GB2524328A - An insulation wall system - Google Patents

Abstract

An insulation system comprises a board 3 having a channel extending between its edges. The channel receives electrical and plumbing services such as piping and cabling. The board may have two sets of perpendicular channels 7, 9. The insulating system may include a plurality of identical boards, the channels of adjacent panels being positioned for connection. The boards may be connected to an internal wall. The system may comprise a location member for indicating the position of the channels relative to the board. The location member may be ferrous or a strip of tape. The system may include one or more plasterboard sheets for bonding to the insulating boards.

Description

I

AN INSULATION WALL SYSTEM

FIELD OF THE INVENTION

This invention relates to an insulation system, more particularly an insulation system for insulating perimeter walls.

BACKGROUND TO THE INVENTION

It is widely acknowledged that a considerable quantity of the energy consumed in commercial and domestic premises for heating purposes is simply wasted due to poorly insulated buildings. To alleviate this problem, new buildings have been provided with insulation, for example in the form of cavity wall insulation and roof insulation, for some time. However, the quantity of insulation included in a modern building is now far higher than that included even a few years ago.

Furthermore, there is a large stock of buildings particularly residential housing with rudimentary or non-existent insulation. For example, buildings built in the Victorian and Edwardian eras or before were tvpicafly constructed with solid brick walls and have no particular insulation. More modem buildings make use of cavity wall construction, but no insulation is provided in the cavities. Whereas cavity wall insulation can be relatively straightforward to retro-fit without major disruption, upgrading the insulation to solid walls is typically very disruptive. This is because it must be applied internally requiring complete internal refinishing e.g. plastering and redecoration and potentially the re-routing or adaptation of electrical and plumbing services.

Some methods for retro-fitting insulation to solid walls involve either the fixing of insulation directly to the solid walls, or the fixing of studs to the interior of the walls and then installing sheet insulation between each of the studs. The studs typically have recesses for retaining the edges of the sheet insulation, Plasterboard or another sheet building material may then be fixed over the insulation to provide a finished surface for decoration.

Aside from the disruption, there is a significant problem with this technique: it becomes extremely difficult to access electrical and plumbing services buried in the walls for repairs of future aheration, This is because cables and pipes will typically be buried in the original wall structure beneath the sheet insulation making them both difficult to locate and requiring significant damage to the sheet insulation to access them, which inevitably compromises the performance of the insulation.

W0201211 75959 discloses a system in which studs are used to fix insulation to a solid wall. The front wall of the stud is spaced apart from the underlying wall, so that services can be routed to a desired location. Apertures are disposed on the front wall of the stud to provide access to the region between the stud and the underlying wall.

In order to maximise the performance of an insulation system, it is desirable to minimise the amount of space in the system which is not insulated. In many cases, it is also desired to keep down the cost of the insulation system.

SUMMARY OF THE INVENTION

According to a first aspect of the invention there is provided a device as claimed in the independent claim.

In one aspect, there is provided an insulation system comprising: an insulation board; and a cable routing channel which extends from an edge of the insulation board to an opposite edge of the insulation board; wherein the cable routing channel is recessed into the insulation board.

The insulation board may be installed by fixing the board to a wall, and routing the pre-existing electrical wiring of the wall into a cable routing channel. It is therefore possible to install service points, by routing wiring through the cable routing channels to a desired installation location. In this way, an installer is able to access the wiring so that alteration and repair work can be carried out quickly and conveniently, without damaging the insulation.

The recessed channels provide an advantage in that they are integrated with the insulation board, so that the insulation system is cheap to manufacture, and simple to install.

In an embodiment, the cable routing channels may comprise a first set of cable routing channels which extend in a first direction and a second set of cable routing channels which extend in a second direction, perpendicular to the first direction; wherein the first set of cable muting channels are interconnected with the second set of cable routing channels.

This arrangement may provide a grid of cable routing channels into which the existing electrical wiring is routed. In this way, it is possible to provide electrical supply from an existing source to any location on the grid. This enables the installation of access points, such as electrical switches and sockets at any point on the wall, on or near to the grid.

The board may comprise a rectangle with sides parallel to the first and second directions.

In one example, the first set of channels are at a first set of distances from one of the perpendicular edges, and the second set of channels are at the same set of distance from one of the perpendicular edges. This means the first set of channels of one board can be aligned with the second set of channels of an adjacent board with a 90 degree relative rotation. This can reduce waste.

A plurality of boards may be provided, with the grid of routing channels connected together to define a continuous grid across the full area of the wall being insulated. Some or all of the insulation boards may be identical to each other to reduce the number of different components needed to form the system.

The channels can be positioned to correspond to a desired service point location, for example the height of the channels may be designed to comply with regulations for the positioning of electrical sockets and switches.

The insulation board may be adapted to be fixed to a wall.

The insulation system may comprise a location member for indicating the position of a cable routing channel relative to the insulation board, Therefore, the location member may assist an installer in identifying the position of the cable routing channel, so that the installer is able to quickly and easily determine positions suitable for installing an access point.

