KR20190048016A - Volume and density measuring apparatus and Maintenance apparatus for liquid storage tank using the same - Google Patents

Abstract

The present invention relates to a maintenance device for a liquid storage tank, which measures the amount of liquid stored in a liquid storage tank and inspects for cracks in the liquid storage tank. The maintenance device for a liquid storage tank includes: a floating unit floating on the surface of the liquid stored in the liquid storage tank; a height measuring unit installed in the floating unit and measuring the floating height of the floating unit, wherein the height measuring unit also outputs a corresponding signal; a density measuring unit installed in the floating unit and measuring the density of the liquid stored in the liquid storage tank, wherein the density measuring unit also outputs a corresponding signal; a voice applying unit installed in the liquid storage tank and applying a predetermined sound to the liquid storage tank; a crack measuring unit installed on the surface of the liquid storage tank and receiving the sound transmitted along the surface of the liquid storage tank, wherein the crack measuring unit outputs the corresponding signal; a calculation unit determining whether the crack of the liquid storage tank is generated, a kind of the liquid, and a storage amount of the liquid by using the signal which is output by the height measuring unit and the crack measuring unit and outputting the same; and a first display unit informing a user of the determination result which is output by the calculation unit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a volume and density measuring apparatus and a liquid storage tank management apparatus using the same.

The present invention relates to a volume and density measuring device capable of measuring the volume of a liquid suspended in a liquid state and measuring the volume of the liquid stored in a predetermined liquid storage tank and the occurrence of cracks in the liquid storage tank, And a storage tank management device.

Generally, various kinds of liquids are widely used in the whole industries such as the chemical industry, the electronic industry, and the machinery industry. The liquid may be water (industrial water) used in the production of the product, raw material of the product, chemical used in the chemical treatment step during the product manufacturing stage, or the like. Because of the high volume of liquids used, liquid storage tanks are essential for almost all industrial installations.

Since a predetermined liquid is stored in the liquid storage tank, it is necessary to measure the amount of liquid to be stored.

Conventionally, since the liquid storage amount measuring device is installed integrally with the liquid storage tank, there is a problem that if any part of the liquid storage tank is abnormally damaged, it is required to be repaired as a whole.

In addition, when a crack is generated in the liquid storage tank, it is necessary to detect the stored liquid because it leaks.

Conventionally, since the crack sensing device is installed integrally with the liquid storage tank, the crack sensing device needs to be repaired in its entirety when it is necessary to repair the device, so that much time and cost are consumed.

Further, there is a problem in that a large amount of cost is required to install the liquid storage amount measuring device and the crack sensing device in the liquid storage tank without the liquid storage amount measuring device and the crack sensing device.

The prior art of the present invention can be exemplified by the disclosure of Japanese Patent Application Laid-Open No. 2003-0048251.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a volume and density measuring apparatus capable of measuring the volume of a liquid stored in a liquid storage tank storing a predetermined liquid.

And it is an object of the present invention to provide a liquid storage tank management apparatus capable of discriminating a storage amount of liquid stored in a liquid storage tank and a type of stored liquid and judging whether or not a crack has occurred on the surface.

It is another object of the present invention to provide a liquid storage tank management apparatus that can be arranged and recovered in a liquid storage tank according to the user's needs.

To achieve the above object, the present invention provides an apparatus for measuring the volume and density of liquid stored in a liquid storage tank, comprising: a spherical body for providing space therein and floating on a liquid surface of the liquid; A height measuring unit disposed inside the main body and measuring a floating height of the main body and outputting a corresponding signal; A density measuring unit disposed inside the body and measuring the density of the liquid and outputting a corresponding signal; A position measuring unit for measuring a position of the main body and outputting a corresponding signal; A water quality measuring unit for measuring the quality of the liquid; A calculator for calculating the volume of the liquid using the signal output from the height measuring unit; A radio transmitter for converting a signal output from the height measuring unit, the density measuring unit, the position measuring unit, the water quality measuring unit, and the radio transmitting unit into a radio signal and outputting the radio signal; Weight; And a power supply unit for supplying power to the height measurement unit, the density measurement unit, the position measurement unit, the water quality measurement unit, and the wireless transmission unit.

