DE886404C - Resistors for the ignition circuit of internal combustion engines - Google Patents

Description

Resistors for the ignition circuit of internal combustion engines The invention relates to resistors for installation in the ignition circuit of internal combustion engines.

About the high frequency vibrations caused by the spark discharge Resistances are usually used to suppress those generated in the ignition system built into the ignition circuit, which in some cases is inside the spark plug form part of the center electrode. For such resistances is among other things the use of a mass, among other additives of glass and carbon exists has been proposed.

According to the invention, the mass representing the resistance is the among other admixtures from the sintered mixture of glass and a special soot consists, in a ceramic insulating housing on each side of one electrical the conductive glass seal and thus puttied in a gastight manner in the insulating housing.

In the following description and in the claims as special carbon black The soot referred to can be obtained from natural gas by cracking in the absence of oxygen will. The structure of the individual particles is roughly dumbbell-shaped: small, spherical Structures -which are connected by rods. The best results could be obtained when using a special soot with the coarsest possible individual particles, about 1, a'3, u size, can be obtained.

In one embodiment of the invention, the isolator constitutes a Spark plug represents the ceramic insulating housing, and the resistance mass forms one Part of the center electrode, while according to another embodiment the insulating compound receiving insulating housing is designed so that the arrangement be installed in series in a high-voltage cable leading to the spark plugs can.

In the drawings, both embodiments are each an example shown.

Fig. I is a section through a spark plug with sealed resistive mass; Fig. 2 is a section through a resistor for installation in a power cable. -Fig. i is a section through a spark plug used for aircraft engines. An insulator 14 is fastened in a spark plug body io provided with electrodes 12, in the embodiment of the invention described below, the ceramic Represents insulating housing for the resistance mass. This isolator 14 is preferably made made of sintered metal oxides, either completely made of aluminum oxide or made of a mixture of mainly aluminum oxide with other additives such as magnesium oxide, Beryllium oxide or suitable silicates such as mullite. If desired, however, can also a porcelain insulator can be used, which is mainly made of mullite, zirconium i (Zr Si 04), zirconia or similar substances and glass.

The insulator 14 is provided with the usual central bore 16 for receiving the central electrode. This central electrode consists firstly of the actual electrode part 18 in the lowest section of the central bore, secondly of an electrically conductive ceramic connector 22 and thirdly of an upper ignition cable connection terminal 24. The electrode part 18 is made of any suitable, high-temperature-resistant material, preferably one Nickel alloy; it can be provided with a copper core for better heat dissipation. The electrode part 18 has at the upper end a widening or a head 20 which rests on a shoulder in the central bore 16 of the insulator 14. The connection clamp 2 @ 4 is preferably made of steel. The ceramic connecting piece 22 is composed of a lower seal 26, an upper seal 28 and the resistor mass 3101 in between.

The conductive seals 26 and 28 are made of any suitable material with a relatively high electrical conductivity that will bond firmly and permanently to the ceramic insulator as well as to the resistive mass and the externally adjoining metal parts. The mixture of hard glass with copper powder is preferably used for this purpose.

The lower seal 26, which heats up strongly during operation, is preferably made from a mixture of 55 parts by weight of copper powder and 45 parts by weight of borosilicate glass with the addition of about 30/0 of a suitable binding agent, such as hardened cottonseed oil. The upper seal 218, which is less heated during operation, consists: preferably of two parts 28 ', 28 ", the lower-lying part 2.8' of which is of the same composition as the seal 26, while for the higher-lying part 28" in addition to the copper powder and the Binder a type of glass is used that softens more than borosilicate glass at the same temperature, preferably a lead-boron-silica glass is used for this.

The most favorable composition of the resistor mass is as follows: 62.4% borosilicate glass, 25.2% fluorspar (CaF2), 7; 8% magnesium dumborate glass, 4; 6% special soot. The starting substances are homogeneous in the specified weight ratio Mixture mixed together. Then to 100 parts by weight of the mixture are 4o Parts by weight of water are added and the mass is dried until it is granular and forced through a 64 mesh / cm2 sieve. can. After full Drying and repeated sieving using a sieve with the same mesh size the substance is ready to use.

The ratio of the starting substances can of course depend on the The properties required by the end product can be modified. As the conductivity the resistance mass is directly proportional to the content of special soot, can .der Resistance by increasing or decreasing the content of special soot to a large extent Boundaries are changed.

