NL2011429C2 - FOUNDATION SYSTEM AND THERMAL INSULATING LAYER SUITABLE FOR SUCH FOUNDATION SYSTEM. - Google Patents

Abstract

A foundation system for a building comprises a thermally insulating layer provided on a ground surface. Air passage ducts extending substantially parallel to the thermally insulating layer are provided between the thermally insulating layer and the ground surface. The air passage ducts are connected to at least one air supply duct on a first side and to at least one air discharge duct on a second side remote from the first side.

Description

Foundation system as well as thermally insulating layer suitable for such a foundation system

The invention relates to a foundation system for a building, which foundation system is provided with a thermally insulating layer located on a substrate.

The invention also relates to a thermally insulating layer suitable for such a foundation system.

When building buildings, it is generally known to first provide a thermally insulating layer on a subsurface and then to provide a floor such as a concrete floor or dry building floor on the thermally insulating layer. Next, walls, etc. are placed on the foundation and / or the floor. The ground of the substrate usually has a temperature of, for example, 10-15 degrees Celsius. The thermally insulating layer effectively prevents undesirable and uncontrolled cooling of the temperature in the space in the building above the floor due to the relatively cold surface.

In order to control the temperature in the room, heating systems can be used in winter to raise the temperature of the air in the room, while in the summer use can be made of, for example, air conditioners to lower the temperature of the air in the room. . External energy is required for the controlled increase or decrease of the temperature in the room.

The invention has for its object to provide a foundation system with which energy can be obtained in a simple manner for changing air temperature.

This object is achieved in the foundation system according to the invention in that air ducts are located between the thermally insulating layer and the substrate substantially parallel to the thermally insulating layer, which air ducts are connected on a first side to at least one air supply duct and to one of the second side facing away from the first side are connected to at least one air discharge duct.

A building is usually provided with a foundation that supports walls. The thermally insulating layer is located within the foundation that the walls support. The air supply duct and the air exhaust duct can be located both inside and outside the building.

In the winter, the outside temperature will usually be lower than the surface temperature. By guiding the air present outside the building via the air supply channel into the air supply channels, the air will be heated by contact with the substrate, so that the air leaving the air discharge channel will have a higher temperature than the air entering the air supply channel. The preheated air can be led directly into the building or can be further heated to the desired temperature with a heating system. Because the air is already pre-heated, less energy is required to heat the outside air to the desired temperature.

In the summer the outside temperature will usually be higher than the surface temperature. By guiding the air present outside the building through the air supply channel into the air supply channels, the air will be cooled by the contact with the substrate, as a result of which the air leaving the air discharge channel will have a lower temperature than the air entering the air supply channel. The pre-cooled air can be led directly into the building or can be further cooled to the desired temperature with an air conditioner. Because the air is already pre-cooled, less energy is needed to cool the outside air to the desired temperature. It is also possible to direct air present in the space in the building through the air supply channel into the air supply channels. This can be controlled, for example, with the aid of three-way valves, which can be used to determine whether outside air or air in the building is led into the air ducts.

The thermally insulating layer prevents direct influence on the temperature in the space above the thermally insulating layer.

Because the thermally insulating layer can extend over the entire bottom surface of the building, air can be pre-heated or pre-cooled over a relatively large surface.

Because air ducts can be provided under the entire building, a relatively large amount of air can be treated without the need for extra space outside the building.

Moreover, since the air ducts extend substantially parallel to the thermally insulating layer, virtually no additional preparatory work has to be performed on the substrate. This preparatory work will in particular consist of excavating the foundation to the desired depth before placing the foundation system. This depth need only be a few centimeters more than with a foundation system with a thermally insulating layer but without air ducts. The air ducts themselves have virtually no thermal insulating value. The dimensions of the thermally insulating layer and in particular the thickness are calculated or determined experimentally such that the thermally insulating layer has the desired insulating value (for example RC value). It is possible to provide an additional thermally insulating layer on the air ducts bounding the air ducts, the insulating value being determined by both superimposed layers. The desired insulating value determines the thickness of the total layer and the depth to be excavated. The foundation for supporting the walls located around the thermally insulating layer can be provided at a different depth, depending on the bearing properties of the substrate.

An embodiment of the foundation system according to the invention is characterized in that the thermally insulating layer is provided with side open slots facing the subsurface, which together with the subsurface form the air ducts.

