NO136654B - - Google Patents

Description

The invention relates to an extensive roof structure

a supporting structure for the roof, a metallic roof covering, a water-resistant layer arranged near the roof covering on its upper side, which water-resistant layer contains combustible organic material that softens when heated, and a layer of thermal insulation material comprising water-impermeable insulation material with a cellular structure attached to the water-resistant layer.

Composite roof constructions have been used for many years, where a roof covering supports a weather-resistant membrane which often includes several layers of cardboard and bitumen which prevents the penetration of moisture. It is often desirable for such a roof to be insulated, and different insulation materials and methods have been used to achieve this. Often, e.g. the insulation material placed under the roof covering on the inside of the building between rafters or similar support means for the roof covering. The insulation material often consists of cellular glass, fibreboard, foam plastic or the like which can be placed on the upper side of the roof covering and then covered with several layers of alternately arranged cardboard and bitumen which form a waterproof membrane. Gravel or similar material is then applied to the top of the roof to protect it from solar radiation. Such roofs have for many years been the cause of many different difficulties. Cracks often occur in the water-resistant membrane, which is presumably due to loss of the volatile components in the bituminous material. Direct damage as a result of people walking on the roof, condensation at low temperatures on or around the roof on the underside facing the building are some of the many reasons why this type of roof construction is not satisfactory. Many of these problems have been solved by using roof constructions where a barrier is placed on the roof deck and an insulation layer over the barrier. When thermoplastic organic material such as e.g. asphalt or foam plastic for such a construction on a metallic roof covering, e.g. a roof covering consisting of steel sheets, considerable difficulties arise in the event of a fire. Within a few minutes, the moisture barrier, such as a membrane composed of asphalt cardboard and a foam plastic insulation layer melts as a result of heating and can result in burning drops falling from the edge of the roof, while cracks form between the elements of which the roof is assembled.

It is an object of the invention to provide an improved and simplified roof construction where the water-resistant barrier or membrane is unbroken, and where the construction simultaneously offers significant resistance to fire.

These purposes are achieved by a plasterboard being arranged between the roof covering and the water-resistant layer.

The invention further includes a method for producing such a roof structure, and the method is characterized by the fact that a non-combustible heat-insulating plasterboard layer is placed on the upper side of a metal roof covering and above this layer a water-impermeable membrane on which a water-impermeable heat-insulating foam with closed cells is placed .

Further features and advantages of the present invention will be apparent from the following description in connection with the drawing, which schematically shows an interrupted isometric view of part of the roof structure, partially in section.

In the drawing, 10 generally denotes the roof structure. The roof construction 10 comprises a metallic roof covering 11. The roof covering 11 has an upward-facing surface 12 and a downward-facing surface 13. The roof covering 11 rests on supports

creep. A non-combustible heat-insulating layer 14 is attached directly to the upward-facing surface 12 of the tire 11. Attached to the insulating layer 14 is a layer 15 which forms a barrier against through-

in

need for water and/or humidity. Appropriately, the water impermeable membrane 15 comprises several alternating layers of cardboard and a bituminous material or asphalt. A thermal insulation layer 16 has a downward-facing surface 11 and an upward-facing surface 12 and is attached to the surface of the layer 15 facing away from the roofing surface 12. The thermal insulation layer 16 has closed cells and is waterproof and impermeable to water. A protective layer 19 is arranged on the surface 12 of the thermal insulation layer 16. In the layer 16, several spaces or cracks 20 are arranged.

A wide variety of materials can be used for the production of the roof structure according to the invention. The roof covering itself, which forms the bottom layer of the composite roof, can be made of sheet material or metal fabric of steel or aluminium. It is appropriate to use a steel plate which is designed with ribs, which give the plates a large degree of stiffness without an inappropriately large weight.

The roof covering can be supported in any suitable way, preferably by being fixed rigidly to the support devices such as e.g. beams using nails, screws, bolts and the like. The roof covering can be produced in the form of plates which can easily be inserted into suitable slots in a framework and produced using methods that are well known.

The non-combustible first or lower thermal insulation layer may comprise or consist of any of a wide variety of materials, such as e.g. cement/asbestos boards, gypsum boards, foam plastic, ceramic foam, heat-setting plastic foam, such as phenolic resin foam, epoxy resin foam or the like.

A particularly suitable non-flammable heat insulation layer is boards made from a mixture of gypsum, inorganic fibers such as glass fibers and expanded mica such as e.g. vermiculite.

Such a composite plasterboard gives the roof structure according to the invention an excellent resistance to fire.