The height measuring unit may include a laser sensor that irradiates a laser to the upper inside of the liquid storage tank and receives the laser reflected from the inner surface of the liquid storage tank.

The density measuring unit may include an absolute pressure sensor.

The position measuring unit may include GPS.

The height measuring unit may be disposed on the body so as to face the weight with respect to a center point of the floating port.

In order to achieve the above object, the present invention provides a liquid storage tank management apparatus for measuring an amount of liquid stored in a liquid storage tank and inspecting a crack of the liquid storage tank, Float floating on liquid surface; A height measuring unit disposed in the floating unit to measure a floating height of the floating unit and output a corresponding signal; A density measuring unit disposed in the floating unit for measuring a density of the liquid stored in the liquid storage tank and outputting a corresponding signal; An acoustic applicator disposed in the liquid storage tank and applying a predetermined sound to the liquid storage tank; A crack measuring unit disposed on a surface of the liquid storage tank and receiving a sound transmitted along the surface of the liquid storage tank and outputting a corresponding signal; A calculator for determining a storage amount of the liquid, a type of the liquid, and whether a crack has occurred in the liquid storage tank, using the signals output from the height measuring unit and the crack measuring unit; And a first display unit for informing the user of the determination result output from the operation unit; The liquid storage tank management apparatus includes:

The float may be in the form of a sphere providing a space therein.

The suspension unit includes a power supply unit for supplying power to the height measurement unit and the density measurement unit, a wireless transmission unit for converting the signals output from the height measurement unit and the density measurement unit into wireless signals, and outputting the wireless signals, And a second display unit for displaying density measured by the density measuring unit.

The height measuring unit may include a laser sensor that irradiates a laser to an inner upper portion of the liquid storage tank and receives the laser reflected from the inner surface of the liquid storage tank.

The height measuring unit may be disposed on the float so as to face the weight with respect to the center point of the float.

The density measuring unit may include an absolute pressure sensor.

The crack measuring unit may include a plurality of unit acoustic sensors detachably arranged in a matrix form on the surface of the liquid storage tank.

The operation unit may compare a signal output from the plurality of unit acoustic sensors with a reference value and determine a space between the unit acoustic sensors indicating a difference from the reference value as a crack occurrence point.

The calculation unit may calculate the volume of the liquid by using the height of the liquid level measured by the height measuring unit.

The operation unit can determine the type of the liquid by using the density of the liquid surface.

The present invention as described above can measure the volume of the liquid stored in the liquid storage tank storing the predetermined liquid and can determine the storage amount of the liquid stored in the liquid storage tank and the type of the stored liquid, , It is possible to judge whether or not a crack occurs on the surface. Further, the present invention can be arranged and recovered in a liquid storage tank according to the needs of the user.

1 is a view showing a configuration of a volume and density measuring apparatus according to an embodiment of the present invention.
2 is a view showing the measurement of the volume using the volume and density measuring apparatus according to the present invention.
3 is a view showing a configuration of a liquid storage tank management apparatus according to an embodiment of the present invention.
Fig. 4 is a view showing an example of the configuration of a floating sphere used in the present invention. Fig.
5 is a cross-sectional view showing an example of the structure of the floating port shown in Fig.
6 is a view showing an arrangement example of a floating section and a crack measurement section on a liquid storage tank.
Fig. 7 is a diagram showing an example of a crack occurrence site measurement by a crack measurement section. Fig.

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

1 is a view showing a configuration of a volume and density measuring apparatus according to an embodiment of the present invention.

Referring to FIG. 1, a volume and density measuring apparatus 100 according to an embodiment of the present invention includes a body 110, a height measuring unit 120, a density measuring unit 130, a position measuring unit 140, A measurement unit 150, an operation unit 160, a wireless transmission unit 170, a weight W, and a power supply unit (BAT).