Such slots can easily be provided in the thermally insulating layer with any desired dimension. The slots can be machined in a factory so that the slots are already provided in the thermally insulating layer at the location of the building to be built. It is also possible to provide slits forming air ducts in the subsurface, but this can only be done on site and is highly dependent on, among other things, the hardness and stability of the subsurface.

Another embodiment of the foundation system according to the invention is characterized in that the air ducts extend parallel to each other.

A relatively large number of air passage channels can hereby be provided over the surface of the thermally insulating layer, whereby a good heat exchange is obtained.

Another embodiment of the foundation system according to the invention is characterized in that the air supply channel and the air discharge channel extend substantially transversely of the air supply channels.

A compact location of the air supply channel and the air discharge channel can hereby be obtained with respect to the air supply channels, wherein all air supply channels are connected with the first side to the air supply channel and are connected with the second side to the air discharge channel.

Another embodiment of the foundation system according to the invention is characterized in that the air ducts are located at a mutual distance of 5 to 15 centimeters from each other.

With such a mutual distance, a good heat transfer between the substrate and the air present in the air ducts is obtained. The mutual distance can be determined, for example, depending on the amount of heat to be absorbed or released, the desired amount of air through the air ducts or the desired air resistance.

Another embodiment of the foundation system according to the invention is characterized in that the air passage channel has a width and / or height of 1 to 10 centimeters.

With such a width and height of the air duct, a good air flow can be realized.

Another embodiment of the foundation system according to the invention is characterized in that the thermally insulating layer comprises expanded polystyrene (EPS), polyurethane (PUR) or polyisocyanurate (PIR).

Such materials have a high thermally insulating value, are airtight, as a result of which the air flowing through the air ducts will not penetrate into the thermally insulating layer and, moreover, are easy to process for providing slots forming the thermally insulating layer therein.

Another embodiment of the foundation system according to the invention is characterized in that the air ducts are located below ground level.

As a result, the substrate is also below ground level, with the substrate having a relatively constant temperature. The deeper the air ducts are with respect to ground level, the more constant the temperature of the underlying substrate is.

Another embodiment of the foundation system according to the invention is characterized in that a foil is located between the substrate and the thermally insulating layer.

The film preferably has moisture-resistant and anti-fungal properties, so that the air flowing through the air ducts is not wetted by the substrate and no mold can form in the air ducts.

Another embodiment of the foundation system according to the invention is characterized in that the foil comprises polyethylene (PE), preferably provided with copper or zinc components.

In practice, the temperature difference of the air flowing through the air ducts at the beginning and end of the air ducts will be relatively limited and will only be a few degrees, for example 1-10 degrees. The moisture precipitation due to this temperature difference will therefore be limited. This will also limit mold formation or virtually no occurrence. The polyethylene film is relatively simple and inexpensive to manufacture and has anti-fungal properties. The antifungal properties are further improved by the copper or zinc components.

Another embodiment of the foundation system according to the invention is characterized in that the air supply channel is connected to outside air present outside the building.

In this way, fresh air from outside the building can easily be pre-heated or pre-cooled before the fresh air is introduced into the building.

It is often required to ensure that there is sufficient ventilation in a building, whereby, for example, 9 m3 per m2 per hour must be refreshed. With the foundation system according to the invention, this is combined in a simple manner with the pre-heating or pre-cooling of the air to be replaced.

Another embodiment of the foundation system according to the invention is characterized in that the air discharge duct is connected to an air treatment installation, a heat pump or a ventilation duct in the building.

With such an air treatment installation, heat pump or ventilation duct, the pre-heated or pre-cooled air can be further processed. The preheated air can, for example, be distributed throughout the entire building and guided along radiators for further heating thereof.

The preheated air can for instance be supplied to an air heat pump. Due to a more constant and higher air temperature of the pre-heated air, the air heat pump will have a higher efficiency (COP). The air heat pump can also be used to extract energy from air to be discharged from the building. The preheated air is then not led into the building but directly outside and only used to increase the efficiency of the air heat pump.

The pre-cooled air can, for example, be distributed throughout the building for cooling the building.

The invention will be further elucidated with reference to the drawings, in which: figures rA-C show bottom and top perspective views and a cross-section of a thermally insulating layer according to the invention; figures 2A - 2E show step by step the building of a building provided with a foundation system according to the invention; figures 3A and 3B show a cross-section and perspective side view of detail III of the foundation system shown in figure 2E; figures 4A and 4B show a cross-section and perspective side view of detail IV of the foundation system shown in figure 2E; Figure 5 shows the foundation system shown in Figure 2E with air flows passing through it; Figures 6A and 6B show the operation of the foundation system according to the invention in winter and summer respectively.

