DE202014100764U1 - Shrink sleeve with diffusion barrier - Google Patents

Abstract

Shrink sleeve for use in shrink sleeve connections, characterized in that the shrink sleeve comprises at least one diffusion barrier layer containing one or more of the polymers PVDC (polyvinylidene chloride), EVOH (ethylene vinyl alcohol) and PA (polyamide).

Description

The invention relates to a shrink sleeve for use in shrink sleeve joints, preferably in compounds of pre-insulated pipes.

background

Pre-insulated pipes are constructed with one or more inner pipes, an outer casing and an insulating layer arranged between the inner pipe (s) and the casing. Pre-insulated pipes are manufactured in desired lengths, which allow a transport, and are further manufactured such that the length of the inner tube / tubes often exceeds the length of the insulating layer and the shell. Thus, at the ends of the insulated pipe, the inner pipe (s) normally cantilever / collar relative to the insulating layer and the jacket.

At the installation site, the insulated pipes are connected end to end by first connecting the inner pipes of each of the two insulated pipes. This bonding typically occurs by welding. In order to cover the connection area with a protective outer jacket, a shrink sleeve can be pulled or pushed over the jacket on one of the insulated tubes, which are to be connected before welding the two inner tubes together. Optionally, a plate sleeve having the form of a plate mounted around the connection area may be used.

After welding the inner tubes together, a layer of insulation material may be applied to the connection in a number of different ways. It is known, for example, to place an envelope over the coat-and-insulation-free piece formed between the inner tubes welded together. This sheath is attached to the sheath ends such that a limited cavity is created. Thereafter, a foam-like insulating material is introduced into the cavity, whereby the insulating layer between the welded tubes and the shell is formed in the foaming of the foam. After the formation of the foam insulation, the shell is removed in some cases, and a material having diffusion barrier properties (e.g., aluminum foil) is wrapped around the shell-free area. In other cases, the sheath is allowed to sit around the foam layer when the sheath has diffusion blocking properties per se, or alternatively a diffusion barrier is wrapped around the sheath prior to final assembly of the shrink sleeve.

It is also known, two half-shells of insulation material, for example in the form of already foamed insulation material or foam-based insulation material to mount around the shrink sleeve connection and then to install the shrink sleeve - optionally combined with the installation of a diffusion barrier prior to assembly of the shrink sleeve.

The shrink sleeve itself is often mounted by sliding it onto the foam layer so that the ends of the shrink sleeve cover the ends of the jacket of the two tubes. The shrink sleeve is normally tacked by means of a mastic which assures the attachment of the shrink sleeve to the jacket during a subsequent heat treatment of the shrink sleeve where it shrinks. Thus, the connection between the two tubes of a shrink sleeve, which has the function of a jacket in the connection area, covered.

A disadvantage of the described methods is that they are time-consuming, since the methods comprise many simple steps, each taking a certain amount of time. Furthermore, the many process steps lead to an increased risk that errors are made during the joining of the tubes and the associated mounting of the shrink film.

In an alternatively known method, a shrink sleeve is first sealed to the shell of the two tubes, whereupon a foaming of insulating material by means of openings which are located in the surface of the shrink sleeve, directly in the shrink sleeve. By this method, however, it is not possible to mount a material with diffusion-blocking properties under the shrink sleeve.

Known shrink sleeves are u.a. from pipes of PE (polyethylene) or PEX (cross-linked polyethylene), which are heated, (if necessary partially) expanded and cooled in expanded form. When the sleeve is heated during assembly, it returns to its original shape and thus shrinks on the shrink sleeve joint. PE and PEX have some degree of diffusion barrier properties, but over a period of time the insulating gases in the insulation layer will diffuse out through the insulation, thus losing part of their insulation properties.

Summary of the product

One aspect of the present invention relates to a shrink sleeve for use with shrink sleeve joints in that the shrink sleeve comprises at least one diffusion barrier layer comprising one or more of the polymers PVDC (polyvinylidene chloride), EVOH (ethylene vinyl alcohol) and PA (polyamide).

