Patent Description:
Typically, known systems for building a temporary wall involve blocks each having one or more holes running through the block and being configured to receive a rod such that multiple blocks are held together by the rod.

For example, one known system (<CIT>) comprises a foundation of poured, levelled concrete having regularly spaced holes for vertical block assembly rods, a plurality of walls blocks where each block has one or more vertical block assembly holes running entirely though the blocks, and a plurality of block assembly rods. When a column of one or more wall blocks is placed on the foundation with the foundation and block holes aligned, one or more block assembly rods can be run through the block column and into the foundation. This enables an assembly of a temporary wall with blocks, rods and foundation which does not require mortar and is easy to disassemble. A problem with the above-described system is that the block assembly rod that is run through each block of a column is subject to bending and therefore likely to be damaged easily and require frequent replacement. Another problem is that the block assembly rod provides vertical structural support only, which means the temporary wall can be prone to toppling and instability. A modular wall unit made in accordance with the preamble of claim <NUM> is described in <CIT>. Furthermore, the wall unit should be adapted to support further objects, such as a frame for hanging or otherwise supporting further objects.

The present invention aims to overcome or at least partly mitigate one or more of the above problems.

According to a first aspect of the present invention, there is provided a modular wall unit made in accordance with claim <NUM>. The first aspect may be modified according to any suitable teaching described herein, including, but not limited to, any one or more of the following optional features. The modular wall unit may further comprise a second through hole, spaced apart from the first through hole and extending between the first and second joining faces. The modular wall unit may further comprise a second elongate reinforcement member extending between the first face and the second face and within the second through hole, the second elongate reinforcement member having at least one tubular portion proximal to a terminating end of the second elongate reinforcement member.

The modular wall unit may be configured such that the internal recess extends at least between the first through hole and the second through hole, and the second elongate reinforcement member further connects to internal recess elongate reinforcement member.

The body portion may comprise a foam material.

The part of the body portion surrounding the reinforcement members may be unitary.

Any of the said elongate reinforcement members may comprise Aluminium.

Any one or more of the said elongate reinforcing members may comprise a tubular portion proximal at both terminating ends.

Any one or more of the one or more of the elongate reinforcement members may comprise a tube running the entire length of the respective reinforcement member.

The one or more support members may comprise an elongate portion and a head portion terminating the one or more support members at a distal end away from the modular wall unit.

The elongate portion may have a maximum diameter that is smaller than the maximum diameter of the head portion.

The support member may extend substantially perpendicular from the first or second reinforcement members.

The first and second joining faces may be planar.

Alternatively, the first and second joining faces may be parallel.

According to a second aspect of the present invention, there is provided a kit comprising a modular wall unit as described above in respect of the first aspect of the present invention, and one or more plugs for assembling a plurality of modular wall units.

According to a third aspect of the present invention, there is provided a modular wall system comprising a plurality of modular wall units.

The first elongate reinforcement member may form part of a reinforcement frame comprising a plurality of elongate reinforcement members, the plurality of elongate reinforcement members at least partially surrounding the body along their respective elongate lengths.

The frame may comprise an H-shaped frame.

At least the first elongate reinforcement member may extend between first and second outer faces of the body.

There is presented a modular wall unit for a modular wall system. It should be noted that features of the different examples of the modular wall unit and the method for making a modular wall unit may also be used in other examples of the same, either as an addition or as a replacement of a technical feature or step.

<FIG> shows an example of a modular wall unit.

There is presented a modular wall unit <NUM> for a modular wall system <NUM>. The modular wall unit <NUM> comprises a body <NUM>. The body <NUM> has first <NUM> and second <NUM> outer wall faces. The body <NUM> also has first <NUM> and second <NUM> joining faces that each extend between the first <NUM> and second <NUM> outer wall faces. At least one of the first <NUM> and second <NUM> joining faces are for facing a joining face of a further modular wall unit <NUM> of the modular wall system <NUM>. The body <NUM> also has a first through-hole <NUM> extending between the first <NUM> and second <NUM> joining faces. The modular wall unit <NUM> further comprises a first elongate reinforcement member <NUM> extending between the first joining face <NUM> and the second joining face <NUM> and within the first through hole <NUM>. The first elongate reinforcement member <NUM> also has at least one tubular portion <NUM> proximal to a terminating end of the first elongate reinforcement member <NUM>.

For purposes of discussing the modular wall system, the modular wall unit described above may be referred to as the 'first modular wall unit' or 'first unit' hereinafter. Likewise, the further modular wall unit may be referred to as the further unit. The modular wall system may be referred to as the 'wall system' or 'system' and may have a plurality of units wherein the system forms a 'wall'. The further units may also be referred to a first, second third units etc. when discussing examples of the system. The modular wall unit <NUM> therefore has an internal reinforcement member <NUM> giving strength to the unit <NUM> but that allows for a connecting element to be inserted into the through hole <NUM> and engage with the tubular end portion <NUM>, for example by an interference fit. The connecting element may be used to connect with other portions of the wall system <NUM>, for example with further wall units or other units such as a base unit. The further adjacent modular wall unit abutting the first unit along respective joining faces may have its terminating tubular portion at the joining surface facing the first unit. This allows the wall system to be interconnected via the internal reinforcement members. The connecting element may for example be a connecting plug, pin or other suitable means as described elsewhere herein.

