JPH0544606B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a slurry amount measuring device for measuring the transported weight of solid components in slurry transported along a slurry transport path.

For example, in tunnel construction, it is sometimes necessary to understand the excavation status in order to improve work efficiency, prevent damage to machinery, and prevent ground surface upheavals. For this reason, the transported weight of solid components (for example, ore) in the discharged slurry (solid-liquid two-phase fluid) is ascertained, and the transported amount is further integrated to provide management data such as hourly reports and daily reports.

In order to know the transported weight of the solid components in the slurry, measure the slurry density with a single tube density meter, measure the slurry flow rate with an electromagnetic flowmeter, and calculate the transported weight of the solid components using equation (1). methods are widely used.

W=QGs(P-Gw)/Gs-Gw...(1) However, W: Transportation weight of solid components (t/h) Q: Slurry flow rate ( ^m3 /h) Gs: True specific gravity (density) of solid components ( t/m ³ ) P: Slurry density (t/m ³ ) Gw: Fluid component (e.g. water) density (t/m ³ ) Figure 1 is a diagram showing an example of a conventional slurry amount measuring device. In addition to the transported weight of solid components, it is now possible to extract data such as slurry density. 1 in the figure is a single tube density meter,
2 is an electromagnetic flowmeter, 3 is a solid component density setting device, 31
32 is an amplifier, 32 is a multiplier/divider, 33 and 34 are multipliers, 35 is an integrator, and 36 is a display meter that displays the integrated amount of transported weight of solid components.

The single-tube densitometer used here as a device for measuring slurry density uses a slight restriction installed in the measurement tube to theoretically compensate for pressure loss due to flow velocity and measure only the density of the fluid. It is a differential pressure type densitometer designed to detect pressure, and it is the most widely used because it has advantages such as no risk of wear and a simple structure.

However, a single-tube density meter requires a relatively long vertical pipe section, and vertical pipe sections above and below it to stabilize the flow rate, so the vertical straight pipe distance is As shown by L in Figure 1, it is quite long. As a result, a large space is required in the height direction, which places great restrictions on the installation location.On the other hand, head loss is added to conduit loss, which poses particularly great restrictions at tunnel construction sites.

On the other hand, in order to measure slurry density, in addition to a single tube density meter, there are float type, vibrating type,
Alternatively, a gamma ray type is known, but the float buoyancy type requires a branch from the main pipe to perform measurements and has large errors due to flow velocity, while the vibrating type cannot be used for slurry. Furthermore, since the gamma ray type uses radiation, it has a vertical structure that is not easy to handle, and requires a vertical pipe section.

The present invention has been made against this background, and aims to provide a slurry amount measuring device that has almost no restrictions on installation location, can perform highly reliable measurements, and is easy to handle. It is something.

A feature of the present invention is that an ultrasonic concentration meter that measures the weight ratio of solid components in the slurry and a slurry flow meter that measures the flow rate of the slurry per unit time are provided in the slurry conveyance path. The density signal of the slurry is determined based on the density signal of the solid component, the density signal of the liquid component in the slurry, and the weight ratio signal from the ultrasonic densitometer. and a transportation weight calculation means for calculating a transportation weight signal of the solid component per unit time by multiplying the weight ratio signal of the slurry flowmeter and the flow rate signal from the slurry flowmeter.

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 2 is a configuration diagram showing an embodiment of the present invention, and P is a slurry conveyance path made of, for example, a conveyance pipe for conveying a slurry consisting of, for example, ore (solid component) and water (liquid component). The slurry conveyance path P includes a slurry flowmeter, for example, an electromagnetic flowmeter 2, for measuring the flow rate of slurry per unit time, and an ultrasonic concentration meter 4, for measuring the solid component weight ratio in the slurry. It is provided. Here, the ultrasonic concentration meter 4 is a device that applies the fact that the amount of attenuation of ultrasonic waves has a comparative relationship with the weight ratio of solid components in the slurry. The ultrasonic waves are converted into ultrasonic waves by the transmitter, and the ultrasonic waves attenuate through the slurry while being transmitted to the receiver, where they are converted back into high-frequency electrical signals, which are taken out as a current output and the concentration is displayed on the concentration indicator. Ru. For example, the ultrasonic densitometer 4 has a solid component of 0 to 25
A device that can provide a current output of 4 to 20 mA (DC) by weight is used, and as the electromagnetic flowmeter 2, one that can provide a current output of 4 to 20 mA (DC) at a slurry flow rate of 0 to 2500 m ³ /h. is used.

