BE1000052A7 - Plate roof insulation. - Google Patents

Abstract

An insulating roofing plate (1) made of thermal insulating material to be placed between the rafters has, on its face (7) turned towards the envelope of the roof of the cavities and projections which constitute passages for the air going from the gutter to the done. The projections have the form of flow guide bodies (9) or spacers which are arranged with distribution on the face (7) of the plate such that the air flowing towards the fact is distributed on the width of the plate.

Description

       

   <Desc / Clms Page number 1>
 



   INSULATION PLATE FOR ROOF
The present invention relates to an insulation plate for a roof made of thermal insulating material, to be placed between the rafters, their surface facing outwards having cavities and projections which
 EMI1.1
 are air passages. from the gutter to An insulating plate for roofing of this kind has already been described, for example, in patent DE-GM 7907167.



  In this case, the upper face of the plate has several cavities arranged parallel to each other and parallel to the rafters of the roof which constitute numerous channels oriented in the direction of the made. The protrusions also simultaneously constitute a support surface for a thin sheet, in order to ensure a sufficient passage section. Otherwise, the thin sheet may collapse, so that proper exhaust of air and water vapor can no longer be ensured.



   The concentration of water vapor in the ventilation space is, however, different. This is the case that occurs both with the channels described above and with a freely ventilated space, as can be the case if using a roofing board. This concentration is, for example, greater near the rafters, since a greater quantity of water vapor can penetrate

 <Desc / Clms Page number 2>

 here because of the inevitable joint between the insulation and the wood of the rafters that is not the case in the other parts of the insulation. On the other hand, the air current sweeping the wood of the rafters is slowed down by the friction of the boundary layer. This implies a greater increase in the water vapor content.

   Air with a higher water vapor concentration is heavier than air with a low water vapor concentration. This means that the heavier air does not have sufficient draft if the air flow is not large enough and if mixing with dry air does not occur. It is, in particular, in the area of the rafters that an accumulation of water vapor can therefore occur. This gives rise to humid and stagnant air which constitutes an ideal medium for pitting of humidity, attacks by fungi, decay and decomposition.



   The air in the channels is supplied from the bottom of the roof through appropriate slots or passages between the roof envelope and the masonry. The evacuation of the air in the area can be done either by ventilation tiles, or by a so-called "ventilation" ridge. In the case of new constructions, this continuous ventilation slot can still be carried out quite easily, albeit with notable costs due; for example, protective mesh against birds and the like. In old buildings, the creation of the ventilation slot in the gutter area, however, requires significant scaffolding and drilling, which causes significant costs.



   However, there is also the disadvantage that there is generally, below the eaves, an angle sheltered from the wind, so that a thermal draft can act there only in a limited way. If no eaves are planned, ventilation takes place behind the gutter, which also constitutes a zone sheltered from the wind.

 <Desc / Clms Page number 3>

 



   Aeration by ventilation tiles arranged in the lower area of the roof is impractical. It is however possible to create a junction by channels in the insulation plate for roofing by suitable cavities, in a planking of wooden roof space, or else to produce a thin sheet but, owing to the shape of the cavity, a ventilation of this kind would be insufficient, since it would only act on the channels located directly below the ventilation tiles. The roof planking or the thin sheet resting on the projecting ribs, in fact, close the channels upwards, so that the lateral exhaust of the air current has been hampered.

   Even with roofs without thin sheets and without planking, as is often the case in old constructions, the air current generated by the ventilation tiles would be brought directly into the channels towards the ridge, as in the guide vanes of 'a turbine.



   The present invention therefore aims to provide a plate. insulation for roofing of the aforementioned type, which allows for simple ventilation over the entire surface of the herringbone structure.



   This object is achieved, in accordance with the invention, by the fact that projections are arranged to serve as flow guide bodies or spacers and are distributed over the surface of the plate, so that the air is pointing towards the ridge is evenly distributed over the width of the plate.



   Thanks to the flow guide body specific to the invention or to the spacers, there is then obtained aeration over the entire surface of the herringbone structure, instead of a ventilation limited to the separate channels. This means that it has no more difficulties in relation to the concentration of water vapor. One of the main advantages of the flow guide bodies specific to the present invention consists in that it is no longer necessary to provide

 <Desc / Clms Page number 4>

 ventilation slots or ventilation holes in the masonry, in the gutter area. We thus obtain, thanks to the flow guide body, a sweep over the entire surface of the plate, which allows ventilation to be carried out in the lower area of the roof by simply placing ventilation tiles.