<FIG> shows a modular wall system <NUM> comprising a plurality of units 2a, 2b, 2c stacked on top of each other to form a three unit high, one unit wide wall. The internal reinforcement member <NUM> of each of the units 2a, 2b, 2c has at least one tubular portion <NUM> proximal to at least one of the terminating ends of the internal reinforcement member <NUM>. In this example the bottom two units 2b, 2c, have a separate tubular portion at each respective terminating end, whilst the top unit 2a only has a tubular portion of its reinforcement member adjacent to the middle wall unit 2b. The wall units are stacked so that the elongate reinforcement members are longitudinally aligned. This allows for a connecting element (not shown) to be inserted into the through hole <NUM> and the tubular portion of one of the units 2a and the tubular portion of an adjacent unit 2b. A similar connecting element can be inserted into the tubular portions at the interface between wall units 2b and 2c. When aligned in this way, at least one of the wall faces may be planar in that the entire said wall face is flat aside from the joining interfaces between the wall units.

When multiple units are engaged with each other via one or more connecting elements, the outer wall faces of the adjoined units may form the overall wall wherein each face of the wall is continuous apart from the unit joining lines.

The wall may be free standing or may be attached to a base unit. The base unit, in use, resides on the floor, platform or other supporting area that the wall sits on and provides stability to the wall to help stop the wall falling over.

The wall may be used to support further objects. These further objects may be directly mounted on a wall outer surface, such as a poster, or, in accordance with the invention, may be supported by a support member extending outwardly from an outer wall face. A wall unit may have, none, one or a plurality of support members. For example, some wall units in a wall may have no support member whilst other wall units have one or more support members. The number and position of the support members of a wall unit or wall may depend on the end use of the wall. The support members are discussed in greater detail elsewhere herein.

The support member may pass into a hole in the outer wall surface and connect to one or more of the reinforcing members internal to the body. An example of a further object that may be supported by the support members may be a frame for hanging or otherwise further supporting other objects. The frame may directly connect or hang upon the support members. Additionally, or alternatively, the support member may be coupled to a hook that in turn is used to hang the frame upon. The hook may be integrally formed with the support member, for example forming the end of the support member distal from the wall outer face. The hook may also be a separately formed object that attaches (preferably mechanically engages) with the said distal end of the support member.

The frame may be a grid frame. The grid frame may have a first set of spaced apart parallel rods that intersect and rigidly connect with a second set of parallel rods, the first set of the rods running perpendicular with the second set of parallel rods.

<FIG> shows an example of such a grid frame. The grid frame <NUM> shown in <FIG> has a first set of spaced apart parallel rods <NUM> that intersect and rigidly connect with a second set of parallel rods <NUM>. <FIG> shows an example of a wall supporting frames used to attach plants or artificial plants (not shown). Other items may be supported by the support member aside from plants or artificial plants. The wall shown in <FIG> is a three unit high, one unit wide wall formed by the outer wall faces of multiple adjoined units 2a, 2b, 2c engaging with each other via one or more connecting elements. The connection of the units 2a, 2b, 2c in this example is described as follows with reference to the units comprising tubular portions (not shown) and internal reinforcement members (not shown). In this example, the lowermost unit 2c comprises a single tubular portion proximal to the end of the reinforcement member internal to the lowermost unit 2c which faces the middle unit 2b. The middle unit 2b comprises two tubular portions, namely a tubular portion proximal to each end of the reinforcement member internal to the middle unit 2b. The uppermost unit 2a comprises a single tubular portion proximal to the end of the reinforcement member internal to the uppermost unit 2a which faces the middle unit 2b. In this example, a first plug engages with the tubular portion of the lowermost unit 2c and the adjacent tubular portion of the middle unit 2b. The first plug thereby connects the lowermost unit 2c to the middle unit 2b. A second plug engages with the tubular portion of the uppermost unit 2a and the adjacent tubular portion of the middle unit 2b. The second plug thereby connects the uppermost unit 2a to the middle unit 2b.

The face of the wall is continuous apart from the unit joining lines <NUM>. Frames 26a, 26b and 26c are supported on the wall shown in <FIG>. The frames 26a, 26b and 26c may be used to attach plants, artificial plants or other items to the wall.

The wall unit will now be described in more detail with reference to <FIG>. Following this, further examples of modular wall systems are described with reference to <FIG>.

<FIG> shows a further example of a modular wall unit for a modular wall system. The modular wall unit comprises a body <NUM> having first <NUM> and second <NUM> outer wall faces, first <NUM> and second <NUM> joining faces that each extend between the first <NUM> and second <NUM> outer wall faces. At least one of the first <NUM> and second <NUM> joining faces for facing a joining face of a further modular wall unit of a modular wall system. The body <NUM> comprises a first through-hole 18a and a second through-hole 18b, both the first through-hole 18a and the second through-hole 18b extending between the first <NUM> and second <NUM> joining faces. The body <NUM> further comprises a first elongate reinforcement member 20a and a second elongate reinforcement member 20b. The first elongate reinforcement member 20a and the second elongate reinforcement member 20b extend between the first joining face <NUM> and the second joining face <NUM> and within the first through-hole 18a and the second through-hole 18b, respectively.

