KR100351998B1 - Measurement apparatus for piston ring - Google Patents

Abstract

The purpose of the present invention is to pinpoint the rotational movement of the piston ring to reduce the engine oil consumption, it is possible to design for the optimization of the piston temperature is a new type of piston that can contribute to the improvement of engine performance and piston durability It is to provide a ring rotation measuring device.

To this end, the present invention is mounted on the cylinder liner opposite to the position where the top ring of the piston is mounted, the gap sensor of the eddy current (eddy current) type of the output voltage changes according to the position of the counterpart;

A slot formed by being processed to have a predetermined depth and length in a form recessed from a surface on an outer circumferential surface of the top ring facing the gap sensor;

A signal amplifier for amplifying the output voltage when the gap sensor outputs a changed voltage according to a distance from the top ring recessed surface of the top ring;

An f-v converter for analyzing the rotation period of the piston ring by analyzing the signal amplified by the signal amplifier;

And a computer for data processing, storage, and display as described above.

Description

Measuring device for rotational movement of piston ring {Measurement apparatus for piston ring}

The present invention relates to a piston ring rotational motion measuring apparatus using a gap sensor (gap sensor).

A piston is a mechanism that reciprocates in a cylinder and receives high-pressure and high-pressure gas pressure in an expansion stroke, and applies it to the crankshaft through a connecting rod.The piston is 2000 ° C like a cylinder because its head forms part of the combustion chamber. It is exposed to the above combustion gas and is affected by the high temperature, but unlike a cylinder, it cannot be cooled directly with cooling water or outside air.

For this reason, the piston has a much larger expansion ratio than the cylinder, and the diameter of the piston is designed to be slightly smaller than the diameter of the cut in consideration of expansion due to the difference in temperature.

However, if the gap between the cylinder and the piston is large, the high pressure gas leaks out during compression and expansion, thereby maintaining the tightness of the combustion chamber, preventing the expansion gas from leaking from the combustion chamber to the crankcase and simultaneously In order to radiate heat through the cylinder wall, the piston ring is fitted into the piston ring groove formed in the piston head.

However, this piston ring cuts a part of the ring and creates a tension by inserting an end gap (gap between two opposite ends of the piston ring) into the piston. If it is too small, it causes the haptic to contact and break or damage the cylinder when thermally expanded.

On the other hand, when the piston ring with the inlet is mounted on the piston, the piston ring rotates according to the piston's reciprocating motion (a phenomenon that rotates along the outer periphery of the piston). Various measures have been taken to measure the rotation of the piston ring in relation to the oil consumption of the engine and the temperature characteristics of the piston.

Recently, as a method of measuring the rotational movement of the piston ring, a method using a radioactive tracker and a method of measuring a temperature change by attaching a temperature sensor to a liner are widely used.

However, it has been pointed out that the method using the radiotracer has a relatively small measurement error, but it is difficult to implement a test apparatus. In other words, the method of using a radiotracer requires the production of radioisotopes and requires special equipment to detect isotopes, and therefore requires special manpower and special management due to the handling of radioactive materials. There is a problem that it is limited to apply this to the actual engine test.

Another method using the temperature sensor is a useful measuring method in diesel engines in which the temperature deviation of the cylinder liner in which the piston port is in contact with the rotation of the piston ring is large. It is pointed out that in gasoline engines which are only less than °, the reliability is poor in consideration of measurement error.

Accordingly, the present invention has been proposed in view of the above point, and its object is to accurately grasp the rotational movement of the piston ring, thereby reducing the consumption of engine oil, and to design the piston temperature for optimization. And to provide a piston ring rotational motion measuring apparatus of a new method that can contribute to the improvement of piston durability.

In order to achieve the above object, the present invention includes a gap sensor of the eddy current type is mounted on the cylinder liner opposite to the position where the top ring of the piston is mounted, the output voltage changes according to the position of the counterpart;

A slot formed by being processed to have a predetermined depth and length in a form recessed from a surface on an outer circumferential surface of the top ring facing the gap sensor;

A signal amplifier for amplifying the output voltage when the gap sensor outputs a changed voltage in accordance with a distance from the slot recessed to the top ring surface;

An f-v converter for analyzing the rotation period of the piston ring by analyzing the signal amplified by the signal amplifier;

And a computer for data processing, storage, and display as described above.

1 is a view showing the mounting state of the gap sensor of the present invention.

2 is a system configuration diagram of a rotational movement measuring device of the piston ring according to the present invention.

Figure 3 is an enlarged view of the main portion of the piston ring according to the present invention.

FIG. 4 is a graph showing voltage characteristics output from a gap sensor when the piston ring of FIG. 3 rotates in a counterclockwise direction.

FIG. 5 is a graph illustrating voltage characteristics output from a gap sensor when the piston ring as shown in FIG. 3 rotates in a clockwise direction.

※ Explanation of codes for main parts of drawing

1: piston 4,5,6, piston ring

7: cylinder liner 8: gap sensor

9,10: slot (groove) 11: signal amplifier

12: f-v converter 13: A / D converter

14 computer 15 flat surface

Hereinafter, the configuration and operation of the present invention will be described with reference to the accompanying drawings.

1 is a view showing the mounting state of the gap sensor of the present invention, Figure 2 is a system configuration diagram of a piston ring rotational motion measuring apparatus according to the present invention.

