JP3470125B2 - Divertor for liquid flow rate calibration device - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a diverter used in a liquid flow rate calibration device for calibrating a flow meter for measuring the flow rate of a liquid with high accuracy.

[0002]

2. Description of the Related Art In order to calibrate a flow meter for measuring a flow rate of a liquid with high accuracy, as shown in FIG. 1, a liquid sucked from an underground tank is guided to a flow meter test pipe via an overflow tank. Then, when a stable flow is generated in the test pipeline and when passing through the flow meter provided in the test pipeline, the liquid measured by the flow meter is switched to the weighing tank side at high speed by the diverter provided at the top of the weighing tank. Flow into the weighing tank. After a lapse of a predetermined time, the flow is switched to the underground tank side by the diverter to stop the inflow of the liquid into the weighing tank, and the liquid flow rate per unit time is calculated from the inflow amount of the liquid flowing into the weighing tank and the inflow time. Was common.

[0003]
In the conventional diverter, for example, the amount of liquid passing through is 3
In the case of 000 m ³ / h, the rotating blade 2 has a large height of 2 m and a width of 1.5 m, and since it is necessary to change the direction of the water flow at a high speed, one rotating blade is used as shown in FIG. Two
Was being hydraulically rotated. In order to reduce the measurement error, the flow velocity distribution of the inflowing water flow is made symmetrical by narrowing the flow at the nozzle 1 for the purpose of making the transitional inflow state at the start and stop of the inflow into the weighing tank symmetrical. There was a need.
In order to switch the flow using this diverter, the rotary vane 2 is rotated counterclockwise when switching from the underground tank to the weighing tank, while the rotary vane 2 is rotated clockwise when switching from the weighing tank to the underground tank. Rotate to.

[0004]
At this time, due to the slight asymmetry of the flow velocity distribution of the water flow coming out of the nozzle 1 and the asymmetry of the rotation of the rotary blades 2, the inflow amount into the weighing tank at the time of switching becomes asymmetric as shown in FIG. It was an error factor.
That is, FIG. 4 shows the inflow state of the liquid flowing into the weighing tank with time. First, assuming that the rotating blade 2 starts rotating counterclockwise at point a, the movement of the rotating blade 2 is as follows. It is detected by a sensor or the like at the point b, and the switching of the rotary blades 2 from the underground tank side to the weighing tank side is completed at the point c. After the liquid has flowed into the weighing tank for a predetermined time, the rotating blade 2 starts rotating clockwise at the point d, the sensor or the like detects the movement of the rotating blade 2 at the point e, and from the weighing tank side to the underground tank side at the point f. The switching of the rotary blade 2 to is completed.

Therefore, by measuring the inflow amount of the liquid into the weighing tank during this period and dividing the inflow amount by the time be, the inflow amount q per unit time in the steady state can be obtained. However, in actuality, as shown in FIG. 4, the transient inflow state of inflow start and inflow stop into the weighing tank is asymmetrical, so the inflow rate differs from the inflow rate per unit time in the steady state. Was flowing into the weighing tank, which was an error. Another example of the conventional diverter is shown in FIG. This is 1
The commutation blade 2 composed of a single blade is supported so as to be reciprocally movable in the horizontal direction, and is switched left and right by an appropriate drive device (not shown) to switch the liquid inflow. Is similar to that of the rotary blade shown in FIG.

[0006]

SUMMARY OF THE INVENTION According to the present invention, even if the flow velocity distribution of the water flow coming out of the nozzle is asymmetric, the rotation of the rotary vanes is asymmetric, or the horizontal reciprocating motion of the commutating vanes is asymmetric. Another object of the present invention is to provide a diverter for a liquid flow rate calibration device which has no error by making the transitional inflow state of start and stop of inflow into the weighing tank symmetrical.

[0007]

The present invention SUMMARY OF], for the purpose of solving the above problems, in a switching apparatus that switches the flow of liquid into the weighing tank, the constant
A switching blade composed of two blades arranged at intervals in the direction of liquid flow is provided to be switchable, and start and stop of inflow of liquid into the weighing tank are switched in a series of operations in one direction of the blade. It is characterized in that it is done. The present invention also provides a switching apparatus that switches the flow of liquid into the weighing tank, regular intervals
A switching blade composed of two blades arranged in the direction of the liquid flow is provided movably in the horizontal direction, and the start and stop of the inflow of the liquid to the weighing tank are switched and a series of operations in one direction of the blade are performed. It is characterized in that it was done in. The present invention also provides a switching apparatus that switches the flow of liquid into the weighing tank, during a predetermined
A switching vane composed of two blades arranged in the direction of liquid flow with a gap is rotatably provided to start and stop the inflow of liquid into the weighing tank in a series of operations in one direction of the vane. It is characterized in that it is done.

[0008]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings. FIG. 5 shows a state in which the switching blades are switched so that the liquid flowing into the underground tank flows into the weighing tank. The liquid that has passed through a flow meter (not shown) is ejected from the nozzle 1 and is switched by the switching blade 2 to an underground tank or a weighing tank. As shown in FIG. 5, the switching blade 2 is composed of two blades arranged at a constant interval and having a streamline shape in the liquid flow direction, and is supported so as to be movable in the liquid path 4 in the horizontal direction. There is. The switching blade 2 is driven to the left and right by an appropriate driving device so that it can selectively take three positions of a left end position, a center position and a right end position. The liquid flows into the underground tank when the switching vane 2 is at the left end position and the right end position, and the liquid flows into the weighing tank when it is at the central position. A flexible pipe 3 and the like are connected below the switching blade 2 so that the liquid is guided to the weighing tank by following the movement of the switching blade 2.