The first elongate reinforcement member 20a and the second elongate reinforcement member 20b have tubular portions 22a, 22b proximal to terminating ends of the first elongate reinforcement member 20a and the second elongate reinforcement member 20b.

The modular wall unit shown in <FIG> therefore has internal reinforcement members 20a, 20b giving strength to the unit. The internal reinforcement members 20a, 20b allow for a connecting element to be inserted into each of the through-holes 18a, 18b and engage with the tubular end portion 22a, 22b, for example by an interference fit. The connecting element may be used to connect with other portions of the wall system <NUM>, for example with further wall units or other units such as a base unit, as discussed above with reference to <FIG> and <FIG>.

<FIG> shows a further example of a modular wall unit for a modular wall system, wherein the modular wall unit comprises an H-shaped frame which is described in further detail as follows. The modular wall unit comprises a body <NUM> having first <NUM> and second <NUM> outer wall faces, first <NUM> and second <NUM> joining faces that each extend between the first <NUM> and second <NUM> outer wall faces. At least one of the first <NUM> and second <NUM> joining faces for facing a joining face of a further modular wall unit of a modular wall system. The body <NUM> comprises a first through-hole 18a and a second through-hole 18b, both the first through-hole 18a and the second through-hole 18b extending between the first <NUM> and second <NUM> joining faces. The body <NUM> further comprises an internal recess <NUM> extending away from and adjoining the first through-hole 18a. The recess <NUM> may also be termed a third through hole extending between and connecting the first and second through holes 18a, 18b. The internal recess <NUM> extends at least between the first through-hole 18a and the second through-hole 18b. The body <NUM> further comprises a first elongate reinforcement member 20a and a second elongate reinforcement member 20b. The first elongate reinforcement member 20a and the second elongate reinforcement member 20b extend between the first joining face <NUM> and the second joining face <NUM> and within the first through-hole 18a and the second through-hole 18b, respectively. The body <NUM> further comprises a internal recess elongate reinforcement member 20c that resides in the internal recess <NUM> and is connected to the first elongate reinforcement member 20a. The internal recess elongate reinforcement member 20c which resides in the internal recess <NUM> is also connected to the second elongate reinforcement member 20b. The first elongate reinforcement member 20a, the second elongate reinforcement member 20b, and the internal recess elongate reinforcement member 20c thereby form an H-shaped frame residing within internal recesses formed by the first through-hole 18a, the second through-hole 18b and the internal recess <NUM>. The internal recess elongate reinforcement member 20c may be connected to the first elongate reinforcement member 20a and the second elongate reinforcement member 20b by welding if the reinforcement members 20a, 20b, 20c are made from a metal, e.g. Aluminium. Alternatively, the first, second and internal recess elongate reinforcement members 20a, 20b, 20c may be a unitary piece. For example the unitary piece may be moulded from plastic such as ABS (acrylonitrile butadiene styrene). The first elongate reinforcement member 20a and the second elongate reinforcement member 20b have tubular portions 22a, 22b proximal to terminating ends of the first elongate reinforcement member 20a and the second elongate reinforcement member 20b. A connecting element can be inserted into the through-holes 18a, 18b and engage with the tubular end portions 22a, 22b.

A plurality of modular wall units can be assembled by placing the lower joining face of a first modular wall unit adjacent to the upper joining face of a second modular wall unit, and aligning the through-holes of the first modular wall unit with the through-holes of the second modular wall unit, such that a connecting element can be inserted into each of the through-holes. The first and second internal reinforcement members may comprise a tubular end portion at each terminating end of the reinforcement member. When a connecting element is inserted into one of the through-holes of the first modular wall unit, it engages with the corresponding tubular end portion within the internal reinforcement member of the first modular wall unit. The same connecting element can then be interested into one of the through-holes of the second modular wall unit, thereby engaging with the corresponding tubular end portion within the internal reinforcement member of the second modular wall unit. Advantageously, the connecting elements provide structural support to the modular wall system formed by the assembly of multiple modular wall units whilst enabling the modular wall system to be assembled in a modular fashion, one modular wall unit at a time. In contrast to prior art systems, the modular wall units need not be assembled into a column before being connected by a connecting element. In addition, the connecting element is not required to run all the way through the through-hole of the modular wall unit. The modular wall therefore requires less material to form the connecting elements required for assembling the modular wall system. Furthermore, the connecting elements can engage with the tubular end portions by an interference fit and do not require any bolts or screws. The modular wall unit further provides not only vertical structural support, but also horizontal structural support by way of the H-shaped frame residing within internal recesses formed by the first through-hole 18a, the second through-hole 18b and the internal recess <NUM>. The provision of an H-shaped frame within each modular wall unit provides structural support to the unit itself as well a modular wall system formed from a plurality of modular wall units. The internal reinforcement members 20a, 20b, 20c which form the H-shaped frame of the modular wall unit shown in <FIG> provide further strength to the modular wall unit in that the first and second elongate reinforcement members 20a, 20b are supported and held in place by the third elongate reinforcement member 20c. This provides a significant advantage over a modular wall unit having only the first and second elongate reinforcement members 20a, 20b, and lacking the third elongate reinforcement member 20c, as the structural support provided by the third elongate reinforcement member 20c prevents the first and second elongate reinforcement members 20a, 20b from bending. This is particularly important for the assembled modular wall system as it enables a more stable wall structure to be assembled which is less prone to toppling. Furthermore, the H-shaped frame enables an improved torsional strength in comparison to several unconnected poles or reinforcement members. In addition, the more stable wall structure enables objects to be mounted on the wall with ease and stability.

