KR200447667Y1 - Flowmeter that accuracy improves - Google Patents

Abstract

The present invention relates to a flowmeter with improved precision, and looks at the features of the configuration, the gear is installed while being rotated on the fuselage 10 of the vane flowmeter, rotated by the fluid conveyed through the inclined fluid transfer hole 20 gear Alternatively, the front surface 32a of the vane 32 of the vane 30, which measures the flow rate by the mechanism M of the magnetic pulse, coincides with the vane 30 vertical center line P or is in a rotational direction. Characterized in that it is provided to be spaced apart.

Accordingly, the present invention, even if the flowmeter is manufactured in a large capacity due to the installation position of the wing and the inclination of the fluid transfer hole, the flow rate is precisely measured by precisely measuring the flow rate due to the small flow rate, as well as the maximum flow rate measurement range as well as the maximum flow rate measurement. The range is also extended at the same time.

Flow meter, vane, vane, fluid, refraction

Description

Flowmeter that accuracy improves

The present invention relates to a flowmeter with improved precision, and more particularly to a flowmeter with improved precision for measuring the transfer amount of the fluid to be transported through the pipe.

Generally, there are various types of flowmeters according to the method of measuring the fluid transfer, but they are relatively widely used, including vane flowmeters, differential pressure flowmeters, and area flowmeters. Among them, the vane flow meter is the most compact in which the vane is turned by the flow of the fluid, and the number of revolutions is detected by the mechanism of the gear or the magnetic pulse and displayed numerically.

However, when the vane flow meter has a weak flow rate, the vane is not rotated or rotated in the reverse direction, and the measurement error is severely generated. That is, as shown in Figures 1a to 1b conventionally the flow meter is installed so that a portion of the wing (3a) of the vanes (3) is exposed to the fluid transfer hole (2) formed horizontally on the body (1), when the fluid is transferred While rotating, the flow rate is detected and the flow rate is measured. At this time, when the length of the blade 3a exposed on the fluid transfer hole 2 is short, as shown in FIG. If the flow rate is weak, the measurement error occurs because the vane is not rotated, and when the exposure length of the vane 3a is long, as shown in FIG. 1B, the flow rate is easy to measure even if the flow rate is weak. As the measurement error occurs by rotating, the area of the blades 3a contacting the fluid is increased, thereby disturbing the fluid flow, thereby reducing the maximum flow rate measurement range.

The commercially available flowmeters have a minimum flow rate measurement range and a maximum flow rate measurement range for the purpose of predicting the flow rate of the installation location and selectively applying the flowmeter. For example, 5-50 m 3 / h, 16- In the case of a flow meter with a flow rate measurement range such as 100㎥ / h, etc., and 16 to 100㎥ / h, the minimum flow rate measurement range is 16㎥ / h and the maximum flow rate measurement range is 100㎥ / h. Below / h was followed by the closure of measurement error.

As the minimum flow rate measurement range of the flowmeter is increased in proportion to the maximum flow rate measurement range, most companies require precise mixing / supply by adopting a flowmeter suitable for the maximum flow rate in consideration of the measurement error that occurs when the flow rate is weak. In the chemical manufacturing plant, the precision of the fluid supply cannot be maintained, and the quality deterioration and the defective rate of the product are increased.

Accordingly, the present invention has been devised in view of the above points, and more specifically, even when the flow rate is weak, reverse rotation of the vane is prevented, and flow measurement is precisely performed, and the precision of the maximum flow rate measurement range is improved. Its purpose is to provide a flow meter.

In order to achieve this purpose, a feature of the present invention is installed to be rotated on the fuselage 10 of the vane flow meter and rotated by a fluid conveyed through the fluid transfer hole 20 while flowing in a mechanism M of a gear or a magnetic pulse. Wing 32 front (32) of the wing 32 to measure the vane 30 is characterized in that it is provided so as to be in line with the vertical center line (P) perpendicular to or spaced apart in the rotational direction.

In addition, the fluid transport hole 20 of the vane flow meter is characterized in that the inlet 22 is positioned closer to the horizontal center line (H) of the vane 30 than the outlet 24 is formed as an inclined hole.

According to the above configuration and action, the present invention is because the front surface of the wing is located in the straight line or the rear of the vertical center line of the van, the fluid is injected into the fluid transfer hole through the pipe to hit the front surface of the wing and push it out. Since the force acts in the straight line or the rear of the vane, it prevents the reverse rotation of the vane and is easily rotated even by the weak force, so that the precision of the flow measurement is improved even when the fluid flow is small.

In addition, while the fluid introduced into the inlet through the pipe is deflected by the inclination of the fluid transport hole, the fluid is transported through one side inner wall of the fluid transport hole (for example, an inner wall adjacent to the vane) and rotates the vane in contact with the front surface of the blade. As a result, even if the transport amount of the fluid decreases, the fluid is refracted and concentrated on the front surface of the wing, so that the vane wheel has an effect of improving the rotation accuracy even when the fluid transport amount is small.

In addition, even if the flowmeter is manufactured in a large capacity due to the installation position of the wing and the inclination of the fluid transfer hole, the minimum flow rate measurement range is expanded as well as the maximum flow rate measurement range as the flow rate is precisely measured according to the small flow rate. At the same time there is an effect to be enlarged.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a configuration diagram generally showing the internal configuration of the horizontal maintenance structure of the excavator according to the invention, Figure 3 is a configuration diagram showing the overall internal configuration of the horizontal maintenance structure of the excavator according to a modification of the present invention.

