KR100962868B1 - Level measuring instrument - Google Patents

Abstract

The present invention relates to a leveler for measuring the degree of inclination of any inclined plane using the phenomenon that the fluid is always horizontal. The leveler according to the present invention is a tilt detection unit which is a container containing a predetermined amount of conductive fluid therein and having a predetermined number of corners, and a plurality of conductive materials are applied to each corner of the container in the longitudinal direction to supply current to the conductive fluid. A tilt detector configured to detect a position of the conductive material applied to each corner of the container when the container is inclined at an arbitrary angle in a flowing state; It is connected so as to be in electrical communication with the conductive material applied to each corner of the inclination detection unit, by collecting the respective data on the contact position of the conductive material and the conductive fluid of each corner according to the inclination of the inclination detection unit A data converter which converts the data into data; And a database storing slope data having numerical values calculated by combining numerical data on respective contact positions of the conductive material and the conductive fluid at each corner, and the conductive material at each corner through the data converter. When the numerical data on the contact position of the conductive fluid is input, it comprises a slope determination unit for comparing the slope data of the database to determine the slope corresponding to the input numerical data and outputs.

Level, conductive fluid, container, cube, conductive material, conductive pattern, current, numerical data, database, slope, data converter

Description

Leveler {LEVEL MEASURING INSTRUMENT}

The present invention relates to a leveler, and in particular, to a leveler for measuring the degree of inclination of any inclined plane by using a phenomenon that the fluid is always horizontal.

Level machine is used to measure whether the surface is flat or to check the inclination. It is used in all fields of industry and is a commonly used instrument in daily life.

Conventional levelers, as shown in Figure 1, put the water in the hose hangs on the surface to be measured and stood both ends to measure whether or not the level of the same depending on whether or not the same. It is used at construction sites and was used to investigate the level of two relatively long distances.

As an improvement, as shown in FIG. 2, the water level was measured to be horizontal or horizontal by using a phenomenon in which water droplets are moved around the center leader line according to hardness. That is, the water droplets on the left side in FIG. 2 measure the inclination of the inclined surfaces on the left and right sides in the drawing. When the water drop is in the center of the leader line, it indicates that the surface of the object on which the level is placed is horizontal to the left and right. On the other hand, the water droplets on the right side of the leveler will measure the inclination of the inclined surface of the upper and lower sides in the drawing. When the water droplets are placed on the center leader, it indicates that the surface of the object on which the leveler is placed is level when viewed from the top to the bottom. Thus, when the horizontal object is to be leveled left and right and up and down, the object is moved so that both droplets of the level are in the center of the leader line.

These conventional instruments are relatively simple to manufacture, and are advantageous in terms of cost, but it is difficult to precisely measure the level of an object, and measuring the inclination is delayed by looking at the position of the water droplets, and precise measurement is impossible.

SUMMARY OF THE INVENTION An object of the present invention is to provide a leveler which measures the inclination and the inclination of any inclined plane by using the principle that the surface of the fluid is always horizontal in an enclosed space by using the electrically conductive fluid.

The leveler according to the present invention is a tilt detection unit which is a container containing a predetermined amount of conductive fluid therein and having a predetermined number of corners, and a plurality of conductive materials are applied to each corner of the container in the longitudinal direction to supply current to the conductive fluid. A tilt detector configured to detect a position of the conductive material applied to each corner of the container when the container is inclined at an arbitrary angle in a flowing state; It is connected so as to be in electrical communication with the conductive material applied to each corner of the inclination detection unit, by collecting the respective data on the contact position of the conductive material and the conductive fluid of each corner according to the inclination of the inclination detection unit A data converter which converts the data into data; And a database storing slope data having numerical values calculated by combining numerical data on respective contact positions of the conductive material and the conductive fluid at each corner, and the conductive material at each corner through the data converter. When the numerical data for the contact position of the conductive fluid is input, it is compared with the inclination data of the database, characterized in that it comprises a slope determination unit for determining and outputting a slope corresponding to each of the input numerical data.

Preferably, the container is characterized in that the cube.

Preferably, the conductive fluid fills half of the container.

Preferably, the inclination detection unit is configured to detect the number of conductive materials conducted by the conductive fluid of each corner and to transmit to the data converter.

Preferably, the inclination determination unit is configured to separately determine the left and right inclination and the front and rear inclination of the inclined surface to be measured according to the numerical data input from the data converting unit.

By practicing the present invention, it is possible to measure the level and inclination of any inclined plane as a simple device since the surface of the conductive fluid is always kept horizontal in an enclosed space.

Hereinafter, a preferred embodiment of the leveler according to the present invention will be described with reference to the accompanying drawings. This embodiment is for convenience of description of the present invention, but is not intended to limit the spirit of the present invention to this embodiment. It can be seen that the technical idea of the present invention is limited only by the claims described below.

3 is a block diagram schematically showing the configuration of a leveler according to the present invention.