First, in the present invention, the liquid storage tank in which a predetermined liquid is stored may be formed in a cylindrical shape having a predetermined height and diameter. In addition, a space in which a predetermined amount of liquid is stored as a predetermined amount is provided inside.

Here, the liquid stored in the liquid storage tank may be water (industrial water) used for production of the product, raw material of the product, chemical used in the chemical treatment step or the like during the production of the product. In addition, various kinds of liquid can be stored according to the user's needs.

The main body 110 has a spherical shape with a predetermined diameter, and provides a space in which the following components are arranged. The main body 110 can be put into a predetermined liquid storage tank 1 for storing liquid according to the user's need and can be recovered by the user after the volumetric measurement work is completed.

The main body 110 can float on the liquid surface of the liquid.

The main body 110 is preferably watertight so as to prevent liquid from flowing into the inside.

The height measuring unit 120 is disposed on the main body 110. The height measuring unit 120 irradiates a laser toward the upper inner surface of the liquid storage tank 1 into which the main body 110 is inserted and a laser sensor for receiving the laser reflected from the upper inner surface of the liquid storage tank 1 .

The laser sensor irradiates the laser and receives the reflected laser to measure the distance from the laser reflection position. The technique of measuring the distance using the irradiation and reflection of the laser is well known in the art such as that disclosed in Japanese Patent Laid-Open No. 10-1493594, and a detailed description thereof will be omitted.

The height measuring unit 120 is disposed on the main body 110 and is disposed opposite to a weight weight W to be described later with reference to a center point of the main body 110. The weight W has a predetermined weight, the weight W is positioned lower than the liquid level, and the height measuring unit 120 is always directed upward.

The density measuring unit 130 measures the density of the liquid stored in the liquid storage tank 1 and outputs a signal corresponding thereto.

The density measuring unit 130 is disposed on the main body 110 and disposed close to the weight W. Therefore, the density measuring unit 130 can be positioned lower than the liquid level. The density measuring unit 130 is arranged to contact the liquid through one side of the main body 110 for measuring the liquid density.

The density measuring unit 130 includes an absolute pressure sensor. The density measuring unit 130 can measure the density of the liquid by measuring the absolute pressure of the stored liquid.

A technology for measuring the density of a liquid by measuring the absolute pressure is disclosed in Japanese Patent Application Laid-Open No. 2016-77003, which is well known in the art, and thus a detailed description thereof will be omitted.

The position measuring unit 140 measures a position where the volume and density measuring apparatus 100 according to the present invention is floating, and outputs a corresponding signal.

The position measuring unit 140 includes a GPS.

The water quality measuring unit 150 measures the quality of the liquid stored in the liquid storage tank 1 and outputs a corresponding signal.

The calculating unit 160 may measure the volume of the liquid stored using the signal output from the height measuring unit 120.

The wireless transmission unit 170 converts a signal output from the height measurement unit 120, the density measurement unit 130, the position measurement unit 140, the water quality measurement unit 150, and the wireless transmission unit 170 into a predetermined wireless signal And outputs it to the outside.

The wireless transmission unit 170 includes an antenna ANT protruding from the main body 110 for outputting a wireless signal.

The weight W has a predetermined load and is disposed on one side of the inside of the main body 110. One side of the main body 110 in which the weight W is disposed by the load of the weight W may always be positioned below the liquid level of the liquid.

The weight W and the height measuring unit 120 are disposed on the main body 110 so as to face each other with respect to the center point of the main body 110. Therefore, the height measuring unit 120 can be directed to the upper portion, that is, the upper inner surface of the liquid storage tank 1.

According to the drawing, the weight W is shown to have a cross-sectional structure of '∩' shape, but it is not limited thereto and various shapes can be made according to the needs of the user.

The power supply unit BAT may include a rechargeable battery of a predetermined capacity. The power supply unit BAT is disposed on one side of the main body 110 to supply power required for operation of the internal components.