Borosilicate glass is characterized by a small coefficient of thermal expansion and distinguished by heat resistance. The magnesium borate glass, that too has a small expansion coefficient, is used to improve the elastic Properties of the finished glass mass, so that its presence of training internal Counteracts tension. Thermal expansion can be reduced by adding fluorspar increase the finished mass and bring it to the desired amount.

For the sake of simplicity, all of the resistance values listed below are based on similarly designed bodies with the same cross-section. The resistance of the reference body when manufactured from a mass of the above composition is between 6'ä ünd @ -io @ Q-9hm. To increase the resistance, the composition of the resistor mass can be modified as follows Approximate resistance of the Composition of reference body soo O hm 5 oo o O h m io ooo ohms Borosilicate glass ...... 63.8 0;, 63.5 0 ,, 64.0 0 " Magnesium borate glass 81o 1 ' 0 9.0 ' "9.0 0 u Fluorspar .......... 25,60.1 o 11, oo " 11100 " Chalk 15.0 0 Beryl ............. - - @ 15.0 Special carbon black ......... 2.6 0'0 1.5 0. "11o oo The increase in resistance is due to the reduction in the special carbon black content.

Boron carbide and tungsten carbide can be added as conductive materials will. An addition of both carbides seems to be good at resisting changes in the Ohm number in the course of use to stabilize. The Wolframkarbi @ d can be replaced by elemental boron. Other, heat-resistant, electrically conductive Materials such as metal carbides or oxides with or without elemental content Metal can be added to the mixture of glass and special carbon black so that the finished resistor mass either just from, depending on the desired properties Glass and special soot or made of glass, special soot and other substances.

To manufacture a spark plug according to the invention, the insulator Shaped in a known manner and fired at temperatures of 145o to 175o ° C, each according to the raw material used. The installation and sealing of the central electrode in the insulator happens roughly as follows: After inserting the electrode 18 into the Center hole 16 is a measured amount of the conductive caulking compound Copper powder and borosilicate glass in powder form in the center hole inserted and firmly tamped together in the space above the head 20 of the electrode 18. Any Residues of the sealing compound in powder form are blown out to create a fusion to prevent with the subsequently added resistance mass. This will then Applied in the desired amount to the tamped sealant and also stomped on. On top of this is another layer of the powder sealant made of copper and borosilicate glass and finally a small amount of the more easily melting ones Sealing compound made from copper powder and lead-boron silica glass. After introduction of the upper ignition cable connection terminal 2 4, the entire arrangement is at about 87o ° C heated. In the process, the glass masses introduced soften, so that the upper connecting terminal @ 24. can be pressed into .the central hole. ;By. the effect of pressure the plastic material is pressed downward and outwardly in intimate contact with brought to the surrounding parts; the more easily melting sealing compound made from copper powder and lead-boron-silica glass penetrates into the space between the wall of the central hole 16 and the terminal 24 and cemented this in the bore.

In Fig. 2 the invention is shown using the example of a resistor 35 for installation in a high-voltage IcAel of the ignition device of an aircraft engine.

The resistor 35 is of a metal housing provided with cooling fins 42 surrounded. This 1Tallgehäus @ e, which is provided with an external thread at one end 42 is screwed into an attachment plate 44, which in turn is secured by screw bolts 46 is attached to the housing 48 of the distributor.

The resistor 35 contains an insulating housing 34 made of sintered metal oxides or porcelain, which corresponds to the spark plug insulator i4 of FIG. The housing 34 can, however, also consist of any other suitable insulating material, since during operation it is not exposed to the high thermal and electrical loads such as a spark plug insulator. Within the insulating housing there is a resistance mass 36, firmly connected to the housing, of the composition described above. This is surrounded on both sides by a conductive glass seal 38 which, due to the firm and durable connection with the insulating housing, the resistance mass and the adjoining metal lines, cement the resistance mass in the insulating housing in a gas-tight manner. The glass seals 38 consist of the same mass .As the glass seals 26 and 28 of Fig. I. If desired, the outer part of the glass seals 38 can also consist of a mixture of copper powder with a glass that melts more easily, just as has been described for the glass seal 28 "in FIG. 1. The glass seals 38 simultaneously cement two metal pole terminals 5o in the insulating housing 34, one of which is connected to a cable 52 coming from the ignition coil, while the other is in conductive connection with a cable 54 leading to the distributor the pole terminals held 5tto.

