JP2863395B2 - Piston prober - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a piston prober for checking the accuracy of a flowmeter, and more particularly, to a piston prober capable of inspecting a flowmeter in an extremely wide flow range.

[0002]

2. Description of the Related Art A verification device for verifying a flow meter is provided when a newly manufactured flow meter is used and when a flow meter in use is used for detecting a temperature,
In order to use the flowmeter with reliable accuracy against changes in characteristics due to external factors such as pressure or internal factors such as wear of the movable part, etc., to obtain characteristics by performing tests periodically or arbitrarily, so-called characteristics It is for conducting a test. This characteristic test can be roughly classified into a calibrator that performs a test by interposing a flow meter under test on a fixed test device, and a piston prober type flow meter that optionally performs a test by interposing a flow meter in a fluid system. It is performed by a test device. As described above, the piston prober system can perform a characteristic test of a flow meter online as described above, and can perform an arbitrary characteristic test as needed. It is often used for testing. A piston prober is a device in which a moving body such as a piston or a sphere moves along with a fluid in a pipe having a constant cross section, and the fluid discharged by moving the moving body in a predetermined section is used as a reference volume. The characteristic test of the flow meter is transmitted per unit volume by detecting the reading of the flow meter when a reference volume of fluid specified in the piston prober flows, that is, detecting the number of flow pulses transmitted from the flow meter. It calculates the number of flow pulses (flow coefficient), the so-called K factor. If necessary, a continuous flow characteristic curve is obtained based on the flow coefficients obtained for a plurality of observed flows.

The calibrator and the piston prober described above are mainly used for testing the characteristics of a large-sized flowmeter, but when testing a small-sized flowmeter, a piston prober having a piston is mainly used. ing. However, the accuracy of the flow meter has been improved, and a very small flow rate can be measured, and a very small flow rate measurement has been required in biotechnology, pharmaceutical measurement, and the like.
A prober that can test a wide range of flow rates is needed.

[0004] However, in the test of the conventional micro flow meter,
There was no valve means for opening and closing the extremely minute flow rate with high precision, and there was no piston prober for the extremely minute flow meter. Conventionally,
In order to flow an extremely small flow rate through the flow meter under test, for example, an injection needle is connected to the downstream side of the flow meter under test, and the test liquid measured by the flow meter under test is passed through a measuring cylinder or the like, and the test liquid is The flow rate has been determined from the volume or weight accommodated within a predetermined time. For this reason, the inner diameter of the injection needle has been selected as a method for setting the test flow rate. In such a method, there is a limit in the processing accuracy of the inner diameter of the injection needle, and furthermore, a required small diameter injection needle is not available, and depending on the selected injection needle, the measurement fluid becomes a droplet due to surface tension, A continuous flow was not obtained, resulting in a discontinuous flow. Further, since an accurate liquid volume cannot be obtained depending on a measuring cylinder or the like, the liquid droplet is stored in a container and measured with a scale. As a result, a constant flow cannot be obtained by the conventional method, and the liquid contained in the container evaporates, and the measured liquid volume and weight change, so that a high-precision test cannot be performed.

[0005]

The present invention has been made in view of the above circumstances, and provides a piston prober capable of flowing a test liquid of a continuous constant flow rate with high accuracy and obtaining a test flow rate in a wide flow rate range. It is intended to do so.

[0006]