Furthermore, the H-shaped frame, in comparison to several unconnected poles or reinforcement members, enables the modular wall unit to be manufactured more efficiently. The body portion of the modular wall unit may be unitary in structure and surround the reinforcement members. For example, the body portion may comprise a foam material and be prepared using insert moulding techniques. Advantageously, inserting the unitary H-shaped frame into a mould is faster and easier in comparison to inserting several unconnected elements into a mould. In addition, the relative position of the reinforcement members and the outer holes of the reinforcement members are fixed, which enables the modular wall system to be assembled more efficiently and with ease.

<FIG> show an H-shaped frame independent of a modular wall unit. The H-shaped frame has a first elongate reinforcement member 20a and a second elongate reinforcement member 20b configured to be in parallel to one another and spaced apart by a distance. The first elongate reinforcement member 20a and the second elongate reinforcement member 20b may each have a length of between <NUM>-<NUM> millimetres and a diameter of between <NUM>-<NUM> millimetres. Preferably, the first elongate reinforcement member 20a and the second elongate reinforcement member 20b may each have a length of between <NUM>-<NUM> millimetres and a diameter of between <NUM>-<NUM> millimetres. The first elongate reinforcement member 20a and the second elongate reinforcement member 20b may each have a length of about <NUM> millimetres and a diameter of about <NUM> millimetres.

An internal recess elongate reinforcement member 20c resides between the first and second elongate reinforcement members 20a, 20b. The internal recess elongate reinforcement member 20c is connected to the first elongate reinforcement member 20a at approximately half way between the ends of the first elongate reinforcement member 20a. The internal recess elongate reinforcement member 20c may have a length of about <NUM>-<NUM> millimetres and a diameter of about <NUM>-<NUM> millimetres. Preferably, the internal recess elongate reinforcement member 20c may each have a length of between <NUM>-<NUM> millimetres and a diameter of between <NUM>-<NUM> millimetres The internal recess elongate reinforcement member 20c may have a length of about <NUM> millimetres and a diameter of about <NUM> millimetres.

Similarly, the internal recess elongate reinforcement member 20c is connected to the second elongate reinforcement member 20b at approximately half way between the ends of the second elongate reinforcement member 20b. The H-shaped frame <NUM> further comprises a fixing mechanism <NUM> located on each of the first and second elongate reinforcement members 20a, 20b for securing the H-shaped frame within a modular wall unit. Although an H-shaped frame is preferable, the internal recess elongate reinforcement member may be connected to the first elongate reinforcement member at other positions along the length of the first elongate reinforcement member and the second elongate reinforcement member.

<FIG> show a modular wall unit <NUM> comprising the internal H-shaped frame described above with reference to <FIG>. The second elongate reinforcement member 20b and the internal recess elongate reinforcement member 20c can be seen in the cutaway portion of the modular wall unit <NUM> shown in <FIG>. The front of the modular wall unit <NUM>, which forms the wall, is shown in <FIG>.

The wall formed using the modular wall unit <NUM> may be used to support further objects which may be supported by a support member extending outwardly from an outer wall face. The modular wall unit <NUM> has two support members <NUM>. Each support member passes into a hole in the outer wall surface and connects to one or more of the reinforcing members internal to the body. The support members connect to one or more of the reinforcing members forming the H-shaped frame <NUM> via the fixing mechanism <NUM> (shown in <FIG>). This fixing mechanism in this example is a screw hole configured to receive a complementary threaded end of the support member. The support members may be attached in other ways including, but not limited to, being welded or attached via an adhesive, e.g. glue. The support members are discussed in greater detail below with reference to <FIG>. The rear of the modular wall unit <NUM> is provided with a three-dimensional pattern <NUM> that is appealing to the eye for display in rooms such as offices.

<FIG> shows a connecting element <NUM> which can be inserted into the through-hole 18a, 18b. Connecting elements may be used to engage multiple units with each other.

The connecting element <NUM> may be used to connect with further wall units or other units such as a base unit. The connecting element <NUM> shown in <FIG> is in the form of a connecting plug. The connecting element may be another suitable means such as a connecting pin. The connecting element <NUM> may be made from plastic, for example ABS. The connecting element <NUM> has a cylindrical portion <NUM>, which is sized in accordance with the tubular portion of the reinforcement member. For example, the outer diameter of the cylindrical portion <NUM> of the connecting element <NUM>, may be substantially similar to or the same as the internal diameter of the tubular portion of the reinforcement member. This enables the connecting element <NUM> to engage with the tubular portion of the reinforcement member by way of an interference fit. Advantageously, the connecting element holds the reinforcement members of adjacent units in place with the interference fit, whilst allowing the reinforcement members to be dissembled at a faster rate when required. The connecting element <NUM> has tapered ends <NUM>. The tapered ends <NUM> make it easier for a user system to locate and/or insert the connecting element <NUM> into the reinforcement member.

Further examples of modular wall systems will now be described with reference to <FIG>.

