DE2903769C2 - Hot melt adhesive for sealing membranes - Google Patents

Description

Sealing membranes in the form of vulcanized polychloroprene, EPDM, polyisobutylene, chlorosulfonated polyethylene or butyl rubber mixtures are characterized by high durability. They are therefore preferred as sealing membranes for roof coverings and civil engineering. Membranes based on the synthetic rubbers mentioned are also suitable for outdoor and indoor sports field surfaces. The sealing membranes can also be bonded to a carrier material made of fiber membranes or fabrics on an inorganic or organic basis. The membranes are characterized by low deformation when exposed to heat or cold. The hot melt adhesives known to date for such membranes have disadvantages in various respects, which appear in different ways from case to case. Some hot melt adhesives lose sufficient cohesive bond strength when used outdoors or on the roof at higher temperatures. In some cases, the hot melt adhesives do not allow the seams to be bonded with sufficient reliability. It is therefore necessary to use additional adhesives and seam tape.

Other hot melt adhesives contain solvents, which can lead to the formation of bubbles when applied and when exposed to heat. In addition, a waiting period is always required for the solvents to evaporate sufficiently. Laying in bitumen or asphalt or on bitumen paper is advantageous if this can be done with the hot melt adhesive temporarily melting, because in this way there is little risk of problems caused by improper laying.

There is no need to worry about residual moisture under the sealing membrane. Furthermore, an installation option that is largely independent of the weather is desirable.

A hot melt adhesive is known from DD-PS 83 801 which consists of 40 to 70 parts by weight of bitumen or tar and 30 to 60 parts by weight of ethylene-vinyl acetate copolymer, the vinyl acetate content of which is 30 to 45% by weight. This hot melt adhesive is a thin, slow-setting mass with good ageing resistance at a processing temperature of around 160°C. However, the adhesive strength of this hot melt adhesive is not particularly good above 60°C. Since temperatures of 90°C are reached on the roof, the hot melt adhesive described in this publication can only be used to a limited extent. In addition, no interfacial cross-linking between the top layer (AP copolymer films according to DE-PS 83 801) and the hot melt adhesive is possible with this hot melt adhesive. However, an improvement in the adhesion between the top layer and the adhesive could be achieved through interfacial cross-linking.

The object of the present invention is to provide a method for bonding sealing sheets using a hot melt adhesive composition. The object is achieved according to patent claim 1.

The main components are ethylene vinyl acetate copolymer, polychloroprene or polyisobutylene, bitumen, butylphenol resin and metal oxides. In the case of the ethylene vinyl acetate copolymer, which is the main ingredient, the vinyl acetate content of 10-50 mol% is essential.

If the ethylene content increases more, this leads to an undesirable drop in the seam strength due to the drop in adhesion in the seam area. If the ethylene content is too small, this leads to relatively poor adhesion due to the drop in cohesion at a higher temperature. With polychloroprene, the ability to crystallize strongly is essential. Strong crystallization is a key distinguishing feature. With polyisobutylene, the limit range of the molar weight is important. Polychloroprenes that already have elasticity and strength when unvulcanized are highly crystallizing.

A hot melt adhesive constructed in this way can also be produced in a simpler way by calendering it onto the sealing sheet as a separate material sheet at a low temperature. The temperature of around 50°C that occurs here already leads to good adhesion between the covering and the hot melt adhesive. Since the sealing sheet is not vulcanized when it is brought together with the hot melt adhesive layer, the subsequent vulcanization at around 165°C leads to an interfacial cross-linking between the covering and the hot melt adhesive. In addition, the presence of metal oxides and the butylene phenol resin causes a slight cross-linking of the polychloroprene during vulcanization, so that the cohesion of the hot melt adhesive is improved at higher temperatures. Completing the sheet with hot melt adhesive thus results in a layered material that can be stored. The final hardening of the hot melt adhesive then takes place later during installation. The hot melt adhesive layer is treated with a gas flame for a few seconds and then pressed onto the substrate. The temporary melting leads to such an effective bond that the web seams also experience a secure and permanent bond.

The production of butt and overlap joints is therefore problem-free and can be carried out in a simple manner. Since the hot melt adhesive layer is bonded across the entire width of the sheet, no reworking is required. In particular, additional adhesives for the seam edges are avoided. The physical properties of this hot melt adhesive and the bond created by vulcanization also mean that they can be advantageously bonded to a thinner sealing sheet than was previously usual. After curing, the hot melt adhesive has properties similar to sealing sheeting. with a thermoplastic character, which easily bridge a property jump between asphalt on the one hand and sealing membrane on the other. The invention is described in connection with an example. The designations AQ mean the following:
A = Ethylene vinyl acetate copolymer with a Mooney viscosity of 12±4
B = polyisobutylene, molecular weight 5,000,000
C = Polychloroprene, strongly crystallizing
D = Stearin wax-like processing aid
E = filler, active or inactive, such as carbon black or chalk
F = Anti-aging agent of type p-phenylenediamine
G = zinc oxide
H = magnesium oxide
I = Heat-active butylene phenol resin
K = Bitumen, ball pressure point 120/130
L = peel strength in daN/2.5 em at RT (e.g. 23°C)
M = peel strength in daN/2.5 cm at +60°C
N = peel strength in daN/2.5 cm at +80°C
O = Adhesive failure (separation between top layer and hot melt adhesive)
P = cohesive failure (separation in the hot melt adhesive)
Q = Assessment of calenderability; where OK means (OK) and shrinkage (the hot melt adhesive shrinks)

The small letters a-i represent the different mixtures. The peel strengths of two sealing sheets with the hot melt adhesive between them are assigned to the mixture structure. The peel angle is 180°. The peel speed is 100 mm/min. The separation images indicate whether the separation occurred between the hot melt adhesive and the sheet or in the hot melt adhesive itself. Finally, the table contains information about the calenderability. The drawing attached in the appendix shows a cross-section through a sheet according to c). This sheet shows an optimum in the tests carried out.

Examples a, e and h in the table, which show significant differences with regard to the characteristics O, P and Q, are for comparative purposes.

The web consists of the cover layer 1 , the fabric insert 2 and the hot melt adhesive layer 3 . &udf53;vu10&udf54;&udf53;vz29&udf54;&udf53;vu10&udf54;

Claims (1)

Hot melt adhesive for sealing membranes, containing 60 to 90 parts by weight of an ethylene-vinyl acetate copolymer with a vinyl acetate content of 10 to 50 mol%, 10 to 40 parts by weight of a highly crystallizable polychloroprene or a polyisobutylene with a molecular weight of 500,000 to 6,000,000, 0.5 to 20 parts by weight of heat-reactive butylphenol resin, 15 to 50 parts by weight of bitumen 120/130 and approximately 1.0 to 2.0 parts by weight of zinc oxide and magnesium oxide.