NL8700789A - ROOF INSULATION PLATE. - Google Patents

Description

V.

34 EN 34.189-Me / hp

Roof insulation board

The invention relates to a roof insulating plate of heat-insulating material for placing between the rafters, in which recesses and elevations are formed in its surface facing the roof covering, which form air conduction paths extending from the base of the roof to the ridge.

A roof insulation panel of this kind is described, for example, in the German Gebrauchsmuster 79 07 167. In addition, a number of recesses running side by side and parallel to the rafters are provided on the top of the panel, through which a number extending in the direction of the ridge channels are formed. The elevations simultaneously also form a support surface for a foil, so that a sufficient flow cross-section is guaranteed. Namely, in the other case the foil would sag, whereby a correct discharge of the air and the water vapor would no longer be guaranteed.

However, the water vapor concentration in the aeration space differs. This is the case with the ducts described above, as well as with a free aeration space, such as can be used when a roof boarding is used. For example, the water vapor concentration is greater in the vicinity of the spruce, because more water vapor can penetrate here than the other places of the insulation due to the inevitable joint between insulating material and fir wood. In addition, the airflow running along the fir wood is inhibited by the boundary wall friction. This means that there is an increased enrichment with water vapor. Air with a higher water vapor concentration is heavier than 30 air with a lower water vapor concentration. This means that the heavier air lacks upward force if no sufficiently high air flow and mixing with dry air is present. Particularly in the area of the spruce, a water vapor build-up is therefore obtained. This leads to an upright moist air, which forms an ideal breeding ground for moisture stains, fungal attack, irritation and rot.

The air supply in the ducts took place from the 8700789 * -2-foot of the roof through appropriate slots, or spaces between the roofing and the wall work. The air in the ridge area can be exhausted by ventilation tiles or a so-called ventilation ridge. In new construction this continuous ventilation slot can still be effected, although with considerable expensive constructions, such as for instance bird protection grids and the like. In old buildings, however, in order to provide the ventilation slot in the area of the base of the roof, a skeleton and considerable breaking work are generally necessary, which entails high costs.

However, it is also a drawback that in general there is a wind blind angle under a roof, for which reason a thermal upward force has only limited effect. If no af-15 roof is present, the ventilation is behind the gutter, which also forms a wind-dead area.

Ventilation by ventilation tiles, which are fitted in the lower area of the roof, is not usable. It is true that a connection to the channels in the roof insulation plate can be effected by means of suitable recesses in a wooden roofing or a foil, but such ventilation would be insufficient because of the shape of the recess, because it would only ducts located directly below the ventilation tables. The roof boarding or foil which abuts against the projecting transverse wood, namely closes the channels upwards, whereby a lateral escape of the air flow is prevented. But also with roofs without foil and walling, such as these often occur in old buildings, the air flow drawn in by the ventilation tiles 30, such as with the baffle plates of a turbine, would be led directly into the channels in the channels.

The object of the present invention is therefore based on the provision of a roof insulation plate of the type mentioned in the preamble 35, by which surface-covering ventilation of the entire fir compartment is achieved in a simple manner.

According to the invention, this object is achieved in that the elevations are designed as flow bodies and spacers, respectively, which are arranged on the surface of the plate with an 8730789 division such that the towards the cam flowing air is also distributed over the width of the plate.

The flow bodies or spacers according to the invention now provide surface-covering ventilation of the entire fir compartment, instead of only a few separate channels. This means that there are no more problems with water vapor concentrations. One of the main advantages of the flow bodies according to the invention lies in the fact that it is no longer necessary to provide ventilation slots or ventilation openings on the wall work in the area of the base of the roof. Because an extensive through-flooding or flooding of the plate by the flow bodies is ensured, ventilation can be achieved by simply installing ventilation tiles in the lower area of the roof.

A ventilation tile for a spar section may then be sufficient in each case, because the airflow that has entered also expands laterally and in this way also touches the direct area of the spar.

However, the flow bodies also further ensure that a cardboard or foil placed on the rafters does not sag and thus influences the air flow.

