls have. These panels 60 may be provided along the length of the obstacle 10, 110, depending on the requirements of the user, or may be included only at a particular point. In a variant, the panel 60 may be a billboard or a sign board.

Yet another additional feature that may be used with the structure 10, 110 is a step over plate 70. The stepover plate 70 is a plate that is adapted to be attached to the structure 10,110 between two framework structures 12,121 and which can be used by a person to traverse the depth of the structure 10,110. Provide the platform. Depending on the dimensions of the structure 10,101, traversing the structure may require an obstacle arm located on the stepover plate and separated and elevated. This feature provides an easy and secure way to traverse across the structures 10,110.

In a further embodiment, the framework structure 12,121 may be provided with a housing (not shown), and when the structure is moved from the deployed configuration to the folded configuration, . In one embodiment, the structure 10,101 may be stored in a folded configuration within the housing, e.g., around the sides of the road. One of the framework structures 12,112 at the end of the structure may be secured to the housing and the framework structure 12,121 at the opposite end of the structure 10,110 may be accessible from the outside of the housing have. Thus, when the structure 10, 110 is taken out of the housing, the structure is moved in a deployed configuration and can be placed across the road.

The framework structure according to the invention can also be used as a structural support, which is quite similar to the scaffolding frame. For example, the framework structure may be used to support additional structures, or may be used as a platform.

As can be appreciated, the length of the obstacle or structure 10, 110 may be varied by removing or adding a single framework structure 12, 112 or by changing the width of the frame in the extended configuration Or by extending it shorter). Thus, it is also advantageous if the obstacle arm has an adjustable length so that the length of the obstacle arm can be adjusted if the width of the extended frame is changed. This can be accomplished by any means known in the art.

In a further embodiment, the obstacle arm 140 may represent an alternative configuration to that described with respect to Figures 5A-5C. For example, the obstacle arm 40 is coupled to a neighboring frame unit in the manner shown in Figure 8, wherein the locking mechanism 186 has a pin 187 that engages the locking plate 150 in a horizontal manner . This requires an obstacle arm 140 that is expandable and retractable in the lengthwise direction. As an alternative, it will be appreciated that any locking mechanism known in the art may be used.

In a further embodiment, the connecting means 36 may be a device for connection via a ball and socket joint. For example, the ball may extend outwardly of the lower connecting bar of the first supporting frame and may engage with the recess in the lower connecting bar of the second supporting frame of the neighboring framework structure. This allows pivoting of framework structures against one another and helps to use the framework structure on rugged terrain. It will be appreciated that any suitable connecting means may be employed.

Other variations on the disclosed embodiments may be understood and effected by those skilled in the art in practicing the claimed invention by studying the figures, disclosure and appended claims. For example, in the above example, The framework structure may be formed of any suitable material, such as any suitable metal or alloy, such as steel or copper or aluminum, or plastic, wood or other suitable material, and any number of wheels or hinges may be present (E.g., 1, 2, 3, 4 or more connection elements) or an obstacle arm, and the obstacle arm may be bi-directionally (clockwise or counterclockwise) And the support can exhibit any suitable structure and can include any number of legs and any other suitable means can be used such as a foot attached to the sub- Or the lower connecting bar may be simply seated against a work surface or secured to a work surface and the chain 48 may be a strap, May be any other suitable means for supporting the frame, it may be omitted.

In the claims, the word "comprising" does not exclude other elements or steps, and the singular expression does not exclude a plurality of cases. The fact that only certain measures are listed in mutually different dependent claims does not indicate that a combination of these measures can not be used to advantage. Any reference signs in the claims should not be construed as limiting the scope.

Claims (23)

A framework structure for providing a barricade or support structure,
A frame comprising a single pair of pivoted supports, wherein the pair of supports are arranged about the first axis about the first axis to adjust the framework structure between the expanded configuration and the collapsed configuration Wherein the frame of the frame is rotatable and the footprint of the frame is larger in the unfolded configuration than in the folded configuration, and
A connecting element pivotally connected to the frame such that it is releasably connected to a neighboring body or structure, the connecting element being rotatable about a second axis, the second axis being identical to the first axis, or Which is parallel to the first axis,
≪ / RTI > The framework structure of claim 1, wherein the footprint of the frame in the folded configuration is substantially the same as the footprint of either the first support portion or the second support portion. 3. The framework structure according to claim 1 or 2, wherein the connecting element is adapted to be coupled with another framework structure. 4. The system of claim 3, wherein the coupling element comprises coupling means adapted to releasably connect a frame of another framework structure, the frame further comprising means for coupling to a coupling element of another framework structure Framework structure. 5. The framework structure of claim 4, wherein the frame comprises a locking device adapted to lock a coupling element of another framework structure to the frame. 6. The framework structure according to any one of claims 1 to 5, wherein the first support comprises at least two legs and the second support comprises at least two legs. 7. The framework structure of claim 6 wherein at least two legs of the first support are connected by a first coupling bar and at least two legs of the second support are connected by a second coupling bar. 8. The framework structure of claim 7, wherein the connecting element is pivotally connected to the first connecting bar of the first support. 9. The framework structure according to any one of claims 6 to 8, wherein the first connecting bar is adapted to engage with a connecting element of an additional framework structure. 10. The method according to any one of claims 1 to 9,
A connecting means adapted to connect the obstacle unit to another framework structure
≪ / RTI > 11. The framework structure of claim 10, wherein the connecting element is located on a first support and connects the obstacle unit to a second support of another framework structure. 12. The framework structure according to any one of claims 1 to 11, wherein in the extended configuration, the connecting element extends beyond the footprint of the frame. The framework structure according to any one of claims 1 to 12, wherein in the folding configuration, the connecting element does not extend beyond the footprint of the frame. 14. The framework structure according to any one of claims 1 to 13, wherein the frame further comprises a removable panel adapted to prevent access to an obstacle unit from a first direction. 15. The framework structure according to claim 14, wherein the panel is adapted to interlock with a panel of another framework structure according to any one of claims 1 to 14. 16. Framework structure according to any one of the preceding claims, wherein the framework structure further comprises a second connecting element. 17. The framework structure of claim 16, wherein the distance between the first connecting element and the second connecting element forms an interval of at least 1 meter. 18. Framework structure according to any one of claims 1 to 17, wherein the framework structure is a temporary framework structure. 19. The framework structure according to any one of claims 1 to 18, wherein the framework structure is an expandable obstacle unit. 20. The framework structure according to any one of claims 1 to 19, wherein the connecting element is an obstacle arm. As a barricade,
A first framework structure according to any one of claims 1 to 20, and
A second framework structure according to any one of claims 1 to 20
Barricades that include. 22. The barricade of claim 21 wherein during use the first framework structure and the second framework structure are in an extended configuration and the connecting elements of the first framework structure are connected to the second framework structure. Use of a framework structure according to any one of claims 1 to 20 as an obstacle.

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