JPS582772A - Particle detector - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a particle detection device of the type in which a particle sensor is provided at a certain location within a flow path.

The present invention particularly relates to, but is not necessarily limited to, an apparatus for detecting metal flakes and other particles in the oil, fuel, or oil flow path of an engine.

The condition of the engine can be effectively checked by examining the properties of particles in the oil flow path of the engine and their generation rate. This is because the checks can predict bearing damage or other defects that require attention before they become serious.

It is known to insert a magnetic plug into the oil flow path of an engine and periodically check for particles adhering to the plug. By comparing the extent of particle accumulation with data obtained from experiments, the condition of the engine can be determined.

However, removing and checking the plug is time consuming and troublesome, and it is impossible to check for the presence of non-magnetic particles.

To overcome these drawbacks, particle detection devices that utilize changes in sensor inductance have been used. An example thereof is disclosed in GB 1.348,881.

In this device, a coil is wound around an oil flow path, and when conductive particles pass through the coil, the impedance changes due to the eddy current losses generated.

However, the problem with this device is that it does not respond to particles below a certain size, and these particles can significantly wear and damage the bearings over time. It becomes.

An object of the present invention is to provide a particle detection device that largely solves the above-mentioned problems.

The particle detection device according to the present invention includes an accumulator above the particle sensor in the flow path, which collects at least a portion of the particles flowing along the flow path, and collects the collected particles. It is characterized by being released periodically.

In this way, small particles that are not individually detected by the sensor pass through the sensor in agglomerates large enough for the sensor to sense and react to.

Accumule batter releases trapped particles according to sensor output.

The accumulator is equipped with a magnet to collect magnetic particles. If this magnet is an electromagnet, the collected particles can be released by deenergizing it.

Hereinafter, the particle detection device according to the present invention will be explained with reference to the drawings.
explain in detail.

The particle detection device as an example is for detecting metal pieces and other particles generated in oil flowing through an oil flow path in a lubrication system of a gas turbine engine. Additionally, this device can also be used to detect and count particles generated within the engine's fuel system.

The oil flows along the flow path (2) in the direction of the arrow (1), that is, towards the bottom of the drawing.

This particle detection device consists of a particle sensor (4) installed in (2).
) and a particle accumulator (
3). The particle accumulator (3) collects particles for a certain period of time and then releases them for sensing by the sensor (4).

The particle accumulator (3) is in the form of an electromagnet with a soft iron pole piece (51) projecting into the oil channel (2). A coil (52) is wound around a portion of the pole piece (61) located outside the oil flow path, and its operation is controlled by a biasing device (63).

The sensor (4) is located downstream of the particle accumulator (3) and is connected to two identical shielding coils (40) (41
), each coil being wound around the flow path (2) at longitudinally spaced apart points of the flow path (2).

The two coils (40) (4F) are the oscillator (42)
connected in series with. The oscillator (42) generates an alternating voltage at a frequency of approximately 1000 KHz, balanced with ground potential.

The oscillator (42) also supplies a reference signal, for example at ground reference potential, on the line (43), which reference signal, together with the output signals from the contacts of the two shielding coils (40) (41), is applied to the demodulator. (44).

a phase shift transformer and synchronizer (4) connected to an oscillator (42);
5) is connected to the demodulator (44), and the demodulator (44)
It functions to control the phase when the AC signal entering the circuit is demodulated.

The output of the demodulator (44) is passed through a bandpass filter device (46).
The output of the bandpass filter device (46) is connected to a pulse reference detector (47).

The detector (47) selects only signals having amplitudes greater than a predetermined reference. Note that this signal is used by the counter (48
), and the accumulator energizing device (33).

The oil flowing in the flow path contains many types of foreign substances that are unrelated to each other, such as magnetic particles, non-magnetic metal particles, non-metal particles, water droplets, air bubbles, and the like.

During operation, the magnetic particles are attracted towards the pole piece (61) of the accumulator (3);
1) Gather above.

The smaller the particles, the smaller the moment, and therefore the higher the rate at which they are collected in the accumulator (3), whereas the larger particles flow towards the downstream sensor (4).

When a foreign object passes through the part of the flow path (2) surrounded by the upper coil (40), the inductance of the coil (40) changes, so that the two coils (40) (4
1) and an oscillator (42).

