KR101939494B1 - Level gauge device - Google Patents

Abstract

According to the present invention, a water level measuring device for measuring a level of a liquid comprises: a float moving in a vertical direction from an initial position by buoyancy, in accordance with changes in water level; and a measuring unit coupled to the float, formed in a circulating closed loop shape in accordance with vertical movement of the float between an upper side support point located at an upper side than the initial position and a lower side support point located at a lower side than the initial position based on the vertical direction, and marked with a scale.

Description

Level gauge device

The present invention relates to a level measuring apparatus.

Generally, when the water level becomes loose, the portion connected to the float does not rise vertically, and the water level becomes difficult to measure accurately due to disordered movement.

Therefore, it is necessary to develop a device that can vertically move the portion connected to the float and measure the water level more accurately.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve these problems, and it is an object of the present invention to provide a measuring apparatus and a measuring apparatus in which a measuring unit is coupled to a float in a vertical closed loop manner, A level measuring device capable of being vertically elevated.

The object of the present invention is to provide a level measuring apparatus capable of measuring the level of a liquid by a difference in scale of a measuring unit connected to a float as the float moves up and down and allowing the user to quantitatively measure the level.

The object of the present invention is to provide a water level measuring apparatus capable of more accurately measuring the water level in accordance with the difference in the scale displayed on the measuring unit, by moving the measuring unit without moving randomly and moving only in the vertical direction.

Disclosure of Invention Technical Problem [8] The present invention provides a level measuring apparatus capable of preventing a component from being detached from the body by arranging a float and a measuring unit inside the body.

According to an embodiment of the present invention, there is provided a water level measuring apparatus for measuring the level of a liquid according to the present invention, comprising: a float which moves in a vertical direction by buoyancy from an initial position as the water level varies; And a measurement part having a graduated surface is formed between the upper supporting point located on the upper side and the lower supporting point located lower than the initial position in a circulating loop shape in accordance with the movement of the float in the vertical direction.

Accordingly. By connecting the measurement part to the float in the vertical closed loop shape, when the float moves in the vertical direction by the buoyancy, the measurement part is lifted in the vertical direction simultaneously with the float, so that the measurement part can be prevented from moving disorderly, Measurement is possible.

Further, according to the elevation of the float, the level of the liquid can be measured by the difference in scale of the measuring unit connected to the float, and the user can quantitatively measure the level.

In addition, since the measuring part is arranged so as to be movable only in the vertical direction without moving randomly, it is possible to more accurately measure the water level according to the difference of the scale displayed on the measuring part.

By disposing the float and the measurement unit inside the body, it is possible to prevent the component from being detached from the body.

1 is a cross-sectional view of a water level measuring apparatus according to an embodiment of the present invention.
Fig. 2 is a sectional view showing that the water level measuring apparatus of Fig. 1 measures the water level.

Hereinafter, some embodiments of the present invention will be described in detail with reference to exemplary drawings. It should be noted that, in adding reference numerals to the constituent elements of the drawings, the same constituent elements are denoted by the same reference symbols as possible even if they are shown in different drawings. In the following description of the embodiments of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the difference that the embodiments of the present invention are not conclusive.

FIG. 1 is a sectional view showing a water level measuring apparatus according to an embodiment of the present invention, and FIG. 2 is a sectional view showing that the water level measuring apparatus of FIG. 1 measures a water level.

As shown in Figs. 1 and 2, the level measuring apparatus for measuring the level of liquid includes a float 10, and a measuring unit 20. As shown in Fig. As shown in Fig. 1, the float 10 moves in the vertical direction by buoyancy as the water level changes from the initial position.

Here, the vertical direction may be a direction in which the liquid level rises or falls.

The measuring unit 20 is coupled to the float 10, and a scale 21 is displayed on the surface. The measuring unit 20 can be coupled to the float 10 such that when the level of the liquid rises or falls, the measuring unit 20 ascends or descends like the moving direction of the float 10.

The measuring unit 20 is configured to rotate between an upper supporting point located on the upper side of the initial position and a lower supporting point located on the lower side of the initial position with respect to the vertical direction, .

The float 10 moves in the vertical direction by buoyancy as the water level changes from the initial position. When the float 10 is positioned at the initial position, the first level of the measurement unit 20 read from the reference position and the first scale of the measurement unit 20 as the float 10 moves vertically by buoyancy from the initial position, ), It can be measured based on the difference between the second scale of the measuring unit 20 read from the reference position.