The location member may be ferrous. In an embodiment, the location member may be a strip of tape. The location member may be provided during the manufacture of the insulation system, or may be added after.

The insulation board may be bonded to plasterboard.

The cable routing channels may extend to a depth of 30% to 70% of the depth of the insulation board. This means the structural rigidity of the insulation boards can be maintained, a sufficient depth for the wiring channels can be formed, and insulation can remain in place behind the channels. The depth may be around 40% to 60% of the depth of the insulation board, In an embodiment, the cable routing channels may be 25 mm deep and the insulation board is 50mm deep.

BRIEF DESCRIPTION OF THE DRAWINGS

An example embodiment of the invention will now be described with reference to the accompanying drawings, in which Figure 1 shows an insulation system according to the invention, Figure 2 shows the cross section across line A of Figure 1, Figure 3 shows the cross section across line B of Figure 1.

Figure 4 shows an embodiment of the insulation system of Figure 1.

DETAILED DESCRIPTION

The invention provides an insulation system which can be installed to increase the insulation of a solid wall. The insulation system comprises insulation boards into which are formed one or more cable routing channel through which supply cables can be wired. The cable routing channel or channels are structured so that supply cables are able to extend from one end of the channel, to an opposite end.

Figure 1 shows an insulation system 1 according to an embodiment of the invention, in the form of a single insulation board. The insulation board is suitable for insulating perimeter walls, so that installation of the board provides additional insulation, The system is modular, and comprises a set of the boards shown in Figure 1.

The insulation board 3 comprises a rectangle, so the multiple boards can be tessellated to form a continuous area of insulation. In the preferred embodiments, cable routing channels 7,9 are recessed in the board in a grid formation such that wiring can be routed through the cable routing channels 7,9 to provide electrical supply at any location on, or in close proximity to the grid. As such, it is possible to install service points at any point on the wall.

The insulation board 3 has two sets of cable routing channels, a first set which extends in a first direction and a second set which extends in a second direction, The first and second directions are perpendicular to each other, so that channels of the first and second sets intersect, The first set 7 of channels extend in a horizontal direction in use, so that they are at a constant height above the floor when the insulation board is installed, The second set 9 of channels extend in a vertical direction, A cable inserted into a channel of the first set 7 can be fed through the connection between the first and second set of cable routing channels, and into a channel 9 of the second set, In this way, when the insulation system is installed, access points may be added at any chosen installation location on the wall. The installer must simply route wiring through the cable routing channels 7,9 to the installation location.

The insulation board is of any suitable insulation material, and one of the most common materials used is Polyisocyanurate (PTR). The board may be covered with heat reflecting surfaces. Furthermore, the material of the board may be designed to provide acoustic insulation as well as thermal insulation, if desired.

By wiring a supply cable through the cable routing channels, it is possible to provide electrical supply via the cable routing channels 7,9 to install an access point at any installation location defined by the grid. Further, it is possible to re-route the cables through the grid to change the layout of the electrical supply cables, In this way, the position of access points can be changed and new access points can be added without conipromi sing the performance of the insulation. It is envisaged that the cable routing channels 7,9 may be suitable for providing access to other amenities such as plumbing, or gas.

Figure 2 illustrates the cross section through line A of Fig.1, and shows the first set of cable routing channels 7. The cable routing channels 7 extend to the opposite edges of the insulation board 3 (in this case the left and right sides), and are about half as deep as the depth of the insulation. For example the depth may be between 30% and 70% of the thickness of the board (more preferably between 40% and 60%). In an example, the insulation is 50 mm deep and the channel is 25 mm deep.

The channels are for example 50 to 100 mm wide, for example 60mm to 90mm wide (e.g. 75mm), so that multiple cables can be routed along the channels.

It will be appreciated that the cable routing channels 7,9 may be of a different depth, for example the cable routing channels 7,9 may be less than half the depth of the insulation board 3. Alternatively, the cable routing channels 7,9 may be deeper than half of the depth of the insulation board 3.

Figure 3 illustrates the cross section through line B of Figure 1, and the second set of cable routing channels 9 are shown. In this example, one of the cable routing channels 9 forms an edge of the insulation board 3. The second set of cable routing channels also extend to opposite edges of the insulation board (in this case the top and bottom).

lii one implementation, the boards can be designed to be tiled with all boards in the same orientation, In this way, only the horizontal channels need to meet when tiled.

However, it is also possible to allow the boards to be tiled with two different orientations, offset by 90 degrees. This means the vertical channels become horizontal channels and the horizontal channels become vertical channels, Figure 4 shows an embodiment the insulation system 1, in which insulation boards 3 of the insulation system I have been installed in two different orientations; which may be considered as portrait and landscape. In this embodiment, the cable routing channels 7, 9 are positioned on the insulation boards 3 so that the boards can be installed in either orientation.

To enable this, the distance of the vertical channels (in the portrait orientation) from one edge (the left edge in this example) corresponds to the distance of the horizontal channels from the bottom edge. With reference to Figure 4, dl=d3 and d2=d4.