As can be seen in the figure, the leveler of the present invention, the tilt detection unit 310 for detecting the degree of inclination of a certain surface using a conductive fluid, and the data conversion unit 320 for collecting the data detected by the tilt detection unit And a tilt determination unit 330 which determines the slope by comparing the collected data with the slope data of the database which is already stored.

4 is a diagram illustrating an embodiment of a tilt detection unit of a leveler according to the present invention.

As can be seen in the figure, the tilt detection unit 310 of the present invention is filled with a conductive fluid to a certain height in a container of one cube. A plurality of conductive materials 315 are applied to the twelve corners a to l of the cube container at regular intervals. As shown in the figure, the conductive materials are connected to the conductive patterns 317 and connected to the data converter 320. In the drawings, a relatively small number of conductive materials 315 are applied to one corner for convenience of description, but in practice, the number is much larger than this. The tilt measurement accuracy of the measurement surface is determined by the number of conductive materials. In other words, the larger the number of conductive materials, the higher the measurement accuracy.

The conductive material is connected to the conductive pattern and connected to the data converter 320. The conductive pattern 317 is insulated with a non-conductor so that adjacent conductive patterns do not cause electrical interference. Therefore, in the cube container, the conductive fluid reacts only with the conductive material applied at each corner, and the conductive pattern is surrounded by the insulator, so that it does not react with this.

Now, the conductive fluid in FIG. 4 is filled in exactly half of the cube container and causes a weak current to flow through the fluid. At this time, the four corners (a, b, c, d) forming the bottom of the cube container is immersed in a conductive fluid, so that the conductive materials applied to the four corners are all electrically conductive.

On the other hand, the conductive material applied to the four corners (e, f, g, h) forming the upper surface of the cube container is not in contact with the conductive fluid at all, so that all of them are electrically disconnected. In addition, the conductive material applied to the four corners (i, j, k, l) forming the side of the cube is immersed in the conductive fluid only in the lower half, so that only half of the electrical conduction starts from the bottom. This state is defined as completely horizontal. That is, in a completely horizontal state, conductive materials forming four corners of the bottom of the twelve corners of the cube container are conducted, conductive materials forming exactly lower half of the four corners of the side are conductive, and the top surface of the cube container or Conductive materials at the four corners of the lid are disconnected.

The data converter collects the conduction or disconnection state of the conductive material at each corner at this time. That is, a plurality of conductive materials are applied to each corner, and how many of these individual conductive materials 0 to n-1 are conductive. In other words, in the case of FIG. 4, when the electrical signal sensed by the tilt detector is transmitted to the data converter, the data converter calculates how many conductive materials are present at each corner, and tilts the data. To the government.

For example, in the case of Figure 4, the four corners (a, b, c, d) forming the bottom all of the conductive material is in the conductive state is all delivered to n-1. In the case of four corners (e, f, g, h) forming the upper surface, all conductive materials are disconnected, and thus all are transmitted as zero. On the other hand, in the case of the four corners (d, e, f, g) forming the side, since only half of the conductive material is conducting state from the center to the bottom, all of them are transferred to (n-1) / 2. In this case, the inclination determination unit defines the plane on which the horizontal plane of the present invention is placed as a completely horizontal plane and is represented by 0 ° through the display device. The inclination determination unit stores a database for each conductive material applied to the twelve corners of the cube container, and compares the inclination degree of the current cube container by comparing the data with respect to each corner transmitted from the data conversion unit. The slope indicated is determined.

FIG. 5 is a diagram showing the relationship of conductive materials to respective edges in a database stored in an inclination determination section according to the present invention.

6 is a view showing a state in which the horizontal plane is inclined at 45 ° according to the present invention.

As can be seen from the figure, when the surface to be measured is tilted at 45 ° with respect to the horizontal plane inclined from the complete horizontal, the conductive fluid in the cube container is in contact with the other surface of the cube container. As can be seen in the figure, of the four corners forming the bottom of the cube container, only three (a, c, d) are immersed in the conductive fluid and only one (h) is formed in the conductive fluid. It is locked and is in a conductive state, and only two (i, l) of the side edges are in the conductive state by being immersed in the conductive fluid. At this time, the tilt detector transmits the value n-1 for the corners a, c, and d, the value n-1 for the corners i, l, and the value n- for the corner h. Pass 1, and pass 0 for the remaining edges (b, j, k, e, f, g).

At this time, the data on the currently delivered numerical value is stored at 45 ° to the right in the database of the tilt determination unit, and is displayed at 45 ° to the right when the data is input.

7 is a view showing a state in which the horizontal plane is inclined at an angle to the right according to the present invention.

As can be seen in the figure, when the surface to be measured is inclined to the right at an angle, the conductive fluid comes into contact with a predetermined height of each corner. That is, the conductive material of both the bottom edge b and the side edges j and k is conducted so that the value n-1 is transmitted to the slope determination unit for the edges b, j and k. The conductive materials at the corners a and c and the corners e and g which form the upper surface are partially conductive and the corresponding number is transferred as a numerical value. For example, the number n-10, which is the number of conductive materials in the bottom corners, and the number 7, which is the number of conductive materials in the upper corners, are transmitted. In addition, the conductive materials of the side edges (i, l) and the top surface of the corner (h) are all disconnected to transmit the value 0. At this time, a value that matches each other is compared with a numerical value already stored in the database of the tilt determination unit, and the tilt value at that time is displayed as being tilted by 50 ° to the right, for example.

