JP2001108564A - Leak measuring instrument - Google Patents

Abstract

(57) [Summary] (with correction) [PROBLEMS] To prevent a measurement time from becoming long due to a high pressure remaining in the other pressure chamber 3 connected to a measurement target side in a leak measurement device. SOLUTION: A piston P provided in a cylinder C divides the inside of the cylinder C into one pressure chamber 2 and the other pressure chamber 3, and moves the piston P when the one pressure chamber 2 is pressurized. To measure the amount of leak of a circuit or the like to be measured, while the piston P is connected to the other pressure chamber 3
A check valve 9 is provided to allow only flow from the pressure chamber 2 to one pressure chamber 2.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a leak measuring device for detecting a leak of a circuit or the like to be measured based on a movement amount of a piston in a cylinder.

[0002]

2. Description of the Related Art FIG. 2 shows a conventional type of leak measuring device. In this conventional leak measuring device, a piston holding portion 1 is formed in a cylinder C, and the piston P is slidably held by the piston holding portion 1. By inserting the piston P into the piston holding portion 1 as described above, the inside of the cylinder C is partitioned into one pressure chamber 2 and the other pressure chamber 3. The piston P has a detection hole 4 formed on its axis. The detection hole 4 is opened only on one pressure chamber 2 side. The pressure receiving area S1 of one pressure chamber 2 including the bottom of the detection hole 4 is equal to the pressure receiving area S2 of the other pressure chamber 3. A sensor element 5 composed of a coil is provided at the opening of the detection hole 4 as described above.

Further, a detection rod 6 is fixed to the one pressure chamber 2 side. The detection rod 6 is made smaller than the inner diameter of the detection hole 4 so that both are kept in a non-contact state. I keep it. Since the non-contact state is maintained as described above, the pressure in one pressure chamber 2 acts on the bottom of the detection hole 4. Therefore, the pressure receiving areas S1 and S2 in the two pressure chambers 2 and 3 are equal as described above.

[0004] A core 7 is provided on the detection rod 6, and the core 7 and the sensor element 5 constitute a differential transformer as a non-contact stroke sensor. The detection rod 6 is electrically connected to a detector 8 provided outside the cylinder C. A differential transformer like this is
The induced voltage changes in accordance with the relative position between the core 7 and the sensor element 5, and the detector 8 detects the change in the induced voltage, thereby detecting the amount of movement of the piston P.

Therefore, for example, if one pressure chamber 2 is connected to the pressurized side (not shown) and the other pressure chamber 3 is connected to the measurement target side, if there is no leakage on the measurement target side, both pressure chambers 2 are connected. The pressures in the chambers 2 and 3 become equal, for the following reason. That is, when the pressure on one pressure chamber 2 side is increased, if there is no leakage on the measurement target side,
The piston P cannot move. The fact that the piston P cannot move means that the acting force of the piston P on one pressure chamber 2 side and the reaction force on the other pressure chamber 3 side are balanced. Moreover, since the pressure receiving areas S1 and S2 of the piston P are equal as described above, when the forces acting on the piston P are balanced as described above, the pressures of the two pressure chambers 2 and 3 are also equal.

[0006] When leakage occurs on the measurement target side,
The pressure in the other pressure chamber 3 decreases by the amount of leakage. As a result, the piston P moves to the right in the drawing,
At this time, an induced voltage corresponding to the amount of movement of the piston P is generated in the differential transformer. The induced voltage is detected by the detector 8, and the amount of movement of the piston P, that is, the amount of leakage on the measurement target side is measured.

[0007]

When the conventional leak measuring device as described above is used, first, the pressure on the side to be measured is introduced into the other pressure chamber 3, and thereafter,
The pressure on one pressure chamber 2 side is increased. However, the initial pressure is also applied to the one pressure chamber 2, but the pressure is set to be considerably low. In the above state, if the pressure on the measurement target side is high, the piston P
To the stroke end on the side. Thereafter, the pressure in the one pressure chamber 2 is increased.
The measurement cannot be performed unless the pressure in the chamber rises to the pressure in the other pressure chamber 3. In other words, in this conventional measuring instrument,
There is a problem that it takes some time until the pressure in the pressure chamber 2 increases and the amount of leakage can be measured. SUMMARY OF THE INVENTION It is an object of the present invention to provide a leak measuring device which can measure immediately when pressure is introduced to one pressure chamber.

[0008]

According to the present invention, a piston provided in a cylinder partitions the inside of the cylinder into one pressure chamber and the other pressure chamber, and connects the one pressure chamber to a pressurizing side. The other pressure chamber is connected to a circuit to be measured or the like, and the amount of movement of the piston when one of the pressure chambers is pressurized is used to measure the amount of leakage in the circuit or the like to be measured. It is assumed that the leak measuring device has the same pressure receiving area of the piston in the pressure chamber. It is characterized in that the piston is provided with a check valve that allows only the flow from the other pressure chamber to the one pressure chamber while assuming the above-described measuring device.

[0009]

In the embodiment shown in FIG. 1, the other pressure chamber 3 and the detection hole 4, that is, one pressure chamber 2 are connected to the piston P via a check valve 9. The check valve 9 is connected between the other pressure chamber 3 and the one pressure chamber 2.
It is configured to allow only distribution to All other configurations are the same as the conventional one.

Now, when the other pressure chamber 3 is connected to the measurement object side holding a certain pressure, the pressure fluid guided there is pushed to open the check valve 9 and is also guided to the one pressure chamber 2. . Therefore, both pressure chambers 2 and 3 immediately become the same pressure. In other words, the other pressure chamber 3 is connected to the object to be measured, and at the same time, becomes ready for measurement.

After the two pressure chambers 2 and 3 have the same pressure as described above, they function as before. In other words, if a leak occurs on the measurement target side, the other pressure chamber 3
The pressure inside is reduced. Therefore, the pressure in one pressure chamber 2 overcomes, the piston P moves rightward, and the amount of leakage on the measurement target side can be measured based on the amount of movement. When the piston P moves rightward as described above, the pressure in the one pressure chamber 2 becomes higher than the pressure in the other pressure chamber 3, so that the check valve 9 remains closed. In other words, the fluid in one pressure chamber 2 does not leak to the other pressure chamber 3.

In the above embodiment, the amount of movement of the piston P is detected based on the amount of relative movement between the sensor element 5 and the core 7. However, as an invention, the piston P
As long as the measuring device has the same pressure receiving area, any mechanism for detecting the amount of movement of the piston may be used. For example, the movement amount of the piston may be taken out of the cylinder C and measured.

[0013]

According to the leak measuring device of the present invention, even when the pressure on the measurement object side is high, it can be connected to the cylinder and the leak can be measured at the same time. Therefore, it is possible to solve the problem that it takes a long time before the measurement can be performed as in the related art.

[Brief description of the drawings]

FIG. 1 is a sectional view.

FIG. 2 is a sectional view of a conventional leak measuring device.

[Explanation of symbols]

 C Cylinder P Piston 1 Piston holding part 2 One pressure chamber 3 The other pressure chamber 4 Detection hole 5 Sensor element as element 9 Check valve

Claims (1)

[Claims] A piston provided in a cylinder divides the inside of the cylinder into one pressure chamber and the other pressure chamber, and connects one of the pressure chambers to a pressurizing side and connects the other pressure chamber to a measurement target. Connected to a certain circuit or the like, the amount of movement of the piston when one of the pressure chambers is pressurized, and configured to measure the leak amount of the circuit to be measured, etc. A leak measuring device, wherein the piston is provided with a check valve that allows only the flow from the other pressure chamber to the one pressure chamber.