The volume measurement using the volume and density measuring apparatus constructed as described above can be carried out as follows.

2 is a view showing the measurement of the volume using the volume and density measuring apparatus according to the present invention.

Referring to FIG. 2, a user places a volume and density measuring apparatus 100 inside a liquid storage tank 1 storing a predetermined liquid.

The volume and density measuring device 100 floats on the liquid surface of the liquid stored in the liquid storage tank 1. [

The height measuring unit 120 including the laser sensor irradiates the laser toward the upper inner surface of the liquid storage tank 1 and receives the laser reflected from the upper part of the liquid storage tank 1 to thereby measure the liquid level and the liquid storage tank 1), and outputs a signal corresponding to the converted value.

The calculating unit 160 can measure the volume of the liquid using the signal output from the height measuring unit 2 as follows.

The height D of the liquid level is calculated by subtracting the distance D between the liquid surface and the upper portion of the liquid storage tank 1 from the height H of the liquid storage tank 1. [

By multiplying the diameter R of the liquid storage tank 1, the volume of the stored liquid can be measured.

The measured volume value may be output to the outside through the wireless transmission unit 170. [

After measuring the volume of the stored liquid, the volume and density measuring device 100 may be retrieved according to the user's needs and may be maintained in the liquid storage tank 100.

3 is a view showing a configuration of a liquid storage tank management apparatus according to an embodiment of the present invention. 4 is a cross-sectional view showing an example of the structure of the floating sphere shown in Fig. 4, Fig. 6 is a cross-sectional view showing a floating sphere and crack measurement Fig.

3 to 6, a liquid storage tank management apparatus 100 according to an embodiment of the present invention includes a floating unit 210, a height measuring unit 220, a density measuring unit 230, 240, a crack measurement unit 250, an operation unit 260, and a first display unit 270.

First, the liquid storage tank 1 in which a predetermined liquid is stored in the present invention is the same as that of the previous embodiment, and thus a detailed description thereof will be omitted.

The floating unit 210 floats on the liquid level of the liquid stored in the liquid storage tank 1. Here, the floating port 210 may have a spherical shape having a predetermined diameter. In addition, the interior of the float 210 provides a predetermined space for placement of the components described below.

The float 210 may comprise a lightweight material (e.g., plastic) that is floating over the liquid phase. At this time, it is preferable that the floating port 210 is airtightly sealed so that liquid does not flow into the floating port 210.

The floating unit 210 can be inserted into the liquid storage tank 1 by the user as needed, and can be recovered by the user after the measurement is completed.

The floating unit 210 may include a height measuring unit 220 and a power supply unit BAT for supplying power to the density measuring unit 230, a radio transmitting unit 214 and a weight W. A water quality measuring unit and a position measuring unit may be further disposed on the floating unit 210.

A power supply unit BAT for supplying power to the density measurement unit 230, a wireless transmission unit 214, a water quality measurement unit, and a position measurement unit are installed in the body of the previous embodiment, The density measuring unit, the power supply unit (BAT), the radio transmitting unit, the water quality measuring unit, and the position measuring unit, which are disposed in the housing 110, Only the configurations with differences will be described.

The second display unit 218 is disposed on one side of the floating unit 210 to display a density value measured by the density measuring unit 230, which will be described later.

The sound applying unit 240 is disposed at a predetermined position of the liquid storage tank 1 and applies a predetermined sound to the liquid storage tank 1 by an operation signal of an operation unit 260 to be described later. The volume and frequency of the sound applied by the sound application unit 240 can be variously set according to the user's need.

According to the drawing, the sound applying unit 240 is disposed at the center of the upper end of the liquid storage tank 1, but may be disposed at another position according to the needs of the user.

The crack measuring unit 250 is disposed along the surface of the liquid storage tank 1. The crack measuring unit 250 receives the sound transmitted through the surface of the liquid storage tank 1 after being applied from the sound applying unit 240 to the liquid storage tank 1 and then outputs a signal corresponding to the received sound .