The water-impermeable membrane can comprise or consist of materials within a wide variety of water-impermeable substances including conventional masses of asphalt and bitumen used in roofing as well as laminates of bituminous materials with fiber reinforcements, such as e.g. roofing felt that is produced using organic or inorganic fibres. Appropriately, such cardboard and bituminous material can be applied in alternating layers to provide a water-impermeable membrane of the desired thickness and mechanical strength, so that it can withstand movements of the roof covering and associated supporting structure. In certain cases, a water impermeable membrane can be made from a synthetic thermoplastic film or foil, j e.g. consisting of polyethylene, polyvinyl chloride, chlorinated polyethylene or the like which is attached to the roof covering using a suitable adhesive.

One or more layers of such a material can be used depending on the desired properties of the finished construction.

The upper or other thermal insulation layer used in carrying out the present invention suitably consists of a material with closed cells which is virtually impermeable to water. Particularly suitable and advantageous in the application of the present invention are cellular foam plastics with a closed cell structure comprising styrene polymer foam, styrene/acrylonitrile copolymer foam, styrene/methyl methacrylate copolymer foam, polyvinyl chloride foam, polyethylene foam and other water-impermeable materials which are available in cellular foam form, and which are well known to a person skilled in the art. Sl^jgiass is particularly advantageous if it is desired to avoid a protective layer over the heat-insulating material. On the other hand, a protective layer can be suitably used if a synthetic organic cell-shaped material is used as the heat-insulating layer. Such organic materials are generally subject to decomposition if they are exposed to the effects of the weather or, more particularly, to the effects of sunlight. It is therefore appropriate to place a protective layer on the outward-facing surface of the heat-insulating layer.

Appropriately, such a protective layer can include or consist of a particulate inorganic material such as e.g. gravel spread over the foam layer, or if desired, a relatively thin protective coating resistant to the effects of weather and sunlight, can be easily obtained by using an inorganic mortar, e.g. consisting of a mixture of portland cement and sand that is spread thinly over the surface of the thermal insulation layer in such a way as to form a protection against sunlight and the effects of the weather. In certain cases, depending on the weather conditions and the pitch of the roof, it may be desirable to provide an intermediate or bonding layer to attach the protective layer to the thermal insulation layer.

In the production of roof structures in accordance with the present invention, the metallic roof covering is generally attached to a suitable support structure, after which the non-combustible layer is attached to the upward-facing surface of the metallic roof covering, while the water-resistant membrane is placed on the non-combustible heat insulation layer; e.g. by placing a layer of a bituminous material on the thermal insulation layer and a suitable roofing felt on the bituminous material and repeated application of roofing felt and bituminous material until a suitable membrane is formed. It is advantageous to attach the upper thermal insulation layer with closed cells to the water-impermeable membrane using the same or a different bituminous mass used for the production of the water-resistant membrane, while the bituminous material is in a state softened by heating, the longitudinal strips or sheets of thermal insulation material are pressed into the bituminous layer to ensure a good connection. When a thermal insulation layer of synthetic thermoplastic is used, it is necessary that the bituminous material does not have such a high temperature that any significant destruction of the cellular insulation material occurs. If it e.g. sheets of polystyrene foam are used as a thermal insulation layer, it is generally desirable that the bituminous material has a temperature that is not significantly higher than 100°C, in order to avoid melting or deformation of the polystyrene foam sheets. It is important and of significant importance for the practical execution of the present invention that the thermal insulation layer has a closed cell structure. The particular density or physical strength of such an insulating material need not be sufficient to withstand

the mechanical stresses for the special roof construction. In general, sheets of polystyrene foam with a specific weight of 24 g per dm 3 be suitable for roof installations that are not exposed to any significant stress from people walking on the roof.

If closed-cell foam materials with lower specific weight and/or lower physical strength are used in the thermal insulation layer, it is often desirable to arrange a protective layer of sufficient strength to resist mechanical destruction. in an area of the roof that is not exposed to foot traffic, a loose gravel coating can be applied directly over the closed-cell thermal insulation layer and form sufficient protection; on the other hand, in areas where a heavy load of pedestrian traffic must be taken into account, it will often be desirable to use a layer of cement-containing material such as e.g. can be made from a mixture of portland cement, sand and water or magnesium oxychloride cement and the like.

It is not of essential importance that the protective layer is resistant to the passage of moisture, nor is it important that the thermal insulation layer has a surface that prevents moisture from coming into contact with the water-resistant membrane.

