DE7515237U - REFLECTIVE METAL THERMAL INSULATION COAT - Google Patents

Description

The innovation relates to a reflective thermal insulation jacket made of Ketal I, with two jacket sections, each of which has an inner and an outer delimitation plate, between which a number of reflective plates is arranged, which by means of at least a spacer are kept at a distance from each other.

The concept of reflective thermal heat insulation has been known for several years. A number of all-metal thermal devices have also been found in the literature Insulation of pipes, containers and heated objects at all described, according to the principle of reflection from Radiant energy work. Reflective insulation (US-PS 2,841,203, US-PS 3,190,412), which are made both curved and with a flat structure usually exist from an inner and an outer delimitation plate, between which a number Thinner metal sheets is arranged. The distance between the intermediate sheets and of the outer sheets is effected by different types of spacers, all of which are developed in such a way that they only touch minimally and in this way one Form a minimum area for a heat flow based on heat conduction. Such spacers are for example slotted supports and conical protrusions. Usually they are

Sheets polished to achieve maximum reflective effect.

The reflective all-metal1 insulation differ significantly from conventional thermal insulation, which blocks made of refractory or poorly conductive material, usually made of ceramics or poorly conductive material Contain fibrous materials such as glass fibers or rock wool. The sheet metal construction of the reflective insulation is a much stronger insulation structure than it which form brittle ceramic blocks or fragile fiber structures. Furthermore, the open structure of the reflective insulation easy cleaning of the inside of the insulation, which is a particular advantage if the isolation as a result of accidents, such as Broken pipes or leaks from containers with corrosive or radioactive liquids becomes contaminated. Advantages of this kind as well as the excellent insulation properties have contributed to an enthusiastic reception of the reflective isolations in particular the nuclear power industry.

However, as such isolations became more prevalent, serious problems arose of manufacture and installation. One of the most common problems is the poor fit of parts. Unlike fiber or ceramic insulation,

which are usually in place on the pipes or respective objects to be insulated With the help of simple tools, like portable saws, it renders the complex metal structure of the reflective insulation by its very nature necessitates that these are manufactured in a sheet metal workshop and ready for installation be transported. As a rule, the sheet metal processor designs and builds the reflective ones Isolation units according to the construction drawings of the pipe container or other objects to be isolated, which are provided by the manufacturer these objects are delivered. Very often, however, arises after the delivery of the prefabricated reflective insulation units at their place of use out that the Worker who has actually erected the structure to be isolated, while doing something of the Design data and drawings have deviated. As a result, the reflective one now fits Insulation that has been produced according to the specified design data does not exactly match the actual structure in the terrain. For example, the construction drawing requires a pipe section 91.4 cm in length and accordingly the insulation manufacturer requires reflective pipe insulation which is also 91.4 cm long. However, on delivery to the place of use it arises found out that the pipelayer has arranged the pipe slightly offset during the laying, so that

its actual length is 94 cm. This means that the reflective isolation must be completely re-manufactured or modified in order not to comply with the design data adapt corresponding pipe. A similar situation naturally exists when the pipe to be insulated is shorter than it corresponds to the design data, for example only 88.9 cm long instead of the 91.4 cm according to specification. To solve this problem of mismatching It has been suggested that the isolation according to the actual dimensions of the parts to manufacture the object to be insulated. However, this is extremely time-consuming in this respect Procedure in which each structure to be isolated has to be measured individually. Also would be a Such an approach the completion of the construction project significantly delaying the production of reflective insulation can only begin when the structure to be insulated has been assembled and put in place is. This of course completely destroys the appointment principle, according to which isolation should be available for installation as soon as the respective element of the construction project is manufactured.

The problem has led to further confusion in that it has made attempts by insulation manufacturers to standardize insulation units To design and supply sizes, loading

• were prevented. As the current units are not manufactured in large numbers and used for projects of various kinds can be kept in stock, but rather each insulation section is tailor-made to specific sizes has to be, reflective insulation has been unduly expensive up to now. this has give them a competitive disadvantage compared to ceramic and fiber insulation, which is readily available can be tailored at the point of use.

