CA1169622A - Shrink-fit object - Google Patents

Abstract

D-6923(Kab) SHRINK-FIT OBJECT

ABSTRACT OF THE DISCLOSURE

A shrink-fit article is made by extruding a silane-grafted polymer which foams, at least at its surface, and cross-links. Upon completion of foaming and cross-linking, the article is expanded while (still) warm and cooled in the expanded state.

Description

1 ~ 69~2~

BACKGROUND OF THE INVENTION

The present invention relates to shrink-fit objects such as shrink hoses, shrink sleeves, shrink caps, or the like.
Austrian patent 188,510, dated January 25, 1957, discloses a method for making shrink hoses by extruding or injection-molding a hose from a thermoplastic material, but having a smaller diameter than the hose to be made.
The extruded hose is then expanded by means of air pressure and cooled to fix its expanded dimension. The hose is later shrunk through application of heat and will contract to a reduced diameter for a shrink fit. The particular thermoplastic hose, e.g. a polyvinylchloride hose, does not achieve a sufficient stabile temperature and does not have an adequately elastic memory, in that it will not shrink exactly to its original dimensions established upon extrusion.
A particular product is known and traded under the designation "THERMOFIT"* which is a high-density polyolefin te be used for injection-molding particular shapes. These parts are subsequently subjected to high-energy electron rays in order to obtain a cross-linked, three-dimensional lattice assembly of the molecules. Such a shape is quite strong mechanically, is creep-resisting, does not tear, and has an * a trade mark, i~, ~ - 2 elastic memory. Upon making a hose or sleeve in that fashion and slipping it upon the object to be covered, shrinkage is obtained by briefly heating the s~eeve above the crystallization point, at about 135 Celsius. The sleeve will, thereupon, return rapidly to its original shape and dimension, and a truly strong cover is obtained.
The method as described in the preceding paragraph is applicable to other base polymers, also to modified polymers, depending upon any special requirements during its use. The critical aspect of this method, however, is the cross-linking by means of electronic beams, prior to heating and expansion.
Such a method is, therefore, quite expensive for reasons of the requisite equipment, and also for reasons of providing adequate protection for persons involved.
DESCRIPTION OF THE INVENTION
The present invention seeks to provide new and improved shrink-fit objects having an elastic memory and having features at least as good and versatile as articles made with cross-linking by means of radiation, but requiring less material.
Thus in a first embodiment a method of making a shrink-fit article such as a hose, a sleeve, a cap, or the like, comprising the steps of extruding or injection-molding a silane grafted material capable of cross-linking in the presence of moisture, under development of foaming, at least at the surface, in order to shape-form a hollow article in the configuration it is to have following a shrink fit; causing the article as extruded to cross-link in the presence of moisture; expanding the cross-linked and foamed article at an elevated temperature to obtain larger dimensions; and cooling the article in the expanded state.
In a second embodiment the method of making a shrink object, comprising the steps of providing a polymer blend with silane as a graft 1 1 ~9~22 component; causing the graft component to be grafted upon the polymer, the graft component being of the type for cross-linking the polymer molecules in the presence of moisture; shaping the grafted-on polymer into a particular hollow object and causing at least a portion of the blend to foam by means of blowing in order to obtain at least partially a foaming surface; exposing said grafted-on polymer to moisture for obtaining the cross-linking; expanding the completely shaped and completely cross-linked object as a whole at an elevated temperature;.and maintaining the expanded state as the object cools.
In a more detailed embodiment the method of making a shrink-fit article such as a hose, a sleeve, a cap, or the like, comprising the steps of providing a blend of a silane and a base polymer and a blowing agent; extruding the blend to cause the blend to melt while concurrently grafting the silane onto the base polymer; extruding being continued in the same step to obtain foaming of the blend forming the article; causing the article to cross-link by exposure to moisture; reshaping the articles prior to completion of cross-linking to form a hollow article; expanding the hollow article as a whole and at an elevated temperature; and cooling the article in the expanded state to form a shrink-fit article.
In accordance with the preferred embodiment of the present invention, it is suggested to make these articles :` -3a-~ ~, ¦ D-6923(Kab) 1 of a cross-linked material so that the surface strata

