DE2431447A1 - Ignition resistant laminates for printed circuit boards - featuring a non-aromatic non-conjugated resin layer beneath the conductor - Google Patents

Abstract

Boards comprise a metallic film on a support made of layers of resin-impregnated material with a layer (I) of an ignition resistant compsn. adjacent to the metallic film. 70-100% of (Ie comprises a crosslinked resin or elastomer which does not include aromatic gps. or conjugated or heterocyclic organic resins. The boards are used in the mfr. of printed circuit boards which will not ignite when subjected to high voltage or high current arcing or to tracking in the presence of electrolytic contamination across any circuit discontinuity. by use of such products, increased safety of high voltage appliances such as 1400 V electrode circuits associated with colour television tubes is possible. A claimed construction will maintain an insulation resistance of >=1012 ohms.

Description

Printed circuits with little tendency to use the subject matter the German patent ..... (patent application P 24 04 777.6) are laminates, due to the use of aeryl or ketone resins as an anti-inflammatory layer between the carrier material and a metal foil on it, also with the Applying high voltages are flame resistant. The present invention is another Refinement of this patent specification by adding additional materials for use as an anti-inflammatory layer. Laminates and the printed circuits made from it are used as wiring elements used in many electrical appliances. You also take over the mechanical fastening of the components. These printed shades exist made of laminates as carrier material on which one or both sides metallic foil, preferably copper foil, is laminated.

The laminates have cellulose as reinforcement in the form of paper webs, Monofilaments or fiber layers - or synthetic papers or webs or fiber layers made of polymeric compounds such as polyesters or polyamides. In addition, the Reinforcements consist of glass silk fibers in the form of fabrics, fleeces or mats The respective reinforcing materials are first made up in known resin solutions impregnated on the basis of phenolic resins, epoxy resins or other thermosetting resins.

The carrier material is usually made of one or a plurality of stacked layers of laminates built up and can in the same working process on one or both sides with a metal foil, preferably Copper foil.

The metal foil lann to achieve a better dog before the Press coated with a hot melt adhesive on the side facing the laminates will.

The composite material is then known in a hot press Process using heat and pressure, thereby hardening the individual layers be connected to a solid laminate and the metal foil firmly on the laminate k is sheared. This base material is used to manufacture printed circuits In addition to circuits laminated on one or both sides, multilayer circuits are also used, in which several individual circuit boards are first produced and then laminated with the help of uncured prepregs to form a multi-layer circuit will.

In the production of printed circuits arise accordingly the desired line pattern Foil conductor with a certain conductor width and one Thickness from 5 to 200 µ, depending on the thickness of the metal foil used. Already at åer Manufacturing of the circuit board can be caused by bending stresses, e.g. during punching, Hairline cracks appear that cut through the ladder platform.

Such hairline cracks can also be caused by breakage of the guide plates during of the transport arise. Such a tear in the hair can be in the respective circuit cause an interruption, the conductor ends weave only a very small distance from one another, in the range from 5 to 100 µ, have skills. Such Interruption of the circuit can also occur if a component is not working properly is soldered to the circuit board. At the cold joint also interrupt gene, with the respective conductor ends a small distance from each other -The interruptions described above are often not one @ must be determined because the ends of the conductors are in a cold device or in a touch a certain position and the interruption only when heated, when touched or occurs when changing the position, æ.B. by shock. This conversation has the following serious disadvantage: Assume a functional The circuit is only interrupted by one of the above-mentioned influences: As a result the current is interrupted to zero and the whole is at the point of interruption System voltage on Depending on the voltage level and the distance at the point of interruption An arc is created here, which generates temperatures of several thousand ° C.

The intensity of the arc depends on both the voltage itself as well as the possible current strength.

The Vc «gears that occur in the event of such a power interruption can be used with the help of a thyristor-controlled horize tal deflection circuit of a Demonstrate color television set well, because the pulse voltage present there of approx. 1400 volts n.

a deflection current of about 2 amps at a frequency of 15.62 KHz particularly good prerequisites for the formation of a lice bow and the inflammation of Ba. n.material offers (see Figure 1). The associated adverse consequences can be seen better on this Nielse.