This causes a sudden modulation of the alternating voltage signal during the input of the demodulator (44), after which the foreign object immediately enters the flow path (2).
Another sharp signal occurs as it passes through the area surrounded by the lower coil (41) in K.

The phase and magnitude of the signal entering the demodulator (44) will vary depending on the resistivity, permeability, size and shape of the foreign object flowing in the flow path, and will also vary depending on the frequency of the oscillator.

The device according to the invention is used to indicate the lifespan of an engine;
This is most effectively accomplished by measuring the amount of magnetic particles present in the lubricating oil.

Therefore, this device selectively counts magnetic particles and ignores foreign objects such as air bubbles and carbon particles.

For this purpose, the demodulator (44) uses an oscillator (53)
The synchronizer (45) is controlled by adjusting the synchronizer (45) to provide a maximum signal-to-noise ratio for an input signal that is approximately 20 degrees out of phase with respect to the alternating current signal emanating from the ac signal.

When the magnetic particles pass through, a maximum signal-to-noise ratio occurs at a particular frequency of the oscillator (33). On the other hand, if a signal is generated that is 90 degrees out of phase with respect to the magnetic signal, for example by a non-magnetic particle, then the magnetic signal is transferred to the demodulator (44
) is significantly attenuated by

The energization of the electromagnet in the accumulator (3) continues until the amount of collected particles is sufficient to be detected by the sensor (4). Thereafter, the particles are deenergized and collected in agglomerated form, causing them to flow together with the liquid in the channel (2).

The electromagnetic coil (32) is energized for a fixed period of time or is controlled depending on the amount of particles detected.

In this device, the energization of the electromagnet causes the amount of particles released after being collected by the accumulator (3) to
This continues until the amount is sufficiently detected by the sensor (4).

It is also possible to control the energization of the electromagnet in response to changes in the inductance of the pole piece (31). This is because the change in inductance changes as the particles contact the pole piece (31).

The pole piece (51) is preferably covered with a non-magnetic material so that particles can be easily removed from the pole piece (31) when the electromagnet is demagnetized.

The accumulator (3) may not protrude into the flow path (2), but may have an annular shape surrounding the flow path.

Further, the accumulator (3) does not necessarily have to be something like a magnet.

Alternatively, particles can be collected in a similar manner, for example using an electrostatic device. This is particularly effective for detecting particles within the gas flow path.

In another embodiment, particles may be collected by a periodically rotating sieve, with particles that collect on the negative side of the sieve being blown into the liquid stream.

Particle sensors do not necessarily have to be of the inductive type, for example, capacitive or optical systems may be used.

The particle detection device of the present invention can be applied not only to engines but also to, for example, chemical plants, mineral processing plants, heating fluid supply systems, sewage treatment plants, waterways such as rivers and canals.

[Brief explanation of the drawing]

The drawing is a schematic representation of an embodiment of a particle detection device according to the invention in relation to a flow path. (1) Arrow (2) Oil flow line (3) Particle accumulator (4) Sensor (31) Pole piece (62) Coil (53) Biasing device (40) L-shaped coil (41) L-shaped coil (42) Oscillator (
43) Line (44) Demodulator (45) Phase shift transformer and synchronizer (46) Bandpass filter device (47) Norse reference detector (48) Counter

Claims (1)

[Claims] (A particle detection device comprising a particle sensor provided at a key point in a flow path, comprising an accumulator at a position upstream of the particle sensor in the flow path, A particle detection device characterized in that the emulator collects at least a portion of the particles flowing in the flow path and periodically releases them in order to send them toward the sensor. (2) The particle detection device according to claim (1), characterized in that the accumulator releases the collected particles in accordance with the output of the sensor (4). (3) The particle detection device according to claim 1 or 2, characterized in that the particle sensor reacts to conductive particles. (4) The particle sensor reacts to conductive particles. The particle detection device according to any one of claims (1) to (4), characterized in that the particle sensor is a sensor of the present invention. The particle detection device according to claim (4), characterized in that the device includes two dielectric coils separated from each other. (6) The nacumulator includes a magnet for collecting magnetic particles. The particle detection device according to any one of claims (1) to (5).(7) The magnet is an electromagnet, and the particles are released by demagnetizing the magnet. (8) The device according to claim (6), characterized in that the accumulator protrudes into the flow path. Chapter (7)
The particle detection device according to any one of paragraphs. (9) The particle detection device according to any one of claims (1) to (8), wherein the flow path is an oil flow path.