The crack measuring unit 250 includes a plurality of unit acoustic sensors arranged in a matrix form on the liquid storage tank 1. [

Each of the plurality of unit acoustic sensors can receive a predetermined sound and output a corresponding signal.

Each of the unit acoustic sensors may be connected to the operation unit 260 to be described later by wire or wirelessly.

Each of the unit acoustic sensors may be arranged on the liquid storage tank 1 as required and may be disposed in another tank which is recovered after the crack measurement is completed and needs to be measured.

The calculating unit 260 receives the signals output from the height measuring unit 220, the density measuring unit 230 and the crack measuring unit 250 and calculates the amount of the liquid stored in the liquid storage tank 1, (1).

The operation unit 260 can be disposed in the control room that manages the supply and use of the liquid to be stored as a whole.

First, the calculation of the amount of liquid stored in the liquid storage tank 1 will be described.

The height measuring unit 220 measures the height of the liquid level on which the floating unit 210 floats and outputs a corresponding signal, and the density measuring unit 230 measures the density of the liquid stored by the absolute pressure measurement And outputs a signal.

Since the diameter of the liquid storage tank 1 is a known value, when the height of the liquid level is measured by the height measuring unit 220, the calculating unit 260 can calculate the volume of the liquid stored in the liquid storage tank 1 have.

Thereafter, the operation unit 260 receiving the signal output from the density measuring unit 230 can compare the measured density with the density values of various stored liquids to determine the type of the stored liquid.

Let's take a look at the measurement of cracks.

The crack measuring unit 250 measures the sound applied to the liquid storage tank 1 from the sound applying unit 240 and measures a sound corresponding to the sound applied to the liquid storage tank 1 And outputs the signal to the operation unit 260. [

Here, it is preferable that the signal output from the crack measuring unit 250 disposed on the surface of the normal liquid storage tank 1 where cracks are not generated is stored in the calculating unit 260 as a reference value.

The crack measuring unit 250 compares the signal outputted from each crack measuring unit 250 with a stored reference value to determine an error signal outputting unit 250.

Fig. 7 is a diagram showing an example of a crack occurrence site measurement by a crack measurement section. Fig.

Referring to FIG. 7, it can be seen that a plurality of acoustic sensors S included in the crack measuring unit 250 are arranged in a matrix form. The first to ninth unit acoustic sensors S1 to S9 will be described with reference to a plurality of acoustic sensors.

It is assumed that a crack occurs at a predetermined position C between the first to ninth unit acoustic sensors S1 to S9 arranged in a matrix form.

When a crack is generated at a predetermined position C of the liquid storage tank 1, the sound received by the acoustic sensor through the crack occurrence site is different from the reference value.

In the drawings, the first, second, fourth and fifth unit acoustic sensors S1, S2, S4 and S5 disposed around the crack occurrence position output a signal indicating that there is a difference from the reference value.

The calculation unit 260 can determine that a crack has occurred between the first, second, fourth, and fifth unit acoustic sensors S1, S2, S4, and S5.

In addition, the operation unit 260 can calculate the crack occurrence position according to the degree of difference from the reference value and output the corresponding signal.

On the other hand, when there is no acoustic sensor for outputting an abnormal signal among the first to ninth unit acoustic sensors S1 to S9, the calculating unit 260 determines that no crack has occurred in the liquid storage tank 1, Can be output.

In the first display unit 2170, the operation unit 260 may output the amount of stored liquid, whether or not a crack has occurred, and the occurrence position to inform the user.