Thus, a shrink sleeve is obtained which has improved diffusion barrier properties which help to extend the life of the shrink sleeve joint. In addition, the shrink sleeve with embedded diffusion barrier is easy and quick to install, with minimized risk of failure mounting. The fact that the shrink sleeve has an embedded diffusion barrier means that an optimized protection of the insulating layer under the shrink sleeve can be obtained. By the above-mentioned shrink sleeve, the life of the shrink sleeve connection is thus significantly increased.

In one or more embodiments, the shrink sleeve further comprises at least one other layer of polymeric material consisting of one or more of PE (polyethylene), PP (polypropylene), PB (polybutylene), and ABS (acrylonitrile-butadiene-styrene).

Most commonly, PE will be used as the other polymeric material layer because it has good mechanical properties for use as a sheath and, moreover, is a low cost and easily accessible material.

In one or more embodiments, the shrink sleeve is water and / or water vapor permeable.

In one or more embodiments, the diffusion barrier layer has a thickness of 1 micron or more, e.g. 1-100 μm, 1-50 μm, 1-20 μm or 1-10 μm.

In one or more embodiments, the diffusion barrier layer is applied to the inside of the shrink sleeve.

In one or more embodiments, the diffusion barrier layer is disposed between two layers of the other polymeric material layer, which provides enhanced protection of the diffusion barrier layer.

In one or more embodiments, the shrink sleeve includes an adhesive layer consisting of e.g. a thermoplastic adhesive or a thermosetting plastic adhesive, wherein the adhesive layer is disposed between the diffusion barrier layer and the other polymeric material layer. This ensures increased bonding between the two polymer layers.

In one or more embodiments, the shrink sleeve includes three layers where the inner layer is a diffusion barrier layer, the middle layer is an adhesive layer, and the outer layer is a polymer layer consisting of one or more of the PE (polyethylene), PP (polypropylene), PB (polybutylene) polymers. and ABS (acrylonitrile-butadiene-styrene). Most often, the outer layer will be a PE layer.

In one or more embodiments, the shrink sleeve includes five layers wherein the middle layer is a diffusion barrier layer, the two adjacent layers are adhesive layers and the two subsequent layers are polymer layers consisting of one or more of PE (polyethylene), PP (polypropylene), PB (polybutylene ) and ABS (acrylonitrile-butadiene-styrene). Most often, the latter layers will be PE layers. In this five-layered embodiment, an additional protection of the central diffusion barrier layer is achieved.

The various layers that make up the shrink sleeve may be coextruded.

In one or more embodiments, the shrink sleeve is constructed of various layers selected from the group consisting of PE / PETP-PVDC / PE, PE / PVDC / PE, PETP-EVOH / PE, OPA / PA-EVOH-PA / PE, and OPA -PVDC / PE are selected.

In one or more embodiments, the other polymeric material layer has shape memory.

In one or more embodiments, the other polymeric material layer forms a semi-crystalline network.

In one or more embodiments, the other polymeric material layer is crosslinked.

In one or more embodiments, the shrink sleeve has openings for the introduction of insulation material and / or for the venting of air.

Brief description of the figures

The 1 shows two pipes to be connected, wherein the shrink sleeve can be used in the thermal insulation of this area.

The 2a and 2 B show two different embodiments of the shrink sleeve.

Detailed description of the product

The 1 shows two pipes 100 , both from one or more inner tubes 102 , a coat 106 and one between the coat 106 and the inner tube (s) 102 arranged insulating layer consist. If two pipes 100 This is often done by connecting the inner tubes 102 on each of the two pipes 100 be welded together. Before the inner tubes are welded together, a tube-shaped shrink sleeve, such as in the 2a and 2 B shown over which one of the ends of the two tubes are pushed. This type of shrink fit sleeve is very often used in conjunction with shrink fit joints. As an alternative to the tube-shaped shrink sleeve, a plate sleeve, optionally with shrinkage properties, can also be used.

The insulating material layer which is placed on top of the inner tube (s) in the shrink-fit joints can be formed by foaming a foaming agent, e.g. in a sleeve mounted in such a way as to cover the entire uninsulated shrink sleeve joint. An example of such a foaming agent is cyclopentane for producing polymer foam from e.g. Polyurethane. In the finished foam, the foam cells will contain a gas composition containing a substantial amount of carbon dioxide and pentane, the carbon dioxide being generated primarily during the course of the chemical reaction.