In the figures, corresponding parts are provided with the same reference numeral.

Figures 1A-1C show a bottom view, top view and cross-section of a thermally insulating layer 1 according to the invention. The thermally insulating layer 1 comprises an elongated top plate 2 and an elongate bottom plate 3 integrally connected thereto. The top plate 2 and the bottom plate 3 are offset in transverse direction with respect to each other, a first longitudinal side 4 of the top plate 2 extending beyond a first longitudinal side 5 of the bottom plate 3. In a similar manner, a second longitudinal side 6 of the bottom plate 3 extends beyond a second longitudinal side 7 of the top plate 2. The first longitudinal side 4 of the top plate 2 is provided with an elongated groove 8 and the first longitudinal side 5 of the bottom plate 3 is provided with an elongated groove 9.

The second longitudinal side 7 of the top plate 2 is provided with an elongated rib 10 and the second longitudinal side 6 of the bottom plate 3 is provided with an elongated rib 11. The ribs 10, 11 of a thermally insulating layer 1 can be coupled to the grooves 8, 9 of an adjacent thermally insulating layer 1.

The top plate 2 and the bottom plate 3 are offset longitudinally with respect to each other, a first transverse side 12 of the top plate 2 extending beyond a first transverse side 13 of the bottom plate 3. A second transverse side extends in the same way the 14 of the bottom plate 3 extends beyond a second transverse side to the 15 of the top plate 2. For thermally insulating layers 1 coupled to each other, the first transverse side is to the 12 of the top plate 2 of the one thermally insulating layer 1 against the second transverse side 14 of the bottom plate 3 of the adjoining thermally insulating layer 1.

The bottom plate 3 of the thermally insulating layer 1 is provided with a number of rectangular slots 16 extending parallel to the longitudinal sides 5, 6 and extending the full length from the transverse side 13 to the transverse side 14. The slot 16 has a width B of 1 to 10 centimeters, for example 2 centimeters and a height H of 1 to 10 centimeters, for example 5 centimeters. The slots 16 are spaced from one another at a pitch of 5 to 15 centimeters, for example 9 centimeters. The slots 16 are open towards the bottom. The thickness of the thermally insulating layer 1 is, for example, at least twice the height of the slot 16, whereby a sturdy thermally insulating layer 1 is obtained.

The thermally insulating layer 1 is preferably made from polystyrene (EPS), polyurethane (PUR) or polyisocyanurate (PIR).

The length and width of the thermally insulating layer 1 is, for example, 80 and 60 centimeters, whereby a total thermally insulating layer of the desired dimensions can be obtained by coupling a number of thermally insulating layers 1.

Figures 2A-2F show various steps of building a building which is provided with the above-described thermally insulating layers 1 for forming a foundation system according to the invention.

In a known manner a compacted sand package 20 is applied to the underlying earth surface, on which a concrete foundation 21 with the desired shape of the building to be built is provided (see figure 2A). The manufacture of such a foundation is known per se and will therefore not be explained further.

Strips of foil 22 are then applied to the sand package 20 in the foundation 21, which strips overlap one another in a tile-like manner, wherein, viewed in the direction indicated by arrow Pi, one strip 22 is located on the following strip 22, so that an air flow in the indicated by arrow Pi presses the overlapping parts of the strips 22 against each other in the direction across the strips 22 (Figure 2B).

The foil of the strip 22 is moisture-resistant and fungal-resistant and is for instance made of polyethylene (PE) with copper or zinc components.

Figure 2C shows the step in which on the strips of film 22 the thermally insulating layers 1 are positioned in a semi-brick relationship, the transverse sides 12-15 extending parallel to the longitudinal direction of the strips 22. In this step, air supply channels 23 and air discharge channels 24 are also placed. The location and operation thereof will be further explained with reference to Figures 3A-4B.

Figure 2D shows the step in which further thermally insulating layers 25 are applied to the thermally insulating layers 1. The thermally insulating layers 25 are substantially identical to the thermally insulating layers 1 but are not provided with slots 16 and have a smooth underside. The thermally insulating layers 25 are positioned in a half-brick relationship, the longitudinal sides of the thermally insulating layers 25 extending transversely to the longitudinal sides of the thermally insulating layers 1.

Figure 2E shows the step in which a concrete layer 26, such as a concrete floor or load-bearing floor, is provided on the thermally insulating layers 25.

