DE3045198A1 - Flexible insulated pipe - has jacket of extruded foamed mixt. of polypropylene and rubber - Google Patents

Abstract

A flexible, heat insulated pipe has a thermally insulating jacket of foamed resin comprising a mixt. of polypropylene (I) and a rubber.

Description

Bendable, thermally insulated conduit

The invention relates to a bendable thermally insulated conduit pipe with a thermally insulating extruded cover made of foamed plastic.

It has long been a bendable thermally insulated conduit pipe the market, which consists of a soft-annealed copper tube and an extruded plastic jacket is based on polyvinyl chloride. To improve the thermal insulation effect the plastic jacket is supported by inwardly protruding projections on the copper pipe surface from (web jacket pipe). This tube enjoys great exposure to @ n @@ al @ ateu @, as it allows easy installation. The disadvantage of this tube construction is to see that a thermal conductivity of less than 0.9 W / m K is not or only with great technical effort is to be achieved.

It is also known a heat-insulated bendable conduit pipe, in which a copper pipe made of a flexible polyurethane foam and a copolymer tape is surrounded.

The copolymer tape becomes continuous in manufacture around formed around the longitudinal copper pipe and inserted it into the still open slotted pipe the foam components introduced. The one between the copolymer tape and the copper pipe The annular space located here is filled by the polyurethane foam. The copolymer tape adheres intimately to the polyurethane foam, so that this known pipe is bent without the copolymer tape wrinkling or tearing. With this construction thermal conductivity values of 0.03 W / m K can be achieved. The disadvantage of this pipe can be seen in the fact that the process engineering for the production of the same in particular in the case of soft-annealed biegbartn ICupferrohren is quite expensive (DE-OS 21 41 476).

It is also known to use an insulating jacket on a copper pipe to extrude foamed polyolefins.

For foaming, chemical blowing agents such as Example azodicarbonamide used. The disadvantage here is that the density is below 0.4 g / ccm and thus thermal conductivity values of less than 0.09 W / m. K hardly to are to be achieved. This density can be fallen below if the viscosity the plastic mass subjected to the foaming process, for example by partial Networking is raised. It has therefore already been suggested that one with a chemical crosslinking agent and a chemical blowing agent added plastic mixture put in an extruder, melted there and immediately before the outlet from the mouthpiece the temperature of the melt above the decomposition temperature of the To raise propellant and the crosslinking agent, in a so-called Shaving head. With this method, thermal conductivity values of approx. 0.065 W / m K can be achieved. The disadvantage of this method is to be seen in the fact that once the implementation The apparatus required for the process is quite complex and the chemical processes are not easy to control (DE-OS 28 06 570).

The invention is based on the object etn biegbcT-ez thermally insulated Specify line pipe, which can be produced without great economic effort lets which tine W; irmclcil.wrl-. of less than 0.05 W / m K, ulld in which the plastic jacket is made of an elastic but at the same time heat-resistant Material.

In the case of a thermally insulated conduit, this task is the one at the beginning mentioned type solved in that the shell is made from a blend (polyblend) Polypropylene and an elasticizing rubber, and the cells of the foamed * thermoplastic Plastic with a physically introduced gas, preferably one halogenated hydrocarbon are filled.

The thermal insulation effect of an insulating material is essentially determined by the degree of foaming or the density of the insulation material, the thermal conductivity the structural substance and the thermal conductivity of the propellant gas in the cells. By using a blend of polypropylene and an elasticizing one Rubber can be used to produce highly foamed but flexible structures, which have a high thermal stability. The higher degree of foaming of the invention Polyblends are based on the higher toughness of polypropylene at extrusion temperature compared to that of polyethylene. Another advantage of polypropylene compared to the previously used polyethylene is in the lower thermal conductivity of the polypropylene.