As an alternative to foaming the insulation material, it is also possible to mount two half-shells of finished-foamed insulation material or the like which still contains a given quantity of gases which has insulating properties.

Known shrink sleeves are most commonly made of PE (polyethylene) or other materials that are relatively open to the diffusion of carbon dioxide (CO ₂ ). Carbon dioxide and pentane will diffuse through the mantle over a period of time and will be replaced by, inter alia, oxygen (O ₂ ) of the surrounding air. Carbon dioxide and pentane are both important gases for maintaining a good insulating capacity of the foam, which is why it is problematic when too large amounts of these gases diffuse out of the foam. The problem with the accumulation of oxygen in the insulation foam is that oxygen has poor insulation properties and also contributes to the decomposition of the foam. The diffusion properties of the PE cladding material thus regulate the transport of oxygen and carbon dioxide molecules through the cladding, which means that the underlying insulating layer, from which or in which gases diffuse, loses its insulating capacity over a period of time.

Previous methods of obtaining better diffusion barrier properties of the joint area between the two pipes have utilized a technique whereby the insulation material is covered with a material having diffusion barrier properties (e.g., aluminum foil) by cladding the cladding-free area with insulation material. This has partially solved the problem, however, water flowing in the inner tube, which may penetrate to some extent into the inner tube and thus diffuse out into the insulating material, has had no opportunity to exit the tube when e.g. an aluminum foil has been used. The water can thus end up in the foam, where it can condense and lead to water saturation of the cells in the insulating foam. Thus, it can also lead to a reduced insulation capacity of the foam.

One aspect of the present invention relates to a shrink sleeve, as in 2a -B is shown for use with shrink-fit joints. The shrink sleeve is in two embodiments 200a . 200b in the 2a -B shown, but other configurations are of course also conceivable.

Before welding the inner tubes 102 together, the shrink sleeve 200a . 200b over one of the pipes 100 pushed so that the shrink sleeve after welding the inner tubes 102 can be pushed over the shrink sleeve connection. When the shrink sleeve is passed over the shrink sleeve joint, the ends overlap 202 the thimbles 200a . 200b the coat 106 from each of the two pipes 100 , The fastening of the shrink sleeve 200a . 200b at the caps 106 is best carried out by a thermal process in which the area is heated, optionally with the aid of mastic, which increases the ability of the shrink sleeve to stick to the shell.

The shrink sleeve may include openings that allow the supply of insulation material after the ends 202 on the sleeves on the coat 106 the pipes 100 are fixed, if a foaming of insulating material is to take place, wherein the sleeve has the function of a shell.

The shrink sleeve 200a . 200b comprises at least one diffusion barrier layer (not shown in the figures) containing one or more of the polymers PVDC (polyvinylidene chloride), EVOH (ethylene vinyl alcohol) and PA (polyamide).

Most often, the shrink sleeve will further comprise at least one other polymeric material layer consisting of one or more of the polymers PE (polyethylene), PP (polypropylene), PB (polybutylene), and ABS (acrylonitrile-butadiene-styrene).

The polymer materials of which the shrink sleeve is constructed, can be permeable to water and / or water vapor. This allows no water to accumulate in the insulating layer, but has the opportunity to diffuse out of the area around the shrink-fit joint.

The diffusion barrier layer containing one or more of the polymers PVDC (polyvinylidene chloride), EVOH (ethylene vinyl alcohol) and PA (polyamide) serves as a diffusion barrier for oxygen and carbon dioxide. The effect of PVDC, EVOH and / or PA is that it achieves a significantly greater barrier to diffusion of oxygen and carbon dioxide compared to a corresponding layer of PE used previously.

It is important that the diffusion barrier layer comprising one or more of the PVDC, EVOH and PA polymers be sufficiently flexible to follow the change in geometry during shrinkage of the shrink sleeve and thereby on the other polymer material (s) containing the Shrink sleeve contains to remain adhered so that the diffusion barrier layer shrinks together with the other polymer layer (s).

