WO2006070426A2

WO2006070426A2 - Process for manufacturing devices carrying at least one active material by deposition of a low-melting alloy

Info

Publication number: WO2006070426A2
Application number: PCT/IT2005/000744
Authority: WO
Inventors: Daniele Martelli; Alessio Corazza; Giovanni Salvago; Luciano Pisoni
Original assignee: SAES Getters SpA
Current assignee: SAES Getters SpA
Priority date: 2004-12-27
Filing date: 2005-12-20
Publication date: 2006-07-06
Anticipated expiration: 2007-06-27
Also published as: RU2395617C2; AR051868A1; US8071172B2; BRPI0519499A2; DE602005027902D1; ATE508213T1; JP2008527163A; CA2590987A1; EP1834006B1; WO2006070426A3; EP1834006A2; CN101090989A; ITMI20042516A1; MX2007007875A; WO2006070426A8; JP4988594B2; MY139734A; US20090022892A1; TW200639272A; CN101090989B

Abstract

A process manufacturing devices (21, 21') that carry an active material is described, based on the continuous deposition of a strip of low-melting alloy in the liquid state on a ribbon (1') of a metal net (12) or a micro-perforated and stretched sheet metal (12) , which surface has been previously treated , for example by means of deoxidation, and preferably prepared for the successive cutting in single components or rather devices (21, 21' ) with active material. The deposition can occur by immersion into laminar waver on into a constant jet, by spraying of small drops or by liquid dispensation.

Description

"PROCESS FOR MANUFACTURING DEVICES CARRYING AT LEAST ONE ACTIVE MATERIAL BY DEPOSITION OF A LOW-MELTING

ALLOY"

The present invention relates to a process for manufacturing devices that carry an active material, particularly on a lateral edge thereof, based on the deposition of a low-melting alloy.

Numerous applications are known in the prior art, which require that inside a manufactured product a material is introduced that has a specific activity, necessary for the correct functioning of the manufactured product itself. Of particular relevance among these applications is that regarding the production of lamps, whereby in the following description reference is made to devices used in gas lamps, keeping however in mind that the process according to the invention can be advantageously utilized to manufacture devices also for different uses. In the gas lamps industry it is known that various active materials have to be introduced into the lamp, e.g. compounds for mercury release, amalgams for the pressure control of that element in the case of fluorescent lamps, getter materials for the removal of undesired gases from the internal atmosphere of the lamp, which may damage the functioning thereof, or materials emitting particular gases, such as oxygen. The use of these materials, as well as the devices that allow their introduction into the lamps, are the subject of numerous documents, such as e.g. the patents US 3,764,842, 3,794,402, 4,056,750, 4,182,971, 4,278,908, 4,282,455, 4,542,319, 4,754,193 and 4,823,047 and Japanese patent applications A-60- 193253, A-06-096728 and A-06-076796, all relating to devices for introducing inside lamps elemental mercury or a material capable of releasing this element; the patents US 3,525,009, 4,461,981 and 4,855,643 that relate to getter devices for the use in lamps; the patents US 5,825,127 and US 6,043,603 and the publication EP-A-0359724, relating to devices that combine, integrated to each other, both the functions of mercury release and of gettering; the patents US 5,789,855 and US 5,798,618 that relate to amalgams for the mercury pressure control inside the lamp; or the patents US 3,519,864 and US 6,169,361, that relate to devices for the oxygen release at the inside of lamps.

The devices described in these patents are generally manufactured by introducing the active material in a container or by applying it on the surface of a support, and then by fixing said container or support to an adequate prop, which is then mounted in a pre-determined position in the lamp.