   In this case, a single ventilation tile may suffice for an interval between rafters, since the air flow thus created widens laterally and arrives, in this way, in direct contact with the rafters.



   The flow guide bodies also allow the cardboard or the thin sheet deposited on the rafters not to collapse and thus not to obstruct the air flow.



   In an advantageous embodiment of the invention, provision may be made for several flow guide bodies to be arranged, distributed one next to the other, over the width of the plate and for several rows of flow bodies to be arranged one behind the other in the longitudinal direction of the plate.



   In this way, a large number of flow guide bodies make it possible to obtain a plate surface. near. entering bosses or projections which ensure a good distribution of air, while simultaneously avoiding a sagging of the thin sheet which is possibly app1ieciée.



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



     It is advantageous for the flow guide bodies of the rows located one behind the other to be offset with respect to each other, the offset being chosen so that each flow guide body is situated approximately in the middle, between two of the flow guide bodies located upstream of

 <Desc / Clms Page number 5>

 The flow.



   Thanks to this arrangement, an excellent distribution of the incoming air is obtained, since this, after having passed between two flow channels, then meets another flow guide body which further divides the air.



   It goes without saying that the collapse guide bodies can also be distributed in an irregular manner, or according to another arrangement on the surface of the plate.



   In another particularly advantageous embodiment of the invention, it can be provided that, in the upstream zone, flow guide bodies of the first row are arranged obliquely to the longitudinal direction of the plate, if although the paths of the current of air flow are oriented obliquely to the longitudinal ribs of the plate.



   Thanks to the oblique arrangement of the flow guide bodies in the upstream area, that is to say, for example, in the area below an aeration tile or, if it already exists a slit in the masonry in the gutter area, there is an oblique flow of the incoming air towards the roof rafters, so that a good mixture of the existing humid air with the incoming dry air is found precisely performed in this dangerous area ...



  Thanks to the inevitable mixing of light air with heavy air, the specific weight of the latter is reduced. In all the section of the intervals between rafters, there is therefore an average weight of air which creates, in all the area of the rafters, a draft of corresponding importance. This avoids areas with stagnant air and high concentrations of water vapor.



  On the other hand, the flow guide bodies arranged with offset ensure scanning of the entire ventilated enclosure for a corresponding wind direction.



   The flow guide bodies themselves can

 <Desc / Clms Page number 6>

 
 EMI6.1
 In general, however, they are given a shape which ensures the lowest possible resistance to collapse, or which avoids significant turbulence.



   The flow guide bodies can have a cross section, seen from above.



   A shape. oval or elliptical is also possible, the major axis being directed in the longitudinal direction of the plate. One can also provide square or rectangular shapes, constituting simple spacers, this however causing significant flow losses.



   If, on the contrary, aerodynamically shaped flow guiding bodies are chosen, optimal air flow is obtained. this aerodynamic shape preventing the creation of an obstacle 5 the air. With aerodynamic flow guiding bodies, there is, in fact, little or no turbulence which can impede the flow.



  The flow guide bodies can therefore weigh, for example, a bearing wing profile.



   In general, the flow guide bodies are made in one piece with the plate, but can obviously also be manufactured independently of the latter and then be fixed thereto in any way, for example, by gluing with a plate. basic. In the latter case, any oblique arrangement of the flow guide bodies may make it possible to obtain even better flow conditions or may make it possible to adapt the insulating plate to the particular local conditions.



   An embodiment of the invention will be described below using the figures, which respectively represent:
Figure 1, a section along the line I-! of Figure 2 through an insulating roofing plate incorporated in a tiled roof, this section being

 <Desc / Clms Page number 7>

 perpendicular to the surface of the roof envelope.



   Figure 2, a top view of the insulating roofing plate according to the present invention.



   Figure 1 shows, in general, an insulating roofing plate 1'qui is arranged between two rafters 2.The insulating roofing plate 1 rests on the slats 3 nailed to the rafters 2. On the rafters 2 and over the insulating plate is deposited a thin sheet 4.



  This thin sheet 4 can also be replaced by a wooden planking. On the rafters 2 are nailed, in a usual manner, roof slats 5, over against battens 8. In the battens. roof tiles 5 are hung roof tiles 6. If aeration tiles are used (not shown), the wooden planking or the thin sheet 4 obviously have cuts in the area below the aeration tiles, in order to allow air penetration.



