DE3439312C2 - Double-layer flexible plastic hose, especially as a line for fluorinated hydrocarbons - Google Patents

Abstract

A plastic hose with a double-layer structure is described which has, as the inner layer, a mixed polyamide-rubber compound with a phase structure in which the polyamide is present as a matrix phase and the rubber is present as a disperse phase and which is achieved by mixing the polyamide with the rubber in the presence of a vulcanizing agent has been obtained, and comprises as the outer layer a resinous material of the polyolefin series, which is firmly bonded to the polyamide rubber composition via functional groups contained therein. The hose of the present invention is easy to manufacture by mixing the polyamide with the rubber in the presence of the vulcanizing agent for 3 to 30 minutes at a temperature above the melting point of the polyamide and coextruding it with the resinous polyolefin series material containing functional groups in a molten state . The hose according to the invention is particularly suitable as a line for cooling media such as fluorinated hydrocarbons (Freon) for use in motor vehicle radiators and air conditioning systems.

Description

The invention relates to a flexible plastic hose, which is particularly useful as a line for fluorinated Hydrocarbons (Freon) are suitable. The plastic hose according to the invention comprises a polyamide-rubber mixture as the inner layer over which a polyolefin material with functional groups as the outer layer is laid

In general, two types of hoses are known as lines for fluid materials. One type of hose, which has been known for a long time, consists of a plastic-coated, hose-shaped textile jacket. This type of hose, e.g. B. in the form of fire hoses, is widely used as a conduit for water, gas and aqueous slurries. Hoses of this type are tough and are suitable for numerous outdoor applications where they are exposed to severe environmental stress. However, these hoses also have some serious disadvantages. One of these disadvantages is that they are not fully flexible, especially if they are only about 2.5 cm in diameter. They tend to crease or wrinkle when bent or curved in accordance with the surface of intricately shaped structures. Another disadvantage of these hoses is that they cannot be used as lines for various organic liquids, especially when used under increased pressure, since the rubber-like coating material of these hoses can be affected by the organic liquid due to peeling or swelling. The other known type of hose is essentially a plastic hose, which is optionally provided with a protective coating. Hoses of this type are more flexible, especially with smaller diameters. With an appropriate choice of the resin material for such hoses, it is possible to conduct various types of fluid materials through these hoses,
With the latter types of hoses, it is known that a certain improvement in terms of gas permeability and resistance to ozone, oil and heat as well as a weight saving can be achieved by using polyamide as the resin material for the hose. In comparison with conventional hoses made of rubber-like elastic materials, however, polyamide hoses are so rigid that they can only be bent or bent with difficulty. They are even prone to cracking or fracturing when bent with force. In order to overcome this disadvantage, according to Japanese Utility Model Application Laid-Open No. 52-1 63 220, a polyamide tube is subjected to a wave treatment in order to improve its flexibility. However, a polyamide tube with such a corrugated structure shows a reduced compressive strength. Furthermore, in order to improve the flexibility of a polyamide hose, it has been proposed to use a double-layer hose in which the rigid polyamide hose is provided as the inner layer, over the ψ. 60 an elastic tube is placed. The thickness of the polyamide tube should be less than 0.5 mm. f% According to this proposal, there is still the disadvantage that the inner polyamide tube leads to cracking

"f> or has a tendency to peel off. Since polyamide shows a tendency to absorb moisture, inside

ρ of polyamide tubing accumulates water, which in the intended use has harmful effects

h can have effects. In order to avoid this disadvantage, according to the laid-open Japanese law

% 65 utility model specification 56-1 20 482 proposed a layer to prevent the ingress of water. | i In this case, chlorosulfonated polyethylene is used as such a layer to prevent the penetration of water

Ii placed between a first reinforcement layer and a second reinforcement layer. If you turn this

'4 procedures on polvamid hoses. an additional process step for vulcanizing the chlorosulfo-

Nated polyethylene required, which makes the production of such hoses difficult

From CH-PS 6 23 390 a hose with a double-layer structure is known in which, for example, a outer layer made of polypropylene and an inner layer made of elastomer blends with anhydrous high-melting synthetic resins is provided. From DE-OS 16 50 138 it is known to produce fuel-impermeable Hoses to provide a composite system, for example made of NBR with polyamide films.

Furthermore, from the laid-open Japanese utility model 58-94 975 rubber hoses are known, consisting of a thin inner metal-plastic composite layer and a rubber layer with a there are reinforcing fiber layer contained therein. Such plastic tubing should be with respect to their flexibility and impermeability to fluorinated hydrocarbons and moisture than prove excellent. However, these rubber hoses still have the disadvantage that it is difficult to to achieve complete adhesion between the composite layer and the rubber layer.

