FR2886776A1 - ELECTRODE IN PARTICULAR FROM AN INTERNAL COMBUSTION ENGINE IGNITION CANDLE - Google Patents

Abstract

Electrode (2), especially a spark plug (1) of an internal combustion engine, comprising a body (24) of generally elongated shapecharacterized in that a section (241) of the body (24) of the electrode (2) comprises a cavity (5) in which is placed a determined amount (8) of fusible material such that the volume of the quantity (8) in the solid state is less than that of the cavity (5) and such that the volume of the amount (8) in the liquid state is less than or equal to that of the cavity (5).

Description

ELECTRODE IN PARTICULAR FROM AN INTERNAL COMBUSTION ENGINE IGNITION CANDLE

  The invention relates to an electrode, in particular an ignition plug of an internal combustion engine, comprising a body of elongate overall shape.

  Plasma-generation spark plugs are high-frequency multi-spark ignition systems, capable of ensuring the ignition of engines with controlled ignition under the best conditions, while at the same time reducing pollutant emissions, especially in lean mixtures. By cons, they are subject to fouling, especially cold.

  Like all candles, they are characterized by a thermal index. This thermal index takes into account their thermal behavior on particular engine operating points. It reflects in particular their ability to withstand high enough temperatures to eliminate clogging by pyrolysis, without pre-ignition.

  By publications FR2859830, FR2859869, FR2859831, a so-called cold spark plug is known because it does not rise quickly enough to avoid fouling. On such candles, it has been found indeed the accumulation of a carbon deposit on the electrodes, which significantly reduces the necessary insulation between the tip of the central electrode and the base. With poor insulation, the high voltage supply of the candle may then be insufficient, to cause the necessary breakdowns, spark triggers.

  To avoid the formation of carbonaceous deposits, especially cold, on the insulator of the candle exposed to the atmosphere of the combustion chamber, we can seek to increase the temperature of the insulator, so as to promote the destruction of deposits by the phenomenon of pyrolysis, the effectiveness of which depends on the thermal resistance of the whole of the candle, including that of the insulation. z

  The measures usually taken to increase the temperature of the insulation find their limit in the appearance of pre-ignition on the candles, when they reach temperatures too high in operation.

  In order to overcome these drawbacks, the invention aims to adjust the thermal index of a multi-spark plug so that it behaves like a very hot candle when the engine is still cold and behaves like a warm candle when the engine is hot.

  For this purpose, the invention proposes an electrode of the type mentioned above, characterized in that a section of the body of the electrode comprises a cavity in which is placed a determined quantity of fusible material so that the volume the amount in the solid state is less than that of the cavity and so that the volume of the amount in the liquid state is less than or equal to that of the cavity.

  According to other features of the invention, the cavity is a closed cavity.

  According to other features of the invention, the body is cylindrical.

  According to other characteristics of the invention, the section comprising the cavity is tubular with a circular annular section. According to other features of the invention, the section comprising the cavity comprises: a first portion of tubular shape with an annular section and a second portion of tubular shape with an annular section of greater width than that of the section of the first section. portion.

  According to other features of the invention, the first portion is tubular in shape with a circular annular section and in that the second portion is tubular in shape with a circular annular section of larger diameter than that of the section of the first portion.

  According to other characteristics of the invention, the electrode comprises an upper component and a lower component.

  According to other characteristics of the invention, the upper component is chosen from a thermal conductive material and the first portion consists of a part of the upper component and a part of the lower component concentric with a part of the upper component, the part of the upper component being interposed between the part of the lower component and the cavity.

  According to other features of the invention, the fusible material is a metal or a eutectic of metals.

  According to other features of the invention, a multi-spark spark plug comprising an electrically insulating block interposed between two coaxial electrodes, including an external electrode and an internal electrode described above.

  According to other features of the invention, the section of the body comprising the cavity is disposed axially inside the electrically insulating block of the candle.

  According to other characteristics of the invention, the candle comprises an annular chamber arranged radially between the external electrode and the electrically insulating block and the chamber is open on the outside.