To achieve the above object, the present invention provides (1)
A small cylinder having a uniform inner diameter, a large cylinder coaxially connected to one end surface of the small cylinder, and having a larger diameter than the small cylinder, and a piston which is movably inserted into the large cylinder in a liquid-tight manner; A piston rod liquid-tightly fitted into the small cylinder and having one end fixed to the piston, a sensor for detecting the movement of the piston, and the piston partitioned by the piston to drive the piston and the piston rod. A hydraulic means for pumping the driving oil at a constant flow rate into the large cylinder on the non-joining side with the small cylinder; and a piston and a rod driven by the hydraulic means are used to drive the large cylinder in a predetermined section of the large cylinder. Comparing the volume of the test liquid discharged from the oil side and / or the small cylinder with the measured flow rate of the flow meter to be measured, and (2) in the above (1),
A closed drive oil tank containing the drive oil, valve means disposed between the drive oil tank and the large cylinder and capable of switching according to a measured flow rate, a test liquid side and a small cylinder side of the large cylinder Each having a switching valve, a test line that is switchably connected to the flow meter to be measured, a bypass line that is switchably connected to the test line upstream of the switching valve, The other end of the test line is opened, and a closed test liquid tank containing a test liquid is provided.When the test flowmeter is inspected, the bypass line is closed, and the pressure of the driving oil tank is set to Higher than the pressure, the switching valve of the test line is closed at the time of non-inspection, the bypass line is opened, and the pressure of the test liquid tank is controlled to be higher than the pressure of the driving oil tank. Large cylinder and small cylinder Repeatedly to return to Da, it is characterized in that to inspect the test meter. Hereinafter, a description will be given based on examples of the present invention.

FIG. 1 is a block diagram for explaining a piston puller according to the present invention. In the drawing, reference numeral 1 denotes a driving oil tank, 2 denotes a flow meter, 3, 11, 12, 13, 14, 16, and 16;
17, 18 are open / close valves, 4 is a large cylinder, 5 is a small cylinder, 6 is a piston, 7 is a piston rod, 8, 9 is a position sensor, 10 is a scale, 15 is a flow meter to be measured, 16 is a converter, 19 Is the test solution tank, 20 is the interface, 2
1 is a flow rate calculation display device.

In the figure, a driving oil tank 1 is a closed tank containing driving oil, for example, kerosene, and the kerosene is provided with a flow meter 2 and
Switching valves 3a, 3b, 3c that are switched according to the flow rate are connected to a large cylinder 4 via an on-off valve 3 connected in parallel. The large cylinder 4 is coaxially connected to a small cylinder 5 having a smaller diameter than the large cylinder 4. Large cylinder 4
A piston 6 whose outer peripheral surface is sealed by a sealing material 6a is movably inserted therein, and a piston rod 7 is fixed to the piston 6. The piston rod 7 is sealed by a seal member 5 a and is fitted into the small cylinder 5.
Position sensors 8 and 9 are arranged on the outer peripheral wall of the large cylinder 4 at a predetermined distance from each other to detect the movement of the piston 6. Further, a scale 10 for detecting the movement of the piston 6 is provided in the large cylinder 4 as necessary.

A test liquid (for example, gasoline) is contained in the chamber 4a on the side of the small cylinder 5 and the small cylinder 5 in the large cylinder 4 partitioned by the piston 6, and the test liquid in the large cylinder 4a is supplied to the pipe 22a by the small liquid. The test liquid for the cylinder 5 is
b, and the flow is switched by the on-off valves 11, 12. The pipes 22a and 22b join to form a test line 22, which communicates with a test solution tank 19 that contains a test solution in a sealed manner. On-off valves 13 and 14 are provided on the test line 22, and a flow meter under test 15 is connected between the on-off valves 13 and 14. In FIG. 1, a plurality of flow meters under test 15 are connected in series. These flow meters under test include No.
8, No. 2,... No. 8, etc. are connected to each other, and flow rate signals from these converters 16 are connected to a flow rate calculation display device 20 via an interface (I / O) 19.

[0010] A bypass line 23 is connected to the test liquid tank 19 in addition to the test line 22. The bypass line 23 is diverted to 23 a and 23 b. And the diversion tube 23b
Is connected to the pipe 22b on the upstream side of the on-off valve 11. The test liquid tank 19 is connected to a high-pressure air source via an on-off valve 18. Naturally, during the test, the pressure in the drive oil tank 1 is kept higher than the pressure in the test liquid tank 19.