By way of example, dl=d3=490mm ±50mm (to the middle of the channel), d2d41 170mm + 50mm, (to the middle of the channel) the full height of the board is 2400mm and the full width of the board is 1200mm, This defines horizontal channels at desired heights and has vertical channels to enable the grid to be formed with differently oriented boards.

The advantage of this possibility is that waste can be reduced, for example by tiling around a window.

S The set of insulation boards may thus be installed in only one orientation, or in a combination of orientations. An insulation board 3 installed in one orientation is connected to the adjacent insulation board to form a grid of cable routing channels. The cable routing channels of the two insulation boards will connect to form a grid regardless of the combination of orientations of the two boards. For example, in one configuration an insulation board 3 is installed in a portrait orientation adjacent to an insulation board 3 installed in a horizontal orientation, Alternatively, the insulation boards 3 may all be installed in the portrait orientation, or the insulation boards 3 may all be installed in the horizontal orientation, The insulation boards 3 can therefore be arranged in different configurations in order to provide different grid layouts.

In use, the insulation board can be stuck to the wall to be insulated by a bonding agent. To provide a finish, plasterboard sheets may then be bonded over the insulation boards.

This design avoids the need for an expensive network of metal channels, and can also simplify the installation procedure. To secure items to the insulated wall, fixings can be used which extend through the insulation to the solid wall behind, since the insulating structure will not normally provide a strong anchoring surface.

When the plasterboard sheets have been installed, it is desirable to be able to locate the channels. The horizontal channels are at known heights, for example corresponding to electrical socket height and kitchen counter height, but the vertical channels may be in unknown positions.

A location member may be provided for indicating the position of a cable routing channel relative to the insulation board, for example ferrous markings to enable location by magnetic detection through the plasterboard. A strip of ferrous tape can for example be provided in the channels.

The dimensions given above relate to an example which enables tiling with different orientations, If this is not needed, the vertical channels may instead be evenly spaced. For example the horizontal channels can be at the desired heights (again around 500mm and 1200mm) but the vertical channels can be at even spacings across the 1200mm width. For example the width can be 525mm of full thickness, a 75mm channel, another 525mm of full thickness and then an edge channel of 75mm.

A further horizontal channel may be provided near the top of the board, for example for supply to devices mounted high up, such as televisions, security cameras, lighting etc. Indeed, the channel configuration may be designed to match the intended equipment to be used within a space.

As a minimum, an insulation board may have a single channel, for example a single horizontal channel at socket height, which connects to channels at each side. For example this may be appropriate under a window, where is not need to have channels running from top to bottom. Thus, some boards may be a grid of crossed channels, and others may have only one or more horizontal channels. Similarly, a board may have only one vertical channel instead of two as shown in the examples, or indeed there may be more than two vertical channels.

Other variations to the disclosed embodiments can be understood and effected by those skilled in the art in practicing the claimed invention, from a study of the drawings, the disclosure, and the appended claims. In the claims, the word "comprising" does not exclude other elements or steps, and the indefinite article "a" or "an" does not exclude a plurality. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measured cannot be used to advantage, Any reference signs in the claims should not be construed as limiting the scope.

Claims (15)

1. CLAIMS1. An insulation system comprising: an insulation board; and a cable routing channel which extends from an edge of the insulation board to an opposite edge of the insulation board; wherein the cable routing channel is recessed into the insulation board.
2. 2. The insulation system of claim I wherein the board comprises a first set of cable routing channels which extend in a first direction and a second set of cable routing channels which extend in a second direction, perpendicular to the first direction; wherein the first set of cable routing channels are interconnected with the second set of cable routing channels.
3. 3. The insulation system of claim 2, wherein the insulation board comprises a rectangle with sides parallel to the first and second directions.
4. 4. The insulation system of claim 2 or 3, wherein the first set of channels are at a first set of distances from one of the perpendicular edges, and the second set of channels are at the same set of distance from one of the perpendicular edges.
5. 5. The insulation system of any preceding claim comprising a plurality of insulation boards.
6. 6. The installation system of claim 5, wherein some or all of the insulation boards are identical to each other.
7. 7. The insulation system of any claim 5 or 6 wherein the cable routing channels are positioned to provide connection between adjacent insulation boards.
8. 8, The insulation system of any preceding claim wherein the insulation board is adapted to be fixed to a wall.
9. 9. The insulation system of any preceding claim, further comprising a location member for indicating the position of a cable routing channel relative to the insulation board.
10. 10. The insulation system of claim 9 wherein the location member is ferrous.
11. L The insulation system of claim 9 wherein the location member is a strip of tape.
12. U, The insulation system of any preceding claim further comprising one or more plasterboard sheets for bonding to the insulation board or boards.
13. 13. The insulation system of any preceding claim wherein the cable routing channel or channels extend to a depth of 30% to 70% of the depth of the insulation board.
14. 14. The insulation system of claim 13 wherein the cable routing channels or channels are 25 mm deep
15. 15. The insulation system of claim 13 or 14 wherein the insulating board is 50 mm deep,