The voltage generated at the point of contact ignites the arc, the conductor material impregnated with the thermosetting plastics due to its high temperatures thermally decomposed The Xtherw or methylene bridges of the phenolic or epoxy resins The bisphenol A base can then be split off, so that the proportion of aromatic C bonds in the resins are increased, which ultimately leads to graphite-like properties Structures so that the insulation resistance is reduced from 1012 ohms to a few 10 O'ain will. The point of failure ignites immediately and the low resistance of the point of fire ensures that the current flow is maintained. If you switch off the device, the damaged area burns depending on the flame retardancy of the laminate Meiter, furthermore When observing the inflammation process, it can be seen that the thin copper foil of e.g. 35 µ, as is customary for the production of printed circuits, evaporated due to the high arc temperature Constantly large distance between the conductor ends due to the melting of the foil conductor enlarged. The arc would break off by itself due to the constantly increasing distance, when the voltage and power present in the system cause the arc to exceed the large Damage place can no longer get right. The tearing off, however, is thereby prevents the hot melt adhesive and / or the binder resin from becoming too graphite-like in the arc Structure is transformed. Thus replaced the one under the melting point Copper foil burns plastic because of its good conductivity the foil conductor ict '- u constantly bridges the electrode gap.

The exact causes of printed circuit fires were not yet known, as the above-mentioned examination met @@ de was previously unknown. So far, only the The following test method was applied, but the practical condition of ignition reproduce a printed circuit board only to a limited extent: 1.Leakage current resistance (according to DIN 53 480 or IEC 112), 2nd high-voltage arc test - UL 492 and 3rd high-current arc test UL 492 (UL = Underwriter Laboratories Subject).

When testing for tracking resistance, electrodes from 2 x 5 mm, spaced 4 mm from each other at an angle of 60 ° on the specimen lie. In the limit voltage method, 50 drops of a test liquid are used at intervals of 30 seconds between the electrodes on the laminate. at The limit stress method is used to determine the stress at which 50 drops appear the laminate dripping without a leakage current of I = 0.5 amps occurs.

The high voltage arc test UL 492 (high voltage arc ignition) uses steel electrodes with a diameter of 3.2 mm, spaced 4 mm apart, in one 45 ° angle on the laminate lie. The electrodes puncture a voltage of 5200 volts (alternating current 50 Hz). The time to inflammation will be measured.

For the high current arc test UL 492 (high current arc ignition) one uses a fixed copper electrode with a chisel-shaped tip and a movable one Tungsten electrode with a pyramid-shaped tip Both electrodes have a diameter of 3.2 mm and lie at an angle of 45 ° on the laminate.

The electrodes are opened at an interval of 1.5 seconds so that through the voltage of 240 volts and a short-circuit current of 33 amperes, an electric arc arises. The number of arcs to ignite are counted.

The aforementioned tests are used to assess the inflammation behavior of a printed circuit board only conditional statement * The main difference is in the electrode dimensions and arrangement. While on the circuit board the thin foil conductor can melt off, the electropene are much larger in these tests Dimensions and are also made of a material that prevents it from melting off, whereby other stresses are initiated0 The measures taken so far to reduce the ignition of printed circuits are based on the Base material of the individual laminates by adding flame retardants known per se, such as pentabromodiphenyl ether, to make them more flame-resistant, the modified laminates then meet the conditions stipulated by DIN 53 480 and the UL test method 492 to be placed on them They also offer passive protection against a device fire its consequential damage remains limited because the material only slightly covers the Plamine nortle1-tet and because after removing the arc flame, a.B. by switching off the appliance voltage is only available for a short period of time. Such laminates but do not prevent an arc from occurring at a fault in the conductor rips off. After switching off and switching on the current again, it forms again an arc with its disadvantages described above.

The task was therefore to produce printed circuits, in which one of possibly existing defective areas of the conductor after applying the Voltage created arc no carbon bridges of a graphite structure forms that költen maintain the arc. Rather, it should be prevented that such graphite-like carbon bridges can form, with it a resulting arc breaks off as quickly as possible and the carrier material does not ignites.

In fulfilling this task was in the German patent specification.

(Patent application P 24 04 777.6) called a laminate that is characterized in that between the metal foil and the carrier material a an anti-inflammatory binding layer made of a heat-resistant plastic, which consists of 60 to 100% acrylic or ketone resins. In further fulfillment of the The above task has now also been found that the anti-inflammatory The binding layer also consists of 70 to 90% of such hardenable resins or crosslinkable resins Elastomers can consist of no aromatic groupings and no organic ones contain ring-shaped compounds with heteroatoms and conjugated double bonds.

The inflammatory layer should have a minimum thickness of 20 μ The maximum thickness depends on the type and form of application of the plastics used. It can be up to 300 µ. The preferred range for the thickness of the inflammatory aqueous Layer lies between 30 and 100.3 .. Depending on the composition, this can be anti-inflammatory Layer preferably also as an adhesive for connecting the metal foil to the carrier material to serve.