As the float 10 moves in the vertical direction from the first scale of the measuring unit 20 shown in Fig. 1 and the float from the initial position, the measuring unit 20 shown in Fig. 2 moves in the vertical direction , And the variable distance of the second scale of the measuring unit 20 may be a water level.

When the float 10 is lifted and lowered by buoyancy by the buoyancy force, the measuring unit 20 is moved at the same time as the float 10, It is possible to more accurately measure the difference between the first and second scales read from the reference position.

The level measuring apparatus according to the present embodiment may further include a body 30. The body 30 can accommodate the float 10 and the measuring unit 20 inside the float 10 and the measuring unit 20 to prevent the float 10 and the measuring unit 20 from being separated from the liquid to be subjected to the water level measurement. The body 30 may have an opening 31 through which liquid may flow into the interior.

The body 30 may include a perspective area formed of a material through which the inside is viewed, and a scale indicator line 33 for indicating a reference position may be displayed in the perspective area.

For example, the scale leader line 33 may be displayed vertically with respect to the vertical direction of the body 30, and may be configured to measure the liquid level by the scale leader 33.

When the float 10 is positioned at the initial position, the first scale of the measuring unit 20 read from the reference position and the first scale of the float 10 are moved from the reference position Can be measured on the basis of the difference between the second graduations of the reading unit 20 to be read.

For example, as shown in Fig. 1, when the water level is close to zero or liquid is not stored in the reservoir 80 to be described later, the float 10 is moved to the lower end side of the body 30 by gravity Can be located.

2, when the liquid flows into the reservoir 80 in which the liquid is stored, the float 10 disposed inside the body 30 rises while the liquid level rises, The measuring section 20 can be configured to move in the vertical direction from the initial position.

When the water level is lowered, the measuring unit 20 coupled to the float 10 can be configured to descend while the float 10 descends with respect to the vertical direction.

The liquid level of the liquid flowing into the body 30 and the liquid level of the liquid contained in the reservoir 80 may be the same.

For example, the first and second graduations and the scale leader line 33 of the measurement unit 20 may be arranged to be parallel to each other. For example, the measuring unit 20 having the scale 21 to be measured and the inner wall of the body 30 may be arranged in parallel.

The measuring unit 20 is arranged to move in the vertical direction by a plurality of rollers 52,53 and 56 which will be described later and when the float 10 ascends and descends by buoyancy, 20 can be vertically elevated so that the errors of the measured values of the first scale and the second scale read by the scale leader 33 can be made smaller.

In the interior of the body 30, a vertical hole 36 extending in the vertical direction may be formed. The vertical hole (36) can accommodate the float (10) and the measuring part (20). The vertical hole 36 can be arranged so that the float 10 can be moved in the vertical direction and the measuring portion 20 can be configured to circulate in the form of a closed loop along the float 10.

Liquid can freely flow in and out of the vertical hole 36 and the float 10 and the measuring unit 20 can be prevented from being separated into the liquid to be subjected to the water level measurement by the body 30. [

The level measuring apparatus according to the present embodiment may further include a sensor unit 70. The sensor unit 70 may be positioned above the initial position with respect to the vertical direction.

The sensor unit 70 can measure the vertical distance to the float 10 in a noncontact manner. When the float 10 is positioned at the initial position, the sensor unit 70 detects the first distance measured from the initial position of the float 10 in the sensor unit 70 and the first distance measured from the initial position by the float 10 The water level can be measured based on the difference between the second distance measured by the sensor unit 70 when the measuring unit 20 circulates as it moves in the vertical direction.

The sensor unit 70 can quickly measure whether the water level is increased or decreased by the difference between the first and second distances.

Further, the sensor unit 70 can be configured to measure the distance in the vertical direction to the water surface of the liquid to be subjected to the water level measurement in a noncontact manner.

For example, the sensor unit 70 may be a proximity sensor, an optical sensor, an ultrasonic sensor, an infrared sensor, or the like.

The sensor unit 70 is configured to measure the distance to the water surface through the space between the inner surface of the vertical hole 36 in which the float 10 and the measurement unit 20 are accommodated and the side surface of the float 10 .

For example, the sensor unit 70 has a vertical hole 36 for measuring the water level in a non-contact manner between the inner side surface of the vertical hole 36 and the side surface of the float 10 in the vertical direction above the initial position, The float 10 and the measuring unit 20 can be arranged eccentrically with respect to the center point of the measuring unit 20. [

The float 10 and the measuring section 20 are eccentrically arranged so that the sensor section 70 can measure the water level by the space between the inner surface of the vertical hole 36 and the side surface of the float 10. [ .