  According to other features of the invention, the walls of the candle chamber are metallized.

  According to other features of the invention, the candle has an annular chamber arranged coaxially in the outer electrode and the chamber is open on the outside.

  According to other features of the invention, the chamber contains a dilation piece capable of opening or closing its inlet to hot gases.

  Other features and advantages of the invention will appear on reading the description of exemplary embodiments with reference to the appended figures.

  Figure 1 shows a sectional view of a multi spark spark plug known in the state of the art.

  FIG. 2 represents a sectional view of a multi-spark plug comprising, in a cavity of the central electrode, a quantity of fuse material in solid form according to a first embodiment of the invention.

  FIG. 3 represents a sectional view along the axis A-A 'of the central electrode of FIG. 2 according to the first embodiment of the invention.

  FIG. 4 shows a sectional view of a multi-spark plug having, in a cavity of the central electrode, a quantity of fusible material in liquid form according to the first embodiment of the invention.

  FIG. 5 represents a sectional view along the axis B-B 'of the central electrode of FIG. 4 according to the first embodiment of the invention of the invention.

  FIG. 6 represents a sectional view of a multi-spark plug comprising, in a cavity of the central electrode, a quantity of fusible material in solid form according to a second embodiment of the invention.

  FIG. 7 represents a sectional view of a multi-spark plug comprising, in a cavity of the central electrode, a quantity of fusible material in liquid and dilated form according to the second embodiment of the invention.

  FIG. 8 represents a sectional view of a multi-spark plug comprising, in a cavity of the central electrode, a quantity of fuse material in solid form and comprising, between the base and the central electrode, a dead volume according to the invention.

  FIG. 9 represents a cross-sectional view of a multi-spark plug comprising, in a cavity of the central electrode, a quantity of fuse material in solid form according to the invention.

  Identical or similar elements are designated by the same reference numerals.

  As represented in FIG. 1, a muti-spark spark plug 1 of known type comprises two plasma-generating electrodes, an internal electrode 2, called a central electrode and an external electrode 3, called a cap, separated by an electrically insulating block. called insulator 4 chosen, for example, ceramic. The base 3 surrounds the insulator 4 and the central electrode 2 is housed in a central bore of the insulator 4.

  The central electrode 2 is composed of a cylindrical body 24 of axis D, of a first free end from which sparks are formed, called the head 22, of a second opposite free end 23 of electrical connection.

  The body 24 has a portion disposed within and away from the annular base 3, said internal portion.

  The base 3 conventionally has an external thread for screwing the spark plug into the cylinder head of the engine.

  As shown in Figures 2, 3, 8 and 9 a section 241 of the inner portion of the body 24 of the central electrode 2 comprises a closed cavity 5.

  In the cavity 5 is placed a specific quantity 8 of fusible material. The fusible material is chosen so that the volume of the quantity 8 in the solid state is smaller than that of the cavity 5 and so that the volume of the quantity 8 in the liquid state is less than or equal to that of the cavity 5.

  The fusible material is selected from metals such as cadmium, indium, thallium, selenium, sodium, tin or from metal eutectics.

  This system depends on two transition temperatures: the melting temperature of the fusible material and the contact temperature for which the expansion induces the contact of the material in liquid form with the material of the electrode. The contact temperature depends on the coefficient of expansion of the fusible metal in the liquid state and the ratio between the volume of this metal in liquid form and the volume of the vacuum to be filled. It is this temperature that determines the main break in conductivity.

  According to a first embodiment, the section 241 has a tubular shape with a circular annular section.

  In the case where the candle 1 is at low temperature, the amount 8 of material is in the solid state. As shown in Figure 2, the cavity 5 is not completely filled. As shown in FIG. 3, the conduction section is then limited to the passage section of the walls 21 of the section 241 of the central electrode 2. In this case, to evacuate a given thermal power from the head 22 towards the second end. of the central za electrode 2, the passage section being reduced to the sections of the wall 21 of the section 241 of the central electrode 2, the temperature gradient between the head 22 (combustion chamber side) and the second end 23 of the electrode 2 is higher. This results in a higher electrode head temperature 22. The candle is 1 then behaves like a hot candle.