It will also be advantageous that the various polymer materials can be coextruded or that the diffusion barrier layer can be extrusion coated or spray coated onto the other polymer material layer.

Both types of polymer layers mentioned herein may have shape memory. This means that the polymer layers have the ability to "remember" a macroscopic primary form. Polymeric materials of shape memory are capable of being elastically deformed (expanded or compacted) under specific conditions, and starting from the primary form, and retained in a secondary form with high stress in the material (often by means of a low temperature). The secondary form may, for example, relax under thermal or electrical action to its original state (primary form).

The other polymer material layer consisting of one or more of the polymers PE, PP, PB and ABS may be crosslinked and may optionally have a partially crystalline network, for example consisting of covalently crosslinked polymers. In this type of material, the melt transition of the crystalline regions in the secondary form is used to return to the primary form.

An example of covalently crosslinked materials is polyethylene (PE), which is a relatively inexpensive polymeric material with good mechanical properties, making it an obvious candidate as a good jacket material.

In order to reduce the material cost of the shrink film, it may be advantageous for the diffusion barrier layer to be as thin as possible. In practice, a thickness of up to 1 μm will form a satisfactory barrier to oxygen and carbon dioxide. Most often, the thickness is reduced to 1 micron or more, e.g. 1-100 μm, 1-50 μm, 1-20 μm or 1-10 μm.

The diffusion barrier layer may be applied to the inside of the shrink sleeve so that it faces the insulating layer directly. Alternatively, the diffusion barrier layer may be disposed between two layers of the other polymer material.

Between the diffusion barrier layer and the other polymer material layer (s) may be an adhesive layer consisting of e.g. a thermoplastic adhesive, an elastomer adhesive or a thermosetting plastic adhesive may be present.

The shrink sleeve may be composed of various layers selected from the group consisting of PE / PETP-PVDC / PE, PE / PVDC / PE, PETP-EVOH / PE, OPA / PA-EVOH-PA / PE and OPA-PVDC / PE.

It should be understood that embodiments and features described in connection with one of the aspects of the present product also apply to the other aspects of the product.

Claims (10)

Shrink sleeve for use in shrink sleeve joints, characterized in that the shrink sleeve comprises at least one diffusion barrier layer comprising one or more of the polymers PVDC (polyvinylidene chloride), EVOH (ethylene vinyl alcohol) and PA (polyamide). Shrink sleeve according to claim 1, characterized in that the shrink sleeve in addition to the diffusion barrier layer additionally at least one other polymer material layer consisting of a or more of the polymers PE (polyethylene), PP (polypropylene), PB (polybutylene) and ABS (acrylonitrile-butadiene-styrene). Shrink sleeve according to claim 1 or 2, characterized in that the shrink sleeve is water and / or water vapor permeable. Shrink sleeve according to one or more of the preceding claims, characterized in that the diffusion barrier layer has a thickness of 1 micron or more, for example 1-100 microns, 1-50 microns, 1-20 microns or 1-10 microns. Shrink sleeve according to one or more of the preceding claims, characterized in that the diffusion barrier layer is applied to the inside of the shrink sleeve. Shrink sleeve according to one or more of claims 2-5, characterized in that the diffusion barrier layer between two layers of the other polymer material layer is arranged. Shrink sleeve according to one or more of claims 2-6, characterized in that the shrink sleeve comprising an adhesive layer consisting of, for example, a thermoplastic adhesive, an elastomeric adhesive, or a thermosetting plastic adhesive, wherein the adhesive layer between the diffusion barrier layer and the other polymer material layer is disposed. Shrink fitting according to one or more of the preceding claims, characterized in that the shrink sleeve is composed of different layers, which consists of the group consisting of PE / PETP-PVDC / PE, PE / PVDC / PE, PETP-EVOH / PE, OPA / PA -EVOH-PA / PE and OPA-PVDC / PE are selected. Shrink sleeve according to one or more of claims 2-8, characterized in that the other polymer material layer has a shape memory. Shrink sleeve according to one or more of claims 2-9, characterized in that the other polymer material layer forms a partially crystalline network and / or is crosslinked.

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