The application of the concrete layer 26 is known per se and will therefore not be further explained.

Figure 2F shows the step in which walls 27 of the building 28 are placed on the foundation 21 and on the concrete layer 26. The walls 27 are provided with air passage openings 29. The building 28 is furthermore provided with an air treatment installation 30 which is connected to the air discharge channel 24.

Figures 3A and 3B show a cross-sectional and perspective side view of detail III of the foundation system shown in Figure 2E. An inner wall 31 and, at a distance therefrom, an outer wall 32 are placed on the foundation 21. Between the inner wall 31 and the outer wall 32 is a cavity 33 in which a thermally insulating layer 34 is provided. The thermally insulating layer 1 located on the strips of foil 22 is cut straight down near the inner wall 31 so that the transverse sides 14, 15 of the top plate 2 and the bottom plate 3 are aligned with each other. The transverse sides 14, 15 are spaced apart from the inner wall 31, an elongated air supply channel 35 being formed between transverse sides 14, 15 and the inner wall 31. The air supply channel 35 is bounded on the underside by the substrate formed by the sand package 20 and the strips of foil 22 and bounded on the top by the thermally insulating layer 25 which extends to the inner wall 31. The air supply channels 23 made of plastic tubes are connected to the air supply channel 35. The air supply duct 23 extends through the inner wall 31, the cavity 33 and the outer wall 32 to outside the building 28, where it is provided with an inlet nozzle 36.

The thermally insulating layer 1 abuts the substrate formed by the sand package 20 and the strips of foil 22. The slots 16 are closed on the open underside by the strips of foil 22 and form air passage ducts which are connected on a first side to the air supply duct 35.

Figures 4A and 4B show a cross-sectional and perspective side view of detail IV of the foundation system shown in Figure 2E. The inner wall 31 and, at a distance therefrom, the outer wall 32 are placed on the foundation 21. Between the inner wall 31 and the outer wall 32 is the cavity 33, in which the thermally insulating layer 34 is provided. Transverse sides 12, 13 of the thermally insulating layer 1 disposed on the strips of film 22 are spaced apart from the inner wall 31, an elongate air discharge channel 37 being formed between transverse sides 12, 13 and the inner wall 31. The transverse sides 14, 15 are for instance situated at a distance of 10 centimeters from the inner wall 31. The air discharge channel 37 is bounded at the bottom by the substrate formed by the sand package 20 and the strips of foil 22 and bounded at the top by the thermally insulating layer 25 which extends to the inner wall 31. Connected to the air exhaust channel 37 is the air exhaust channel 24 made of plastic tubes. The air exhaust channel 24 extends through the thermally insulating layer 25 and the concrete floor 26 into the building 28, where it is provided with an outlet nozzle 38. In the building 28, the air exhaust channel 24 can be connected to an air treatment installation 30 or can be directly in opening the building 28 in a ventilation duct in the building 28. The air treatment installation 30 can be an air treatment installation or a heat pump.

The air passage channels bounded by the slots 16 and the substrate formed by the sand package 20 and the strips of foil 22 are connected on a second side to the air discharge channel 37.

As is usual with a foundation 21, the sand package 20 and at least a part of the foundation lie below ground level 39, so that also the thermally insulating layers 1 and air passage channels formed through the slots 16 in the thermally insulating layers 1 and the substrate are below ground level. 39 are located.

Figure 5 shows a perspective view of a part of the building 28 that is provided with the foundation system according to the invention. Air is led from outside the building 28 into the inlet nozzles 36 by means of a fan (not shown) or is sucked from the outlet nozzle 38 into the building by means of a suction pump (not shown), so that an air flow in the arrows P2, P3, P4 and P5 are caused by the air supply channels 23, the air supply channel 35, the air supply channels formed by the slots 16 in the thermally insulating layers 1 and the substrate, the air discharge channel 37 and the air discharge channels 24.

Figure 6A shows the air flow in the winter through the air passage channels formed through the slots 16 in the thermally insulating layers 1 and the substrate, the incoming air in the air supply channel 35 (arrow P2) having a temperature of, for example, o degrees. For example, the earth through the sand package 20 and the soil below it has a temperature of 10 degrees. During the flow of air through the air ducts, heat transfer takes place from the substrate to the air in the air ducts in the direction indicated by the arrow P6, as a result of which the air is heated and has a temperature in the air duct 37 (arrow P5) for example 5 degrees.