  In the case where the temperature of the candle 1 increases, the material melts and expands so that the entire inner surface 51 of the section 241 is in contact with the quantity 8 of the material, as shown in FIGS. 4 and 5. conduction surface is then increased. In this case, to evacuate a given thermal power from the head 22 to the second end 23, the passage section being increased, the temperature gradient is reduced. This results in an increased cooling of the electrode head 22 2. The candle 1 then behaves like a cold candle by limiting its heating.

  The spark plug 1 is positioned in such a way that, when the vehicle is started, the position of the solidified material allows the candle to behave like a cold candle as previously described.

  According to a second embodiment, the cylindrical electrode 2 has two components: an upper component 25 and a lower component 26.

  The upper component 25 is chosen from a thermal conductive material such as copper so as to discharge a given thermal power from the head 22 of the electrode to the second end 23 of the central electrode 2.

  The lower component 26 is selected from a material such that it resists oxidation. For example, the lower component 26 may be selected from nickel.

  The section 241 comprises a first portion 241a of tubular shape with circular annular section and a second portion 241b of tubular form with circular annular section of larger diameter than that of the section of the first portion 241a.

  1a The first portion 241a acts as a safety volume to prevent, in case of excessive expansion of the metal, that is to say a break electrode 2.

  The second portion 241b is constituted by a portion of the upper component 25 and a portion of the lower component 1s 26 concentric with a portion of the portion of the upper component 25, this portion being interposed between the portion of the lower component 26 and the cavity 5.

  The second portion 241b is constituted by a portion of the lower component 26.

  In the case where the candle 1 is at low temperature, the amount 8 of material is in the solid state. As shown in Figure 6, the second portion 241b of the cavity 5 is not completely filled. The conduction section is then limited to the sections of the wall 261 of the lower component 26 of the electrode 2 zs. In this case to evacuate a given thermal power from the head 22 to the second end of the central electrode 2, the Temperature gradient between the head 22 (combustion chamber side) and the second end 23 of the electrode 2 is higher. This results in a higher electrode head temperature 22. The candle 1 then behaves like a hot candle.

  In the case where the temperature of the candle 1 increases, the material melts and expands so that the second portion 241b is completely filled and the first portion 241a is partially filled, as shown in FIG. conduction is then increased. It comprises the walls 261 of the lower component 26 and the walls 251 of the upper component 25 which are concentric with the walls 261 of the lower component 26.

  In this case, to evacuate a given thermal power from the head 22 to the second end 23, the temperature gradient is reduced. This results in an increased cooling of the electrode head 22 2. The candle 1 then behaves like a cold candle by limiting its heating.

  Io The candle 1 is positioned so that at the start of the vehicle the position of the solidified material allows the candle to behave like a cold candle as previously described.

  According to another characteristic of the invention, as shown in FIG. 8, the candle 1 may, in addition, comprise a dead volume 6 constituting an open chamber to the outside. The chamber may extend between the base 3 and the insulator 4 or in the mass of the insulator 4. According to the diagram, the chamber may advantageously have a first tubular sector 6a connected to a second circular sector 6b open on the outside.

  According to another characteristic of the invention, as shown in FIG. 8, the walls of the chamber may be metallized. The layer, or metal sleeve 7 applied to the insulator 4 is then in direct contact with the hot gases, and particularly oxidizing lean mixture (lean bure)) of the combustion chamber. The metallization of the walls of the chamber 6 makes it possible in particular to prevent the creation of a plasma between the ceramic of the insulator 4 and the base 3. This metal layer 7 may consist for example of a sleeve brazed to the ceramic , which will ensure the resistance thereof to oxidizing gases. In practice, the thickness of the sleeve may be a compromise between its resistance to thermochemical erosion, its thermal resistance and its cost of production. Indeed, if the sleeve is too thick, its thermal resistance will be too low, and the ceramic will not heat up enough to destroy the deposits by pyrolysis. The material of the sleeve will also be chosen according to its conductivity and its expansion coefficient which must be compatible with that of the ceramic and the mechanical properties of the latter. Finally, without departing from the scope of the invention, the metal layer may itself be protected by an inert deposition, a thin ceramic layer, or other metal deposit particularly resistant to oxidation, such as nickel.

