RU2070532C1 - Protective packing for getter material - Google Patents

Abstract

FIELD: electronic industry; packing of getter material. SUBSTANCE: protective packing has two walls with space in between, getter material being placed in space. According to invention, first wall of protective packing is made of sheet of thermostable material, and second wall, of sheet of thermoshrinking plastic material. Indicated space is formed by cavity made in thermostable material sheet. Sheets are connected by gluing. EFFECT: enhanced quality of packing and storage. 14 cl, 4 dwg

Description

 The present invention relates to a protective vessel for getter material.

Remedies for getter materials have long been known. Barium, when it is used as a metal in its suitable form, is placed in a tank of protective metal, which is protected from atmospheric gases. With the development of more complex getter thickening devices, the nature of the alloys used, such as BaAl ₄ , makes it necessary to apply appropriate protection in order to exclude the interaction of alloys with atmospheric gases. However, they must be heated to about 800-1200 ^o C to cause the release of barium metal, and thereby develop their reactivity.

Non-tightening getters also have a protective mechanism by which they form protective layers on the surface of the getter material. However, their protective layer must be removed by heat treatment or activation at high temperature for a certain time to allow the surface to become clean and act as a deoxidizing gas. Even at low temperatures, the activated getter materials still have to raise this temperature to almost 400 ^° C. in order to make the material active.

 The protection of such non-evaporating getters was ensured after appropriate activation by using destructible containers, such as described in US Pat. No. 4,124,659, or by using glass vessels, as described in US Pat. No. 4,938,667, to which reference is generally made.

 Consequently, the aim of the present invention is to eliminate one or more of the disadvantages of the known protective vessels for getter materials.

 Another objective of the present invention is to provide a protective vessel for getter materials, the cost of manufacture of which is significantly reduced.

Another objective of the present invention is the creation of a protective vessel for getter materials, which would not need a temperature above 150 ^o C to open it.

 Another objective of the present invention is to provide a protective vessel for getter materials, which would be simple and effective.

 These and other objectives and advantages of the present invention will become more apparent to those skilled in the art by reference to the following description and drawings, in which FIG. 1 is an exploded view of one embodiment of the present invention; FIG. 2 is a view of another exemplary embodiment of the present invention, FIG. 3 is yet another exploded view of an embodiment of the present invention; FIG. 4 is a view of a less preferred embodiment of the present invention.

 The present invention provides a protective vessel for getter material, which comprises a first sheet of heat-resistant material attached to a layer of glue, which, in turn, is attached to a second sheet of heat-compressible organic plastic material, the first and second sheets enclosing said getter material.

 In FIG. 1 shows an exploded view of a protective vessel 100, which comprises a first sheet 102 of heat-resistant material 104 in the form of a first annular disk 106. The heat-resistant material 104 can be any material suitable for use in a vacuum environment with a low degassing rate, but preferably with a low gas permeability. It can be made from organic plastic, such as polyethylene or polyvinyl chloride (PVC), or polystyrene, or from an easily formable but rigid material such as metal, for example a thin sheet of stainless steel, nickel or aluminum. Organic plastic can be coated with a thin layer of metal (such as aluminum) or other layers of organic plastic with low atmospheric gas permeability to improve packing gas density. Examples of such “insulating” materials are PVDC (vinylidene chloride copolymers) and EVOX (ethylene vinyl alcohol copolymers), which can be used separately as separate coatings or on top of another type of coextrusion. A hollow receptacle or recess 108 is pressed inside the first sheet 102 in the form of a shallow cylinder 110, which has an outer wall 112 and a bottom wall 114 with an annular flange 115 in the disk 106. The shallow cylinder 110 contains getter material 116. Any getter material that requires protection can be used such as barium, or activated non-volatile getter materials, but reactive non-volatile getter alloys of barium are most preferred.

The recess 108 and, therefore, the shallow cylinder 110 containing the getter material 116 are hermetically sealed with the second sheet 118 of thermally compressible organic plastic material 120 in the form of a second annular disk 122. The lower surface 124 of the disk is glued to the annular flange 115 by means of glue 126. Glue 126 can be any adhesive suitable for bonding the materials of the disk 104 to the disk 122, as well as a heat-sensitive varnish. The corresponding varnish is sold by SOMET from Lanet, Milan, Italy, under the trademark YA276, which consists of a polyurethane resin diluted in a solvent of ethyl acetate. The varnish is applied to the bead 115 and left to dry using a stream of warm air heated to about 40 ^o C until it becomes dry. Thereby, both parts are forced to be glued together by compression, which are the side 115 with the adhesive 126 (varnish) applied to it and the disk 122, when heat is supplied above room temperature, but lower than the temperature of thermal compression of the disk 122.