It would therefore be of considerable benefit to have a reflective isolation structure, which is inherent to a certain degree of adaptability or variability in length, so that they can be easily adapted at the place of use to the usual deviations between target values and to balance actual values of the finished structure.

It would also be of considerable benefit to have a reflective isolation structure, which can be manufactured in large numbers in certain standard sizes, so that the Make use of the economic advantages of mass production, and still have to adjust the size according to the respective order.

The task of the innovation is therefore to create a reflective thermal insulation jacket, which changes to dimensions of

I I ·

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Can be easily adapted to objects. The reflective insulation jacket to be created should be light can be manufactured in standard dimensions and have adapting elements.

This object is achieved according to the invention in that each sheet of a section on one corresponding sheet of the other section adjacent and displaceable with respect to this is arranged, with two successive reflection plates of one section lie between successive reflective plates of the other section and the outer one Perimeter plate of a section on the outside of the outer perimeter plate of the other Section. The insulation jacket according to the innovation thus creates an extendable thermal Isolation unit, which consists of two telescopically displaceable sections. Each section consists of an inner and an outer boundary plate and between them from a number of spaced apart thinner reflective sheets passing through Spacers are kept at a distance from each other. The outer perimeter of the first Section is slidable on the inside of the outer delimitation plate of the second Section. Each reflective plate of one section comes into sliding contact with a corresponding reflective plate of another section. Adjacent pairs of sheets of a section

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lie with their ends between adjacent pairs of sheets of the other section, and adjacent Pairs mutually work together in such a way that the relative distance between the reflection plates Is maintained- Preferably each have two sheets of one Section that lie between the opposite pair of sheets, spacers between them, which lie adjacent to the ends which can be displaced telescopically with respect to one another. At least on the outer delimitation plate of the second section are tensioning elements attached to prevent the structure from spreading outwards. They are preferred Tensioning elements attached to the inner and outer delimitation plate of the second section and pass through the inner and outer delimitation plates of the first section and all reflective plates. The inner and outer delimitation plates and the reflection plates of the first section have the Clamping elements cooperating means that a telescopic movement of the sections allow relative to each other, but prevent a separation of the two sections. The insulation jacket can be flat for wall insulation or for insulation of containers, pipes and similarly curved objects. At a The curved structure usually used, the insulation jacket has a hollow cylindrical shape and is used to isolate pipe sections,

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Embodiments are based on the figure drawing described.

La and Ib show a perspective view of a round (cylindrical) section a reflective insulation jacket that surrounds a pipe to be insulated, or a flat plate structure that is located on a flat surface to be insulated.

Fig. 2 is a side view of a curved insulation structure of Fig. La, the in a broken partial section shows the inner telescopic structure of the insulation.

Fig. 3 is a partial cross-sectional view taken along line 3-3 of Fig. 2 showing the Arrangement of the reflective plates and typical elements to maintain the distances shows between the reflective plates.

4a and 4b are schematic partial representations on an enlarged scale of the telescope structure of the insulation jacket, FIG. 4b additionally showing the spacer elements between adjacent reflective plates.

Fig. 5 is an exploded view showing schematically the. Elements shows the one Prevent separation, misalignment or rotation while being telescopic Allow movement between sections.

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Based on these figures, the innovation can be easily understood. In the Fig. La and Ib are two common embodiments of the insulation jacket. (Other embodiments were also used and are well known to those skilled in the art; As can be seen from the following, the innovation 'is also applicable to these). Fig. La shows a cylindrical jacket 2 which surrounds a hot pipe 4 which insulates shall be. Usually the insulation jacket is in the form of two semi-cylindrical ones Constructed halves 6 and 8 and selected in its inner and outer diameter so that the halves tightly surround the tube and then form a continuous cylindrical insulation jacket can be connected to each other. Tapes, clips and other conventional tools (not shown), can be used to secure the cylindrical structure. Typically, each semi-cylindrical structure has arcuate end plates at each end 10 or 12 attached. These end plates of the halves serve to move the inside of the structure outwards complete and at the same time act as a support that maintains the cylindrical shape and at the same time ensures that the insulation jacket is positioned correctly around the pipe.