However, the manufacturing of these devices is generally rather complex, requiring the mechanical shaping of (generally metallic) small size parts and the assembly of these to each other in various ways. The problem becomes even more serious when considering the present tendency in the lamp industry to miniaturization, which imposes that also the above-mentioned devices be miniaturized. This miniaturization involves furthermore also a greater control, both geometrical and dimensional, of these devices, because in the finished lamp these are all arranged in the same zone (the terminal portion of the lamp or at most the two terminal portions in the case of tubular lamps), while it must be avoided that these devices come into contact with the electrodes or their supports. A contact of this type could in fact change the lamp functioning. Moreover, adopting production processes in which the device is manufactured by assembling (mechanically or through welding) pre-formed parts results in a reproducibility problem as to the shape and size of the finished devices. Another problem that arises in the production of said devices, made more serious by the miniaturization thereof, is that in some instances it is possible to have particularly delicate manufacturing steps that imply a possible risk of compromising the semimanufactured product. For example, in the case in which a device must be manufactured provided with an amalgam for the mercury pressure control, introducing the amalgam into (or affixing onto) the final piece turn out to be complex operations, that require the mechanical moving of a piece, generally having non-planar shape. On the contrary, working a part already having the amalgam thereon, e.g., performing a welding between this part and its support, may compromise the adhesion of the amalgam itself on said part. Finally, all these constructive problems result in relatively high costs of the devices, especially when referred to the low selling price of the lamps, whereby their use is often limited by economical reasons.

The object of the present invention is to provide a process for manufacturing devices carrying an active material, which is free of the above listed problems of the prior art. Said object is obtained according to the present invention with a process that comprises the steps of preparing a ribbon of a metallic material and depositing along a lateral edge of said ribbon at least one strip of active material in the form of a low-melting alloy in the melted state, characterized in that said ribbon is formed of a metal net or a perforated metal band, pre-treated to eliminate passivated surface layers.

The single devices can then be obtained by cutting adequate sections of said ribbon, which can be beforehand prepared for cutting by a preliminary punching step through the introduction of parallel transversal weakening lines.

These and other objects, advantages and characteristics of the process according to the invention will be clearer from the following description, given by way of a non limiting example, with reference to the annexed drawings wherein:

Fig. 1 shows a schematic view, in a top plan view, of an example of carrying out the process according to the invention; and

Fig. 2 shows a view, also schematic, of a segment of the ribbon used in the process according to the invention, after the deposition of the layer of active material, according to one of the equivalent methods exemplified in Fig. 1, from which some devices are formed by cutting (in the drawing three pieces are shown).

The ribbon may be a simple metal net or, alternatively, a so-called "stretched micro-perforated sheet metal"; this latter product (simply referred to as stretched sheet metal in the following) is obtained by practicing micro-holes in a metal band, preferably ordered in an ordered pattern on the band, and then stretching the band so as to cause a widening of the holes. The use of the metal net ribbon or stretched sheet metal in the process according to the invention allows avoiding any step of fixing a support to the part of the device on which the active material is provided, and also the steps for the containment of the active material in those devices which would require it. In fact, the material in question, in the form of a low-melting alloy in its melted state, ensures its perfect adhesion to the perforated substrate owing to the dimensional characteristics of the holes and to the morphology of the areas of the metallic ribbon between the holes, which as a result of the perforation step have a non-planar surface but slightly drawn between adjacent holes, thus resulting to form a preferential path along which the melted material rises due to a phenomenon similar to capillarity, thereby wetting the whole surface onto which the active product must be applied.

Both the metal nets and the stretched sheet metal bands used in the process according to the invention are commercially available and are sold, e.g., by the company Fratelli Mariani S.p.A. of Milan, Italy. It is essential for the purpose of the present invention, that the nets or stretched sheet metal bands forming the substrate for the devices to be produced, are previously treated in a such way to remove the passivated surface layers, mainly of oxide but also of greasy substances, normally present on the metal in order to allow a good adhesion of the deposited alloy on the ribbon itself. For this purpose use can be made of steps of mechanical surface abrasion or of acid solutions or corrosive components suitable for the removal of the passivated surface layers. For this purpose deoxidizing or pickling liquids or powders are known, capable of attacking the thin films of oxide and possibly of grease present on the metal surface.