 The filling of the hollow cylinder 110 with getter material 116 and the glue application procedure can take place in a protective casing or other protective atmosphere. A preferred protective atmosphere is argon, which then fills the recess 108 and protects the getter material 116.

Figure 2 shows another preferred embodiment of a temporary protective vessel 200 for a reactive non-volatile getter barium alloy against unwanted gas until an explosion occurs. It contains a first rectangular sheet 202 of heat-resistant rigid polyvinyl chloride. It has an upper surface 204 that is coated with a layer 206 of evaporated aluminum. The rectangular sheet 202 comprises a rectangular recess 208 for containing a getter alloy. Thus, the collar 210 remains on the upper surface 204 having four sides. The first two sides 212, 212 'are parallel to each other and essentially the same width. The remaining two sides 214, 214 'are parallel to each other, but side 214' has a large width. Then, heat-sensitive varnish 216 is attached to the layer of evaporating aluminum 206 and partially overlapping it, whose gluing temperature is higher than room temperature but lower than the heat-shrink temperature of the second rectangular sheet of heat-shrinkable organic plastic material. There is a second rectangular sheet 218 of heat-shrinkable organic plastic material, which corresponds to the upper surface 204 of the first rectangular sheet 202. The shrinkage direction indicated by arrows 220, 220 'parallel to both first sides 212, 212' having substantially the same width. The heat-sensitive lacquer 216 is hermetically sealed and adhered to the second rectangular sheet 218, and when the protective vessel 200 is heated to a temperature lower than 150 ^° C, the thermally compressible organic plastic is compressed to expose the barium getter to residual gases. Since side 214 'is wider than side 214, heat shrink preferably occurs in the direction of arrow 220'.

 It is advisable that the metallization of plastic materials can occur on one or both surfaces of the sheets 202 and 218, and especially on those surfaces that are in contact with the heat-sensitive varnish to facilitate adhesion. However, if this is not the case, it is preferable to be able to visually observe the presence of a non-vaporizing getter material. Moreover, one should carefully monitor changes in physical shape or color in order to know whether gas is adsorbed as a result of sealing defects.

 A glue layer may also be applied to one of the two surfaces, moreover, to that which must be hermetically sealed, for example, either to the first sheet of heat-resistant material or to the second sheet of heat-compressing material.

 Protected getter materials are any getter materials that react with residual gases, but preferably are getter materials that are barium alloys.

Examples of such materials are reactive non-volatile getter barium alloys, which include an alloy Ba _z + (Ba _1-x A _x ) _n B _m , in which A is a metal selected from the group consisting of elements of group IIa of the periodic system of elements, with the exception of barium; B a metal selected from the group consisting of elements of groups Ib, IIb, IIIa, IVa and Va of the periodic system of elements; n 1, 2, 3 or 4; m 1, 2 or 5; 0 ≅ x ≅ 0.5; 0 ≅ z ≅ 0.5 means that total barium is not more than 95 weight.

 Such alloys are described in pending Italian application N M191A001036 dated April 16, 1991 of the same applicant.

Other examples are reactive non-volatile getter barium alloys, which include Ba _1-x A _x Li _4-y B _y alloy, in which A is a metal selected from the group consisting of elements of group IIa of the periodic table of elements, with the exception of barium; B a metal selected from the group consisting of elements of group IIIa of the periodic table of elements, and magnesium; 0 ≅ x ≅ 0.8 and 0 ≅ y ≅ 3.5.

 Such alloys are described in pending Italian application N M191A001038, filed April 16, 1991 by the same applicant.

 Changes may be made similar to those shown in FIG. 3, a protective vessel 300 is provided comprising a first sheet of thermostable material 302, an adhesive 304, and a second sheet of heat-shrinkable organic plastic material 306. A grid 308 is also provided in the form of beams 310, 310 ′ that ensure that the getter material 312 remains freely held on the location after shrinkage of the heat-shrinkable material 306. FIG. 4, a protective vessel 400 is shown comprising a first sheet of thermostable material 402 without a recess on its surface, adhesive (not shown) and heat-shrinkable organic plastic 404. The heat-resistant material 402 is glued to the sides 406, 406 ', 406' 'and 406' '' to material 404. A cutting edge 408 is used on the base 410 so that when the heat-shrinkable material begins to shrink with heat applied, the cutting edge 408 provides a preferred tear zone. The cutting edge 408 may be replaced by a needle or other tear-causing tool.

Example 1. A series of protective vessels, consisting of rectangular recesses with a depth of 3 mm and a size of 3 cm x 1.5 cm, was made in a continuous tape of layered nylon (20 μm) aluminum (45 μm) PVC sheet from CARCANO of Mandello Lario (Somo ), Italy. In a protective casing in a neutral atmosphere of argon gas, the recesses were filled with 1 gram of Ba _0.5 Ca _0.5 Al _0.8 alloy, broken into pieces of less than 0.5 mm in diameter.