<FIG> shows a modular wall system <NUM> comprising a plurality of modular wall units 52a-52d stacked on top of each other and connected together by connecting elements 54a-54d to form a four unit high, one unit wide wall. The connecting elements 54a-54d are substantially similar to the connecting element described above with respect to <FIG>. The lowermost modular wall unit 52d is connected to a further unit <NUM> wherein the purpose of the further unit <NUM> is to stabilise the wall formed by the stacked modular wall units 52a-52d and to enable connection of the stacked modular wall units 52a-52d to a base unit <NUM>. The base unit <NUM> is rectangular in shape with a surface area that is larger than the surface area of the modular wall unit facing the base unit <NUM>. Advantageously, this enables the base unit <NUM> to provide stability to the stacked modular wall units 52a-52d. The further unit <NUM> is connected to the base unit <NUM> using a connecting element <NUM>. The connecting element <NUM> shown in <FIG> is cylindrical in shape, but may be sized and shaped suitably to fulfil its purpose of connecting the base unit <NUM> to the further unit <NUM>. For example, the connecting element used to connect the further unit <NUM> to the base unit <NUM> may be similar in size and shape to the connecting element discussed above with reference to <FIG>. Alternatively, the base unit <NUM> may connect directly to the lowermost modular wall unit 52d, without requiring a connecting element.

<FIG> show front and rear views of the modular wall system <NUM>. The modular wall system <NUM> has a plurality of modular wall units 52a-52d wherein the system forms a wall <NUM>. The wall <NUM> is stabilised by the further unit <NUM> and the base unit <NUM>. The rear of the modular wall system <NUM> is provided with a three-dimensional pattern <NUM> that is appealing to the eye for display in rooms such as offices.

<FIG> show front and rear views of a modular wall system <NUM> comprising a plurality of modular wall units 52a-<NUM>. The modular wall system <NUM> forms a four unit high, two unit wide wall. Four modular wall units 52a-52d are stacked on top of each other and connected to a further set of four modular wall units 52e-<NUM> that are stacked on top of each other, to form the four unit high, two unit wide wall. The lowermost modular wall units 52d, <NUM> are connected to further units 56a, 56b wherein the purpose of the further units 56a, 56b is to stabilise the wall formed by the stacked modular wall units 52a-<NUM> and to enable connection of the stacked modular wall units 52a-<NUM> to base units 58a, 58b. The further units 56a, 56b may take the form of a modular wall unit as described herein. In the example shown in <FIG>, the further units 56a, 56b further comprise a three-dimensional pattern that is appealing to the eye for display in rooms such as offices. As such, the further units 56a, 56b provide the three-dimensional pattern at the outer surface of the further units, in contrast to the wall as provided by the modular wall units 52d, <NUM>.

The base units 58a, 58b are rectangular in shape with a total surface area that is larger than the total surface area of the modular wall units facing the base units 58a, 58b. Alternatively, the base unit may be made of a single unit with a size corresponding to the total surface area of the modular wall units facing the base unit.

<FIG> shows a modular wall system <NUM> comprising corner units <NUM>, <NUM> for connecting walls at a <NUM> degree angle. The modular wall system <NUM> has a four unit high, two unit wide wall <NUM> located at a central part of the modular wall system <NUM>. The wall <NUM> is sandwiched between two corner units <NUM>, <NUM>. The corner units may be configured to connect the wall <NUM> to further walls 60a, 60b such that the central wall <NUM> and the further walls 60a, 60b are positioned at a <NUM> degree angle with respect to each other. A corner unit <NUM> may be formed of two portions extending along the length of the wall <NUM>, the two portions being fixed perpendicularly to one another. Placement of the corner unit <NUM> between the wall <NUM> and further wall 60b enables the wall <NUM> and the further wall 60b to be connected at a <NUM> degree angle. The further wall 60a, 60b may be connected to the wall <NUM> such that the further wall extends in a direction behind the wall <NUM> at a <NUM> degree angle or in a direction in front of the wall <NUM> at a <NUM> degree angle. In the example shown in <FIG>, the corner unit <NUM> provides connection for a wall 60a extending behind the central wall <NUM>. Similarly, the corner unit <NUM> provides connection for a wall 60b extending in front of the central wall <NUM>. It should be noted that the terminology 'in front' and 'behind' is simply used here to illustrate the example from the viewpoint shown in <FIG>. A first further wall 60a may extend from the main wall <NUM> in a direction opposite to the direction of a second further wall 60b extending from the main wall <NUM>, such that the modular wall system <NUM> forms a Z-shape or pseudo Z-shape. Alternatively, a first further wall 60a may extend from the main wall <NUM> in the same direction as the direction in which the second further wall 60b extends from the main wall <NUM>, such that the modular wall system <NUM> forms a U-shape.

<FIG> shows a modular wall system <NUM> comprising corner units <NUM> for connecting walls at a <NUM> degree angle. The modular wall system <NUM> has a four unit high, two unit wide wall <NUM> located at a central part of the modular wall system <NUM>. The wall <NUM> is sandwiched between two corner units <NUM>. The corner units may be configured to connect the wall <NUM> to further walls 60a, 60b such that the central wall <NUM> and the further wall 60a, 60b are positioned at a <NUM> degree angle with respect to each other. A corner unit <NUM> may be formed of two portions extending along the length of the wall <NUM>, the two portions being fixed in a non-parallel position with respect to one another. Placement of the corner unit <NUM> between the wall <NUM> and further walls 60a, 60b enables the wall <NUM> and the further wall 60a, 60b to be connected at a <NUM> degree angle. The corner units may be adapted to connect walls at angles smaller or greater than <NUM> degrees, e.g. walls may be connected at angles of <NUM> degrees or <NUM> degrees to form a subtle curve in the modular wall system <NUM>, or at angles of <NUM> degrees to form more substantive bends in the modular wall system <NUM>. The versatility of such modular wall systems enable them to be adapted to suit different environments and spaces.