Figure 6B shows the air flow through the air ducts formed by the slots 16 in the thermally insulating layers 1 and the substrate in the summer, with the incoming air in the air supply duct 35 (arrow P2) having a temperature of, for example, 25 degrees. For example, the soil through the sand package 20 and the earth beneath it has a temperature of 15 degrees in the summer. During the flow of air through the air ducts, heat transfer takes place from the air in the air ducts to the substrate in the direction indicated by the arrow P7, whereby the air is cooled and has a temperature of in the air duct 37 (arrow P5) for example 20 degrees.

The preheated or pre-cooled air can then be brought to the desired temperature by means known per se.

It is also possible to manufacture the thermally insulating layer from rock wool or glass fibers, wherein the underside provided with slots is made air-tight, for example through a foil, so that air flowing through the slots cannot flow into the rock wool or the glass fibers.

It is also possible not to use strips of foil 22 if there is no risk of moisture or mold formation or if this is prevented in another way.

The thermally insulating layers 25 can be omitted with sufficient insulating effect from the thermally insulating layers 1.

It is also possible to install an air supply duct in the building, so that in the summer the relatively warm air in the building can be led directly into the air ducts between the thermally insulating layer and the substrate for cooling.

It is also possible that the slots have a different one, such as for example a triangular or round cross-section, instead of a rectangular cross-section. Typically, EPS is cut with the help of hot wires, with the easiest way to cut rectangular slots by machine. However, the shape of the slots is not essential to the function of the slots. The thickness of the thermally insulating layer with slots is preferably chosen such that the thermally insulating layer is relatively stiff so that it can be easily transported and placed.

The building can be a home, office, store, flat.

It is possible to provide the air supply channel with a filter or device to, for example, disinfect the incoming air with ozone, perfume or purify it.

List with reference numerals 1 thermally insulating layer 2 top plate 3 bottom plate 4 longitudinal side 5 longitudinal side 6 longitudinal side 7 longitudinal side 8 groove 9 groove 10 ribs and ribs 12 transverse 13 transverse 13 transverse 15 transverse 16 slot 20 sand package 21 foundation 22 strip of foil 23 air supply channel 24 air discharge channel 25 thermally insulating layer 26 concrete layer 27 wall 28 building 29 air passage opening 30 air treatment installation 31 inner wall 32 outer wall 33 cavity 34 thermally insulating layer 35 air supply channel 36 inlet nozzle 37 air outlet channel 38 outlet nozzle 39 ground level B width H height P1-P7 arrow S pitch

Claims (13)

A foundation system for a building (28), which foundation system is provided with a thermally insulating layer (1) located on a substrate, characterized in that substantially parallel to the thermally insulating layer (1) and the substrate (28) air ducts extending from the thermally insulating layer (1) are located, which air ducts are connected on a first side to at least one air supply duct (35) and on a second side remote from the first side are connected to at least one air extract duct (37). Foundation system according to claim 1, characterized in that the thermally insulating layer (1) is provided with side open slots (16) facing the substrate, which together with the substrate (20) form the air ducts. 3. Foundation system as claimed in claim 1 or 2, characterized in that the air ducts extend parallel to each other. Foundation system according to claim 2, characterized in that the air supply duct (35) and the air discharge duct (37) extend substantially transversely to the air ducts. Foundation system according to claim 3 or 4, characterized in that the air ducts are located at a mutual distance of 5 to 15 centimeters from each other. Foundation system according to one of the preceding claims, characterized in that the air passage channel has a width and / or height of 1 to 10 centimeters. Foundation system according to one of the preceding claims, characterized in that the thermally insulating layer (1) comprises expanded polystyrene (EPS), polyurethane (PUR) or polyisocyanurate (PIR). Foundation system according to one of the preceding claims, characterized in that the air passage channels are located below ground level (39). Foundation system according to one of the preceding claims, characterized in that a foil (22) is located between the substrate (20) and the thermally insulating layer (1). Foundation system according to claim 9, characterized in that the foil (22) comprises polyethylene (PE), preferably provided with copper or zinc components. Foundation system according to one of the preceding claims, characterized in that the air supply duct is connected to outside air present outside the building. Foundation system according to one of the preceding claims, characterized in that the air discharge duct is connected to an air treatment installation, a heat pump or a ventilation duct in the building (28). A thermally insulating layer (1) suitable for a foundation system according to any one of the preceding claims, characterized in that the thermally insulating layer (1) is provided with open slots (16) to be directed towards a substrate, which air ducts together with the substrate to shape.