It is further fundamental that the substrate has optimal dimensional characteristics to capture in its perforated structure a certain amount of melted alloy in a precise and reproducible way. The size of the holes must be sufficiently small in order to keep the liquid alloy from the formation of drops or percolation. It has been found that the preferred geometric characteristics, particularly to exploit the phenomena of capillarity to fill holes and channels with the alloy, are related to the thickness of the substrate, the dimensions of the holes and the centre distance between a row and/or a column of holes and the adjacent one. The first value, relative to the thickness, is between 0.20 and 0.50 mm; the second dimensional value, relative to the holes of the ribbon of sheet metal which forms the substrate is such that a circle inscribed therein has a diameter that is smaller than 0.45 mm, while the above-mentioned centre distances will be between 0.55 and 1.10 mm, with a ratio between the holed area and the solid material of the overall surface between 12 and 25%.

With reference to Fig. 1, the process according to the present invention is schematically represented by showing the ribbon of stretched metal sheet 1 coming from the perforation being continuously unrolled from a coil 10 that rotates in the sense of the arrow F moving forward in a vertical plane, perpendicular to that of the drawing. Ribbon 1 first encounters a station for surface treatment 2 to eliminate the passivated surface layers by mechanical or chemical deoxidation action, as previously mentioned, necessary to allow the following deposition of the liquid alloy which occurs downstream along the path of ribbon 1, in the station schematically indicated by the block 3, from which ribbon I' comes out with the active product deposited along the lower edge, opposite to that visible in Fig. 1, over a pre-established width of the lower lateral edge, to be then wound up on a coil 11 on the right side, rotating in the direction of the arrow F'. Of course means are provided to put into rotation said coil 11 and possibly coil 10, which instead can be idle and pulled into rotation by the ribbon itself.

The ribbon is better shown, in front view, in Fig. 2, where the edge 13, covered with active material made of a low-melting alloy, applied in the melted state in correspondence with the operative block 3 of Fig. 1, is distinguished from the substrate 12, perforated and possibly subjected to a surface pre-treatment.

Low-melting alloys suitable for the purpose are e.g. indium-based alloys with a high content of that element, such as binary indium-silver or indium-tin alloys or ternary indium-silver-copper or indium-silver-nickel alloys containing in any case at least 80% by weight of indium. Other materials with suitable characteristics are bismuth-based alloys, for example bismuth-indium alloys, bismuth-tin alloys or ternary alloys such as bismuth-tin-lead alloys, containing in any case at least 50% by weight of bismuth. Still with reference to Fig. 2, there is shown schematically how ribbon 1 ' is subsequently cut in the direction orthogonal to its longitudinal extension so as to obtain the desired single devices 21, 21'. To facilitate the cutting operation, ribbon 1 can be prepared, before or after the surface treatment 2, with adequate weakening or punching lines, along which the feet 22, 22' of each device can be obtained, apart from some easily eliminable off-cuts, each foot being narrower than the head zone 13, 13', ...., carrying the active material.

The deposition step of the low-melting alloy in the liquid state can be performed in various ways, among which the following can be mentioned: a) by partial immersion into a laminar standing wave, as known in technique for example in certain welding applications; b) by partial immersion into a liquid jet or gush kept at constant level; c) by spraying of small drops from a suitable nozzle; and d) by liquid dispensation from a suitable dispenser.

When the process is finished, and the active product of strip 13 along the edge of ribbon 1 ' is stabilized, the ribbon itself can undergo a new process as in Fig. 1, by letting it pass through the surface treatment station 2 and the deposition of liquid alloy 3 with inversely positioned edges, i.e. with the already deposited strip 13 turned upwards (as in Fig. 2) so that the edge opposite to that of the strip 13 can undergo the surface treatment (if not already done in view of the first deposition), to obtain thereon a symmetric strip of an active product according to one of the previously-mentioned methods, in the operative block 3 of Fig. 1. In this way a ribbon will be obtained having on both opposite edges thereof a strip of deposited active material, whereby with a median longitudinal cut it is possible to have two symmetric ribbons from which a double series of single devices as 21, 21' can be obtained. Before proceeding to the cutting of the ribbon as described above to obtain the single desired devices, if the deoxidation operation has left residuals, a further washing step can be foreseen for their elimination.