The present invention relates to a flowmeter with improved precision, wherein the flowmeter with improved precision is a measuring device for quantitatively supplying a fluid to a predetermined position or measuring a transport amount of the fluid, which is installed at one end of a pipe (B) and The vehicle 30 is rotated, and the rotational force of the vane 30 is driven by operating the meter through the gear M or the mechanism of the magnetic pulse (for example, a state in which the mechanism of the magnetic pulse is applied in FIGS. 1 to 3). Detect the flow rate. At this time, in order to precisely measure the flow rate using the mechanism (M) of the gear or magnet pulse, the vanes 30 must be precisely rotated in response to the fluid flow.

The present invention is installed so as to rotate on the fuselage 10 of the vane flow meter is rotated by the fluid transported through the fluid transfer hole 20 while measuring the flow rate by the mechanism of the gear or magnetic pulse (M) (30) The front surface (32a) of the blade 32 is provided so as to be in line with the vane 30 vertical center line (P) or spaced apart in the rotation direction.

The body 10 has a space portion 10a formed at the center of the van body 30 so as to be rotatable, and a fluid transfer hole 20 is formed to penetrate the space portion 10a at one end of the body. The fluid transfer hole 20 is formed such that the inlet 22 through which fluid is injected into one end of the body 10 and the outlet 24 through which the fluid is discharged into the other end communicate with each other. In this case, the inlet 22 and the outlet 24 are connected. Is connected on the pipe (B) to which the fluid is transferred.

In addition, the vanes 30 are formed so that a plurality of vanes 32 are formed at a regular conformal angle in a radial structure on the outer circumference thereof, and are accommodated in the space portion 10a of the fuselage 10 before the vanes due to the flow of fluid. ) The surface is abutted and rotated. In this case, the front surface of the wing is installed to coincide with the vertical center line P of the vane 30 as shown in FIG. 2, or the front surface 32a of the vane 32 as shown in FIG. It is installed to be spaced apart from the vertical center line (P) of 30 (for example, eccentrically installed in the center of the vanes 30).

As described above, since the front surface 32a of the wing 32 is aligned with or perpendicular to the vertical center line P of the vane 30, the fluid transfer hole 20 is provided through the pipe B. Since the conveying force of the fluid injected into) acts in a straight line or rearward with the vertical center line (P) of the vane 30, the reverse velocity of the vane 30 is prevented, and thus it is easily rotated even in a weak conveying force. Even when the fluid transfer amount is small, there is an advantage that the flow rate is detected by precise rotation.

At this time, the fluid transfer hole 20 of the vane flow meter is formed in the inclined hole is located closer to the horizontal center line (H) of the vane 30 than the inlet (22). That is, as shown in FIGS. 2 to 3, the injection port 22 and the discharge port 24 do not coincide with each other on a horizontal line coaxial with each other, and the injection hole 22 is disposed at the horizontal center line H of the vane 30 rather than the discharge port 24. As it is formed adjacent to the ()) the fluid transfer hole 20 connecting the inlet 22 and the outlet 24 is formed to be inclined to the inclined hole.

Accordingly, the fluid introduced into the inlet 22 through the pipe B is refracted by the inclination of the fluid transfer hole 20 and is transferred to the outlet 24. In this case, the fluid injected in a straight line through the pipe B is refracted, and the fluid is refracted. Rotating the vanes 30 in contact with the front surface 32a of the vanes 32 while being transported aboard an inner wall of the air hole 20 (eg, an inner wall adjacent to the vanes 30) 20a. Let's go. Therefore, even if the amount of fluid is reduced, the fluid is refracted and concentrated on the wing 32 through one side inner wall 20a of the fluid transfer hole 20, so that the flow rate detection accuracy is improved even when the fluid transfer amount is small. Even if the length of the vane 32 is exposed to the short, there is an advantage that the vane 30 is precisely rotated to increase the capacity of the flow meter.

For example, if the inclination angle of the fluid transfer hole 20 is too fine, a phenomenon in which the fluid is not refracted during the transfer occurs, and if the inclination angle is too large, the fluid is severely refracted to interfere with the fluid flow. ) Is preferably inclined to about 1 ° ~ 5 °.

1a to 1b is a block diagram showing the internal configuration of a conventional flow meter.

Figure 2 is a schematic diagram showing the internal configuration of the horizontal maintenance structure of the excavator according to the invention as a whole.

Figure 3 is a block diagram showing the overall internal configuration of the horizontal maintenance structure of the excavator according to a modification of the present invention.

Claims (2)

Wings of the vanes 30 which are installed to be rotated on the fuselage 10 of the vane flow meter and rotated by the fluid conveyed through the fluid transfer hole 20 to measure the flow rate by the mechanism M of the gear or the magnetic pulse ( 32) The front surface 32a is formed to be in line with the vane 30 center line P or to be spaced apart in the rotational direction (installed eccentrically at the center of the wing van 30), The fluid transfer hole 20 is formed as an inclined hole inclined at an inclination of 1 ° ~ 5 ° so that the inlet 22 and the outlet 24 formed at both ends are inconsistent on a horizontal line coaxial with the inlet 22 and connected to the inlet 22. A flowmeter with improved precision, characterized in that the conveying force of the fluid injected in a straight line through (B) is concentrated on the inner wall (20a) of the fluid transfer hole (20) adjacent to the vanes (30). delete

Images