FI58837B - MAETSOND FOER MAETNING AV YTAVNOETNINGEN HOS MASKINDELAR - Google Patents

Description

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Patent · och ragistaratyralMn At least utitgd och utUkrtfun pubtkerad 31.12. oo (32) (33) (31) Requested MUolkMi — B «g« rd prlorlt »20.09-7 * +

Federal Republic of Germany-Förbundsrepubliken Tyskland (DE) P 2W * 5111.U

(71) B&W Diesel A / S, no. 2, Torvegade, l * + 00 K ^ benhavn K, Denmark-Danmark (DK) (72) Franz Michael Mannstaedt, Allerfid, Denmark-Danmark (DK) (7 * 0 Berggren Oy Ab (5U) Measuring probe for measuring surface wear of machine parts -Mätsond for the purposes of this Regulation

The present invention relates to a measuring probe for inductively measuring the surface wear of machine parts, comprising an electromagnetic coil connected to the measuring circuit and surrounded by a gap-forming magnetic circuit which is a material having a high magnetic permeability.

To measure the thicknesses of ferromagnetic materials, it is known to use inductive measuring probes comprising a magnetic circuit which is fitted to an object whose thickness is to be measured. An object belongs to a magnetic circuit, and when the thickness of this object changes, for example as a result of wear, a corresponding change in the reluctance of the magnetic circuit occurs, and this change in reluctance is a measure of the wear that has taken place.

Such an arrangement, especially in the case where it is desired to measure the wear of the cylinder in the engine, has the disadvantage that the measuring probe cannot be particularly sensitive, since it has to be placed externally in the cylinder wall. The decrease in the thickness of the object, i.e. the thickness of the cylinder wall, has only a small effect on the magnetic reluctance, and since the thickness of the cylinder wall is usually relatively large, the change in reluctance in the magnetic circuit 2,58837 may not be very significant. Another disadvantage of the known arrangement is that the cylinder wall or other machine part may not be designed for mounting such a measuring probe, and therefore special measures must be taken to mount the measuring probe in a suitable place on the cylinder wall or machine part.

The object of the invention is to eliminate said drawbacks and to achieve this the measuring probe according to the invention is characterized in that the gap is magnetically inert and that the gap thickness is limited by two parts of the magnetic circuit. from the wear-resistant surface of the machine part, and that the wear thus reduces the surface area of the gap.

By arranging the magnetic circuit of the measuring probe so that the wear directly applies to the gap or gap, a much higher sensitivity is achieved because the reluctance changes strongly as the gap area decreases as a result of wear.

In order to measure the wear of machine parts, for example the engine cylinder, it is also known to use a resistor piece arranged between the electrodes, which is fitted to the wear-prone machine part, and to measure the change in ohmic resistance of this piece as wear occurs. Normally, a direct current measurement is performed.

This method also has various disadvantages. There is a risk that the resistor will be mechanically damaged and possibly break when placed in the machine part. The variable resistance value according to wear depends on e.g. the temperature in the measuring range and may be chemically or corrosively affected by the lubricant in the machine. There is still a risk that the lubricant, which must necessarily be placed between the probe and the machine part, penetrates between the resistor and its insulating material and provides alternative current paths, resulting in misleading measurement results.

These disadvantages do not occur in the measuring probe according to the invention.

According to a preferred embodiment of the invention, the measuring probe is characterized in that the probe is shaped as a pin placed in the machine part, that it comprises in part an elongate central core of high magnetic permeability material, in part an at least one core-wound winding, in part an external winding and a sheath surrounding the core, which is a material of high magnetic permeability, as part of a gap between the core and the sheath at one end of the core filled with a magnetically inert material, and that the end sides of the core, slot and sheath at the other end of the pin are shaped so as to: they are flush with the surface of the machine part which is susceptible to wear, whereby the coil is connected to the induction measuring circuit.

When the end surface of the pin in the plane of the surface of the machine part is subjected to wear, the area of the gap decreases. Since the self-induction of the coil in the magnetic circuit in question depends on the speed of the coil on the one hand and on the area and width of the gap on the other, and since the area of the gap is the only variable variable with wear, the self-induction of the coil will decrease The measuring probe therefore gives a direct indication of wear via the induction measuring circuit. With the compact and sturdy construction thus achievable, the probe can be placed directly in the machine part without the risk of mechanical damage, and the lubricant is not affected by the lubricant. In addition, there is no risk to the chemical effect of the lubricant and thus to the erroneousness of the wear measurement.

According to another embodiment of the invention, there may further be a winding around the core and under the sheath, separate from the first winding, wherein the corresponding magnetic circuit comprising a part of the core and a part of the sheath has a constant gap. The second winding and the corresponding magnetic circuit have a constant reluctance because the gap has a constant size, and therefore this winding can be a reference winding included in the measuring circuit, which measuring circuit can be, for example, a measuring bridge circuit. Compensation for the temperature effect can thus be achieved with this reference winding.

The invention will now be described with reference to the accompanying schematic drawing, which shows an embodiment of a measuring probe according to the invention.