2 of these articles are comprised of foam, i.e., the material

3 of which such an article is made is converted at its surface,

4 at least partially, into foam. Aside from being lighter, such an article has inherently a larger resistance to heat 6 transmission; but the cross-linking fortifies the cell or 7 pore structure, giving it considerable mechanical strength.
- 8 In the preferred form of practicing the invention, the 9 material being amenable to cross-linking, is extruded and/or molded, whereby the development of the foam occurs during 1~ the shaping. Preferably~ the shrink-fit object is of a hol-12 low configuration, and such an object is directly extruded 13 as a hollow string. In the case of injection molding, the 14 mold is preferably charged by means of an extruder. In a preferred form of practicing the invention, the material is 16 to be made of an olefin-polymerisate or oly,in-copolymerisate 17 in which silane or a silane compound has been grafted and 18 cross-linked, at a degree of from 30~ to 80~ cross-linking.
19 In the preferred form, this base material is grafted in an extruder; and downstream, in that same extruder, foaming 21 commences in order to obtain the foam-developing expansion 22 as the product (such as a hose) leaves the extruder. Silane 23 molecules, grafted on a polyolefin, will cross-link in the 24 presense of moisture. This grafted-on material is shaped into an object having the shape that the final product will 26 ultimately have, after heat-shrinking has been provided ~q 11~9622 I D-6923(Kab) 1 in situ at a later time. Presently, moisture cross-linking 2 is to occur, or to be initiated, prior to or during shaping.
3 Foaming occurs prior to or after the onset of cross-linking.
4 Foaming and cross-linking are to be completed prior to expan-sion as the object is maintained at a shape similar to the 6 ultimate heat-shrunk shape.
q 8 Following completion of foaming and cross-linking, 9 the object is expanded as a whole at an elevated temperature which, in turn, is followed by cooling so that the object 1~ maintains its expanded configuration until heat is again 12 applied, causing the object to shrink back to the shape in 1 which it cross-linked. It should be noted that expansion 14 for foaming should be distinguished from expansion of the 1 object as a whole to obtain the final configuration. ~he 1 cross-linking as well as the foaming may already commence 17 when the material is being given its shape (extruder head, 18 mold); cross-linking and foaming may even be completed in 19 the mold or completed merely by exposure to the atmosphere, possibly being enriched in moisture (steam). Alternatively, 21 the shape may be cross-linked, at least to a significant 22 extent after shaping, but as the shape is being maintained, 2 under utilization of a suitable device (tank) exposing 24 the shape to water.

I I 1 6 9 6 2 2 D-6923(Xab) 1 ¦ The invention makes use of a discovery by one of 2 ¦ us and another that, pursuant to the grafting of low-molecu-3 ¦ lar compounds (e.g., organo-silane) onto the marcomolecules 4 ¦ of a polymer, secondary reactions thereof produce polyfunc-

5 ¦ tional chain-linking, resulting in "bundled" cross-linking

6 ¦ points or nodes, whereby a single cross-linking node fixes (links) several macromolecules simultaneously via the silane.
8 This particular chemical cross-linking mechanism leads to 9 large bonding forces of the molecules. Upon heating, or at an elevated temperature, there is some loosening of the bond 1~ which permits an expansion and "freezing" in the expanded con-12 figuration on cooling; but upon reheating, the original shape 13 is res~ored exactly by shrinking. Thus, the moisture cross-1 linking of the material of the shaped object results directly 1 in the generation of an elastic memory condition and configura-1 tion for the article, which memory is retained after expan-1 sion. The preferred application of the invention is the 1 making of hoses, sleeves, and caps, to be used as gas-tight 1 and moisture-proof covers for cable ends, cable or tube 2 splices, or other connections and joints for cables, tubes, 2 and so forth.
2 The invention now is specifically based upon the dis-2 covery that the mechanical strength of foamed, insulating 2 synthetics depends not only upon the properties of the base 26 polymer, but also on the number, size, and distribution of 28 `

