DE3023840C2 - Device for generating heat and distributing the heat on a shrink sleeve - Google Patents

Description

Ensure heat distribution for both materials.

In this way, the even distribution of heat on the surface of a shrink sleeve and the correct measurement of the shrinkage temperature and the duration of action, solved, and additionally ensured is that directly or indirectly neighboring heat-sensitive parts are not endangered.

The device according to the invention is explained below with reference to three exemplary embodiments shows

F i g. 1 shows a cross section through a sleeve-shaped device arranged around a shrink sleeve Heat carriers according to the first embodiment,

F i g. FIG. 2 shows a partially cut-away plan view of the device according to FIG. 1,

3 shows a cross section through a device arranged around a shrink sleeve with a gauze-like device Heat distribution element according to the second embodiment,

4 is a partially cut-away plan view the device according to FIG. 3,

5 shows a cross section through a device arranged around a shrink sleeve with a reaction center arranged laterally in a clamp-like closure! according to the third embodiment and

6 shows a plan view of the device according to FIG. 5, shown partially cut away.

A shrink sleeve 1 that shrinks when exposed to heat, e.g. a cable sleeve that is shrunk onto a cable 2 is to be surrounded by a device for distributing heat. The device consists of heat carriers 5, which are designed in the form of sleeves and with reactants 6 introduced into their bores which react chemically after appropriate ignition and generate heat. The heat transfer medium 5 are aligned longitudinally in the axial direction on a corrugated tube-shaped heat distribution element 3 made of a highly thermally conductive Material firmly arranged, so that a good heat transfer from the heat carriers 5 to the Heat distribution element 3 takes place The wave troughs 4 of the heat distribution element facing the shrink sleeve 1 3. Touch it either firmly or loosely and thereby distribute the heat. After the reactant 6 is ignited, the shrink sleeve 1 begins to contract and in the process the heat distribution element should also be 3 reduce its diameter. This diameter reduction is made possible by a tubular and the shrinkable casing 12 caused by the also outwardly directed heat action shrinks, a heat-reflecting and thermally conductive layer 11 being arranged on the inside is. In the longitudinal spaces of the heat distribution element 3 are metallic passive heat carriers 10 arranged in the form of wires, whereby the heat distribution is supported.

The beginning 7 of the heat transfer medium 5 arranged one behind the other in a chain-like manner is provided with a secured insert 14 provided for inserting a detonator, not shown. The reaction process thus runs after ignition along the chain of the heat transfer medium 5 until the end 8 is reached. Between the individual heat carriers 5 delay media 9 are arranged with which the heat generator reacts too quickly 5 is prevented. The delay media 9 consist of fuses or wires with good thermal conductivity. the Lateral terminations of the device consist of a corrugated film 13 to provide protection to prevent accidental ignition.

In the embodiment according to FIG. 3 and 4, the heat distribution element 19 is formed from gauze-like fabric, for example from copper wires. This fabric is connected to one another in the form of lines or points on the shrinkable object or mutually. In these fabrics, the warp threads 20 are narrow and the weft threads 21 are wide and undulating so as not to influence the shrinkage movement. In the embodiment according to FIG. 5 and 6, the reaction agent 6 is concentrated in a heat transfer medium 26 designed as a locking clip. A heat distribution element 25 with its ends, which is designed as a highly thermally conductive metallic fabric, also extends into the locking clip. After the reactant 6 has ignited, the heat generated is distributed evenly over the circumference of the shrink sleeve 1 via the heat distribution element 25.

The locking clip is wave-shaped to ensure good flexibility in both directions, which is necessary when adapting the shape during the shrinking process. The reactant 6 is in several smaller chambers lying one behind the other 27 attached, which are connected to one another via the delay media 9.