A through hole 38 extending in the vertical direction and communicating with the vertical hole 36 may be formed on the outer surface of the body 30. [

The liquid introduced into the vertical hole 36 through the through hole 38 can freely flow in and out. For example, the pressure inside the body 30 can be increased as the liquid level in the body 30 increases, but the pressure inside the vertical hole 36 is discharged to the outside of the body 30 by the passage hole 38 The pressure inside the body 30 can be prevented from increasing.

For example, the liquid inside the body 30 can be raised by the capillary phenomenon, but the through hole 38 can eliminate the considerable adhesion between the inside of the vertical hole 36 and the water molecules of the liquid, 30 can be prevented from being increased.

The liquid level measuring apparatus according to the present embodiment may further include the fixing unit 40 since the liquid level measuring apparatus according to the present embodiment is supported on the reservoir 80 in which the liquid shown in Figs. 1 and 2 is stored.

For example, the reservoir 80 according to the present invention is shown in the form of a container, but it is not limited to a container, but may be a reservoir, a rainfall, a river, etc., The level gauge can be applied to any level of liquid level measurement.

The fixing portion 40 may be detachably coupled to the body 30 and may be configured to surround the body 30 and fix the body 30 to the reservoir 80. [

The fixation portion 40 may be coupled to the body 30 at any of a plurality of vertical positions.

The body 30 may have a plurality of first fastening holes 32 formed on the outer surface at predetermined intervals along the vertical direction and the fastening portion 40 may be provided with a second fastening hole 32 corresponding to the first fastening hole 32, And a hole 41 may be provided.

And can be coupled to the body 30 in any one of a plurality of vertical positions by a fastening member 43 fastened to the first and second fastening holes 41.

For example, the body 30 may be provided with a plurality of different lengths in the vertical direction corresponding to the water level.

It is possible to adjust the length of the body 30 in the vertical direction by coupling the fastening members 43 to the first and second fastening holes through adjustment of the distance between the fastening portion 40 and the lower end of the body 30 have.

So that the fixing portion 40 can be fixed to the reservoir 80. The distance between the fixing portion 40 and the lower end of the body 30 can be determined according to the vertical position where the fixing portion 40 is coupled to the upper portion of the reservoir 80. [

For example, the fixing portion 40 may be fixed to the reservoir 80 so that the bottom surface of the reservoir 80 and the lower end of the body 30 are in contact with each other.

For example, when the bottom surface of the reservoir 80 and the lower end of the body 30 are not in contact with each other, the first scale read from the reference position and the float 10 move in the vertical direction by buoyancy, 20 and the distance between the second scale of the measuring unit 20 read from the reference position and the bottom surface of the reservoir 80 and the initial position of the float 10, The water level can be measured.

For example, a first roller 52, which will be described later, may be provided on one side of the lower end of the body 30, and a fixing bar 39 extending in the vertical direction may be provided on the other side.

The height of the fixing bar 39 in the vertical direction and the height of the first roller 52 may be the same. The float 10 can be configured not to be released to the lower portion of the body 30 by the fixing bar 39. [

When the liquid is not received in the body 30, the float 10 may be configured to contact the upper side of the fixed bar 39 by gravity. When the liquid is received in the body 30, (10) can be configured to move in the vertical direction by buoyancy. For example, when the float 10 moves vertically by buoyancy, the water level can be measured based on the sum of the values of the first and second graduation differences and the length of the vertical bar in the vertical direction.

The level measuring apparatus according to the present embodiment may further include a cap unit 50. The cap portion 50 may be detachably coupled to the upper end of the body 30.

The cap portion 50 covers the upper opening of the body 30 which is opened by a vertical hole 36 vertically penetrating the inside of the body 30 to accommodate the float 10 and the measurement portion 20. [ .

For example, the body 30 and the cap portion 50 may be joined together by an engaging member 48. The engaging member 48 can be configured to be able to engage with a bolt clamp or a magnetic force.

For example, the user may be configured to separate the body 30 and the cap portion 50, thereby replacing the measuring portion 20, the float 10, and the like.

1 and 2, the cap unit 50 may be provided with a sensor unit 70 for measuring the distance to the float 10 or the distance to the water surface of the liquid.

The cap portion 50 may be provided with an air vent 51. For example, as the water level varies, when the liquid is received above the vertical hole 36 with respect to the vertical direction, the pressure inside the body 30 may suddenly increase. The air vent 51 may be configured to communicate with the vertical hole 36 to discharge the pressure inside the body 30 to the outside in order to prevent the pressure inside the body 30 from being increased. The air vent 51 may be configured to communicate the vertical hole 36 with the outside.