I ~ 69622 the pores and cells which were formed upon foaming.
The smaller these pores and the more uniformly they are distributed, the stronger will the article become.
One may also say that the more viscous the melt is at the instant of foaming, the more uniform will be the distribution of the cells. This aspect has physical-chemical reasons. Pore size and structure depends decisively upon the vapor pressure of the blowing agent and the surface tension of the melt. The surface tension is greater for a higher viscosity. In the past, it was a common practice to lower the viscosity of a melt immediately prior to foaming by lowering its temperature.
This, however, is an expensive approach, requiring, e.g., rather long extruders. It is, therefore, much more appropriate to increase the viscosity by cross-linking.
In order to practice the inventive method, the object or article is extruded or injection-molded, the mold being charged by an extruder. The article thus made has the "contracted" configuration, but at least surface~near strata have been foamed, partially or completely, upon mold;ng and/or shaping by the extruder.
That article is also cross-linked to the desired degree because, preferably, the onset of cross-linking has preceded the foaming. FoaMing (blowing) the materialj when cross-linking has already begun, is of advantage for obtaining the formation of the cell structure

- 7 -! ~169~22 D-6923(Kab) 1 in the highly viscous material. The resulting cell struc-2 ture has small pores which are evenly distributed. The 3 cross-linked and foamed object is now expanded and heated 4 (or is still hot) and cooled in its expanded state. The expanded state is retained; but upon subsequently reheating 6 the object, it contracts on account of its elastic memory.
q

8 Graft cross-linking is preferred; but other modes can

9 also be used, for example, by exposing the article to high-energy radiation before, during, and/or after foaming.
l~;
12 In the case of moisture-cross-linking material, one 13 may use chemical blowing agents. However, if foaming and graft-14 ing occur at the same stage (though separated in time), one still has to take care that the foaming agent which was 16 added to the blend prior to grafting, does not produce 17 by-products that interfer with the grafting. It is, there-18 fore, preferred to use a physically acting foaming agent.
19 For example, one may use low, fluorinated or chlorinated hydrocarbons or nitrogen. These agents produce a consider-21 able degree of foaming, small pores, and a uniform cell 22 structure, resulting in strong, stable configurations of the 23 cross-linked product, without interference in the grafting 24 process.

2q ,, 1169622 D-6923(Kab) 1 It is of advantage to use the foaming agent as 2 a carrier for at least a portion of the moisture needed 3 for moisture-cross-linking. Thus, one may introduce a 4 moist gas, e.g. pressurized water vapor (steam) and carbon dioxide, into the blend which causes cross-linking in a short 6 time, particularly from the inside as the cell walls are 7 being formed. The overall residence time for the object 8 in water (for purposes of further cross-linking) can thus 9 be reduced.

1~ The blowing agent (whether or not it is a moisture 12 carrier) can be added conventionally to the polymer plus the 13 graft component blend. It is easier, however, to provide 14 the polymer as a powder and to blend it with the blowing agent in an appropriate mixer. It can also be of advantage 16 to prepare two batches: one for grafting with the olefin-17 polymer or copolymer; and a second batch of the same polymer 18 or copolymer, but with the foaming agent added. Both batches 19 are then blended.

21 Another way of stabilizing the cell walls of the pores, 22 as they are being formed by causing them to begin to cross-23 link, is to use a blowing agent which, as it decomposes, 24 releases water as one of its by-products. Such a material is, for example,benzene-sulfohydra~idaend can be added to the blend 26 (or a batch, as described earlier) so that, upon heating the 28 _9_ ~q blend by and in the extruder to the decomposing temperature, blowing and cross-linking begin at the same time.
Initiating cross-linking internally by using a moist-blowing gas or a water-releasing blowing agent has the added advantage that subsequently, i.e., after completion of shaping, the residence time of the article (e.g., in a water tank or other exposure to moisture) is reduced. This is particularly of interest in the case of continuous production of a hose (later to be cut into shrink sleeves) which passes through a water tank, or the like. The amount of water picked up by the hose may be insufficient to complete the cross-linking.
As was mentioned earlier, it is a specific feature of the inventlon that the blowing should commence when the material has already begun to cr~ss-link. In the case siloxane cross-linking, i.e. cross-linking through exposure to water, the blend should contain additives which release water, e.g., w-hen the blend reaches (or prior to its reaching) the decomposition temperature of the blowing. In this case, silane grafting occured earlier and, upon further heating, the material will begin to cross-link on account of the release of water within the material itself. Now, the blowing agent decomposes, and the cells and pores are generated as their wall structure is and continues to cross-link.