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The outer walls of the two semi-cylindrical halves are usually as at 7 and 8 shown, somewhat extended, so that there is an overlap, the joint between covers the halves.

Fig. Ib shows a flat insulating jacket 14, in a position that isolates a hot flat surface 4 ¹ . This structure comprises rigid Be ⁴ enwände 16, a ceiling plate (or outer plate) 18, a bottom plate (or inner plate) 20. This structure is mounted on the surface to be insulated by means of brackets, straps or other aids.

Located within the individual insulation jacket a number of reflective metal sheets 22. The number of sheets, you The distance and the total thickness of the jacket depend on the temperature on the hot Side and according to the temperature drop to be achieved. The individual sheets are polished and are separated from one another by spacers such as the conical projections 24. Where how if there are no end plates in the case of the flat jacket 14, a boundary surface can be used 26 and / or strut 28 are used to set the reflective sheets and thus to prevent them from leaving the surrounding scaffolding.

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As far as the general structure of the insulation jacket of the innovation is conventional. It will, however It is immediately apparent that these conventional structures are necessarily of fixed dimensions have and can be changed in this essentially only by new production. The improved structure to be described below overcomes these serious problems Disadvantages' of the known structures and represents a coat that is easy can be adapted to the changing conditions in its use.

According to the innovation, each insulation jacket is in two sections, a first or nut section 30 and a second or male section 32 divided. (For the purposes of this Each half-cylindrical half of the pipe insulation should be described as its own Structure are considered). These sections are designed so that the outer perimeter plate 34 of the second section 32 slidably rests against the outer delimitation plate 36 of the first section 30, specifically on the inside thereof. The inner delimitation plate 38 of the second section 32 engages in a similar manner slidably against the inner delimitation plate 40 of the first section 30 and generally lies also on the inside. (It is possible to choose the structure so that the inner Boundary plate 38 is outside the inner boundary plate 40, but is such Structure considerably more complex than with

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reverse order, which is why the first is much preferable.) Each section 30 and 32 contains his own set of reflective insulation sheets 22 or 22 '"These extend in the essentially together with the inner and outer delimitation plates of the section in Longitudinal direction. Normally, each individual reflective plate overlaps with a corresponding one Sheet metal of the other section and is in sliding contact with this, as shown in detail in FIGS. 4a and 4b. (It is possible to design a structure in which one section contains more reflective plates than the other, so why some of the excess sheets do not slide against sheets of the other section. However, there are no technical advantages from such a structure, and since he unduly increases the complexity of the structure, it is not among the preferred.)

The details of the telescope structure according to the Innovation that has a double function, which is at the same time a telescopic one To allow movement and to maintain the required separation of the reflective plates, result from FIGS. 4a and 4b. As I said, each of the shows Figures are a partial section of a piece of sections 30 and 32. In Figure 4a there are four Pairs of corresponding sheets 42a and 42b,

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44a and 44b, 46a and 46b, and 48a and 48b. Figure 4b shows many of the same Reflection plates and additionally the outer boundary plates 34 and 36 of sections 32 and 30, respectively.

