DE4404669A1 - Thermally switchable electrical short-circuiting link, and a method for its production - Google Patents

Abstract

The invention relates to thermally switchable electrical short-circuiting links in conjunction with a resistor component, which generally has a low resistance, which have common bases for the resistance and short-circuiting function connections, and a method for their production. A short-circuiting bracket which is firmly connected in DC terms to a base connection presses with a defined force against the second base connection, which is covered with a non-conductive coating. This coating consists of a dried solder paste whose solder alloys are present in a grain band of 3 to 100 mu m and are micro-encapsulated with organic polymers. An irreversible solder contact to the second base can be initiated in the adjustable temperature ranges from 70 to 260 DEG C in response to thermal influences resulting from an increased calorific amount of heat being developed in the resistor component. This ensures that the electronic or electrical apparatuses are protected in the event of a defect, and that the risk of fire is avoided.

Description

The invention relates to thermally switchable electrical shorting bridges and Ver drive to their manufacture, which in the event of an electrical overload close irreversible solder contact and the actual electrical device functions Protect in the event of an accident. Accordingly, it is used in electronics and electrical devices and should functionally protect these After eliminating the source of interference, devices also rule out fire eat. This principle of operation and the corresponding switching arrangement are always in Combined with a mostly low-resistance electrical resistance.

Devices of the type described above are made with different components or Assemblies equipped, including inrush currents and overvoltages as Short-term or longer-term energy quantities are taken into account:

• - device fuses,
• - fuse resistors,
• - bimetal contacts,
• - Field plates, the switching function on an excessive magnetic flux exercise
• - Combinations of the z. B. aforementioned security elements with irreversible Switches, relays and. a.

If there is an irreversible shutdown of these devices under the mentioned Randbe special value is the triggering of a short circuit in the Power supply of particular interest. In these cases, the external Security elements activated and justify the above Protection requirements.  

An internal component is expedient here, which operates at certain temperatures triggers an irreversible short circuit through a soldering process. This arrangement is initiate physically and to design so that only a certain Temperaturbe rich causes the short-circuit soldering and guarantee long-term operational readiness is achieved. Here, an inexpensive solution must be used universally justify.

From the accessible state of the art, a technically satisfactory on all sides Solution can not be determined.

The object of the invention is that of the known prior art to eliminate adhering defects by according to the preamble of claim 1 a thermally irreversible switchable short circuit bridge in combination with a mostly low-resistance electrical resistance as device protection and fire protection element ment is used. In this case, a soldered connection should be one under a mechanical Voltage shorting bar by exceeding adjustable thermi levels can be reached. This assumes that the contact point with ge suitable substances up to the thermal insulator level has properties. This task closes the process engineering Concern for the realization of these component switching functions.

According to the invention, this task according to the characteristic Features of claims 1 and 6 solved in that an organic insulation encapsulated solder metal and with organic auxiliaries that fix and have paste-forming properties and flux effects, between the Short-circuit contacts are arranged. This is one for the application designed compact solder alloy in a high temperature organic flux melted and with the help of the flow dispersion process into one Grain belt from 3 to 100 ○ m led. After the sedimentation of the solder balls the organic liquid is decanted or aspirated in such a way that the sediment remains covered. With a solvent that is compatible with the high temperature or ganic liquid does not mix, the sediment is added by a stirring process  lower speed added and z. B. with an oligomeric melamine resin solution transferred. The microencapsulation or particulation takes place with moderate heat, whereby Various agents can be added to ensure even separation of the oligomeric phase to form a polymeric and dense coating on the solder balls permitted and acid hardening of this phase.

In this process, the remaining high-temperature organic liquid is led to a fine emulsion, the spherical individual coagulates of which are also microencapsulated with the same shell material. Since the difference in density between the two capsule types is above 6 to 1 (in the dimension g · cm ^-3 ), the quantitative separation can be carried out in a simple manner using various methods. It is understood that this anaerobic technology provides solder particulates that consist only of the components of the solder metal and the capsule shell material.

Of the numerous processes for the production of microencapsulated active ingredients, for Carbonless papers, screw locks, pharmaceutical applications, Adhesives and a., the following are relevant:

• - Complex coacervation between positively and negatively charged (colloid) poly meren, the reaction conditions over pH and temperature positions are effected. (ARMADEO, C., BENOIT, J.P., THIES, C ,; STP Pharma 2, (15), 303-306 (1986); BECHARD, S., McMULLEN, J.N ,; Pharma 31, 91-98 (1986).
• - Polymerization to form various wall materials, the capsule formation from internal diffusion processes of dissolved polymers to the polar solvent. (HARMIA, T .; SPEISER, P .; KREUTER, J .; Int. J. Microencapsulation, 3 , 3-12, (1988).
• - spray drying and similar processes, e.g. B. Spray with a more fabric nozzle or enveloping by means of a rotating disc DE 27 46 489 (1979) and DD 2 39 951 (1986).