I ~ 696~ D-69~3 (E~ab) 1 A particular approach here for providing the requi-2 site amount of water for the moisture-cross-linking of 3 the cell's wall resides in the utilization of nonhygroscopic 4 metal oxides, such as tin oxide or zinc oxide. Again, it is assumed that siloxane cross-linking is employed. Imme-6 diately after shaping, these oxides lead directly to a 7 cross-linking at a degree of 30%. The cross-linking, as 8 resulting, e.g., from the additon of zinc oxide, produces a 9 noticeable increase in melt viscosity. Such increase occurs over and beyond the increase in viscosity due to grafting.
1~ The melt is, thus, quite viscous so that the resulting pore 12 structure is very fine and evenly distributed as desired.
13 The metal oxide may be added after the grafting has been 14 completed; this way, one will avoid premature cross-linking during grafting.

17 Zinc oxide has further advantages. For example, it 18 is known that the zinc oxide enhances the kinetics of the 19 decompositioning process of the blowing agent. The decompo-sition temperature is reduced, possibly considerably, when 21 the zinc oxide is present. This, in turn, means that 22 blowing can begi.- at a rather low temperature, a feature 23 that is also instrumental in improving the foam's structure.
24 The fact that little or no undecomposed blowing agent ,emains in the object is also of advantage in regard to the electric 26 properties of the shrink-fit article.

I 1 ~962~

Grafting and foaming, though consecutive steps, will be carried out in preferably one and the same process step; e.g., while the material is melted and heated in an extruder. This increases operational safety and reduces the possibility of external interference. The same advantage remains if the final object is composed of foamed and unfoamed strata, as explained next. `
If the article to be made is to have foam only in a surface-near layer, one may proceed as follows. A
suitable extruder is used with separate barrels and/or separate intakes of pressurized material. The head produces, for example, concentric layers in a hose. An inner hose will have the material that is used without an expanding and blowing agent to produce a solid material for the hose while an expandable foaming layer of otherwise like material is extruded on top of and around that solid-material hose The resulting two-ply hose has, thus, a solid portion and a foam layer.
In one preferred form of practicing the invention, cross-linking is carried out at an elevated temperature of above 80 C, but not higher than about 200 C, preferably in 1 1 6962~
D-6923(Kab) 1a range of 140 C to 180 C, if that particular, thermally 2 enhanced cross-linking is carried out or continued after 3 the shaping proper has been completed. The expansion may 4 now be carried out when the object is still hot, i.e. on line;
and thereafter, the object will cool and "freeze" in the 6 expanded configuration. The cross-linking may already com-7 mence and proceed during the initial molding or extruding 8 process in which the product is given its shape. In this 9 case, positive exposure to moisture of the product, subse-quent to shaping proper, can be dispensed with. This is 11 particularly the case when the material contains additives 12 which will release water upon heating, such as aluminum 13 oxide hydrate.

15Whenever cross-linking is not possible, or only 16 insufficiently possible while the shape resides in the shaping lq tool (die, mold, and so forth), the shape may be passed 18 through a steam atmosphere, analogous to a sauna, at a rather 19 high temperature. Alternatively, one may use a hot glycerin water bath or a hot oil water bath or water mixed with 21 polyalcohol, such as ethylene glycol and homologes thereof.
22 Aside from a rather uniform temperature, this has the follow-2ing advantage. The bath's components, which are better com-24 patable with the polymer than water, speed the diffusion of the water into the grafted polymer in order to obtain the 26 cross-linking.
2q ~q t 169~22 D-6923(Kab) 1 The base material can be any polymer permitting 2 radically initiated grafting, particularly of organo silane.
3 For reasons of working, polyethylene or an ethylene copoly-4 mer with vinylacetate or acrylate comonomer are preferred.
One may also use ethylene propylene rubber, possibly blended 6 with polypropylene.

8 The organo silane is preferably vinyltrimethoxy 9 silane under utilization of a relatively small amount of a catalyst, preferably dibutyl-tin-dilaurate. The amount of 11 organo silane needed can be taken by analogy to peroxidic 12 cross-linking. The molar ratio of peroxide-generating, 13 radical sites at the macromolecules to silane is preferably 1 about 1:10. This way, one ensures that the requisite mole-cular bonding forces are, indeed, available for causing 16 the expanded object to shrink back to its "memorizedl' con-17 figuration.