1 and 2, the lower end of the body 30 may be provided with a first roller 52 for rotatably supporting the measuring unit 20 at a lower supporting point. A second roller 53 for rotatably supporting the measuring unit 20 can be provided. The measuring unit 20 can be configured to circulate in the form of a closed loop by the first and second rollers 52 and 53 and the measuring unit 20 coupled with the float 10 can ascend or descend Down.

The cap portion 50 may be provided with a third roller 56. The third roller 56 is disposed adjacent to the second roller 53 and can support the measuring unit 20 in a circulating manner.

The third roller 56 may be configured to vary the distance from the second roller 53 to maintain the tension of the measuring portion 20. [

For example, within a range in which the interval between the graduations 21 indicating the liquid level is not variable, the third roller 56 may be configured to maintain the tension.

It is possible to more accurately measure the water level according to the difference of the scale 21 displayed on the measurement unit 20 by arranging the measurement unit 20 to move only in the vertical direction without moving disorderly.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of equivalents should be construed as falling within the scope of the present invention.

10: float 20: measuring part
30: body 40:
50: cap part 70: sensor part
80: Reservoir

Claims (16)

A level measuring apparatus for measuring a level of a liquid,
A float moving in a vertical direction by buoyancy from an initial position as the water level varies;
And an upper support point connected to the float and positioned above the initial position with respect to the vertical direction and a lower support point located below the initial position, A measurement part formed on the surface and having a graduation;
A body accommodating the float and the measurement unit therein and having an opening for allowing the liquid to flow into the interior of the float and the measurement unit to prevent the float and the measurement unit from being separated from the liquid to be measured;
Wherein the body is coupled to the body at one of a plurality of vertical positions, the body being enclosed by the body, the body being supported on an upper portion of the reservoir in which the liquid is stored to fix the body to the reservoir government;
A cap portion removably coupled to an upper end of the body and covering an upper opening of the body, the cap portion being opened by a vertical hole penetrating the interior of the body in the vertical direction; And
Wherein the float is disposed at a position corresponding to a space between a side surface of the float and an inner surface of a vertical hole in which the float is movably disposed in the vertical direction, A sensor unit arranged in a non-contact manner to measure a distance to the water surface between the inner surface of the vertical hole and the side surface of the float;
/ RTI >
Wherein the cap portion is provided with an air vent communicating the vertical hole with the outside,
Wherein the body includes a plurality of first fastening holes formed on an outer surface at predetermined intervals along the vertical direction,
Wherein the fixing portion includes a second fastening hole corresponding to the first fastening hole and is coupled to the body by a fastening member fastened to the first fastening hole and the second fastening hole,
Wherein the distance between the fixing part and the lower end of the body is determined according to a vertical position where the fixing part is coupled. The method according to claim 1,
Wherein the level is determined by a first scale of the measurement unit read from the reference position when the float is located at the initial position and a second scale of the measurement unit from the initial position as the float moves in the vertical direction by the buoyancy And a second scale of the measurement unit read from the reference position. The method according to claim 1,
Further comprising a sensor unit located above the initial position with respect to the vertical direction and measuring the vertical distance to the float in a non-contact manner,
Wherein the water level is a first distance measured by the sensor unit when the float is located at the initial position and a second distance measured when the measuring unit circulates as the float moves from the initial position by the buoyancy in the vertical direction And a second distance measured by the sensor unit. The method according to claim 1,
And a sensor unit located on the upper side of the initial position with respect to the vertical direction and measuring the vertical distance to the water surface of the liquid to be measured. delete The method according to claim 1,
Wherein the water level is a first scale of the measurement unit read from the reference position when the float is located at the initial position and a second scale of the second measurement unit read from the reference position when the measurement unit circulates according to the movement of the float Measured on the basis of the difference between the scales,
Wherein the body includes a perspective region formed from a material through which the interior is viewed,
And a ruled line for indicating the reference position is displayed in the perspective region. The method according to claim 1,
A vertical hole is formed in the body so as to extend in the vertical direction to receive the float and the measurement unit, and the float to be movable in the vertical direction,
And a through hole extending in the vertical direction and communicating with the vertical hole is formed on the outer surface of the body. delete delete delete delete delete delete delete The method according to claim 1,
And a first roller rotatably supporting the measurement unit at the lower supporting point is provided at a lower end of the body,
Wherein the cap portion is provided with a second roller that rotatably supports the measurement portion at the upper support point. 16. The method of claim 15,
Wherein the cap is provided with a third roller disposed adjacent to the second roller for circulatingly supporting the measurement unit and varying a distance from the second roller to maintain the tension of the measurement unit.

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