Then, from the slurry flow rate measured by the electromagnetic flowmeter 2 and the weight ratio of the solid component measured by the ultrasonic concentration meter 4, the flow rate of the solid component per unit time is determined by equation (2).

W=Ds・Q・1/(1−Ds)/G _w +Ds/Gs……(2
) However, Ds is the weight ratio (wt%) of solid components,
Other symbols are the same as those in formula (1).

The reason why equation (2) holds true is that the transported weight (W) of solid components is expressed as the product of the flow rate (Q) of the slurry, the weight ratio of the solid components (Ds), and the density (apparent specific gravity) of the slurry. However, since the density of the slurry is expressed as the reciprocal of the sum of the volume per unit weight of the liquid component, ie (1-Ds)/G _w , and the volume per unit weight of the solid component, ie Ds/Gs, ( 2) Equation will be derived.

In FIG. 2, 5 is a transport weight calculation means for performing such calculations, and 51 is a solid component density setting device for presetting the density of solid components (Gs) according to the type of ore to be cut. It is. 52
is an arithmetic unit for calculating the density of the slurry, and in this example, the specific gravity (Gw) of water as a liquid component is stored in this arithmetic unit 52 as a constant. 53 is the arithmetic unit 52 and the electromagnetic flowmeter 2
This multiplier multiplies the output signals of the ultrasonic concentration meter 4 and the ultrasonic densitometer 4 to obtain a transport weight signal of the solid component per unit time. Reference numeral 54 denotes an integrator that integrates the output signal from the multiplier 53 in order to obtain a signal corresponding to the weight of solid components transported over a predetermined period such as one hour or one day. In the figure, W _H is the integrated transport weight of solid components, and is expressed as W _H =∫wdt.

In the slurry amount measuring device having such a configuration, when the slurry is transported along the slurry transport path P, the flow rate and solid content of the slurry per unit time are measured by the electromagnetic flowmeter 2 and the ultrasonic concentration meter 4, respectively. The weight ratio of And ultrasonic concentration meter 4
The output signal is input to the calculator 52 together with the output signal of the solid component density setting device 51, where the density of the portion corresponding to the fraction in equation (2), that is, the slurry, is determined. On the other hand, the output signal of the ultrasonic concentration meter 4 is also input to a multiplier 53, and each output signal of the arithmetic unit 52 and the electromagnetic flowmeter 2 is input to this multiplier 53. Each signal is multiplied by , and thus the weight of solid components transported per unit time can be determined. At the same time, the transport weight of the solid component for a predetermined period is determined via the integrator 54 and is used as management data.

In the above embodiment, the ultrasonic concentration meter 4 and the slurry flowmeter are used to determine the weight of solid components transported per unit time, and the ultrasonic concentration meter used here is a single-tube density meter. It does not require a long vertical pipe section, the vertical length is determined by the height of the pipe, and the height is small, so
It does not require a large space in the height direction, so there are almost no restrictions on the installation location, and it is especially effective at tunnel construction sites because it is not subject to any major restrictions. Also, the increase in head loss in the pipeline can be almost ignored. Additionally, since no vertical tube section is required, there is no risk of slurry depositing at the bottom of the tube. And because it directly measures the slurry in the main pipe, rather than measuring the slurry in the branch pipe like conventional float buoyancy type density meters, the pipe configuration is simple and there is almost no error due to flow velocity. It is possible to perform highly reliable measurements without any problems. Furthermore, since the measurement is performed using ultrasonic waves, it has no effect on the human body and is extremely easy to handle. Furthermore, even when highly corrosive slurry is being transported, measurements can be made without any problems by using a highly corrosion-resistant lining for the parts of the device that come into contact with the liquid.