In an advantageous embodiment of the invention it can be ensured that a number of flow bodies are arranged at a distance next to each other over the width of the plate, while a number of rows of flow bodies are arranged one behind the other in the longitudinal direction of the plate.

In this way, with a number of flow bodies, a stud or cam-like surface of the plate is provided, whereby a good air distribution is achieved, while at the same time this also avoids sagging of any film overlying it.

The longitudinal rows of the flow bodies can thereby be arranged at a distance from each other.

It is advantageous if the flow bodies are arranged in rows which are staggered one behind the other, whereby the offset can be arranged in such a way that each subsequent flow body 40 is at least approximately in the middle between two previously passed 8700789 V <► Flowed flow bodies are located.

As a result of this arrangement, a very good distribution of the inflowing air is achieved, because it, in its flow between two flow channels, subsequently collides with a further flow body, whereby the air is further distributed.

However, the flow bodies can of course also be arranged irregularly or in a different pattern on the surface of the plate.

In a further very advantageous embodiment of the invention it can be ensured that flow bodies of the first row are arranged obliquely in the inlet region with respect to the longitudinal direction of the plate, so that air guiding paths are inclined on the longitudinal sides of the plate 15. focused.

Due to the inclination of the flow bodies in the inlet area, that is to say, for example, in the area under a ventilation tile or with an existing slot in the wall work in the area of the base of the roof, an oblique flow of the inflowed air in the towards the rafters, so that it is precisely in this endangered area that a good mixture of the moist air present there is achieved with the incoming dry air. This forced mixing of the light with the heavy air reduces the weight of the latter. A uniform air weight therefore prevails in the entire cross section of the spar section, as a result of which a corresponding rise force occurs in the entire spar section. Stagnant air zones with a high water vapor concentration are thereby avoided.

In addition, the staggered flow bodies effect a wipe-out of the entire ventilation space with the appropriate wind direction.

The flow bodies themselves may be of any design. In general, however, one will choose a shape which does not offer a large flow resistance, or which does not generate large turbulences.

In simple manner, for example, the flow bodies can have a circular cross-section in plan view. Likewise, an oval or ellipse shape 40 is possible, the longer axis extending in the longitudinal direction of the plate. Furthermore, rectangular or square 8700789 -5- shapes are also possible as simple spacers, whereby one would have to increase clear flow losses.

If, on the other hand, a streamlined shape of flow bodies is advantageously chosen, an optimum air flow is achieved, whereby blockages are prevented by the aerodynamic shapes thereof. Namely, with aerodynamic flow bodies no or only very minimal eddies occur, which adversely affect the flow. For example, the flow bodies can have support wing profiles.

In general, the flow bodies will be integrally formed with the plate, but they can of course also be manufactured separately and subsequently be connected in any desired manner, for example by sticking to a base plate. In the latter case, special flow ratios can still be achieved by arbitrary tilting positions of the flow bodies, or the heat-insulating plate can then be adjusted to special place conditions.

The invention will be explained below with reference to the drawing, which schematically represents an exemplary embodiment of the roof insulation panel according to the invention.

FIG. 1 is a section on line I-I in FIG.

2 through a roof insulation board built into a tile roof perpendicular to the surface of the roof covering.

Fig. 2 is a top view of the roof insulation board according to the invention.

Fig. 1 shows an overview image of a roof insulation plate 1, which is arranged between two rafters 2. The roof insulation plate 1 rests on battens 3 nailed to the rafters 2. A foil 4 is placed on the rafters 2 and over the heat-insulating plate. Instead of a foil 4, a wooden partition can also be provided in this place. Roof battens 5 are nailed to the rafters 2 via a counter-trellis 8 in the usual manner. Roof tiles 6 are hung in the roof battens 5. If ventilation tiles (not shown) are used, then the wooden boarding or film 4 is of course cut out in the area below the ventilation tiles, so that air can enter.

8700789 S "* -6-

The surface 7 of the insulating plate 1 facing the roof covering is formed with elevations in the form of flow bodies 9, between which recesses 10 lie.