The complex coazer is particularly suitable for the present applications  vation procedure, since this is the cheapest possible result in anaerobic microencapsulation of the solder particles. The exclusion of Sauer substance and other reactive substances prevents a chemical change in the pure spherical solder metal surfaces. That is a requirement for the functional reflow soldering process for short circuit formation is crucial is.

The separated microencapsulated solder particles are led to a micro solder paste according to the usual procedure, which is usually transferred to the base contact by means of the also usual methods of screen printing, stencil printing, dispenser orders up to a layer thickness of a few ½ mm. After the solvent, which is necessary for rheology adjustment, has evaporated, the switch contact is placed on with a compressive stress of approx. 200 p · cm ^-2 . For the reasons of the long-term stability of the switching system, it is advisable to provide both the base contact before the coating and the active surface of the pressure contact with a gold layer of approximately 100 nm. This enables trouble-free reflow solder contact. The switch contact is in turn fixed on the other base contact, for example by a spot welding process. Between these two base contacts, the low-resistance resistor component is arranged in a suitable film or layer form by conventional methods, chemical, mechanical or optical balancing methods being used here for setting the effective resistance.

If the film or sheet resistance is overloaded due to a fault in the downstream electronic or electrical device increases JOULE operating temperature of the resistance / short-circuit element and leads to Activation of the soldering process triggering the short circuit. The trigger temperature is due to the suitable choice of the micro solder paste composition within wide limits adjustable. The main parameters are:

• Melting point or interval of the solder phase used,  
• - type of organic capsule shell materials,
• - Activity of the flux integrated in the pastes.
• - Types of media and rheological materials.

Based on material studies, these are the trigger temperatures to realize in the temperature range of 70 to 260 ° C, being relatively narrow Switching temperature fixed points can be established at approx. 20 K intervals. The The basis for these manufacturing processes of suitable systems are in the Thick film paste literature (solder, conductive, resistance, sensor and polymer pastes) described in detail.

For the present subject matter of the material composite, the following are relevant to the substances:

• - Metal phases: all known low and high melting solder alloys stanchions,
• - Print media: from natural to high temperature polymers,
• - Solvents: terpineols, carbitols, aliphatic and aromatic (mostly polar) species,
• - Flux: all known low and highly effective organic and inorganic modifiers.

For the paste mixture, it is advisable to use an anaerobic process such as e.g. B. described in DD 2 14 479 (1984). The storage of the microlotpa Most can be done analogously to the usual solder pastes with unencapsulated metal phases. The same applies to application technologies.

Since conventional solder pastes always have a relatively high electrical conductivity,  they cannot be used for the operating principle according to the invention.

The microencapsulated solder metal paste system is supposed to be a technological gap for the close the device and fire protection mentioned above and also a enable practical and inexpensive application.

Embodiment

For the principle of operation of the subject matter of the invention and its manufacturing process the electrically non-conductive phase between the switching is particularly interesting contacts is arranged and when reaching a defined temperature triggers a short circuit solder contact. For practical reasons, this phase realized on the basis of solder pastes, which in contrast to conventional Paste systems consist of electrically insulated solder alloy particles. Therefore, the embodiment is primarily on the manufacture of the solder metal micro particulates and their microencapsulation designed.

Comprehensive information on the implementation of the microencapsulation process can be found in the following quotes:

• - SLIWKA, W., microencapsulation, Angew. Chemie, 87, pp. 556-567 (1975),
• - ULLMANN, Encyclopedia of Technical Chemistry, Vol. 16, 675 ff.,
• - BORNSCHElN, M., MELEGARI, P., BISMARCK, C., KEIPERT, S .; Pharmacy, 44, 585-593 (1989),
• - JP 01 54 081 (89 54 081), (1.3.1989),
• - DIETRICH, K., BONATZ, E., et al, Acta Polymerica, 40, 325-331 (1989) "Amino resin microcapsules"

300 ml of castor oil ("Kastoroil") according to DAB 10 are heated to 220 to 230 ° C in a vessel in a vessel and 70 g of the tin / lead eutectic LSn 63 are melted in a rod shape. A ULTRA-TURRAX disperser is installed a few mm above the metallic sediment and operated at a speed of 14,000 min ^-1 over a period of 240 to 300 s. Castor oil is suitable for this process because of its temperature resistance and the relatively high viscosity even at higher temperatures. At the same time, there is a cleaning effect because of the oil's unlocking effects against impurities in the specified conditions, so that at least the metal surfaces can be refined.

This flow dispersion converts the metallic sediment into a grain band of 3 to max. 100 µm ball diameter. The stability of this system results from the high surface energies of the solder metal balls. At a speed of the disperser of approx. 700 min ^-1 , the dispersed system is cooled down to 60 ° C.