In the journal Gummi, Asbest, Kunststoffe, 8, p. 378 (1984) was about blends of chlorinated Polyethylene and nylon are reported without this publication giving any indication of the use of such Materials for hose manufacture can be found

Recently, it has been found that the disadvantages resulting from the water absorbency of polyamide can be overcome by coextruding the polyamide with a polyolefin-series resinous material having functional groups which has good water impermeability while firmly bonding the resinous material to the outer surface the polyamide hose causes the other hand, it has also been found that by providing a polyamide with good flexibility to ÜbP ^r "vindung resulting from the rigid nature of this material drawbacks by mixing the polyamide with a plasticizer or rubber or by .Copolymerisation the polyamide with a rubber, the Adhesion of the polyamide to the resin-like material of the polyolefin series containing functional groups is considerably deteriorated.

The object of the invention is to overcome the aforementioned disadvantages of polyamide tubes and To provide plastic tubing with improved flexibility and water impermeability and one To create a hose that is used to transport liquid or gaseous media in the event of pressure and temperature fluctuations is suitable and is characterized by extensive chemical resistance These plastic hoses should also be impermeable to fluorinated hydrocarbons and thus act as lines for cooling media suitable. Also with the planned two-day construction, the best possible adhesion between the two tube layers can be achieved.

The problem posed is achieved by a plastic hose with the characterizing features of Claim 1.

In claims 2 to 6, designs of the plastic hose according to claim 1 are given.

The plastic hose according to the invention is made by coextruding the aforementioned mixed polyamide-rubber compound with a phase structure in which the polyamide is the matrix phase and the rubber is the disperse phase are present, with a resinous material of the polyolefin series with a content of functional Groups that have good water impermeability and adhesiveness to polyamides

The invention is explained in more detail below with reference to the drawing

F i g. Fig. 1 is a perspective view of a basic embodiment of a plastic tube of the invention; and

F i g. 2 shows a perspective view of an embodiment of the plastic tube which is particularly suitable for practical use the invention.

In Fig. 1 is an inner layer 1 made of the polyamide rubber composition having the aforementioned phase structure provided, over which there is an outer layer 2, which is made of the resinous material of the Pulyolefin range, the functional groups contained therein are bound to the inner layer. Since the inner Layer i has a structure such that the vulcanized rubber phase is in the polyamide matrix phase is dispersed, the inner layer 1 proves to be greatly improved in terms of flexibility and proves to be overall as largely impermeable to freon. On the other hand, the outer layer 2, which is different from the resinous Polyclefin series material with functional groups derived on the outer surface of the inner layer 1 provided by coextrusion, the groups contained in the resinous material partially or entirely the interface between the two layers 1 and 2 with the polyamide to form an integral connected hose have been implemented. Thus, the outer layer 2 can only be removed with difficulty from the inner one Peel off layer 1 and give the inner layer 1 good water impermeability. Under the expression “Coextrusion” is a simultaneous extrusion of the polyamide-rubber fabric in a molten state and the polyolefin series resinous material in a molten state to form a double layer To understand hose from the mixed melt. The coextrusion process itself is based on conventional Manner, for example using a twin extruder performed. Regarding the thickness of the There are no special restrictions on the inner or outer layer: In general, the thickness the inner or the outer layer depending on the type and pressure of the fluid to be conducted through the hose Medium and selected depending on the intended use, these thicknesses generally in Range from 0.2 to 5 mm and preferably from 0.5 to 2 mm. Similarly, there are none special restrictions on the hose diameter, since the diameter depends on various factors, e.g. B. Resistance to internal pressure, type of media to be conveyed, length of the Hose, flexibility and the size of the connectors to which the hoses are connected, can vary. Generally the diameter is 5 to 30 mm and preferably 10 to 20 mm.

The in F i g. 2 , an embodiment of the hose according to the invention which is particularly suitable for practical use has an inner layer 1 which is covered with the outer layer 3. Above that there is a reinforcement layer 4 and an outer layer or protective layer 5. Layers 4 and 5 are generally used

Reinforcement and protection of the hose against external damage. It is generally used as a Reinforcement layer 4 is a woven or non-woven textile material and, as a protective layer 5, a scratch-resistant, abrasion-resistant resin material used. If necessary, these layers 4 and 5 can be further reinforced by incorporating metal thread, wire, or other reinforcing components into them. It is it should be noted that the reinforcing layer 4 and the protective layer 5 for the hose according to the invention Represent contingent components, one or both of which can be used as required. The layers 4 and / or 5 can be connected integrally to the hose with the aid of an appropriate binding agent.

The polyamide used for the mixed polyamide-rubber composition constituting the inner layer 1 is selected from commercially available polyamide materials. Corresponding examples are nylon 6, Nylon 6-6, nylon 11, nylon 12, nylon 6-9, nylon 6-to, nylon 8 or mixtures or copolymers of these Polyamides such as nylon 6 / 6-6 or nylon 6 / 6-10. Using nylon 6 or 6-6 provides a relatively soft one Blend, while nylon 11 gives a blend with moderate flexibility. In terms of the desired Flexibility and the desired use of a commercially available material are preferably nylon 6, Nylon 6-6 or nylon 11 used.