A plurality of ring grooves (2) (3) (16) are formed in the head of the piston (1), and each ring groove (2) (3) (16) has a piston ring (4) (5) consisting of a compression ring and an oil ring. (6) is mounted.

One of the piston rings 4, 5 and 6 is provided with a gap sensor 8 (Gap Sensor) at a portion (TRR point) of the cylinder liner 7 opposite the top ring 4 at the preferred position. do.

The gap sensor 8 is an eddy current method in which the output voltage changes according to the position of the counterpart object. Likewise, its outer circumferential surface has a constant depth (t ₁ , t ₂ ) and length ( Slots 9 and 10 having a are machined.

The slots 9, 10 are preferably at least two recesses 9, for example, recessed from a surface having a depth of 50 μm and a width of 3 mm and a depth of 50 μm adjacent to the recess 9. The groove 10 having a length of 3 mm is molded to be adjacent to each other.

And the gap sensor 8 is installed in a plurality of cylinder liner (7), for example, three places at intervals of 120 °, its measurement temperature is able to detect a depth (distance from the gap sensor) in the 500㎛ range Is suitable.

The installation angle of the gap sensor 8 is installed at an angle that can minimize the measurement error, and the position of the top ring 4 is determined by measuring the crank angle signal.

The gap sensor 8 increases the electromotive force as the distance from the counterpart increases and the output voltage increases. The gap sensor 8 measures the position of the top ring 4 as the output voltage changes, and the top ring 4 rotates. When the slot 9, 10 passes the position where the gap sensor 8 is mounted, the depth of the groove of the slot 9, 10 increases, the electromotive force increases, and the output voltage changes, and the gap sensor 8 The output voltage from) is applied to the signal amplifier 11, the signal is amplified to the extent that can be analyzed, and then sent to the fv converter 12 to analyze the rotation period of the top ring (4).

The f-v converter 12 is connected to the A / D converter 13 and the computer 14 so that the measurement data is processed and stored in the computer 14 and displayed through the monitor.

Accordingly, if the piston ring, that is, the top ring 4 rotates in the counterclockwise direction, the signal output from the gap sensors 9 and 10 exhibits the characteristics as shown in FIG. 4.

That is, in the state where the flat surface 15 of the top ring 4 except the portion where the slots 9 and 10 are machined is opposed to the gap sensor 8, the reference voltage 1V is output. When 9 and 10 pass in front of the gap sensor 8, the distance from the gap sensor 8 is increased according to the depth of the slots 9 and 10, so that the output voltage increases and appears.

4 shows that the output voltage is increased in two stages. This is because the grooves of the slots 9 and 10 are composed of two grooves 9 and 10 having different depths. Since the depth from the gap sensor 8 is smaller than the grooves 10 and 50 μm deep through which the grooves 9 and 30 μm deeply pass, for example, when the grooves 9 pass through the gap sensor 8. If V is output, when the deeper groove 10 passes through the gap sensor 8, 2V is output, and all of these slots 9 and 10 pass in front of the gap sensor 8, When the flat surface 15 passes, the output voltage is lowered to the reference voltage (1V), resulting in a voltage output pattern as shown, and the rotation period is judged by the change of the high and low state of the voltage.

However, if the piston ring, that is, the top ring 4 is rotated in the clockwise direction, the deep groove 10 first passes through the gap sensor 8, so that the voltage output pattern is shown in FIG. If the different appear as shown in Figure 5 it means that the direction of rotation of the piston ring (4) is reversed, so that the direction of rotation of the piston ring (4) can also be seen by looking at the voltage characteristics shown.

Therefore, by measuring the change in the signal in real time it is possible to grasp the rotation cycle and the direction of rotation, which is the characteristic of the rotary motion of the piston ring.

In the present invention, when a plurality of gap sensors 8 are installed at three places, for example, at 120 ° intervals, the rotational characteristics of the piston ring are regarded as one rotation when the output voltage change of the high and low occurs three times. It is possible to grasp how the operation time is different, and in particular, when the piston ring 4 stops rotating, it is possible to estimate the stop position of the piston ring 4 at that time.

According to the present invention as described above, one gap sensor in which the output voltage changes according to the distance to the counterpart is embedded at the TRR position of the cylinder liner, and one at any position of the top ring mounted on the piston at the position opposite to the gap sensor. By forming the above grooves (the depths of the grooves are different when two are formed), when the grooves pass through the gap sensor, a high voltage is output and the change characteristics of the output voltage are analyzed and represented by a computer. It is possible to accurately measure the rotational characteristics of the ring, that is, the rotation period and the direction of rotation, so that the temperature of the piston and the amount of oil consumption can be measured, which greatly increases the efficiency of the engine design.

Claims (2)

A gap sensor mounted on a cylinder liner opposite to the position where the top ring of the piston is mounted, wherein an output voltage changes according to the position of the counterpart; A slot formed by being processed to have a predetermined depth and length in a form recessed from a surface on an outer circumferential surface of the top ring facing the gap sensor; A signal amplifier for amplifying the output voltage when the gap sensor outputs a changed voltage according to a distance from the top ring recessed surface of the top ring; An f-v converter for analyzing the rotation period of the piston ring by analyzing the signal amplified by the signal amplifier; And a computer for data processing, storage, and display as described above. The method of claim 1, The slot is a rotational movement measuring device of the piston ring, characterized in that formed by a plurality of grooves are continuously out of the depth different from each other.