[0009]
In order to measure the amount of liquid that has passed through the flow meter, first, the switching blade 2 is moved in parallel from the state of the left end position where the liquid was flowing into the underground tank to the central position. When the switching vanes 2 are in the central position, the liquid flows from the underground tank into the weighing tank. After the liquid has flowed into the weighing tank for a predetermined time, the switching blade 2 is further translated rightward and stopped at the right end position. Then, the inflow of liquid switches from the weighing tank to the underground tank. By measuring the amount of liquid flowing into the weighing tank during this period, the amount of liquid that has passed through the flowmeter can be measured. Also, the switching blade 2
In order to measure the inflow amount of the liquid into the weighing tank from the state where is at the right end position, first, the switching vane 2 is switched to the central position to allow the liquid to flow into the weighing tank, and after a predetermined time, the switching vane is further moved to the left end position. The liquid may be switched to stop the flow of the liquid into the weighing tank.

FIG. 7 shows the inflow state of the liquid flowing into the weighing tank with time. First, if the switching blade 2 starts to move in parallel from the left end position to the central position at point a, the switching blade will be described. The movement of 2 is detected by a sensor or the like at point b, and the switching of blade 2 is completed from the underground tank side to the weighing tank side at point c. After the liquid has flowed into the weighing tank for a predetermined time, the switching blade 2 starts moving from the central position to the right end position at point d, a sensor or the like detects the movement of the switching blade 2 at point e, and from the weighing tank side at point f. The switching of the switching blade 2 to the underground tank side is completed.

Therefore, by measuring the inflow amount of the liquid into the weighing tank during this period and dividing the inflow amount by the time be, the inflow amount q per unit time in the steady state can be obtained. From FIG. 7, it can be seen that the transitional inflow state of the inflow start and inflow stop into the weighing tank is symmetrical. That is, the shaded portion between the points ab and the shaded portion between the points de, and the shaded portion between the points bc and the shaded portion between the points ef show the same shape,
As a whole, the transitional inflow state of inflow start and inflow stop into the weighing tank is symmetrical. This is because switching of the switching vanes 2 is performed in a series of operations in one direction, so that whether the flow velocity distribution of the water flow exiting the nozzle 1 is asymmetrical or the rotation of the switching vanes 2 is asymmetrical is not affected by these factors. It is due.

Therefore, even if the velocity distribution of the water flow coming out of the nozzle 1 is asymmetric, or the left and right rotation or reciprocal movement of the switching blade is asymmetric, the amount of inflow into the weighing tank at the time of switching is affected. It is possible to accurately measure the inflow amount per unit time without affecting.
In another embodiment according to the present invention shown in FIG. 6, a switching blade 2 composed of two blades is rotatably supported around a rotation center 5, and the switching blade 2 is at a left end position, a center position or a right end position. The rotational position is driven by an appropriate drive device so that the three positions can be selectively taken. The inflow state of the liquid into the weighing tank is the same as that of the switching blade shown in FIG. The transitional inflow state of the stop is symmetrical.

[0013]

In the diverter according to the present invention, 2
By providing a switching vane consisting of a single blade and starting and stopping the inflow of the liquid into the weighing tank in a series of operations in one direction of the switching vane, the velocity distribution of the water flow exiting the nozzle Even if the switch is asymmetrical, or the left and right rotation or reciprocating motion of the switching blade is asymmetrical, it does not affect the inflow into the weighing tank at the time of switching, and the inflow per unit time is accurate. It becomes possible to measure.

[Brief description of drawings]

FIG. 1 is an overall schematic view showing an entire liquid flow rate calibration device.

FIG. 2 is a cross-sectional view of essential parts showing an example of a diverter used in a conventional liquid flow rate calibration device.

FIG. 3 is a cross-sectional view of essential parts showing another example of the diverter used in the conventional liquid flow rate calibration device.

FIG. 4 is an explanatory diagram showing a flow state of a liquid into a weighing tank when the conventional diverter shown in FIGS. 2 and 3 is used.

FIG. 5 is a cross-sectional view of essential parts of the diverter according to the first embodiment of the present invention.

FIG. 6 is a cross-sectional view of essential parts of a diverter according to a second embodiment of the present invention.

FIG. 7 is an explanatory diagram showing a flow state of the liquid into the weighing tank when the diverter of the embodiment of the present invention shown in FIGS. 5 and 6 is used.

[Explanation of symbols]

1 nozzle 2 switching blades 3 flexible tubes 4 fluid path 5 Rotation center of switching blade

─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-51-2451 (JP, A) SAI-KAI 64-29571 (JP, U) SHIMADA Takashi, Petroleum Large Flow Calibration Equipment, AIST today, 2002 February 7, (58) Fields surveyed (Int.Cl. ⁷ , DB name) G01F 25/00

Claims (3)

(57) [Claims] 1. A switching device adapted to switch the flow of liquid into a weighing tank at regular intervals.
A switching blade composed of two blades arranged in the direction of liquid flow is provided so as to be switchable, and the start and stop of the inflow of liquid into the weighing tank are performed in a series of operations in one direction of the switching blade. A diverter for a liquid flow rate calibration device characterized in that 2. A switching device for switching the flow of liquid into a weighing tank, wherein the liquid is kept at a constant interval.
A switching blade consisting of two blades arranged in the direction of body flow is provided movably in the horizontal direction, and the start and stop of inflow of liquid into the weighing tank are switched in a series of operations in one direction. A diverter for a liquid flow rate calibration device, characterized in that 3. A switching device for switching the flow of liquid into a weighing tank, wherein the liquid is held at regular intervals.
A switching blade composed of two blades arranged in the direction of body flow is rotatably provided, and the start and stop of the inflow of liquid into the weighing tank are performed in a series of operations in one direction of the switching blade. A diverter for a liquid flow rate calibration device characterized in that