The rubber to be mixed with the polyamide in the inner layer 1 is made of a large number of natural and synthetic rubbers selected. Specific examples are natural rubber (NR), isoprene rubber (IR), styrene-butadiene rubber (SBR), acrylonitrile-butadiene rubber (NBR), isobutylene-isoprene rubber (!! Rl chloroprene rubber (CR), ethylene-propylene rubber (EPM , EPDM), chlorinated polyethylene (CSM), chlorinated polyethylene (CPE), acrylic rubber (ACM), epichlorohydrin rubber (EO, ECO), urethane rubber (U), silicone rubber (Q), fluororubber (FKM), and butadiene rubber (BR). In addition, chemically modified derivatives of the aforementioned types of rubber and mixtures thereof can be used Rubbers are used, e.g. B. rubber types modified with carboxyl or epoxy groups and Mixtures of NBR and ECO. Among these rubbers are acrylonitrile-butadiene rubber, epichlorohydro rubber, acid-modified (e.g., containing carboxyl groups) ethylene-propylene rubber and mixtures of acrylonitrile butadiene rubber and epichlorohydrin rubber are preferred because they work well with the Are polyamide compatible and result in hoses with satisfactory strength. Using a Mixtures of acrylonitrile-butadiene rubber and epichlorohydric rubber are particularly preferred because it a hose with excellent resistance to ozone and whitening under stress results

In the inner phase the polyamide and the rubber are used in proportions of 30 to 70 Weight percent polyamide to 70 to 30 weight percent rubber used. Obersteigi the polyamide content 70 percent by weight, the desired improvement in the flexibility of the hose can hardly be achieved determine. On the other hand, if the polyamide content is below 30 percent by weight, the .hermoplastischen Properties of the mass impaired, so that the machinability suffers considerably. A polyamide content of 40 up to 60 percent by weight and a rubber content of 60 to 40 percent by weight are particularly preferred for the hose according to the invention.

In the polyamide-rubber mixture, the rubber is dispersed in the polyamide medium Vulcanized or crosslinked with the help of a vulcanizing agent or crosslinking agent. More detailed information on special vulcanizing agents cannot be given, as this depends on the type of rubber used varies In general, those vulcanizing agents are preferred which vulcanize (crosslink) the the rubber used at the kneading temperature (mixing temperature) within 3 to 30 minutes. In general, a temperature above the melting point of the polyamide is used as the kneading temperature selected If the rate of vulcanization of the rubber is too fast, it will be difficult to get the rubber to be dispersed as a disperse phase in the polyamide matrix phase. Examples of vulcanizing agents (crosslinking agents) effective under such conditions are m-phenylene-bis-maleimide or a mixture of m-phenylene-bis-maleimide and dibenzothiazyl disulfide for unsaturated rubbers such as SBR and NBR, 2,5-Dimethyl-2,5-di- (teit-butyI-peroxy) -hexyne-3 for types of rubber that are capable of forming peroxy bridges, such as EPM, EPDM and BR, as well as alkylphenol-formaldehyde resins (reactive types ) or similar Phenolic resins for SBR, NBR, CR, HR and types of rubber with a content of carboxyl groups. These so vulcanizing agents' are commercially available and are used in amounts sufficient for vulcanization of the rubber used are generally required by kneading the rubber with the Polyamide in the presence of the vulcanizing agent at temperatures above the melting point of the one used Polyamide is the desired mixed polyamide-rubber composition with a phase structure in which the The rubber is present as a disperse phase and the polyamide is present as a matrix phase.

The resin-like material of the polyolefin series used for coextrusion with the polyamide-rubber mixture contains functional groups which are capable of reacting with the polyamide. The resin-like material is conductive from polymers or copolymers of at least one lower olefin, such as ethylene, propylene and butylene, the total amount of ethylene, propylene and / or butylene being 50 percent by weight or more and functional groups such as carboxyl groups, epoxy groups and amino groups are contained in the molecular chain of the polyolefin. In this case, the functional group content is 0.01-5 Percentage by weight of the polymer or copolymer. The molecular weight of the resinous material is at least 10,000.

The hose according to the invention is produced by extrusion. For example, the polyamide Put the rubber and the vulcanizing agent (crosslinking agent) in an extruder and add 3 to 30 minutes a temperature above the melting point of the polyamide used, resulting in a polyamide-rubber mixture with a phase structure in which the polyamide is the matrix phase and the vulcanized Rubber is present as a phase dispersed therein, the mass is then formed with the resinous Material of the polyolefin series with a content of functional groups that react with the polyamide

are able to be coextruded. This resinous material is separately added and loaded into the extruder heated molten state. In coextrusion, the outer layer becomes resinous Material chemically bonded to the polyamide-rubber mixture that forms the inner layer, creating a integrally connected hose is created.