The measuring probe comprises a central, substantially cylindrical elongate core 1, in which two circumferential flanges 11 58837 2 and 3 are formed, which are spaced apart and one of which is located at the other end of the core 1. The core 1 is a substance with high magnetic permeability.

A winding 4 wound around the core is arranged around the core 1 and between the two circumferential flanges 2 and 3, and a second winding 5 around the core 1 is further arranged on one side of the flange 2.

The core 1 and the two coils 4 and 5 arranged around the core are surrounded by a sheath 6, which is also a material with high magnetic permeability. The jacket, the outer surface 7 of which is weakly conical, as shown in the drawing, is intended to be pressed into a hole of corresponding conicity in the machine part 8, for example the cylinder wall of a diesel engine, which is susceptible to wear and must be measured by a probe.

The casing 6 is dimensioned so that its end surface 6a is flush with the wear surface 11 of the machine part 8.

The coil 5 extends only along a part of the flange 2 of the length calculated at the free end of the core 1 and leaves the end 1a of the core free. The sheath is shaped so that its inner diameter in the area around the coil 5 is slightly larger than the outer diameter of the coil and in the area 1a of the free end of the core slightly larger than the outer diameter of the core.

Said space between the inner surface of the sheath and the core 5a of the coil 5 is filled with a magnetically inert substance, e.g. a plastic material, which creates a gap or gap 12 between the core 1 and the shell 6 in the magnetic circuit associated with the coil 5. the end surfaces of the gap are in the same plane as the end surface 6a of the jacket 6, i.e. in the same plane as the wear-resistant surface 11.

At the opposite end of the probe there is a ring 13 arranged between the end face of the sheath and the flange 3, which is e.g. plastic or preferably a retrograde, magnetically inert substance such as copper and which forms a gap in the magnetic circuit associated with the winding 4.

At the rear end of the probe, i.e. at the end away from the wear flange, the end of the jacket 6 is coated or fitted with an electrically insulating material, for example a material similar to the shell 15 in the slot 12, 5 58837 · The wires 14 entering and leaving the windings 4 and 5 are e.g. through the rear flange 3 and the shell 15. In order to remove the load on these lines, they can be fastened to the flange 3 with a fastener (not shown) and fitted through the shell 15.

The operation of the probe is described below:

A conical hole is provided in the machine part, the second surface of which is prone to wear, so large that the probe can be pressed into this hole and that the front end surface of the probe, i.e. the end surfaces of the core, slot and jacket, is flush with the surface of said machine part.

The two windings 4 and 5 are connected to an impedance measuring bridge to which an alternating voltage is applied at a constant frequency. The magnetic circuit associated with the winding 4 has a constant reluctance because the area of its gap does not change, so that the winding has a substantially constant impedance. Coil 4 forms a reference for its measuring bridge.

When the surface 11 of the machine part 8 wears, wear also occurs on the end surface of the probe. That is, the end surface 12 of the casing end surface 6a, the gap and the core end surface wear in the figure, the direction indicated by the arrow S. Since the self-induction of the coil 5 depends on the speed of the coil and the area and width of the gap 12, being directly proportional to the area and inversely proportional to the width, the self-induction of the coil 5 decreases in proportion to wear, as this only reduces the area of the gap. In this case, the impedance of the winding 5 decreases, whereby a change in the equilibrium state is observed in the bridge connection, which very close directly indicates the wear that has taken place.

Incidentally, a change in the reluctance of the magnetic circuit containing the coil 5 could also indicate wear if the coil 5 is connected to the resonant circuit. In this case, there is a necessary change in the measuring frequency to regain the resonant state also as a measure of wear.

Claims (6)

58837 A measuring probe for measuring the surface wear of machine parts from an inductive electromagnetic coil connected to a measuring circuit surrounded by a gap-forming magnetic circuit of high magnetic permeability material, characterized in that the gap is a magnetically inert material (2) , 6) that the planar dimension of the surface areas of the two parts delimiting the working space on one side thereof is adapted to depend directly on the wear-resistant surface (11) of the machine part (8), and that the wear thus reduces the surface area of the space. A measuring probe according to claim 1, wherein the probe is formed as a pin placed in a recess opening on a wear-prone surface, characterized in that the working gap (12) extends approximately perpendicular to the axis of the probe and approximately parallel to the wear-prone surface (11). A measuring probe according to claim 2, wherein the magnetic circuit has a central core surrounded by a coil and a shell surrounding the coil, characterized in that the coaxially arranged working space (12) as well as the working space delimiting the space between the magnetic circuit housing (6) and the core (1) end up on the same common probe surface of the probe, which is arranged together with the wear-prone surface. Measuring probe according to Claim 3, characterized in that the core (1) of the magnetic circuit and the housing (6) together with the second electromagnetic coil (4) connected to the magnetic circuit form a reference magnetic circuit with a constant working gap (13). 1. Mätsond fät mätning av ytavnötningen hos maskindelar pä in-ducttiv gág med en i en mätkrets inkopplad electromagnetisk Spole, som är omgiven av en arbetsspalt bildande magnetkrets av ett material med hög magnetisk permeabit, kännetecknad av at arbetsspalten it av magnetiskt in ar-betsspaltens (12) tjocklek är begränsad av tvä avsnitt (1, 6) av