The body <NUM> or body portion of the modular wall unit <NUM> may be formed of any material. The body <NUM> preferably comprises a rigid material. The body portion may comprise a foam material, e.g. polyurethane foam. The body portion may comprise steel, timber, other sheet materials, stone and/or concrete. The part of the body portion surrounding the reinforcement members may be unitary. The body portion may therefore be unitary in its structure and may be manufactured using insert moulding techniques. Polyurethane foam material comprised in the body portion is formed by reacting a polyol (an alcohol with more than two reactive hydroxyl groups per molecule) with a diisocyanate or a polymeric isocyanate in the presence of suitable catalysts and additives. In an example of manufacturing the modular wall unit, the H-shaped frame is surrounded by a mould that holds the H-shaped frame in a specific position. The foam material is then poured into the mould. The foam material then self-expands to fill all voids within the mould, to form the body portion of the modular wall unit whereby the body portion surrounds the H-shaped frame. Alternatively, the body may be formed from multiple parts that are attached to each other.

Where the body portion comprises a foam material, the foam material may be a polymeric foam such as but not limited to any one or more of: Ethylene-vinyl acetate (EVA) foam, polyethylene-vinyl acetate (PEVA), Low-density polyethylene (LDPE) foam, first grade of polyethylene (PE), Nitrile rubber (NBR) foam, the copolymers of acrylonitrile (ACN) and butadiene, Polychloroprene foam or Neoprene, Polyimide foam, Polypropylene (PP) foam, expanded polypropylene (EPP), polypropylene paper (PPP), Polystyrene (PS) foam, expanded polystyrene (EPS), extruded polystyrene foam (XPS), polystyrene paper (PSP), Styrofoam, extruded polystyrene foam (XPS) expanded polystyrene (EPS), Polyurethane (PU) foam, LRPu low-resilience polyurethane, Memory foam, Sorbothane, Polyethylene foam, Polyvinyl chloride (PVC) foam, closed-cell PVC foamboard, Silicone foam, or Microcellular foam. Typically, PU foam is comprised within the body portion due to the lightweight nature of PU. PE may be preferable in some instances due to its strength and low water absorption. Some examples may comprise two or more polymeric foam materials mixed into the same body portion.

The shape of the body may be any suitable shape. The body shape may be substantially box-like. One of the outer wall faces may have a single planar face whilst the opposing outer wall face may have a generally overall rectangular shape but have several surfaces joined at apex lines.

The elongate reinforcement members, e.g. the first elongate reinforcement member 20a and the second elongate reinforcement member 20b, comprised within the body <NUM> may be formed of any suitable material. Any of the elongate reinforcement members may comprise a metal, for example Aluminium. Any of the elongate reinforcement members may comprise a plastic, for example ABS plastic. In the examples discussed above with reference to <FIG> and <FIG>, the first elongate reinforcement member 20a and the second elongate reinforcement member 20b have tubular portions 22a, 22b proximal to a terminating end of the first elongate reinforcement member 20a and a terminating end of the second elongate reinforcement member 20b. Any one or more of the elongate reinforcement members may comprise a tubular portion proximal at both terminating ends. In the examples shown in <FIG>, for example, only the first elongate reinforcement member 20a may comprise a tubular portion proximal to a terminating end of the first elongate reinforcement member 20a. In the alternative, the first elongate reinforcement member and the second elongate reinforcement member may have tubular portions proximal to both terminating ends of each of the first elongate reinforcement member and the second elongate reinforcement member. Preferably at least the first and second reinforcement members comprise tubular end portions.

In alternative configurations, any one or more of the one or more of the elongate reinforcement members may comprise a tube running the entire length of the respective reinforcement member. In one example, the reinforcement members running between the joining faces are tubes. In the examples given above with two spaced apart reinforcement members running between the joining faces and another one running between these two spaced apart members, the first and third reinforcement members are tubes. The second reinforcement member may also be a tube.

The elongate reinforcement members, particularly the ones interfacing the one or more faces of the body that are for facing an adjacent wall unit, may have an male end connector for engaging with the tubular portion of another wall unit. The connector may be one as described above and shown in <FIG>, but may also be a connector that is at least partially integrally formed with the elongate reinforcement member. Such a connector portion of the member may protrude proud of the body.

As described above, the wall unit may further comprise one or more support members extending outwardly from an outer wall face. The one or more support members may be used to support further objects, such as a frame for hanging or otherwise further supporting other objects.

<FIG> shows an example where two support members - named first support member <NUM> and second support member <NUM> herein - extend outwardly from an outer wall face. The first support member <NUM> passes into a hole in the outer wall surface (not shown) and connects to one or more of the reinforcing members internal to the body.