Fig. 2 shows the construction of the roof insulation board 1 and the surface 7 thereof more clearly. As shown, flow bodies 9 each have a hydrofoil profile. The flow bodies are arranged in a number of rows one behind the other, each of which 10 flow bodies of successive rows are arranged offset from one another. As can be seen, for example, in Fig. 2, four or three flow bodies are alternately arranged over the width of the roof insulation board. In general, at the usual spacing of the spruces, this number will be sufficient, although other numbers are of course also possible if desired.

As can further be seen in Fig. 2, a flow body of a subsequent row is in each case in the middle between two previous flow bodies. This means that the air entering in the direction of the arrow always hits the subsequent flow bodies and is thereby deflected laterally in the direction of the longitudinal sides 11A and 11B and thus also in the direction of the spar 2.

In this way, numerous air guiding paths and optimum air distribution are achieved.

In addition, it can also be ensured that in the inlet region the flow bodies of the first and second rows are arranged slightly obliquely, the inclined position 30 being chosen such that a deflection in the direction of the longitudinal sides 11A and 11B of the plate 1 is reached. In the form shown, however, the flow body arranged centrally in the second row remains parallel to the longitudinal direction of the insulating plate 1 and thus also to the spruces 2. The same applies to the flow bodies of the other rows.

In order to avoid thermal bridges, the insulating plates 1 can be alternately formed on their upper and lower sides with a tongue 12 and a groove 13, respectively, in a known manner. In this way, the insulating plates 1 arranged one behind the other between two rafters can be connected in a simple manner and tightly sealing by means of the tongue and groove connection.

The invention is not limited to the exemplary embodiment shown in the drawing, which can be varied in a number of ways within the scope of the invention.

8700789

Claims (12)

Roof insulation board of heat-insulating material for installation between the rafters, in which recesses and elevations are formed in its surface facing the roof covering, which form air conduction paths extending from the base of the roof to the ridge, characterized in that the elevations are designed as flow bodies (9) or spacers, which are arranged on the surface (7) of the plate with such a distribution that the air flowing to the ridge is also distributed over the width of the plate. Roof insulation panel according to claim 1, characterized in that a number of flow bodies (9) are arranged spaced apart next to each other over the width of the plate, while a number of rows of flow bodies (9) in the longitudinal direction of the plate. is arranged one after the other. Roof insulation panel according to claim 2, characterized in that the longitudinal rows of the flow bodies (9) are arranged at a distance from each other. Roof insulation board according to claim 2 or 3, characterized in that the flow bodies (9) are arranged in rows arranged one behind the other, offset from one another. Roof insulation panel according to claim 4, characterized in that the flow bodies are arranged so that they are staggered relative to each other, in each case that a subsequent flow body (9) is located at least approximately in the middle between two previously flow-through flow bodies (9). Roof insulation panel according to any one of claims 1 to 5, characterized in that flow bodies (9) of the first row are arranged obliquely in the inlet region with respect to the longitudinal direction of the panel such that air guiding paths (11A, 11B) are inclined to the longitudinal sides of the plate (1) are oriented. Roof insulation panel according to claim 6, characterized in that in the inlet area additional flow bodies (9) of the second row are arranged obliquely to the longitudinal direction of the panel in such a way that air conduits are inclined relative to the longitudinal side (11A, 11B) of the plate (1) are oriented. Roof insulation board according to any one of claims 1 to 7, characterized in that the flow bodies 5 (9) have at least approximately a circular cross-section in plan view on the board (1). Roof insulation board according to any one of claims t-7, characterized in that the flow bodies (9) have at least approximately an oval or elliptical shape in plan view on the board (1), the long axis extending in the longitudinal direction of the board . Roof insulation board according to any one of claims 1-7, characterized in that the flow bodies (9) have a streamlined shape. Roof insulation panel according to claim 10, characterized in that the flow bodies (9) have at least about a hydrofoil profile. Roof insulation board according to any one of claims 1-11, characterized in that the flow bodies 20 (9) are integrally formed with the board (1). 8700789