  The surface 7 of the insulating plate 1 turned towards the roof envelope is provided with projections in the form of flow guide bodies 9, situated between the cavities 10.



   Figure 2 shows the arrangement of the insulating roofing plate 1 and its surface 7 with a more explicit hinge. As can be seen, the flow guide bodies 9 have a bearing wing profile.



  The flow guide bodies are then arranged in several rows one behind the other, while each flow guide body of the successive rows is offset with respect to those of the other rows. As indicated, by way of example, in FIG. 2, four or three flow guide bodies are arranged alternately and distributed over the width of the insulating roofing plate.



  In general, and for the usual distance between the rafters, this number will be sufficient, although other numbers can also obviously be chosen if necessary.

 <Desc / Clms Page number 8>

 
 EMI8.1
 As also seen in Figure 2, a flow guide body is located each time in the middle with respect to two flow guide bodies of the previous row. This means that the air penetrating in the direction of the arrow meets, each time, the following flow guide bodies and is deviated laterally in the direction of the longitudinal dimensions 11A and 11b and of which also on the rafters 2.

   In this way, numerous air flow paths and optimum air distribution are obtained.



   It can also be provided, moreover, that in the upstream zone, the flow guide bodies of the first and of the second row are arranged so
 EMI8.2
 lightly so as to 11A and second body in the longitudinal direction relative to those of To insulate the insulators f themselves, their upper face and on their lower face alternately, with a tongue 12 or a groove 13.



  In this way, the insulating plates 1 arranged one behind the other between two rafters can be assembled simply by a groove and tongue joint, so as to obtain a good seal.


    

Claims (12)

 CLAIMS 1. Insulating plate for roofing made of thermal insulating material to be placed between the rafters, their surface facing the envelope of the roof having cavities and projections which constitute flow paths for the air, arranged from the gutter to the ridge , characterized in that the projections are in the form of flow guide bodies (9) or spacers which are arranged with a distribution on the surface (7) of the plate such that the air flowing towards the made is distributed over the width of the plate.  2. Insulating roofing plate according to claim 1, characterized in that several flow guide bodies (9) are arranged next to each other and at intervals, being distributed over the width of the plate, and in that that several rows of flow guide bodies (9) are arranged one behind the other in the longitudinal direction of the plate.  3. Insulating plate for roofing according to claim 2, characterized in that the longitudinal rows of the flow guide bodies (9) are arranged at a certain distance from each other.  4. Insulating plate for roofing according to claims 2 or 3, characterized in that the flow guide bodies (9) are arranged with offset relative to each other in the rows arranged one behind the other.  5. Insulating plate for roofing according to claim 4, characterized in that the flow guide bodies are offset from each other so that a flow guide body (9) is located at least roughly in the middle between two flow guide bodies (9) located upstream.  6. Insulating plate for roofing according to one of  <Desc / Clms Page number 10>  Claims 1 to 5, characterized in that, in the upstream region, the flow guide bodies (9) of the first row are arranged obliquely to the longitudinal direction of the plate, so that the paths of the air are directed obliquely to the longitudinal ribs (11A, 11B) of the plate (l).  7. Insulating roofing plate according to claim 6, characterized in that in the area. upstream, other flow guide bodies (9) of the second row are arranged obliquely to the longitudinal direction of the plate, so that the air path is oriented obliquely to the longitudinal dimensions (11A, 11B) of the plate (1).  8. Insulating roofing plate according to one of claims 1 to 7, characterized in that the flow guide bodies (9) have, in top view on the plate (1) at least one section approximately circular in shape.  9. Insulating roofing plate according to one of claims 1 to 7, characterized in that the flow guide bodies (9) have, in top view on the plate, an at least approximately oval or elliptical shape, the major axis being oriented in the longitudinal direction of the plate.  10. Insulating roofing plate according to one of claims 1 to 7, characterized in that the flow guide bodies (9) have an aerodynamic shape.  11. Insulating roofing plate according to claim 10, characterized in that the flow guide bodies (9) have a shape at least approximately similar to a profile of a bearing wing.  12. Insulating roofing plate according to one of claims 1 to 11, characterized in that the flow guide bodies (9) are made in one piece with the plate (1).