The halogenated hydrocarbons introduced by physical means have a significantly lower thermal conductivity than that from chemical blowing agents splitting gases (C02). The addition of elasticizing rubber improves on the one hand the extrudability of the polypropylene and on the other hand gives the heat insulating Coat a sufficient flexibility. As elasticizing rubbers with special Advantage of ethylene-propylene rubber (EPR), terpolymers of ethylene-polypropylene- * preferred Rubber, chlorinated polyethylene (CM), chlorosulphonated polyethylene (CSM) or styrene-butadiene block polymer used. The polypropylene component advantageously consists of a mixture of different types of polypropylene. The selection is expediently made so that polypropylene, which has a particularly high dissolving power for the foaming gas tonci polypropylene, which Increase the toughness of the polyblends, they are mixed by this measure Ciii Iso (l higher degree of foaming is possible and porch formation is improved. The mixing range of the polypropylene with the elasticizing rubber can be can be varied within wide limits, with an increase in the proportion of polypropylene in Direction of an increased degree of foaming and a higher thermal stability, an increase in the proportion of elasticizing rubbers towards a exhibits greater flexibility of the shell. One can see the heat resistance of the heat insulating Increase envelope if, as a further idea of the invention provides, the Polyblend siloxane cross-linked. The elasticizing rubber is crosslinked here and mechanically improved. Furthermore, it is achieved by the networking that the Polymer melt has a higher viscosity, which has a positive effect on the foaming behavior affects because the surface tension ("melt strength") is greater and both higher degrees of foaming as well as more uniform pore distribution is achieved.

The polyblend is particularly advantageous for nucleating agents Polytetrafluoroethylene powder added. These compounds are in the finest distribution dispersed in the compound and lead to the formation of a fine-pored and uniform Foam structure. Chemical blowing agents such as azodicarbonamide are also used as nucleating agents in question, which are added in small amounts.

The invention further relates to a method for producing a heat-insulated pipe, which is characterized in that a polyblend made of poly propylene and an elasticizing rubber in one Extruder is melted homogeneously that in the plastic melt under high A foaming gas, preferably a halogenated hydrocarbon, is introduced under pressure, is distributed and dissolved in the melt and then the plastic on the Metal pipe is extruded and the melt is foamed. Used as an extruder it is advisable to use a 25 D extruder with a cylinder bore for metering of the propellant gas in the range 8 - 12 D, the screw of which has a few SIert <i] e, to distribute the gas well. The propellants, for example the chlorinated hydrocarbons dissolve in the melt. As a result of the spontaneous pressure drop at the nozzle outlet of the extruder suddenly oversaturation of the dissolved in the melt occurs Gas on. As a result, there is a separation of the two phases gas and Melt and the gas forms a multitude of bubbles. The number and size of bubbles can be influenced by the nucleating agents.

The effect just described occurs especially when, like it according to a further concept of the invention, the hydrocarbon is provided is fed into the extruder in liquid form. Due to the high temperature of the The liquid hydrocarbon evaporates in the melt and dissolves in the plastic melt due to the high pressure.

The polypropylene in the compound crystallizes or solidifies already at 1600C, so that the foamed shell is less sensitive to crushing is at the withdrawal. The result is that the cooling section required downstream of the extruder can be chosen much shorter. Another major benefit in the Use of polypropylene can be seen in the fact that this material is available in a wide range Viscosity scale is available.

This leaves a lot of leeway for setting the melt toughness, the dell degree of foaming largely determines given.

The invention is based on the embodiment shown schematically in the figure and some execution examples explained in more detail.

In the figure, 1 is a copper pipe with an outer diameter of 22 mm, for example and a wall thickness of 1 mm, which is in the soft-annealed condition, while with 2 a heat-insulating cover made of a foamed thermoplastic Plastic is designated. The heat insulating cover 2 consists of a mixture made of polypropylene and an elasticizing rubber, for example ethylene-propylene rubber. The foaming of this heat-insulating cover 2 was made by physical means achieved by feeding chlorinated hydrocarbons into the plastic melt. Due to the polypropylene content, it has a heat resistance of up to 1500C, which makes networking unnecessary.

Furthermore, polypropylene has compared to the previously used polyethylene significantly lower thermal conductivity values.

The rubber content also brings high melt toughness, which is has a favorable effect on the degree of foaming, d. H.

makes a higher degree of foaming possible. The flexibility of the heat insulating Sheath 2 can be made by the ratio of folypropylene to the elasticizing rubber can be varied within wide limits. As polypropylene in a wide viscosity range is available, the melt toughness can also be determined by the polypropylene itself can still be varied.