19 In addition, one may use use certain fillers which 2 should be nonhygroscopic, if possible even hydrophobic, 2 so that the moisture cross-linking is not interfered with;
2 any H20 molecules should be available for the cross-linking 2 and not be absorbed or trapped, otherwise. A particular 24 filler of interest is carbon black (soot) for reasons of enhancing resistance against ultraviolet radiation. So-called 26 acetylene black is very suitable here for reasons of its ~a nonhygroscopic properties. This particular type of carbon black has a high conductivity and relatively low quantities; e.g., 1.5 to 3.0 parts (by weight) per 100 parts of polymer suffice to provide the object with a desirable resistivity to ultraviolet radiation. Also, this type of additive does not interfere with the grafting.
As mentioned above, one may use still other additives, namely those of the type which release a definite amount of water at higher temperatures.
These additives may be provided in addition to carbon black. This gives the assurance that cross-linking begins already in the die or mold, i.e., right in the shaping tool, possibly even during shaping . - 15 -1 ~ 69~2~

in an extruder head. Suitable additives for this purpose are, for example, silicic acid made partially hydrophibic or silicates or aluminum oxiae hydrate. The latter decomposes at a temperature of above 180 C as per the relation 2 Al(OH)3 A12O3 + 3 H2O
A particularly useful product for purposes of the invention is an aluminum oxide hydrate traded by the company Martinswerk under the designation "Martinal A-S*."
The silanized version is traded under the designation "Martinal A-S/101*." These fillers have on the average a grain size of about 0.4~, and particularly the silanized addit~ve is very compatible with polyethylene.

DESCRIPTION OF THE DRAWINGS
_ While the specification concludes with claims, particularly pointing out and distinctly claiming the subject matter which is regarded as the invention, it is believed that the invention, the objects and features of the invent~on, and-further objects, features, and advantages thereof, will be better understood from the following descripbion taken in connection with the accompanying drawings, in which:
Figure 1 is a schematic view of an equipment for practicing the preferred embodiment in accordance with the best mode thereof for making caps;

* a trade mark.

~' I 1 6~622 Figure 2 is a similar view of a modified equipment;
Figure 3 is a schematic view of an equipment for making shrink hoses in accordance with the preferred embodi-ment and best mode of practicing the invention;
Figure 3a is a cross section through a shrink sleeve; and . Figure 4 is a diagram showing temperature versus time for different materials.
Proceeding now to the detailed description of the drawings, Figure 1 illustrates an extruder 2 having an inlet hopper to be charged with a granulated blend of the following composition (all parts by weight):

100 parts polyethylene homopolymer ~0.94 g/cm density, 0.2 - 2.5 melt index) 1.0 - 1.5 parts vinyltrimethoxysilane 0.03 - 0.05 parts dicumylperoxide 0.05 part of a graft catalyst, e.g. NAFTOVIN SN/L*
(dibutyl-tin-dilaurate) 2,5 parts carbon black (acetylene black Y~
0.5 - 1.5 parts azodicarbonamide (blowing agent) Actually, one may charge the extruder with the individual components and rely on the blending capabilities of the barrel-and-screw combination. It is, however, advisable to premix and homogenize the PE and the filler (e.g., soot). In any event, the material (PE) will melt in the extruder 2 and will be homogenized therein. Since * a trade mark.

~7~ 17 -I 1 69~22 a graft catalyst and a radical site initiator have been added, the silane will be grafted on the polymer when a te!mperature of above 140C has been reached. The temp-erature should, preferably, rise to from 160 to 200C.
The blowing agent decomposes at about 180 C.
The extruder nozzle 4 feeds a shaping tool such as a die or mold 3 for making caps. Thus, the molding process is actually analogous to injection-molding using an extruder for the preparation of the raw material, a homogenized blend of silane-grafted PE. Some cross-linking will occur already in the mold because there is some residual water in the blend. However, the product will be cooled for taking it out of the mold but not down to room temperature.
The caps as made are still quîte hot (80C), and it is advisable to use that thermal content for obtaining an accelerated cross~linking in a moist atmos-phere or environment. As schematically indicated, a tank 5 filled with an oil water emulsion or a water glycerin blend is provided to receive the caps made. This bath keeps the temperature constant (by suitable heating) and accelerates the cross-linking process further by direct exposure of the objects to water, The temperature is above 80 C, preferably between 140 C and 180 C, and possibly as high as 200C. The caps as made remain in that bath for a certain period of time such as 3 minutes to 30 minutes, and while still warm, are ~ 9 ~ 2 2 ~-6923(~ab) 1 taken out and expanded. Reference numeral 7 denotes a 2 mandrel, or the like, upon which a cap, such as 6, is 3 slipped. It is important that the caps be expanded while 4 the cross-linked material is heated to a temperature above the crystallization point of melting. The heat content 6 of the product, acquired during the cross-linking, should 7 be used as much as possible during the expansion. Thus, 8 expansion should follow immediately upon completion of 9 cross-linking in the bath and removal of the caps from the bath. The mandrel may additionally be pro~ided with lI apertures to blow air into the cap and expand it. The cap 12 is permitted to cool in this expanded state, to "freeze"
13 this configuration even after~expansion pressure is relieved.