The process of making such resistors is essentially same as the procedure described above for spark plugs. After inserting one of the both pole terminals Soi is the powdery mass of one of the glass seals, then that of the resistance mass and finally the material of the other glass seal introduced into the insulating housing. After the introduction of the second pole terminal 5o and subsequent heating, the pole terminals 5o are pressed against each other, so that they penetrate into the softened glass seals 38 and are cemented there (Fig. 2). Suitable stops ensure that the resistance mass in the Center of the insulating housing 34 is mounted.

In some cases it can be advantageous to use the resistor 35 to Purpose of better heat dissipation to the metal housing 42 on the outside with to provide a silver coating 4o @. The outer housing 42 consists, at least at Use of the resistor in the ignition system of a motor vehicle, usually from Metal to shield the Wi, derstan.d and the ignition cable from the environment and thereby avoiding interference in radio reception. Of course, such a Resistance can also be used wherever a substantial Temperature interval constant resistance is needed.

A resistor of the invention has a number of advantages. As a result of solid, gap-free and gas-tight connection of the resistance mass with the insulating housing is the possibility of arcing on the surface of the resistor, just as it can sometimes occur with other resistances at high loads, perfectly locked out; the resistance mass is due to the electrically conductive, pressure-resistant Glass seals completely against the effects of surrounding gases and Vapors protected, and the resistance value is in the wide range of the temperature independent.

The resistance value can be changed by changing the content of special carbon black to be changed. On the other hand, a decrease in the resistance value can result in equal resistance mass due to pressure or temperature increase during assembly can be achieved because the conductive particles in the glass masses are then in better contact come together.

Although the use of glass and due to the 'small expansion coefficient, the good temperature resistance and the relatively low softening point in particular the use of borosilicate glass as a ceramic component of the resistor mass and the sealing material is preferable, the use may in some cases of a material that is still heat-resistant, such as sintered Metal oxides or sintered mixtures of metal oxides and silicates. In any In this case, the ceramic component used should be used at the temperatures on .which the resistor heats up during operation, do not yet soften, .da determined became that the resistance value in this case increases with time.

A resistive mass of the composition described above stretches look a little less than an ordinary insulating body when heated Alumina base. In the case of the cooling that occurs after assembly Contraction is therefore the resistance mass and so are the glass seals Fully meet the available space and make the arrangement durable and seal pressure-tight.

Claims (7)

PATENT CLAIMS; i. Resistance for the ignition circuit of an internal combustion engine, characterized by a resistance mass (30,3; 6), which is mainly made of the sintered mixture of glass and special soot and which is firmly connected to the inner walls of an insulating housing (14.34) and connected to both Each side is surrounded by an electrically conductive glass seal (26, 28, 38) and is therefore cemented gas-tight and pressure-tight in the insulating housing. 2. Resistance according to claim i, characterized in that .that .the resistance mass (3b, 36) consists of the sintered Mixture of borosilicate glass, magnesium borate glass, fluorspar and special soot and that the electrically conductive glass seals (26, 28, 38) are made of borosilicate glass and assemble copper powder. 3. Resistor according to claim i and 2, characterized by a resistance mass of the following composition: Borosilicate glass 62.4 weight percent , Magnesium borate glass 7.8 - Fluorspar 215; 2 - ISpecial carbon black 4.6 - 4. Resistor according to claim i. and 2, characterized by a resistance mass of the following composition: Borosilicate glass 63.8 percent by weight Magnesium borate glass 8, o. Fluorspar 25,161 - Special carbon black 2.6 - 5. Resistor according to claim i and 2, characterized by a resistance mass of the following composition: Borosilicate glass 63.5 percent by weight Magnesium borate glass 9, o1 - Fluorspar II ,, a - Special carbon 1.5 - Chalk 15.101 - 6. Resistor according to claim i and e2, characterized by a resistance mass of the following composition: Borosilicate glass 614, o weight percent Magnesium borate glass 9; a - Fluorspar IIiot - Special carbon black I, 0 - Beryl 15.0 - 7. Resistor according to claim 1 'to @ 6, characterized in that the special carbon black the resistance mass consists mainly of particles around i, u. B. Resistor according to claim i 'to 7', characterized in that the insulating housing (14, 34) a coating of a on the outside for better heat dissipation Has metal with high thermal conductivity. G. Resistance according to claim i to 18, characterized in that the resistance measures are used as the basic substance instead of glass sintered metal oxides or a sintered mixture of metal oxides and silicates contains. ok Spark plug with a resistor according to claim i, ibis g, characterized in g@kennzeich.net, that. The insulating housing for receiving the resistance mass from the insulator (14) a Spark plug is formed with the resistive mass part of the center electrode represents.