The operation of the block diagram of FIG. 1 configured as described above will be described. The piston prober is composed of a large cylinder 4 and a small cylinder 5, and the piston 6 has position sensors 8, 9
The volume at the time of moving between
When a, 16 and 17 are closed, the test liquid proportional to the movement of the piston 6 flows out from the pipe 22a to the test line 22. When the on-off valves 22a, 16 and 17 are closed, the amount of test liquid from the small cylinder 5 is proportional to the volume of the piston rod 7 into which the piston rod 7 is inserted, that is, the movement of the piston 6. Piping 2 in proportion to quantity
2b. Therefore, from the large cylinder 4 and the small cylinder 5, the actual area of the piston 6 and the piston rod 7
The test liquid flows at a flow rate proportional to the cross-sectional area of.

Small cylinder 5 of piston 6 of large cylinder 4
High pressure (for example, 5 kg / cm ² ) kerosene is press-fitted from the driving oil tank 1 into the chamber 4 b on the non-joining side. The flow rate of kerosene is detected by a flow meter 2 and switching valves 3 a to 3 according to the flow rate flowing into the large cylinder 4 by flow control means (not shown).
c is selected and switched to be controlled at a constant flow rate. That is, kerosene flows through the large cylinder 4 at a flow rate ratio corresponding to the capacity of the switching valves 3a to 3c.

The test liquid stored in the small cylinder 5 and the large cylinder 4a is switched by the on-off valve 11 or 12 to obtain a test flow rate. The test liquid is measured at 15 and flows into the test liquid tank 17. At this time, one of the on-off valves 16 and 17 of the bypass line on the test cylinder side is closed, and the non-test cylinder side is open. That is, when testing a large flow rate, the drive oil tank select the capacity corresponding off valve 3 to the flow-off valve V ₁₁ closed, V ₁₂ open, the bypass line side opening closing valve V _16, V ₁₇ closed and then, when testing convection amount off valve V ₁₁ closed, V ₁₂ open, close valve V ₁₆ opens the bypass line side and V ₁₇ closed. A flow rate signal is transmitted from the converter 16 of the flow meter under test 15 and input to the flow rate calculation display device 20 via the (I / O) 19 to calculate and display the flow meter accuracy such as flow meter difference.

When the test is completed, the test liquid in the large cylinder 4 and the small cylinder 5 has the minimum volume, and must be refilled to the initial state for the next test. Therefore, the pressure of the driving oil tank 1 is released to the atmosphere, the on-off valves 11, 12 are closed, and the on-off valves 16, 17, 18 are opened. At this time, since the pressure in the test tank 19 is rising, the test liquid is returned to the large cylinder 4 and the small cylinder 5 from the bypass lines 23a and 23b through the pipes 22a and 22b. As described above, as described above, the on-off valve 11,
12, 16 and 17 are switched, and the driving oil tank 1
Is set to a high pressure, and when the test is not performed, the test liquid is released to the atmosphere and the pressure ratio between the driving oil tank 1 and the test liquid tank 17 is changed to circulate the test liquid. The test can be safely repeated without being opened. In the above description, a constant test flow rate is obtained by controlling the flow meter 2 to be constant, but it may be controlled so that the scale 10 connected to the piston 9 is driven at a constant speed.

FIGS. 2A and 2B are views for explaining an example of a flow rate test range according to the present invention. FIG. 2A shows a test corresponding to the drive oil return valves 3a, 3b and 3c. Flow range,
(B) is a diagram showing a test flow range when the ratio of the outer diameter of the piston rod 7 of the large cylinder 4 to the inner diameter of the small cylinder 5 is set to 10.