Providing cross-linking by means of a water bath 16 is practical, particularly in the case of continuous pro-17 duction; but it is not essential in principle, exposure 18 to steam may suffice. In other instances, the moisture con-19 tent of the polymer or of any additive may suffice to obtain cross~linking already in the mold 3. Subsequent exposure 21 to moisture may be needed merely to complete cross-linking.

23 The otherwise completed object (cap, and so forth) 24 may subsequently be coated on the inside with a melt adhesive on the base of polyamid or polyester, to enhance bonding 26 when the object is subsequently heat-shrunk.
2q ~a ~¦ i 1 6962Z D-6923(~ab) 1 The example shown in Figure 2 includes similar molding 2 equipment; also, the expansion process for a cap is the same, 3 at least in principle. It is, however, assumed that no exten-4 sive exposure of the cap to water is needed. Rather, the blend used here for making a cap may include water-releasing sub-6 stances, e.g. A12(0H)3 (see one of the examples below). Par-7 tially hydrophobized silicate can also be used. In either 8 case, the very hot material in the mold will release the requi-9 site water throughout the material, and cross-linking occurs speedily, right in the mold, without requiring diffusions of 1~ water from the outside.
12 The completed product has been permitted to cool in the 13 mold and will, next, be reheated in a microwave unit 8, prior 14 to and for purposes of expansion. If carbon black is included in the material, ready absorption thereof and speedy heating 16 is ensured.
17 It should be mentioned that in other cases, whenever a 18 mere exposure to moisture suffices for cross-linking or com-19 pletion of cross-linking, a microwave heater may be used to enhance or complete that cross-linking and to prepare the object 21 for subsequent expansion as well.
22 Figure 3 illustrates an extruder 11 having an extrusion 23 head 10 for making a hose 15 on a continuous basis. At least 24 the surface layer of the hose has a-foam-consistency as it leaves the extruder. The material to be used is preferably 26 the same or similar to the composition outlined above. This hose is fed into a vacuum calibrator 12, preventing it from collapsing having sizing rings for providing it with the dimen-sions which the final product is to have after shrink fit; in other words, the equipment 12 provides the hose with the dimensions it is to memorize. The internal pressure inside the hose serves also as an inflating support. The hose is next fed through a glycerin water bath 13 maintained at a temperature of from 130C to 180 C, preferably from 160 C to 180 C. Since the hose is a continuous object, internal pressure continues to act upon the hose wall, for serving as a support and for preventing the hot hose from collapsing in the bath.
The hose passes next through a cooling tank 14, and the cooled hose may then be cut into the desired lengths. q'he cooling step is needed here to make sure that the shape remains stable. The hoses, sleeves, hollow fittings, and so forth, as subsequently cut, do have, at this point, a diameter which is to be memorized and will be memorized by operation of the cross~linking which is now completed. Next, the hoses, sleeves, and so forth, will be expanded, e.g. by slipping them over mandrels. Preheating will be necessary, e.g., by operation of microwave heating, as described earlier. A highly suitable method of expanding an uncut hose is disclosed by one of us and others in companion Canadian application 364,244 filed on November 7, 1980.

'~

~ 16~62~
D-6923(Kab) 1 This example also serves to demonstrate the making 2 of multiple ply shrink sleeves in which different materials 3 are extruded by a concentric extruder head. One may use 4 here the material of the example above for obtaining a foam surface layer underneath which there is a hose of the 6 same material, but without the blowing agent. The resulting 7 sleeve (after the hose has been expanded as a whole and 8 cut) has a consistency as shown in Figure 3a; there is a solid inner sleeve carrying an outer sleeve of foam, but of the same cross-linked polymer.