The support members <NUM>, <NUM> shown in <FIG> are coupled to a hook <NUM>. The hook may also be referred to as a hanging device and is described in more detail elsewhere herein. The hook <NUM> is formed separately from the support members <NUM>, <NUM> and mechanically engages with the support members <NUM>, <NUM>. The hook <NUM> comprises a wall portion 74a and a two hook portions 74b. The first support member <NUM> is mechanically engaged with the hook <NUM> via the wall portion 74a, whereas the second support member <NUM> is mechanically engaged with the hook <NUM> via both the wall portion 74a and one of the hook portions 74b, as can be seen in <FIG>. The second support member <NUM> thereby acts as a securing pin to prevent objects from being removed from the hook.

The support members <NUM>, <NUM> comprise an elongate portion 76a, 78a and a head portion 76b, 78b terminating each support member <NUM>, <NUM> at a distal end away from the modular wall unit. The elongate portions 76a, 78a have a smaller maximum diameter than the maximum diameter of the respective head portions 76b, 78b.

In this example, the order in which the support members <NUM>, <NUM> are engaged with the hook <NUM> is important in securing an object to the wall unit. The first support member <NUM> is passed through a hole in the wall portion 74a of the hook and into a hole in the outer wall surface (not shown) to connect to one or more of the reinforcing members internal to the body. The first support member <NUM> thereby initially secures the hook <NUM> to the outer wall surface and in turn the one or more of the reinforcing members. A frame <NUM> can be hung upon the hook <NUM>. An example of such a frame is discussed above with reference to <FIG>. The second support member <NUM> is then passed through a hole in the hook portion 74b and then through a hole in the wall portion 74a of the hook, to secure the object within the hook and prevent it from being removed. The second support member <NUM> is subsequently passed into a hole in the outer wall surface (not shown). Alternatively, the second support member <NUM> may not be connected to the outer wall surface, the securing functionality being provided by connected the second support member <NUM> to the wall portion of the hook only. The present arrangement enables the frame <NUM> to be held securely in place, whilst preventing removal by, for instance, theft.

A plurality of hooks <NUM> may be attached to the outer wall surface of the wall in the manner described above and at appropriate distances apart in order to accommodate the required frame <NUM>. Alternative objects may be hung upon the hook.

The modular wall unit may further comprise a further support member extending from the second reinforcement member. The support member may extend substantially perpendicular from the first or second reinforcement members.

There is presented a hanging device <NUM> for supporting a frame <NUM>. The hanging device comprises a main body 74a comprising an engagement region <NUM> for engaging a headed fixing <NUM> that passes through the main body 74a. The hanging device also comprises spaced apart first and second arms 74b connected to, and arranged with, the main body 74a to form respective first and second hook portions 74b for supporting the frame <NUM>. The engagement region <NUM> being at least partially between the first and second hook portions.

An example of the hanging device is shown in <FIG>. When referring back to the hook <NUM> described above, the main body may be the wall portion 74a of the hook <NUM> whilst the two arms are akin to the hook portions labelled 74b.

The hanging device may therefore support the frame by allowing it to hang from the first and second hook portions whilst allowing a portion of the frame to extend vertically in between the first and second hook portions. Having the engagement region at least partially between the first and second hook portions allows a user to access the engagement region (for example attach/insert the headed fixing) without the hook portions being in the way. The device may be formed from separate components that are attached to each other, for example the arms may be formed separately and attached to the main body. Alternatively, the device may be unitary wherein the main body and arms are integrally formed with each other. The device may be formed from any suitable material, preferably a rigid material such as a metal or hard plastic. The device may be formed by moulding or other manufacturing process.

The first and second hook portions may form a channel extending at least: A) from, and including, the first hook portion; B) to, and including, the second hook portion, wherein the engagement region faces the channel.

The section of the main body that forms the channel (with the arms) may have the engagement region. The channel may be described as 'segmented' because the main body has a wall forming one continuous side of the channel where the other side of the channel is discontinuous and formed by respective walls of the separated arms that form the hooks portions. The separation of the arms 'segmenting' at least along one of the channels side and optionally the channel base.

The side of the main body opposite to the side forming the channel may be shaped to lie adjacent to an external wall, for example an outer wall of a modular wall unit as described elsewhere herein. This side of the device may be substantially planar. The main body may have a substantially rectangular block-like shape.

The arms 74b may initially extend outwardly, preferably perpendicularly away, from the main body 74a to form the base of the channel and then turn upwardly to form the hook portions and hence a side of the channel. The point where the arms extend outwardly from the main body may be from a peripheral portion of the main body.

The channel may be open at the top proximal to where the unconnected free ends of the arms terminate. The channel may have any suitable cross-sectional channel shape, including but not limited to a J-shape, U-shape or V-shape.

The engagement region may be recessed inwardly from a wall of the main body forming the channel. This allows the heading fixing <NUM>, when engaged with the device, to not obstruct the frame <NUM> when located in the channel.

The engagement region may face the lower half of the channel. Furthermore, the engagement region may be located about a portion of the said main body channel wall that is proximal to the base of the channel.