A sheet of colorless Alfaclear OR K 265 of a heat-shrinkable PVC strip 75 microns thick from Alfacherm Industrial S.R.A, Venegono Superiore (Varese), Italy, was coated on one side with varnish UA 276, which was dried in a stream of air heated approximately to 40 ^o C. Then it was placed in a protective casing and each filled recess was closed with a heat-compressing strip and glued by applying heat and a slight pressure to the sides of the recess at a temperature of less than 73 ^o C, at which the thermo-compressing plastic is compressed. The filled protective vessels were then separated from each other.

Example 2. A protective vessel made according to example 1 was placed in a vacuum enclosure. Then it was heated and when the heat-shrinkable material reached 73 ^o C, it was compressed in length by 50% in order to expose the getter alloy to undesirable gas.

The getter materials protected by the protective vessels of the present invention can be placed in enclosures in which a vacuum must be created or the vacuum therein maintained and where the temperature must not rise above 150 ^o C. A temperature above 150 ^o C causes excessive gas evolution or degassing and gas formation due to thermal decomposition of the structural components of the fence. Such barriers can be, for example, barriers used for vacuum insulation in industrial or domestic refrigerators or deep-freezing plants and wherever organic or inorganic insulation materials are used in vacuum conditions: insulating double glass panels, vehicle walls, etc. and generally thermal insulation of houses and office premises.

 The totality of patent claims involves the protection of a protective vessel when a sheet of heat-shrinkable plastic encloses a getter material, as well as when the protective vessel was heated, similar to how a heat-shrinkable material that shrinks is heated by exposing the getter material to residual gases.

 Although the invention has been described in detail with reference to several preferred examples of its implementation, intended to enable specialists to take advice on how to best implement this invention, other changes may be made to it without departing from the concept and scope of the attached patent claims.

Claims (14)

 1. A protective package for getter material containing two walls, a cavity located between them and a getter material placed in the cavity, characterized in that the first wall is formed from a sheet of heat-resistant material, the second from a sheet of heat-shrinkable plastic material, while the cavity is formed by a recess made in a sheet of thermostable material, and the sheets are interconnected by means of glue.  2. Packaging according to claim 1, characterized in that the thermostable material is metal.  3. The packaging according to claim 2, characterized in that the thermostable material is aluminum.  4. Packaging according to claim 1, characterized in that the thermally stable material is plastic.  5. Packaging according to claim 4, characterized in that the thermostable material is polyvinyl chloride.  6. Packaging according to claim 4, characterized in that the thermostable material is polystyrene.  7. Packaging according to claim 1, characterized in that the thermostable material is a layered material comprising layers of nylon, aluminum and polyvinyl chloride.  8. Packaging according to claim 1, characterized in that the adhesive is a varnish, the adhesion point of which is higher than room temperature, but lower than the shrink temperature of heat-shrinkable plastics.  9. Packaging according to claim 8, characterized in that the varnish is polyurethane diluted in ethyl acetate. 10. Packaging according to claim 1, characterized in that the shrink temperature of the shrink material is less than 150 ^o C.  11. Packaging according to claim 1, characterized in that the getter material remains held in place when the shrink material is pulled together.  12. The packaging according to claim 1, characterized in that it is equipped with a tool for tearing it. 13. The packaging according to claim 1, characterized in that if the getter material is a reactive non-evaporative getter alloy of barium, the sheet of thermostable material is made of polyvinyl chloride and has a rectangular shape, the upper surface of the specified sheet is covered with a layer of evaporated aluminum, the recess has a rectangular shape and made with a side in the upper part having four sides, pairwise parallel to one another, two of which are of equal width, and the other two are made unequal in width, while the layer of grazing Wren aluminum is coated with heat-sensitive varnish, the adhesion point of which is higher than room temperature, but lower than the temperature of the heat shrink sheet of heat-shrinkable plastic material, while the sheet of heat-shrink material has a rectangular shape corresponding to the shape of a sheet of heat-resistant material, the sheets are glued one to another so that the direction of shrinkage shrink material parallel to the sides of the side having the same width, and the packaging is made so that when it is heated to a temperature below 150 ^o Shrinkable organic plastic is pulled together to expose the barium getter to residual gases. 14. The package according to p. 10 or 11, characterized in that the reactive non-volatile getter of barium contains an alloy of the formula
Ba _z + (Ba _1-x A _x ) _n B _m ,
where A is a metal selected from the group consisting of elements of group IIa of the Periodic system of elements, excluding barium;
In a metal selected from the group consisting of elements of groups Ib, IIb, IIIa, IVa and Va of the Periodic system of elements;
n 1, 2, 3 or 4;
m 1, 2 or 5;
0≅x≅0.5;
z from 0 to such a value that the total amount of barium is not more than 95 wt.

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