Furthermore, in the present invention, in addition to the transported weight of the solid components, the ratio of the integrated value of the transported weight of the solid components to the integrated value of the transported weight of the slurry for a predetermined period can be determined using the output signal of the ultrasonic concentration meter. An example of such a slurry amount measuring device is shown in FIG. Defining the above ratio as the average weight concentration, this is expressed as follows.

[Average weight concentration] = [cumulative amount of transported weight of solid components for a predetermined period] / [cumulative amount of transported weight of slurry for a predetermined period]
=W _H /Q _H・G _w +W _H・(1−G _W /G _s )……(3) However, Q _H =∫Qdt.

To explain the denominator of equation (3), the value of the denominator is
It is the sum of the transported weight of the liquid component and the transported weight of the solid component for a given period, and the transported weight of the liquid component is the value obtained by multiplying the integrated value of the flow rate of the liquid component by the density of the liquid component, that is, ( _{G H} /G _s )・G _w , and the weight of the solid component transported is the value obtained by multiplying the integrated value of the flow rate of the solid component by the density of the solid component, that is, W _H /G _s・G _s , and therefore, these values By adding and rearranging, we get equation (3).

6 in Figure 3 is an electromagnetic flowmeter 2 to obtain a signal corresponding to the slurry flow rate (Q _H ) for a predetermined period such as one day.
7 is an integrator that integrates the output signals of
The integrated value (Q _H ) signal from the integrator 6, the integrated value (W _H ) signal from the integrator 54, and the density (G _s ) signal from the fixed component density setter 5 are input, and each This means calculates the average weight concentration by calculating the equation (3) based on the signal and the density (G _w ) signal of the liquid component to obtain the average weight concentration. Note that G _w is stored in advance in the average weight concentration calculation means as a density constant of the liquid component.

As shown in FIG. 3, if an integrator 6 and an average weight calculation means 7 are provided to obtain the average weight concentration,
For example, it is useful data for managing and understanding the contents of operations at excavation work sites.

In the present invention, the slurry flowmeter is not limited to an electromagnetic flowmeter, but may be an orifice type, an ultrasonic type, or another type.

As described above, according to the present invention, the transported weight of solid components per unit time is determined using an ultrasonic concentration meter and a slurry flowmeter. Since no pipe distance is required, the lift height of the pipe does not increase, and a large space in the height direction is not required, so there are almost no restrictions on the installation location. Moreover, the ultrasonic concentration meter directly sets the slurry in the main pipe, so it can perform highly reliable measurements with almost no errors due to flow velocity, and ultrasonic waves have no effect on the human body. It is extremely easy to handle.

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram showing a conventional slurry amount measuring device, FIG. 2 is a configuration diagram showing a slurry amount measuring device according to an embodiment of the present invention, and FIG. 3 is a configuration diagram showing a device according to an embodiment of the present invention. FIG. 2 is a configuration diagram showing a slurry amount measuring device with an added function of calculating the ratio of the integrated value of the transported weight of solid components to the integrated value of the transported weight of slurry. 1... Single tube density meter, 2... Electromagnetic flow meter, 3...
Solid component density setting device, 4... Ultrasonic concentration meter, 5
. . . Transport weight calculation means, 51 . . . Solid component density setting device, 52 . . . Computing unit, 53 .
...Integrator, 6...Integrator, 7... Average weight concentration calculation means, P... Slurry conveyance path.

Claims (1)

[Scope of Claims] 1. An ultrasonic concentration meter that measures the weight ratio of solid components in the slurry and a slurry flow meter that measures the flow rate of the slurry per unit time are installed in the slurry conveyance path. The density signal of the slurry is determined based on the density signal of the component, the density signal of the liquid component in the slurry, and the weight ratio signal from the ultrasonic densitometer. Transport weight calculation means for multiplying the ratio signal and the flow rate signal from the slurry flowmeter to obtain a transport weight signal of the solid component per unit time, and calculating the slurry flow rate per unit time from the flow rate signal from the slurry flowmeter. The integrated value signal from this integrator, the transported weight signal and solid component density signal from the transported weight calculation means are inputted, and these signals are calculated to obtain an average weight concentration signal. What is claimed is: 1. A slurry amount measuring device, comprising means for calculating an average weight concentration.