In the test, the switching valves 3a, 3b, 3c
The kerosene is pumped to the large cylinder 4 via. The flow rate at this time is limited by the capacity of the switching valves 3a, 3b, 3c,
In this case, the flow rate ranges are set to 4 times, 5 times, and 5 times, respectively, and are set to 100 times by combination. Since the cross-sectional area of the large cylinder 4 is constant, the piston 6 moves at a constant speed (to the left in the figure) according to the capacity of the switching valves 3a to 3c. At this time, the piston 6 simultaneously drives the piston rod 7. If the outer diameter of the piston is 10d and the outer diameter of the piston rod is d, the flow ratio between the large piston 4 and the small piston 5 becomes 100 times. Therefore, by switching and combining the switching valve 3 and the large piston 4 or the small piston 5, 10
⁴ times the test flow range is obtained. In addition, since the test flow rate switching is performed on the large flow rate side of the large cylinder 4, the switching valve 3
There is no need to use anything special.

[0017]

As is clear from the above description, according to the present invention, the test flow rate is determined by the area ratio of the piston 6 moving in a fixed section of the large cylinder 4 and the piston rod 7 integral with the piston. Further, since the driving of the piston 6 is determined by the capacity of the switching valve 3 switched by switching the switching valve 3, the test flow rate is performed in a wide range determined by the product of the area ratio and the capacity ratio of the switching valve 3. In addition, since the selection of the switching is performed on the large cylinder side, no special switching valve is required even when the test is performed in a very small area. In addition, the test liquid tank 19 is closed, and the test liquid is circulated and used by changing only the pressure on the drive oil tank 1 side. Therefore, the test liquid does not leak to the outside air and the test liquid is dangerous. But you can test safely.

[Brief description of the drawings]

FIG. 1 is a block diagram for explaining a piston prober according to the present invention.

FIG. 2 is a diagram for explaining an example of a flow rate test range according to the present invention.

[Explanation of symbols]

1: Drive oil tank, 2: Flow meter, 3, 11, 12, 1
3, 14, 16, 17, 18 ... On-off valve, 4 ... Large cylinder, 5 ... Small cylinder, 6 ... Piston, 7 ... Piston rod, 8, 9 ... Position sensor, 10 ... Scale, 15 ... Test flow meter, 16: converter, 19: test liquid tank, 20: interface, 21: flow rate calculation display device.

──────────────────────────────────────────────────続 き Continued on front page (58) Field surveyed (Int.Cl. ⁶ , DB name) G01F 25/00

Claims (2)

(57) [Claims] 1. A small cylinder having a uniform inner diameter, a large cylinder connected coaxially to one end face of the small cylinder and having a diameter larger than the small cylinder, and movably inserted into the large cylinder in a liquid-tight manner. A piston, a piston rod one end of which is fixedly attached to the piston, which is inserted into the small cylinder in a liquid-tight manner, a sensor for detecting the movement of the piston, and the piston for driving the piston and the piston rod. In the large cylinder on the non-joining side with the small cylinder partitioned by the small cylinder has a hydraulic means for pumping the driving oil at a constant flow rate, the piston and the rod driven by the hydraulic means in a predetermined section of the large cylinder, A piston prober for comparing a volume of a test liquid discharged from a non-drive oil side of a large cylinder and / or a small cylinder with a measured flow rate of a flow meter to be measured. 2. A closed drive oil tank containing the drive oil, valve means disposed between the drive oil tank and the large cylinder and capable of switching according to a measured flow rate, and a test liquid for the large cylinder. A test line having a switching valve on each of the side and the small cylinder side, and a test line that is switchably connected to the test flowmeter, a bypass line that is switchably connected to the test line upstream of the switching valve, The other end of the bypass line and the test line is open, and comprises a sealed test liquid tank containing a test liquid. When the test flowmeter is inspected, the bypass line is closed and the pressure of the driving oil tank is reduced. Is higher than the pressure of the test liquid tank, and at the time of non-inspection, the switching valve of the test line is closed to open the bypass line, and the pressure of the test liquid tank is controlled to be higher than the pressure of the driving oil tank. , The test liquid into the large cylinder The piston prober according to claim 1, wherein the test flowmeter is inspected by repeating the return to the small cylinder.