The castor oil located above the deposited metal phase is then suctioned off, care must be taken to cover the metal phase and a solvent immiscible with castor oil is added. A paddle stirrer is then set to a speed of 2000 min ^-1 and a PIAMID solution (partially methylated etherified melamine-formaldehyde resin with a solids content of 50% by mass) is gradually introduced.

The addition of the citric acid catalyst and polyethylene glycol (n approx. 2000) leads to the encapsulation of the fine spherical suspended metal phase and the emulsified castor oil phase. The stirring is then reduced to a speed of 500 min ^-1 and this dispersion is kept at a temperature of 60 ° C. for 60 min. After a post-curing time of 240 min at room temperature, the microencapsulated solder balls are separated and washed with a solvent.

Since the remaining castor oil is also encapsulated quantitatively in the microencapsulation process described, the separation takes place in such a way that the encapsulated organic phase is first completely flotated. This operation can be carried out quickly and easily due to the large difference in density of both capsule types from above 6 to 1 (in the dimension g · cm ^-3 ). Then the washing process is carried out, the task of which is to remove the coacervation solution from the encapsulated metal microparticles.

This batch procedure is due to a suitable apparatus arrangement to be carried out continuously according to modified equipment, whereby CIM integration is expedient via a simple sensor system.

This is microencapsulated under inert conditions in gas or liquid phases To store solder powder over long periods and to transport it over any distance animals. Of course, this also includes the immediate production of fine-grain solder pastes locked in. All of the usual restrictions in this regard are met by the Subject of the invention and its manufacturing process canceled.

For the application of the subject of the invention as a thermally switchable short-circuit bridge, reference is made to the following drawing ( Fig. 1). The substrate ( 1 ) consists of an anodized aluminum sheet, on which the base or connection contacts ( 2 ) and a balanced resistance layer ( 3 ) are arranged. On the base contact field ( 4 ) a contact bracket ( 6 ) is fixed, which presses with a mechanical load of approx. 200 p · cm ^-2 on the base contact field ( 5 ).

From the detailed drawing ( Fig. 2) it can be seen that the base contact field ( 5 ) was coated with the micro solder paste ( 7 ) before the contact bracket assembly ( 6 ).

Claims (8)

1. Thermally switchable electrical short-circuit bridge in connection with a mostly low-resistance component, which have common bases for the resistance and short-circuit function connections, characterized in that when a certain temperature is reached under mechanical tension, the shorting bar is irreversibly soldered, whereby
a. the shorting bar is attached to a base contact of the resistance component,
b. the other base contact is covered by a solder paste, the microparticulated metal alloy content of which is microencapsulated with an organic insulating material,
c. the base contact was gold-plated before coating,
d. the shorting bar is clamped onto the coated base contact,
e. the soldering zone of the shorting bar is gold-plated,
f. a predetermined increase in resistance temperature triggers the soldering process. 2. Thermally switchable electrical shorting bridge according to claim 1, characterized characterized in that the microencapsulated solder pastes by appropriate material compositions the short circuit soldering process in the required manner and in ge the desired temperature range from 70 to 260 ° C. 3. Thermally switchable electrical shorting bridge according to claim 1 and 2, characterized in that the microencapsulated metal alloys in one Grain band from 3 to 100 µm are present and from a dense organic insulating cover are surrounded, whose thickness is in 10 to 100 nm ranges. 4. Thermally switchable electrical shorting bridge according to claims 1 to 3, characterized in that the microencapsulated solder pastes according to the soldering tempera due to activity-graded organic and / or inorganic flow are equipped.   5. Thermally switchable electrical shorting bridge according to claims 1 to 3, characterized in that the microencapsulated solder pastes according to the soldering tempera due to natural and / or high-temperature polymers as pressure medium materials. 6. A method for producing a thermally switchable electrical short circuit in connection with a mostly low-resistance resistor component, which have common bases for the resistance and short circuit function connections, characterized in that, according to FIG. 1, a shorting bar ( 6 ) by means of welding technology with the contact field ( 4 ) and with a mechanical tension of about 200 p · cm ^-2 on the contact field ( 5 ) coated with a microencapsulated insulating solder paste and in Fig. 2 ( 5, 6 ). 7. Process for the production of thermally switchable short-circuit bridges Claim 6, characterized in that solder metals of different melting points after the flow dispersion process to a spherical grain band from 3 to 100 microns and by the complex coacervation method with a polymer Resin shell in the 100 nm range provided by a conventional method to a solder paste processed and arranged between the switch contacts. 8. A process for the production of thermally switchable short-circuit bridges according to claims 6 and 7, characterized in that the area areas adjacent to the microencapsulated solder paste and intended for soldering according to Fig. 2 ( 5 ) and ( 6 ) with a gold coating in the 100 nm range be provided by known methods.