The laminates according to the invention fulfill the requirements made of them Conditions. The point of damage in the electrical conductor becomes during evaporation of the foil conductor in the arc is not electrically conductive, but rather retains a high insulation resistance of more than 1012 ohms. This is a prerequisite for the anti-inflammatory laminate according to the invention. In such an anti-inflammatory Laminate is also interrupted in the event of damage and the resulting Arc vaporizes the foil conductors, which melt away, as it does not anti-inflammatory laminate, but this increases the electrode gap until the voltage and power are no longer sufficient to cause the arc maintain. Die.-ser evaporation process including the demolition of the The arc occurred so quickly that the laminate could not catch fire.

The damage switched itself off. When switching on again of the device, the arc no longer ignites because the The distance between the electrodes has become too great. Such a material according to the invention offers active security against ignition in the arc.

Curable ones serve as components of the anti-inflammatory layer Resins and crosslinkable elastomers that have no aromatic moieties and no ring-shaped ones contain organic compounds with heteroatoms and conjugated double bonds (e.g. melamine) In principle, all known curable resins and crosslinkable resins can be used Blastomeres that meet these conditions are used because it has been recognized that aromatic compounds and / or said heterocycles in the heating in the Arc also forms the graphite-like carbon bridges described above decompose the disadvantages described. If these connections are in the to be used However, resin is present in proportions below 30% by weight, preferably below 15% by weight, the disadvantages mentioned do not occur.

As the anti-inflammatory layer after hardening if possible the same thermal and mechanical properties as that for impregnation the resin used is to have the laminate used, it is advantageous to use the Manufacture of the binding layer | used plastic with a curable resin, with with which the laminates are impregnated, e.g. phenolic or epoxy resin. Of the However, the proportion of these phenolic or epoxy resins 2n in the anti-inflammatory layer should be Do not exceed 30% by weight, otherwise the effect according to the invention will no longer be achieved entry. It is preferably between 10 and 20% by weight, based on the non-inflammatory Layer.

The curable resins that can be used according to the invention include cycloaliphatic epoxy resins which, by definition, have one or several cycloaliphatic rings and apart from these and the epoxy groups only aliphatic ones Contains leftovers. These include cycloaliphatic resins that are built on cycloaliphatic-1 Rings with boxid oxygen bound to it (e.g. dicyclopentadiene dioxide) or on cycloaliphatic compounds, in which the epoxy oxygen to the aliphatic side chains, such as diglycidyl ester of hexahydrophthalic acid. The epoxy oxygen can continue in the starting compounds both on the ring as well as on the side chain, such as with vinylcyclohexane dioxide, The production and hardening of these resins takes place according to general. n known methods. Aliphatic carboxylic acids or their anhydrides as well as are predominantly used as hardeners Boron fluoride or its addition compounds with aliphatic amines are used.

The curable resins that can be used according to the invention also include aliphatic unsaturated polyesters, urea-formaldehyde resins and polyurethane resins, provided the isocyanate and alcohol components are not aromatics are. The unsaturated polyesters include condensation products from α, ß-unsaturated aliphatic Dicnrbonsäurenbzw. their anhydrides (e.g. maleic anhydride, Maleic acid, fumaric acid, itaconic acid, mesaconic acid) or saturated aliphatic Dicarboxylic acids or their anhydrides (e.g. succinic anhydride, adipic acid, sebacic acid, Dodecanedicarboxylic acid, dimethylmelonic acid) with aliphatic diols, preferably Ethylene glycol, propylene diols or butanediols. Also ether alcohols, such as z * B. Glycerol monaflyl ether, Di- or triethylene glycol can be used as starting compounds The starting product for a polyurethane resin that can be used according to the invention is e.g. 1,6-diisocyanato-hexane called. as Alcohol components can e.g. the unsaturated polyesters mentioned above are used. However, you can also aliphatic polyethers or other aliphatic polyhydroxy compounds second Component of the polyurethane resins are used according to the invention cistzbe.ren Elastomers include polybutadienes, their methyl substitution products and theirs Mixed and copolymers with acrylic resins are also said to be crosslinkable elastomers also the crosslinkable products made of polyeoichlorohydrin (CHR) or chlorohydrin polymers (Copclymer with ethylene oxide, known as GHC plastic). The networking takes place at. the last-mentioned elastomers either by amines or by metal oxides.