The engagement region <NUM> may comprise a passage extending through the main body away from the channel. The passage may be counter bored or counter sunk to accommodate the head 76b of the headed fixing <NUM> such that the head does not obstruct the frame <NUM> when located in the channel. The passage may be a through hole or through bore that allows the fixing <NUM> to pass through the main body 74a and engage with an external feature. The bore hole may have a longitudinal axis aligned with the bottom portion of the channel such that the headed fixing has at least a portion that is in line with, and faces, the base of the channel. When the frame is located in the channel, the frame may at least partially cover the head of the fixing, helping to prevent access to the head of the fixing. This helps prevent the unwanted removal of the device <NUM> from the external feature by hindering the removal of the headed fixing. The head 76b of the said fixing may have an outer diameter larger than the through hole thus only allowing the fixing to be removed from the device and external feature by pulling it out through the channel, in between the two arms 74b.

The headed fixing <NUM> that engages with the hanging device <NUM> may be a screw or a bolt. The headed fixing may act as a support member <NUM> (as described elsewhere herein) wherein, in <FIG> the main longitudinal part of the bolt/screw is akin to the 'wall portion' 76a of the support member <NUM>; whilst the head is akin to the 'hook portion' 76b of the same support member <NUM>.

When the headed fixing is a headed screw/bolt, the external feature may be a hole having an internal thread complementary to that of the screw. The external feature may be, for example, the 'fixing mechanism' <NUM> as described elsewhere herein.

The frame may comprise a first bar perpendicularly extending to and connected to a second bar wherein the said channel is for supporting the first bar. The main body may comprise a recessed second channel <NUM> at least partially accommodating the second bar. The recess may take the form of an elongate recess with a curved cross section shaped to flushly accommodate the vertical bar of the frame.

The wall of the main body forming part of the channel (i.e. the wall of the main body 74a facing the legs 74b) may be divided into two portions. A first portion opposing the first arm 74b and a second portion opposing the second arm 74b. The recessed second channel <NUM> may be located between the two said wall portions of the main body 74a. These two wall portions may be inclined to help form a V shape of the channel formed by the hook portions of the device. Likewise, the arms 74b may have an opposing inclined to the incline of the two said wall portions of the main body 74a so that the channel cross section (formed by the hook portions) resembles a narrowing taper extending from the open top of the channel towards the channel base.

The frame may be a grid frame as described elsewhere herein having a set or one or more first bars perpendicularly extending to and connected to a second set of one or more bars. The recessed second channel <NUM> may have its elongate length in a direction perpendicular to the direction of the channel formed by the hook portions.

A vertical bar of the frame may therefore, when accommodated by the device, be located in the recessed second channel <NUM> whilst a horizontal bar of the frame may sit in the bottom/base of the channel formed by the hook portions. When the frame <NUM> is in this final resting position in the device, the frame may be obstructing and/or at least partially covering the engagement region and headed fixing. Hence, at least part of the engagement region may be aligned along the length of second channel.

The engagement region may also be inwardly recessed into the main body from the second channel. This again allows the headed fixing to not obstruct the frame <NUM> when located in the device <NUM>.

At least one of the arms may comprise a through hole <NUM>. The main body 74a may comprise a fixing recess <NUM>. The through hole <NUM> and the fixing recess <NUM> may be aligned such that a further fixing <NUM> may be inserted through the through hole <NUM> and at least partially into the fixing recess <NUM>.

The through hole <NUM> may be proximal to the terminating free end of the said arm 74b. The further fixing <NUM>, when engaged into the fixing recess <NUM> and extending across the top of the channel, may therefore secure the frame <NUM> to the device <NUM> and prevent the frame being lifted out from the channel. The further fixing <NUM> may be similar to the headed fixing described above in that it may be a bolt or a screw. The further fixing <NUM> is akin to the support member <NUM> described above. The fixing recess <NUM> may be a through hole through the main body 74a or may be a bottomed recess within the main body 74a. Correspondingly the further fixing <NUM> may pass through the main body and optionally into a further external fixing recess (for example in a wall behind the device <NUM> that the device backs onto and is affixed to), or may only protrude partially into the main body 74a. The fixing recess <NUM> may have an internal thread complementary to an external thread of the further fixing.

Claim 1:
A modular wall unit (<NUM>) for a modular wall system (<NUM>), the modular wall unit comprising:
A) a body (<NUM>) having:
first (<NUM>) and second (<NUM>) outer wall faces;
first (<NUM>) and second (<NUM>) joining faces that each extend between the first and second outer wall faces; at least one of the first and second joining faces for facing a joining face of a further modular wall unit (<NUM>) of the modular wall system;
a first through-hole (<NUM>) extending between the first (<NUM>) and second (<NUM>) joining faces;
B) a first elongate reinforcement member (20a):
extending between the first joining face (<NUM>) and the second joining face (<NUM>) and within the first through hole (<NUM>);
having at least one tubular portion proximal to a terminating end of the first elongate reinforcement member (20a),
wherein the modular wall unit is configured such that:
the body (<NUM>) further comprises an internal recess extending away from and adjoining the first through hole (<NUM>);
the modular wall unit (<NUM>) further comprising an internal recess elongate reinforcement member (20c) that:
resides in the internal recess; and
is connected to the first elongate reinforcement member (20a);
characterised in that
the modular wall unit further comprises one or more support members for supporting further objects, the one or more support members extending outwardly from the first (<NUM>) or second (<NUM>) outer wall face; and
wherein the one or more support members comprises a first support member extending from the first elongate reinforcement member (20a).