11112 ' I

1~ . ' I

19 ., ~4 1 169~ D-6923~1~ab) 2 ¦ Figure 4 compares a known process with the present pro-3 ¦ cess, particularly in regard to peroxide cross-linking. The 4 ¦ silane-to-peroxide ratio (molar values) is to be at least 10:1.
Trace "a" depicts moisture cross-linking; trace "b" depicts 6 peroxide cross-linking; both are plotted against time, 7 with time "0" being the instant that the material leaves 8 the extruder or is injected into a mold, as schematically 9 indicated.

11 As far as moisture cross-linking is concerned, the 12 PE blend to be grafted and being grafted is heated in the 13 extruder by means of heat conduction through the wall of the 14 extruder barrel, being heated. Also, the worm creates significant amount of friction, including shear forces in 16 the blend which are dissipated internally as heat. As the 17 temperature rises, grafting occurs. Cooling of the material 18 begins on the transition from the extruder to the mold.
19 This is, in fact, the meaning of curve "a." The object resides for two minutes in the mold during cooling, where-21 upon it is removed. Silane moisture cross-linking has begun 22 in the mold and may have to be completed as outlined above.

~q , t~6g~22 D-6923(Kab) 1 In the case of peroxidic cross-linking, the tempera-2 ture must not exceed 130C as cross-linking is not to 3 begin prior to charging of the mold. No such limit exists 4 for moisture cross-linking. Hence, the particular material must be heated in the mold in order to obtain the cross-6 linking temperature of 200C, reside in the mold for one minute 7 or so at that temperature, followed by cooling, when still in 8 the mold. Total residence time is, thus, considerably longer 9 than in the case of moisture cross-linking. Moreover, the energy consumption is higher in a peroxidic cross-linking 1~ method because one must cool the material so that it will 12 not exceed 130C prior to entry into the mold. That active 13 cooling of the peroxidic cross-linking material consumes 1 more energy than heating of a moisture cross-linking material in the extruder barrel, up to 200C, particularly under 16 utilization of all of the available heat-dissipating processes 17 (friction).

19 In the following, additional examples are given for 2 materials to be used for different kinds of shrink objects, 2221~ ¦ in pa cular for caps: all parts are ~y weight.

~n t 1 69~22 100 parts polyethylene copolymer (2 to 7 Mol % vinylacetate) 0.5 - 1.5 parts azodicarbonamide (blowing agent) 3.0 parts carbon black (Ketjen* black E.C.) 2.0 parts vinyltrimethoxy silane 0.05 - 0.1 parts peroxide 0.05 part dibutyl-tin-dilaurate catalyst (NAFTOVIN SN/L)*
In another example, the carbon black content was increased to 5 parts and the blowing agent was specifically 0.8 part.
In yet another example (see particularly Figure 2 for its usage~, a filler is used which will decompose and release water, already prior to and during the shaping process.
100 parts polyethylene homopolymer (density 0.94g/cm3, melt index 0.2 to 2.5) 0.8 - 1.2 parts diphenoloxide-4,4-disulfohydrazide (blowing agent) 2.0 - 10 parts aluminum oxide hydrate (e.g., Martinal A-S/101*)

10 parts carbon black (aztylene soot NOIR
Y 200*) 1.8 - 2.0 parts vinyltrimethoxy silane 0.05 - 0.1 parts peroxide 0.05 part catalyst (dibutyl-tin-dilaurate) * a trade mark.

~ 1 69622 The aluminum oxide hydrate can be replacea by silicic acid made partially hydrophibic. In either case, this particular blend releases water in the mold, and even earlier than that. Thus, this particular composition is highly suitable for making caps because cross-linking has begun upon foaming and is, at least partially, completed prior to taking the article out of the mold.
Another example is representative of using a rubber based compound as base material:
100 parts ethylene-propylene rubber (e.g., BUNA AP 407K*) 80 parts propylene (e.g., HOSTALEN PPH
1050*) 5 pa~ts carbon (KETJEN* black E.C,) 1.5 part vinyltrimethoxy silane 0.1 part peroxide (PERKADOX 14*) 0.05 part catalyst (dibutyl-tin-dilaurate) 0.5 - 1.5 parts blowing agent (azodicarbon-amide) * a trade mark.