In the production of a roof construction according to the invention, thermal insulation elements of a form such as planks or plates and consisting of cellular polystyrene or other cellular material can be placed next to each other edge to edge without it being necessary to make any attempt to seal the joints or cracks between the individual elements . In some constructions where incompletely cured or unstabilized synthetic foam plastic has been used, cracks have occurred in the foam plastic, with the foam cracking in an irregular pattern in a similar way to clay, and mortar on the surface cracking in a similar way. Such cracking does not appear to have any significant detrimental effect on the roof construction.

Roof constructions according to the invention are not exposed

for damage caused by water freezing in smaller spaces between adjacent foam insulation elements. The foam insulation elements appear to have sufficient compliance to resist breakage due to expansion of freezing water in cracks. On the other hand, the temperature in a roof structure for a heated building will generally not reach freezing temperature in the vicinity of the waterproof membrane. In buildings provided with a roof structure according to the invention, little or no tendency for moisture to condense on the inner surface of the roof covering can be observed. For most applications, the thermal conductivity of the lower or non-combustible thermal insulation layer will be from about 100% to about 1000% of the upper closed cell thermal insulation layer and should suitably have a thermal conductivity of from 100% to 500%. The normal temperature variations in the membrane layer will be relatively small compared to the variations in the surrounding atmosphere, while at the same time a reasonable protection against internal fire is achieved; a time delay of many minutes can be observed between the ignition of a fire and the melting of the layer which forms a moisture barrier and/or the thermal insulation layer with a closed cell structure.

For further illustration of the invention, the results of an experiment will be explained below. A number of roof tiles were examined for their fire resistance ability by placing the tiles in a test oven. The oven consisted of a hollow, square construction of refractory stone with an upper opening of 30 cm 2. In all the samples, a square steel plate with a side edge of 35 cm and a thickness of about 0.64 mm was used with a depth of 3.8 cm and 2.5 cm wide rectangular ribs spaced 15 cm apart. The ribs were removed near their end edges so that the ribs fit into the upper opening in the oven. A number of such roof plates were produced, each of which had the general construction as shown in the drawing. In each sample, the moisture barrier layer consisted of three layers of roofing cardboard, each layer of cardboard being connected to the adjacent layer or layers (including both thermal insulation layers) by means of asphalt. The heat insulation layer with closed cells had a thickness of 2.5 cm and consisted of polystyrene foam with a specific weight of about 0.032 g per cm 31'. The upturned surface of the polystyrene foam was covered with fine shingle in an amount of 45.4 g. A propane gas burner was placed in the furnace; the burner was directed upwards and was located 10 cm below the ribs in the steel plate which was located at the bottom of the test plate. A thermocouple was placed immediately under the steel plate,

and the temperatures read during the execution of the experiments are shown in the following table:

Five test plates were produced using the materials indicated in the following table for layer 14 in the drawing. The table shows the time it took until the roof plate failed. Failure of the sample was considered to have taken place when the combustible asphalt or polystyrene foam ignited, or that the polystyrene foam collapsed.

Claims (9)

1. Roof structure comprising a support structure (lia) for the roof, a metallic roof covering (11), a water-resistant layer (15) arranged near the roof covering (11) on its upper side, which water-resistant layer contains combustible organic material that becomes soft when heated, and a layer of thermal insulation material comprising water-impermeable insulation material with cellular structure attached to the water-resistant layer (15), characterized in that a plasterboard (14) is arranged between the roof covering (LI) and the water-resistant layer (15). 2. Roof construction as specified in claim 1, characterized in that the water-resistant layer comprises a plurality of layers of bituminous material and roofing felt. 3. Roof construction as stated in claim 1, characterized in that the cellular thermal insulation layer consists of —__ of synthetic foam plastic. 4. Roof construction as specified in claim 1, characterized in that the plasterboard contains inorganic fibers and expanded mica. 5. Roof construction as stated in claim 1, characterized by a protective layer arranged on the upward facing surface of the thermal insulation material with closed cells. 6. Method for the production of a roof structure as stated in claim 1, characterized by placing and fixing a non-combustible heat-insulating plasterboard layer on the upward-facing surface of a metallic roof covering and placing on the heat-insulating layer a water-impermeable membrane over which a water-impermeable heat-insulating foam with closed cells. 7. Method as stated in claim 6, characterized in that the water-impermeable membrane is made of several layers of roofing felt and a bituminous adhesive. 8. Method as stated in claim 6, characterized in that the cell-shaped thermal insulation layer is attached to the water-impermeable membrane. 9. Method as stated in claim 6, characterized in that an inorganic protective layer is placed over the cellular heat insulation layer.