The two sheets 42a-42b, 48a-48b

touch each other in a displaceable manner and can move freely in the longitudinal direction. One Rotary or lateral movement is made possible by the strut 28 of the planar structure or a equivalent component of the cylindrical structure prevented. A twist and Lateral movement is also made possible by the screw-nut bracing described below prevented. The direction of the telescopic movement is indicated by the large arrow between Figures 4a and 4b indicated. Screw bolts 56, secured by nuts 60 (43), or similar bracing elements, through all the slotted reflection plates and delimitation plates of the Section 32 go, hold these sheets in a fixed position to each other with respect to the longitudinal direction and permit telescopic displacement of section 32 as a whole with regard to section 30. The structure after the innovation does not only work with regard to a possible telescopic displacement of the sections, but receives at the same time the correct distances between adjacent reflective plates of the insulation jacket upright. Two consecutive times

Sheets of one section are "weighted" between two sheets of the other section. In this way, an equal and opposite tendency to spread of an adjacent pair of the other section counteracts the tendency of two adjacent metal sheets to spread apart from one another, and that of one another. oppositely equal forces act in the sense of maintaining the desired spacing between the respective sheets. This is clearly shown in FIGS. 4a and 4b. In Fig. 4a the pairs A and B of the section 30, which consist of the metal sheets 42a, '44a and 46a, 48a, respectively, lie between the metal sheets of the successive pairs Y and Z. of the section 32, which the metal sheets 42b, 44b and 46b, 48b, respectively. Similarly, the pair C, which consists of the sheets 44b and 46b, lies between the sheets 44a and 46a of the pair X of the section Pairs A and B; - on the other hand, with the net result that all sheets maintain the desired relative position.

The alternating sheet metal pairs acting against one another transmit the separating forces inwards and outwards until it reaches the rigid inner and outer sheaths or boundary plates will. The desired distance between the inner and outer perimeter plates is Maintained by bracing elements. There

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the position of the inner delimitation plate or the bottom of the first section 30 by the Position of the pipe 4 or the surface to be insulated 4 'is fixed, such bracing elements can For example, an inelastic band drawn around the outer jacket or the outer delimitation plate of section 30 in the Case of the cylindrical structure 2, or fixed brackets that hold the ceiling plate 18 of the level structure 14 set, be. However, a structure is preferred in which a rod penetrates all the delimitation plates and reflective plates and this on is secured to the inner and outer surfaces of the jacket so as to allow it to expand restrict. In a typical embodiment of this preferred structure, shown • In Figures 2 and 4b, a bolt 56 extends through the inner and outer Boundary plates and all reflective plates of both sections. A comparatively the thin, flat head 58 of the screw bolt 56 engages the inner limiting plate 40 or the inner delimitation plate (base plate) 20 of the first section 30 at and is secured to the structure by a nut 60 on the opposite end of the screw bolt 56 is screwed or inserted, this being on the outer boundary plate 36 or the outer delimitation plate (ceiling plate) 18 of section 30 engages. (Normally there is

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.What a washer between the cutter 60 and the surface of the plate 36 or the top plate 18.) Space for the screw head 58 between the inner delimitation plate 40 or the delimitation plate (bottom plate) 20 of section 30 and the outer surface of the tube 4 or the Surface 4 ¹ can be gained through the projections 24. An equivalent result is obtained by using a threadless rod and a quick-release nut instead of the screw bolt and nut described above.

The telescopic movement is made possible by elongated holes 64a, ... in the two delimitation plates and reflective plates of the second or father section 32 are possible. The corresponding Boundary plates and reflective plates of the first or nut section 30 have Through-holes 66a, ... for the screw bolt 56. (A typical assembly is shown in the exploded view of FIG. 5; 34 and 36 denote the two outer delimitation plates). The entire structure can therefore freely telescope over move the entire length S of the elongated holes 64a, .... Since the long holes are not up to End of the inner or outer delimitation plate and the reflection plates of the second section 32 extend, it can not happen that this section in the course of its telescopic Movement from the first section 30 releases.

This structure therefore enables a telescopic movement and prevents at the same time a disintegration of the unity.