According to the present invention configured as described above, it is possible to determine the storage amount of the liquid stored in the liquid storage tank and the type of the stored liquid, and to judge whether or not a crack has occurred on the surface. It is possible to place and collect in the tank.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

100: Volume and density measuring device
110: main body 120: height measuring unit
130: density measuring unit 140: position measuring unit
150: water quality measuring unit 160:
170:
200: Liquid storage tank management device
210: floating part 220: height measuring part
230: density measuring unit 240: sound applying unit
250: crack measuring unit 260:
270: first display section
W: weight weight BAT: power supply

Claims (15)

An apparatus for measuring the volume and density of liquid stored in a liquid storage tank,
A spherical body for providing space therein and floating on the liquid surface of the liquid;
A height measuring unit disposed inside the main body and measuring a floating height of the main body and outputting a corresponding signal;
A density measuring unit disposed inside the body and measuring the density of the liquid and outputting a corresponding signal;
A position measuring unit for measuring a position of the main body and outputting a corresponding signal;
A water quality measuring unit for measuring the quality of the liquid;
A calculator for calculating the volume of the liquid using the signal output from the height measuring unit;
A radio transmitter for converting a signal output from the height measuring unit, the density measuring unit, the position measuring unit, the water quality measuring unit, and the radio transmitting unit into a radio signal and outputting the radio signal;
Weight; And
And a power supply unit for supplying power to the height measurement unit, the density measurement unit, the position measurement unit, the water quality measurement unit, and the wireless transmission unit. The method according to claim 1,
The height measuring unit
And a laser sensor for irradiating a laser to an inner upper portion of the liquid storage tank and receiving a laser reflected from the inner surface of the liquid storage tank. The method according to claim 1,
The density-
A volume and density measuring device comprising an absolute pressure sensor. The method according to claim 1,
The position-
A volume and density measuring device comprising GPS. The method according to claim 1,
Wherein the height measuring unit is disposed on the body so as to face the weight with respect to a center point of the floating port. A liquid storage tank management apparatus for measuring an amount of liquid stored in a liquid storage tank and inspecting a crack of the liquid storage tank,
A floating unit floating on the liquid level of the liquid stored in the liquid storage tank;
A height measuring unit disposed in the floating unit to measure a floating height of the floating unit and output a corresponding signal;
A density measuring unit disposed in the floating unit for measuring a density of the liquid stored in the liquid storage tank and outputting a corresponding signal;
An acoustic applicator disposed in the liquid storage tank and applying a predetermined sound to the liquid storage tank;
A crack measuring unit disposed on a surface of the liquid storage tank and receiving a sound transmitted along the surface of the liquid storage tank and outputting a corresponding signal;
A calculator for determining a storage amount of the liquid, a type of the liquid, and whether a crack has occurred in the liquid storage tank, using the signals output from the height measuring unit and the crack measuring unit; And
A first display unit for informing a user of a determination result output from the operation unit; And the liquid storage tank management device. The method according to claim 6,
In this case,
A liquid storage tank management device in the form of a sphere providing space therein. 8. The method of claim 7,
In this case,
A power supply unit for supplying power to the height measuring unit and the density measuring unit,
A radio transmitter for converting the signal output from the height measuring unit and the density measuring unit into a radio signal,
Weight,
And a second display unit for displaying the density measured by the density measuring unit. 9. The method of claim 8,
The height measuring unit
And a laser sensor for irradiating a laser to an inner upper portion of the liquid storage tank and receiving a laser reflected from the inner surface of the liquid storage tank. 10. The method of claim 9,
Wherein the height measuring unit is disposed on the floating unit so as to face the weight unit with respect to a center point of the floating unit. 8. The method of claim 7,
The density-
A liquid storage tank management device comprising an absolute pressure sensor. 8. The method of claim 7,
The crack measuring unit may measure,
And a plurality of unit acoustic sensors detachably arranged in a matrix form on the surface of the liquid storage tank. 13. The method of claim 12,
The operation unit,
Wherein a signal output from the plurality of unit acoustic sensors is compared with a reference value and a space between the unit acoustic sensors indicating a difference from the reference value is determined as a crack occurrence point. 14. The method of claim 13,
The operation unit,
And the volume of the liquid is calculated using the height of the liquid level measured by the height measuring unit. 15. The method of claim 14,
The operation unit,
And determines the type of the liquid by using the density of the liquid surface.

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