A mixture of 50 parts of polypropylene and 50 parts of ethylene-propylene rubber (EPR) was made with dyes, antioxidants, nucleating agents and a low Amount of azo carbonamide mixed and melted homogeneously in a so-called 25 D extruder. The screw of the 25 D extruder has shear parts. In the area of the highest pressure becomes a chlorinated hydrocarbon such as that used for Example below the trade name "Frigen" is available, overcoming the melt pressure directly metered into the extruder barrel. Under the high pressure in the extruder barrel prevails, the liquid that has changed into the gas state dissolves. As a result of the spontaneous pressure drop at the mouthpiece of the extruder, which is the heat insulating Envelope 2 is applied to the copper tube @, a sudden oversaturation of the frilts dissolved gas in the melt and there is a separation of the two phases Gas and melt and the gas forms a multitude of pores. The pore formation will by the gas released from the azodicarbonamide during the melting process activated. By adding suitable nucleating agents or nucleating agents, the Pore number and pore size are influenced. The extrusion temperature, i.e. the temperature the heat-insulating sheath 2 when it emerges from the mouthpiece is approximately 190 to 2000C. The plastic sheathing of the copper pipe 1 foams immediately after Exits the mouthpiece in the atmosphere and is after foaming in introduced a water bath to cool down quickly. Because polypropylene already crystallizes at 160 ° C and solidifies in the process, the cooling section can can be significantly shortened compared to a polyethylene jacket. The thermally insulated Line pipe can therefore already at 140 to 150 0C from a caterpillar haul-off, which is necessary is to pull the pipe through the production line, be grasped without the foamed Shell is crushed. In addition, the thermally insulated conduit can already be wound up into rings at approx. 120 ° C.

Instead of ethylene-propylene rubber, chlorinated rubber can also be used, for example Polyethylene (CPE) or styrene-butadiene block polymers occur.

The heat resistance of the heat insulating shell 2 at very high Temperatures can be increased if the polyblend contains silanes and peroxides added to the extrusion that later when stored in normal Ambient air can lead to crosslinking of the elasticizing component. Usually the air humidity is sufficient to be complete over time To bring about crosslinking of the rubber.

L e r s e i t e

Claims (12)

P a t # 11 t fl s p r ii c h e Bendable, thermally insulated conduit with a thermally insulating extruded cover made of foamed plastic, characterized in that the shell is made from a blend (polyblend) of polypropylene and an elasticizing rubber, and the cells of the foamed * thermoplastic Plastic with a physically introduced gas, preferably one halogenated hydrocarbon. * preferably 2. Bendable thermally insulated Conduit pipe according to Claim I, characterized in that the elastic rubber is used Ethylene Propylene Rubber (EPR) is used. 3. Bendable heat-insulated conduit according to claim 1, characterized characterized in that a terpolymer of ethylene-propylene rubber is used as the elasticizing rubber is used. 4. Bendable heat-insulated conduit pipe according to claim 1, characterized characterized that chlorinated polyethylene (CM) is used as elasticizing rubber is used. 5. Bendable thermally insulated conduit according to claim 1, dit? I - ('I1 NOT A SIGNED. that the elastifying rubber is chlorosulfonated Polyethylene (CSM) is used 6. Flexible thermally insulated conduit pipe according to claim 1, characterized in that the elasticizing rubber is styrene-butadiene block polymers are used. 7. Bendable thermally insulated conduit according to claim 1, or one the following, characterized in that the polyblend is siloxane crosslinked. 8. Bendable thermally insulated conduit according to claim 1 or one the following, characterized in that the Polyr> ropyleiianteil from one Mixture of different types of polypropylene. 9. Bendable thermally insulated conduit according to claim 1 or one the following, characterized in that the polyblend nucleating agent is preferred Polytetrafluoroethylene powder is added. 10. Bendable heat-insulated conduit pipe according to claim 9, characterized characterized in that chemical blowing agents such as azodicarbonamide are used as nucleating agents are used in low doses. 11. Process for the production of a bendable thermally insulated conduit pipe according to claim 1 or one of the following, characterized in that a polyblend made of polypropylene and an elasticizing rubber homogeneously in an extruder is melted, that in the plastic melt under high pressure a foaming gas, preferably a halogenated hydrocarbon introduced, distributed and in the Melt is dissolved and then the plastic is extruded onto the metal tube and the melt is foamed in the process. 12. The method according to claim 11, characterized in that the foaming gas is fed into the extruder in liquid form.