A typical example of this structure was a semi-cylindrical pipe cover Insulation of a steel pipe with a nominal width of 25.4 cm designed for a nominal length of 915 mm. Each of sections 30 and 32 was designed to be 508 mm in length so that resulted in an overlap of 101.6 mm. 50.8 mm long slots were in the inner and outer perimeter plates and all reflective plates of section 32 were provided and rested on half the length of the 101.6 mm overlap area; the two slots were circumferential seen at a distance from one another, essentially on opposite sides of the semi-cylindrical structure roughly as shown in FIG. In the inner and outer The delimitation plate and all reflective plates of the first section 30 corresponded through holes are provided for this purpose, also at half the length of the overlap area. This arrangement gave a 50.8 mm adjustment range for the total length of the structure, so that an actual adjustable length of 915 + 25.4 mm.

A preferred arrangement of the metal sheets is shown in FIG. 4b. In this preferred embodiment are the conical spacers

te 24a, 24b, 24y and 24z, which separate adjacent pairs, are arranged so that the spacer elements of those pairs of sheets (e.g. A ¹ , B ¹ , Y ¹ and Z ¹ ) lying between the next adjacent pairs are more at the ends of the sections 30 and 32 are the spacers (24c and 24x) that separate other pairs of sheets (such as C and X ¹ ). In this way, each pair of sheets can exert the maximum pressure against the next adjacent pair, since in most cases the sheets of metal have a certain degree of flexibility and elasticity.

The structures described here can be made from a wide variety of metals or metal alloys be made. Which material is chosen in each individual case depends on the material in play Temperatures, the desired strength of the structure, the service life, the requirements customer, corrosion resistance, cost and the like. Typical Materials that can be used are steel, titanium and aluminum sheets, where a preferred material is stainless steel. In general, the surfaces become the polished individual sheets to increase their reflectivity.

Starnberg, July 10, 1978/1056

Claims (10)

Protection claims: 1. Metal reflective thermal insulation jacket, with two jacket sections, each of which has an inner and an outer delimitation plate, between which a number of reflective plates / is arranged, which by means of at least a spacer are held at a distance from one another, characterized in that each Sheet (36; 42a to 48a; 40) of one section (30) on a corresponding sheet (34; 42b to 48b; 38) of the other section (32) is adjacent and displaceable relative to this, :. two successive reflective plates (42a, 44a, 46a, 48a) of one section (30) between successive Reflection plates (42b, 44b; 46b, 48b) of the other section (32) lie and the outer delimitation plate (36) of a section (30) on the outside of the outer boundary plate (34) of the other section (32) is applied. 2. Insulation jacket according to claim 1, characterized in that the inner delimitation plate (40) a section (30) displaceable on the outside of the inner delimitation plate (38) of the other section (32) is applied. 3. Insulation jacket according to claim 2, characterized in that the sections (30, 32) are arched are trained. 4. Insulation jacket according to claim 3, characterized in that the sections (30,32) as Half cylinders are formed. 5. Insulation jacket according to claim 2, characterized in that that the sections (30, 32) are flat. 6. Insulation jacket according to claim 2, characterized in that that the boundary plates and ^; - Reflection plates are penetrated by a tie rod (50) which is attached to the inner and outer surface of a section (30,32). 7. Insulation jacket according to claim 6, characterized in that the rod (50) through a a nut (60) is a secured bolt (56). 8. Insulation jacket according to claim 6, characterized in that the rod (50) through a a quick nut is secured unthreaded bolt. 9. Insulation jacket according to claim 6, characterized in that each delimitation plate (40,36) and each reflection plate (22: 42a, 44a, 46a, 48a) of one section (30) a through hole (66a, 66b, 66c, 66d) and each delimitation plate (22 '; 42b, 44b, 46b, 48b) of the other section (32) has an elongated hole (64a, 64b, 64c, 64d ') - that the elongated holes and through-bores on one another are aligned, and that the rod (50) penetrates the elongated holes and bores. 10. Insulation jacket according to claim 9, characterized in that the elongated holes (64a, 64b, 64c, 64d), viewed in the longitudinal direction, are offset from the end of the metal sheets.