The invention will be further illustrated by the following examples. Example 1 A ribbon of stretched sheet metal of nickel-plated iron, having a thickness of

0.35 mm, a square mesh perforation with a diameter of the circle inscribed in each hole of 0.28 mm and the centre distances between the rows of holes equal to 0.71 mm and between the columns of holes equal to 0.85 mm, in which the thickness of the nickel layer is of about 1 μm, is subjected to a surface deoxidation treatment and then immersed in a bath of an alloy in the liquid state having weight percentage composition In 94% - Ag 6%, thereby succeeding to capture an amount of material equal to 110.8 ± 6.0 mg/cm². Example 2

The test of example 1 is repeated, with the only difference that the ribbon is wetted with the liquid alloy, rather than by simple immersion of the edge into the bath, by passage thereof in vertical position through a laminar wave of the liquid alloy, thus obtaining the capture of 110.2 ± 3.3 mg/cm² of alloy, namely with a smaller margin of uncertainty. Example 3 The test of example 1 is repeated using a ribbon of stretched sheet metal of nickel-plated iron having a thickness of 0.40 mm, a square mesh perforation with a diameter of the circle inscribed in each hole of 0.26 mm and the centre distances between rows of holes equal to 0.84 mm and between the columns of holes equal to 0.95 mm, in which the thickness of the nickel layer is of about 1 μm; the amount of In-Ag alloy captured is equal to 112.8 ± 5.4 mg/cm². Example 4

The test of example 3 is repeated, adopting however in this case the wetting method of example 2 (passing the metal band through a laminar wave of the liquid alloy). Also in this case a higher reproducibility is obtained, with a loaded amount of 110.8 + 3.5 mg/cm². The examples show that the process of the invention is capable of producing metal nets or micro-perforated bands with deposits of desired materials without any formation of drops or abnormal material deposits, characterized by highly reproducible amounts of deposited material, in particular when the wetting method employed is by passing the net or band through a laminar wave of the liquid material.

Claims

1. Process for the mass-production of devices (21, 21', ...) carrying at least one active material, comprising the steps of preparing a ribbon (1) of metallic material and of depositing along a lateral edge of said ribbon at least one strip (13) of active material in the form of a low-melting alloy in the melted state, characterized in that said ribbon (1) is formed of a metal net or a perforated metal band, pre-treated to eliminate passivated surface layers.

2. Process according to claim 1, characterized in that said ribbon of metallic material has a thickness between 0.20 and 0.50 mm; the dimensions of the holes are such that a circle inscribed therein has a diameter smaller than 0.45 mm; and the centre distance between adjacent rows or columns of holes is between 0.55 and 1.10 mm.

3. Process according to claim 1, wherein at least said lateral edge of said metallic ribbon is caused to pass continuously through a pre-treatment step (2) in a deoxidizing bath and, subsequently, into a bath (3) of a low-melting liquid alloy.

4. Process according to claim 1, wherein said low-melting alloy is a binary or ternary indium-based alloy comprising at least 80% by weight of indium.

5. Process according to claim 1, wherein said low-melting alloy is a binary or ternary bismuth-based alloy comprising at least 50% by weight of bismuth.

6. Process according to claim 3, wherein the deposition of said low- melting alloy occurs by partial immersion of the lower edge of the ribbon (1), held vertically into a laminar wave of said alloy in the liquid state.

7. Process according to claim 3, wherein the deposition of said low- melting alloy occurs by keeping in a vertical position the lower edge of the ribbon (1), that is hit at constant level by a gush or jet of said alloy in the liquid state.

8. Process according to claim 1, wherein, subsequent to the deposition step (3), the ribbon (1') is cut along parallel lines, orthogonal to its longitudinal extension, to obtain said single devices (21, 21', ...) carrying active material.

9. Process according to claim 8, wherein the ribbon (1) is prepared for said cutting operation by punching along transversal lines.

10. Process according to claim 8, wherein, after the deposition step and before said cutting operation, the ribbon (1 ') undergoes a cleaning step for the elimination of residuals of the deoxidation step.