For this purpose 2 sheets of drawings

Claims (12)

1 2 means and to distribute the heat to a hollow cylinder 1. Device for generating heat by means of the shrinking of the surface which follows its shape and a chemical reaction agent and the shrinking sleeve for distributing it len the heat to a hollow cylindrical shrinkage In such a known device according to the sleeve from US-PS 33 15 986 which can be shrunk when heated, the reactant is applied directly to the Plastic, whereby the reactant is applied and burns during the surface of the shrink sleeve Shrinkage of the surface of its shape on- after ignition completely off, with the shrinkage The corresponding shrink sleeve follows, thereby only being successful in the part that is currently burning indicates that the reaction medium (6) is heated uniformly over the entire shrinkage perpendicular to the direction of the shrinkage and parallel sleeve or a distribution of the heat over the entire IeI run to the longitudinal axis of the shrink sleeve (1) - the surface of the shrink sleeve is therefore not given, that consist of a material that conducts heat well. This has disadvantages under certain circumstances, since the shrinkage is arranged in the heat carriers (5, 26) and the adjacent sleeve shrinks unevenly and uncontrollably tend to be flexible and movable, while the DE-OS 17 04 131 aVorrich- Shrinking the shape of the shrink sleeve (I) fol- tion to generate heat for the curing of a lowing heat distribution elements (3,19,2S) ausgebil- adhesive connection known in which the reactant are. in perpendicular to the circumferential direction and parallel to the 2. Apparatus according to claim 1, characterized in that the longitudinal axis of a sleeve extends heat carriers distinguishes that the reactant (6) is arranged from one 3. Device according to one of claims 1 to 2, this is not a shrink body which at heat is characterized in that the heat distribution elements change their shape. elements (3, 19, 25) are designed as carrier films, 25 The object of the present invention is whereupon the heat carriers (5,26) are arranged. a device for generating heat according to the 4. Device according to one of claims 1 to 3, to create the initially explained type in which during characterized in that the heat transfer medium (5, of the entire-.i shrinking process) is uniform 26) are arranged in a zigzag shape. Heat distribution on the surface of the shrink sleeve 5. Device according to one of claims 1 to 4, 30 se is guaranteed. characterized in that delay media This object is achieved according to the invention by (9) between the reactants (6) arranged that the reactant in perpendicular to the direction of the are. Shrinking and parallel to the longitudinal axis of the 6. Device according to one of claims 1 to 5, shrink sleeve extending, made of good heat conductivity characterized in that the heat distribution element is arranged in existing heat carriers elements (3, 19, 25) releasable on the shrink sleeve (1) which rests on flexible and movable, while are arranged. the shrinkage of the shape of the shrink sleeve follow- 7. Device according to one of claims 1 to 5, the heat distribution elements are formed, characterized in that the heat distribution elements The mutual thermal insulation of the heat carriers Elements (3, 19, 25) inextricably linked to the shrink sleeve (1) 40 must be designed so that they are arranged next to one another. do not ignite each other, but rather 8. Device according to one of claims 1 to 7, which react one after the other. Through interposition characterized in that the heat transfer medium (5) of retarding means, the ignition and reaction of a shrinkable envelope (12) are surrounded by the reactants and thus the heat release gas. 45 be on the material to be shrunk in intensity 9. Apparatus according to claim 8, characterized and precisely predetermined over time. These distinguishes that the envelope (12) on its inner surface retarders exercise the function of heat, a heat-reflecting layer (11) has me- or ignition bridges and consist, for example 10. Device according to one of claims 1 to 9, made of pieces of wire, thin slivers or similar heat, characterized in that the heat distribution element 50 metransmission means. element (3) made of a corrugated, good heat conduction The effect of the heat transfer medium and heat distribution element Foil exists in their wave troughs (4) the heat elements can be improved if they are from carrier (5) are arranged. a heat-storing, heat-insulating or 11. Device according to one of claims 1 to heat-reflecting layer are surrounded. These 10, characterized in that approximately parallel to 55 layer can be used as an inner coating of another the heat transfer medium (5) passive heat transfer medium (10) attached to shrink tubing, which for the are arranged. Shape adaptation of the heat-distributing system while 12. Device according to one of claims 1-9, is used for the shrinking process. It is characterized in that the heat distribution element, however, is also possible, instead of a uniform distribution (19), is designed as a gauze-like fabric 60 system reactant of a at a defined point, _K. the warp threads (20) being narrow and the weft threads, for example along the closure plane of a flexible one ■ '■ - (21) are arranged far. Cuff, to be applied in a concentrated manner. The heat supply division then also takes place via heat distributors that outside of the object to be shrunk 65 are brought. If they are to be attached to the inside of the material to be shrunk, The invention relates to a device for generating them, preferably between the shrink material een of heat by means of a chemical reaction agent and the hot melt adhesive layer to the