The plastic tube formed in this way has the structure shown in FIG. 1 structure shown. Possibly conventionally, it becomes a practically desirable hose of the type shown in FIG. 2 shown Art processed. A woven or non-woven polyester textile material is suitable as the reinforcement layer 4. Polyurethane resin is suitable as the upper protective layer 5 because it is very waterproof and has good abrasion resistance having. However, any kinds of fibrous materials can be used for the layer 4 and for the upper Layer 5 rubbers derived from unsaturated polyesters can be used. If necessary, can the hose can be further protected by surrounding it with a metal foil or layer.

If the mixed polyamide-rubber compound constituting the inner layer, in which the polyamide is used as Matrix phase is in a molten state with the polyolefin material forming the outer layer coextruded, the result is an adhesion of the polyolefin material which, compared to similar polyamide materials, as usual nylon blended with rubber, nylon copolymerized with rubber or plasticized nylon that is superb. Thus, the peel strength of the inner layer is from the outer Layer in the plastic hose according to the invention is significantly higher than in similar double-layer plastic hoses.

The plastic hose according to the invention is characterized by a special double-layer structure, at the inner layer, impermeable to fluorinated hydrocarbons (freon), made of a cross-linked rubber-polyamide matrix and the waterproof outer layer made of the functional group Resin-like material, the latter chemically forming an integral tube on the inner Layer is bound. Thus, the plastic hose according to the invention not only has an excellent one Flexibility, but it is also impermeable to fluorinated hydrocarbons and water. Thus become all disadvantages of conventional plastic hoses avoided. Because of these valuable properties the plastic hose according to the invention is particularly suitable as a line for cooling media, such as fluorinated media Hydrocarbons (Freon), in automobile radiators and air conditioning systems. In Table I are the results of Comparative tests compiled in which the peel strength of the inner layer (polyamide-rubber compound) and the outer layer (polyolefin material) of the plastic hose of the invention with the corresponding values of conventional plastic hoses are compared.

Table I.

Inner layer peel strength test,

kg / 234 cm

Comparative Example 1 Nylon 12 3.2

Comparative Example 2 plasticized nylon 12 1.8

Comparative Example 3 Nylon 12 / NBR blend 1.5

(not networked) "

Example 1 Nylon 12 / NBR blend 3.1

(networked)

Annotation:

The test pieces of the samples used are made using a melt press
manufactured under the following conditions:

55

Temperature: 210 ° C Pressure: 100 kg / cm ² Time: 3 min

The measurement is made using a crosshead speed of 50 mm / min
made of an autograph.

1 sheet of drawings

Claims (6)

Patent claims: 1. Double-layer plastic hose with an inner layer made of rubber-containing material and a outer layer of resinous material of the polyolefin series, characterized in that the mutually contacting surfaces of the inner layer, which is made as a polyamide rubber mixture with Polyamide is present as the matrix phase and rubber as the disperse phase, and the outer layer, which consists of Resin-like material of the polyolefin series, chemically by means of functional ones contained in the outer layer Groups that are reactive with the polyamide of the inner layer are bonded to one another. 2. Plastic hose according to claim 1, characterized in that the polyamide is nylon 6, Nylon 6-6, nylon 12, nylon 6-9, nylon 6-10, nylon 8 or a mixture or copolymer thereof 3. Plastic hose according to claim 1, characterized in that the rubber is natural Rubber, isoprene rubber, styrene-butadiene rubber, acrylonitrile-butadiene rubber, isobutylene-isoprene rubber, Chloroprene rubber, ethylene propylene rubber, chlorosulfonated polyethylene, chlorinated polyethylene, acrylic rubber, epichlorohydrin rubber, urethane rubber, silicone rubber, Fluororubber, butadiene rubber, modified types of rubber of the aforementioned types of rubber with a content of carboxyl or epoxy groups and mixtures of these types of rubber. 4. Plastic hose according to claim 3, characterized in that the rubber is a Mixture of acrylonitrile butadiene rubber and epichlorohydrin rubber 5. Plastic hose according to claim 1, characterized in that 30 to 70 percent by weight of polyamide to 70 to 30 weight percent rubber have been used. 6. Plastic hose according to claim 1, characterized in that it is the resinous material of the Polyolefin series is a polymer or copolymer of ethylene, propylene and / or butylene, wherein the total amount of ethylene, propylene and / or butylene is at least 50 percent by weight, based on the polymer or copolymer, and functional groups that are reactive with the polyamide are, in the molecular chain in an amount of 0.01 to 5 percent by weight, based on the polymer or copolymer, are included.