Silicones can also be used according to the invention as an inflammation-resistant binding layer if they have resin character and can be crosslinked. Possibly such silicone resins are used together with acrylic resins and / or known adhesion promoters used to denote the thermal and mechanical properties of these resins the laminates of the laminates or the adhesion of these resins to improve with the metal foil.

Organofunctional silanes are also suitable as adhesion promoters or organophophonic acid esters.

A copper foil is preferably used as the metal foil but also foils made of other ST metals with good electrical conductivity, such as aluminum, silver or tin, can be used. The thickness of the foil can be in vary widely; A film that is as thin as possible is preferred with a Thickness between 30 and 100, u.

The bond between the metal foil and the carrier material can be different Way to be carried out. It is possible both the anti-inflammatory layer to be applied to the metal foil as well as to the top layer of the carrier material and then to produce the composite by heating under pressure. When the anti-inflammatory Layer is applied to the carrier material, it is also possible to use the metal coating to be carried out first chemically and then galvanically according to known methods. Man but can also produce a film from the anti-inflammatory layer and this Insert between the metal foil and the carrier material and then hot-press the composite Furthermore, it is also possible to make the reinforcement material of the top Laminate to be bonded to the metal foil instead of the binding resin to be coated with a solution or dispersion of the anti-inflammatory plastic or to impregnate and use this impregnated laminate layer as an adhesive layer.

The carrier material used for the production of printed circuits consists of layers of material known per se, each out a reinforcement material and a bandage.

Flat fiber materials based on natural fibers are used as reinforcement or synthetic organic fibers especially papers, e.g. cotton paper, preferably cotton linters papers, or also those made of sulphate or sulphate, obtained from coniferous wood, yield - suitable hard paper; but the flat ones can Fiber materials also consist of 5 sen, layers, mats or fabrics, which are made of Pulp, fibers or ribbons made from synthetic fibers such as polyesters' polyamides or other polymeric organic substances. Completely or partially These organic substances can be replaced by fibrous mineral substances such as glass fibers1 Glass silk, glass fleece, mineral wool, asbestos fibers can be replaced as a binding resin hardenable resins, such as epoxy, phenol, melamine, polyester or silicone resins, as are customary for the production of industrial laminates. The 'respective Reinforcing materials of the individual layers are used according to known methods impregnated with the binding resin, then in a mixed iron with prepolymerization of the resin dried. Then several of these layers come together with the metal foil placed on top of each other as the top layer and closed using heat and pressure Cured laminates.

Examples 1 and 2 A copper foil supplied as a roll with a width of 1100 mm and a weight per unit area of)) 0 g / m2, corresponding to a thickness of 35 P, is coated with a plastic solution with a doctor blade, each having the following composition: Example 1 Example 2 Plastic solution A Plastic solution B 80 parts phenol resol resin 100 parts cycloaliphatic 2C parts epoxy resin 828 Shell resin, commercially available under the 5 parts hardener Diainod.iphe- name Araldit 580 obtained nylmethan Lich 50 parts acetone 1 part BF3 / amine. Complex 20 parts acetone The plastic solutions each have a viscosity of approx. 500 to 600 cP. The copper tape is passed through a dryer duct in which it is heated from 100 to 1,140 ° C. within 5 minutes in order to remove the solvents. After leaving the dryer, the film has received an application of 40 g / m2.

A copper foil coated in this way is used together with eight layers Core paper of a phenolic resin hard paper between press plates under a heating press Heated for 70 minutes under a pressure of 170 ° C. A copper-clad was created Hard paper board about 1.6mm thick.

Example 3 Analogously to Example 2, a phenolic resin impregnated Filling paper with an aqueous solution of a urea-formaldehyde resin (solid resin treated 65-70%)) coated, as is usual for the production of phenolic resin hard paper is. Coating and drying were done in the same manner as above when coating the copper foil. The applied weight per unit area was also 40 g / m2. A sheet of hard paper coated in this way is used together with other paper layers coated with phenolic resin and an overlaid copper foil pressed in the same way as described in Example 2.

Example 4 The plastic solution B mentioned in Example 2 is through the addition of acetone diluted to a viscosity of 200 cP. in cellulose paper made of sulfite pulp with a weight per unit area of 120 g / m² alrde in this acetone solution immersed and squeezed with! ue + rollers so that the dried substrate is a Has a surface weight of 240 g / sqm. An arch impregnated in this way is used together with Phenolic resin-coated core layers and with a copper foil on top to form one Laminate in the heating press according to the same method as described in Example 1 pressed.