  According to another characteristic of the invention, as represented in FIG. 9, the chamber 6 is a simple tubular opening arranged in the mass of the base 3. In this case, the chamber 6 constitutes a cut-out in the mass of the base 3. The application of a metal layer 7 can also be very useful for protecting the ceramic against oxidizing gases. Here, the metallization will be applied simply on the bonding interface between the ceramic 4 and the base 3 independently of the chamber 6.

  According to another characteristic of the invention not shown, the chamber may contain a dilation piece capable of opening or closing its inlet to hot gases. This expansion piece may be a corrugated sleeve or flanges serving as flaps.

  All of these measures proposed by the invention makes it possible to adjust the thermal index of the candle, and more particularly to obtain a nonlinear thermal index.

  The embodiment described does not limit the invention to the application of multi-spark plugs. The invention can be applied to other types of candles.

Claims (15)

- 10-CLAIMS   1. Electrode (2), especially a spark plug (1) for ignition of an internal combustion engine, comprising a body (24) of elongated general shape characterized in that a section (241) of the body (24) of the electrode (2) has a cavity (5) in which is placed a determined amount (8) of fusible material such that the volume of the quantity (8) in the solid state is less than that of the cavity (5) and so that the volume of the amount (8) in the liquid state is less than or equal to that of the cavity (5).   2. Electrode (2) according to claim 1, characterized in that the cavity (5) is a closed cavity.   3. Electrode (2) according to any one of claims 1 and 2, characterized in that the body (24) is cylindrical.   4. Electrode (2) according to any one of claims 1 to 3, characterized in that the section (241) comprising the cavity (5) is tubular circular annular section.   5. Electrode (2) according to any one of claims 1 to 3, characterized in that the section (241) comprising the cavity (5) 25 comprises: - a first portion (241a) of tubular form with annular section and a second portion (241b) of tubular shape with an annular section of greater width than that of the section of the first portion 30 (241a).   6. Electrode (2) according to claim 5, characterized in that the first portion (241a) is tubular in shape with circular annular section and in that the second portion (241 b) is -l1tubular shape with circular annular section of larger diameter than that of the section of the first portion (241 a).   7. Electrode (2) according to any one of claims 5 to 6, s characterized in that the electrode (2) comprises an upper component (25) and a lower component (26).   8. Electrode (2) according to claim 7, characterized in that the upper component (25) is selected from a thermal conductive material and the first portion (241a) is constituted by a portion of the upper component (25) and by a part of the lower component (26) concentric with a portion of the upper component (25), the portion of the upper component (25) being interposed between the lower component portion (26) and the cavity (5).   9. Electrode (2) according to any one of the preceding claims, characterized in that the fusible material is a metal or a eutectic of metals.   10. Spark plug (1) comprising an electrically insulating block (4) interposed between two coaxial electrodes, including an outer electrode (3) and an inner electrode (2) which is made according to any one of the preceding claims.   11. Spark plug (1) according to claim 10, characterized in that the section (241) of the body (24) having the cavity (5) is arranged axially inside the electrically insulating block (4).   12. Spark plug (1) according to any one of the preceding claims IO to 11, characterized in that the spark plug (1) comprises an annular chamber (6) arranged radially between the external electrode (3) and the electrically insulating block ( 4) and the chamber (6) is open to the outside. io   - 1 2 - 13. Spark plug (1) according to any one of the preceding claims 10 to 12, characterized in that the walls of the chamber (6) are metallized.   14. Spark plug (1) according to any one of the preceding claims 10 to 11, characterized in that the spark plug (1) comprises an annular chamber (6) arranged coaxially in the external electrode (3) and the chamber (6). is open to the outside.   15. Candle (1) according to any one of the preceding claims 10 to 14, characterized in that the chamber (6) contains a dilation piece capable of opening or closing its inlet to hot gases.