~`

1 1 6962~

A furthe~ example is representative of physical blowing:
1()0 parts polyethylene-homopolymerisate (melt index 1.5 to 2.0) 5 parts carbon (KETJEN* black E .C . ) 0.5 - 2.5 parts physical blowing agent (trichloro-fluor methane or dichlorofluor methane) 1.8 to 2.0 parts vinyltrimethoxy silane 0.25 part peroxide (e.g., LUPEROX 270*) 0.05 part catalyst (dibutyl-tin-dilaurate) The invention is not limited to the embodiments described above; but all changes and modifications thereof, not cons~ituting departures from the spirit and scope of the invention, are intended to be included.

* a trade ma~k.

Claims (20)

THE EMBODIMENTS OF THE INVENTION IN WHICH AN EXCLUSIVE
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:

1. A method of making a shrink-fit article such as a hose, a sleeve, a cap, or the like, comprising the steps of extruding or injection-molding a silane grafted material capable of cross-linking in the presence of moisture, under development of foaming, at least at the surface, in order to shape-form a hollow article in the configuration it is to have following a shrink fit;
causing the article as extruded to cross-link in the presence of moisture;
expanding the cross-linked and foamed article at an elevated temperature to obtain layer dimensions; and cooling the article in the expanded state.

2. A method as in claim 1, including blending of the material with a foaming agent which will chemically decompose during the extruding.

3. A method as in claim 1, including blending of the material with a foaming agent which will physically expand during the extruding, thereby to obtain the foaming.

4. A method as in claim 1, including blending of the material with an additive which releases water during the extruding, so that cross-linking begins internally during the shape forming.

5. A method as in claim 1, including the step of reheating the article following the foaming and the cross-linking, but prior to the expansion step.

6. A method as in claim 5, the reheating step being carried out by means of microwave radiation.

7. A method as in claim 1, the cross-linking being carried out by means of a high-energy radiation.

8. The method of making a shrink object, comprising the steps of providing a polymer blend with silane as a graft component;
causing the graft component to be grafted upon the polymer, the graft component being of the type for cross-linking the polymer molecule in the presence of moisture;
shaping the grafted-on polymer into a particular hollow object and causing at least a portion of the blend to foam by means of blowing in order to obtain at least partially a foaming surface;
exposing said grafted-on polymer to moisture for obtaining the cross-linking;
expanding the completely shaped and completely cross-linked object as a whole at an elevated temperature; and maintaining the expanded state as the object cools.

9. The method of making a shrink-fit article such as a hose, a sleeve, a cap, or the like, comprising the steps of providing a blend of a silane and a base polymer and a blowing agent;
extruding the blend to cause the blend to melt while concurrently grafting the silane onto the base polymer;
extruding being continued in the same step to obtain foaming of the blend forming the article;

causing the article to cross-link by exposure to moisture;
reshaping the articles prior to completion of cross-linking to form a hollow article;
expanding the hollow article as a whole and at an elevated temperature; and cooling the article in the expanded state to form a shrink-fit article.

10. A method as in Claim 8 or 9, wherein the foaming step includes the insertion of a pressurized, moist gas into the blend so that foaming and onset of cross-linking concur.

11. A method as in Claim 8 or 9, wherein the foaming step includes adding a water-releasing blowing agent to the blend so that foaming and onset of cross-linking concur.

12. A method as in Claim 8 or 9, including the step of adding a filler to the blend which releases water in the extruder.

13. A method as in Claim 9 as applied to extruding a shrink hose, including the step of expanding the hose when still warm from the extrusion.

14. A method as in Claim 1 or 9, wherein the polymer material is polyethylene, a copolymer of ethylene, an ethylene-propylene rubber, by itself or blended with a polyolefin, such as polypropylene.

15. A method as in Claim 1 or 9, comprising:
the step of adding nonhygroscopic carbon black to the blend.

16. A method as in Claim 1 or 9, wherein said foam develops on an article of like material but not being a foam.

17. A method as in Claim 8, including blending of the material with a foaming agent which will physically expand during the extruding, thereby to obtain the foaming.

18. A method as in Claim 8, including blending of the material with an additive which releases water during the extruding so that cross-linking begins internally during shape-forming.

19. A shrink article such as a shrink hose, shrink sleeve, or shrink cap, made of an expanded foam material being comprised of an extruded and cross-linked material having been expanded in order to foam, the article as a whole having been expanded to a larger size following completion of cross-linking and foam expansion.

20. An article as in Claim 19, wherein underneath the foam surface layer there is an unfoamed layer.