Example 5 In the same way as described in Example 2, proceeded, but wobel as a plastic solution of a suspension in methanol 0.7 mol% neopentyl glycol, 0.3 mol% ethylene glycol, 1 mol% fumaric acid and 2% by weight, based on the other ingredients, dibenzoyl peroxide paste was used. the Suspension has a solids content of about 70% by weight example 6 90 parts by weight (calculated as solid resin) of a 50% strength dispersion are used Butadiene-acrylonitrile resin with 10 parts by weight (also calculated as solid resin) a phenolic resole resin (residual material content approx. 70%) mixed. The dispersion obtained is applied analogously to Example 2 to a copper foil with a thickness of 35p and as there specified further processed.

To demonstrate and test the desired effect of an improved Two test electrodes according to FIG. 2 were produced for resistance to ignition. The Kazz electrodes and the sterile electrodes are printed on the laminates after the photo printing process Example 1 to 6 applied and produced by known methods with etching. This creates a replica of several conductor track interruptions. These Test electrodes are placed in the horizontal deflection circle of a color television set Figure 2 switched. If you switch on the device, it is at the point of interruption the open circuit voltage that initiates the arc.

This test assesses whether the arc ignites the laminate, because the current flow is constantly maintained through the formation of graphite bridges, or whether the Feh-1 switches itself off. A shutdown proves the erfiiidungsgemaß Desired effect, which is due to the fact that the foil conductor -an the Melt the interruption point without the underlying layer being conductive will.

The determined on the test electrode with the help of the horizontal deflector Properties of laminates according to Examples 1 to 6 are shown in FIG. Tabel 1 listed, the laminate according to Example 1 ignites both during the test Kammele; trode as well as with the star electrode. In addition, X5L-th takes place after re-entry the voltage, re-ignition and re-ignition of the test specimen. The laminates according to examples 2 to 6 show the desired resistance to inflammation during the test. The electrode is not ignited by the arc, and there is no re-ignition during the Switching on the voltage again. This is true of both. for the, comb electrode as well for the stone electrode.

In the manufacture of printed circuits, it is still common practice to To declren parts of the line picture with a heat-resistant varnish. This so-called Solder mask is intended to prevent the copper foil from tinning over its entire surface will. Small areas remain unprinted, in order to only make the jointed soldering points for the fastening of the Bauelémente to solder To the inventive effect of the anti-inflammatory In order to be able to optimally achieve the said composition, it should also be possible he uses solder mask in an anti-inflammatory form. The invention Resins also serve this purpose and can therefore also be used as solder resists insert. When using known solder resists, there is the possibility of that these thermosetting resins initiate ignition and thus ignition of the carrier, even if the underlying carrier layer consists of individually anti-inflammatory substances according to the invention Material made fashion. The use of the resins of the invention also eliminates this disadvantage of the resins used hitherto.

The attached FIG. 1 shows the principle circuit diagram of a horizontal deflection part in the color television set with thyristor control. FIG. 2 shows a test device and test electrodes for ignition tests. In both figures the individual Letters have the following meaning: A = operating voltage B = booster capacitor C = booster diode E = oscillator F = line transformer G = deflection coil H = picture tube I. = Interruption point with arc K = comb electrode L = star electrode Tabel 1 Example 1 2 3 4 5 6 Application method on copper copper paper paper copper copper coated x x x x x impregnated x Behavior in an arc yes no no no no no ignition with star electrode yes no no no no no backfire when switching on again yes no no no no no

Claims (6)

P a t e n t a n 5 p r ü c h e 1. Further development of the laminates, the carrier material containing resin-hardened layers and one located on it, with the help of an anti-inflammatory layer made of a heat-resistant plastic connected metal foils exist according to patent ... (patent application P @@ (54 777 6) characterized in that the anti-inflammatory layer is 7054 to 90% off such curable resins or crosslinkable elastomers that are not aromatic Groupings and no organic ring-shaped compounds with heteroatoms and contain conjugated double bonds. 2. Laminates according to claim 1, characterized in that they contain hardened cycloaliphatic epoxy resins as an inflammation-resistant layer 3. Laminates according to hnsprt 1, characterized in that they are anti-inflammatory Layer contain aliphatic unsaturated polyester. 4. Laminates according to claim 1, characterized in that they are preserved as an anti-inflammatory layer of urea-formaldehyde resins. 5. Laminates according to claim 1, characterized in that they contain mixed or copolymers of butadiene as an inflammation-resistant layer Acrylic compounds included. 6. Laminates according to claim 19, characterized in that they crosslinked silicones, which may have an adhesion promoter mixed in, contain. Blank page