As such, the position at which the conductive fluid contacts each corner in the cube container when the leveler according to the invention lies on an inclined surface with a certain inclination is different for all inclination angles. The present invention has been devised in view of this fact. That is, by applying a certain number of conductive materials to each corner of the cube container of the present invention and the container is tilted with the conductive fluid contained therein, the fluid is in contact with the different points of each corner in the container The inclination of the container is measured.

The foregoing has described the measurement of the degree to which the horizontal plane of the present invention is inclined left or right with respect to the horizontal plane. The horizontal level of the present invention can measure the inclination of the inclined surface not only in the left and right as well as the front and rear, and can also simultaneously measure the inclination of the inclined surface inclined in the left and right and front and rear.

8 is a view illustrating a state in which the horizontal plane according to the present invention is inclined by a predetermined angle to the left and right and front and rear.

FIG. 8 is a view illustrating a state in which a predetermined angle is further inclined forward in view of the drawing in FIG. That is, the figure of FIG. 6 shows the measurement of the inclination of the inclined surface inclined at 45 ° to the right with respect to the horizontal plane. Fig. 8 shows the measurement of the inclined plane inclined at a certain angle, for example, about 10 degrees back in that state.

At this time, each of the corners of the cube container is conductive all the conductive material of the bottom corner (a, d) and the side of the corner (i), the upper edge (f, g) and the side of the corner (k) All conductive materials are disconnected. In addition, the conductive material of the bottom edges b and c, the side edges j and l, and the top edges e and h is partially conductive.

At this time, if the number of conductive materials of each corner is calculated by the data conversion unit and the data is transmitted to the tilt determining unit, the database stored in the tilt determining unit is currently connected to the number of conductive materials of each corner. Find the corresponding data. At this time, the slope corresponding to the found data, that is, left and right tilt and front and rear tilt are output to the outside through the display.

On the other hand, the conductive fluid entering the cube container of the present invention may use a material that is less drastic than the water, so that the flow occurs less rapidly when operating the leveler of the present invention. In other words, when the level is moved or repositioned, the level of the conductive fluid is changed. Once the level is changed, the water level must be quickly restored to the horizontal level. On the other hand, the conductive fluid has a certain degree of viscosity so that if the level of the fluid changes after contact with the conductive material applied to each corner, no residue should remain in the conductive material released from contact.

1 is a view of a device for measuring the horizontal level of the surface to be measured by placing water in the hose.

Figure 2 is a view of the device for measuring the level or the horizontal level by using the phenomenon that the water droplet is moved around the center leader line according to the hardness.

Figure 3 is a block diagram schematically showing the configuration of a leveler according to the present invention.

Figure 4 is a view showing an embodiment of a tilt detection unit of the leveler according to the present invention.

Fig. 5 shows the relationship of the conductive material to each corner in the database stored in the inclination determination section in accordance with the present invention.

6 is a view showing a state in which the horizontal plane is inclined at 45 ° in accordance with the present invention.

7 is a view showing a state in which the horizontal plane is inclined at an angle to the right according to the present invention.

8 is a view showing a state in which the horizontal plane according to the present invention is inclined by a predetermined angle to the left and right and front and rear.

* Description of the symbols for the main parts of the drawings *

310: tilt detection unit

315: conductive material

317: conductive pattern

320: data conversion unit

330: tilt determination unit

a, b, c ... l: corner

Claims (5)

An inclination detection unit, which is a container having a predetermined number of corners and containing a predetermined amount of conductive fluid therein, wherein a plurality of conductive materials are applied to each corner of the container in a longitudinal direction so that the container is in a state in which current flows in the conductive fluid. A tilt detector configured to detect, to a certain degree, where the conductive material applied to each corner is conductive with the conductive fluid when tilted at an arbitrary angle; It is connected so as to be in electrical communication with the conductive material applied to each corner of the inclination detection unit, by collecting the respective data on the contact position of the conductive material and the conductive fluid of each corner according to the inclination of the inclination detection unit A data converter which converts the data into data; And And a database storing gradient data having numerical values calculated by combining numerical data on respective contact positions of the conductive material and the conductive fluid at each corner, and the conductive material and the conductive material at each corner through the data converter. And an inclination determination unit for comparing the numerical data on the contact position of the conductive fluid with the inclination data of the database and determining and outputting the inclination corresponding to each of the input numerical data. The method of claim 1, And said container is a cube container. The method according to claim 1 or 2, And said conductive fluid fills half of said container. The method according to claim 1 or 2, And the tilt detection unit is configured to detect the number of conductive materials conducting by the conductive fluid in each corner and transmit the detected number of conductive materials to the data conversion unit. The method according to claim 1 or 2, And the tilt determination unit is configured to separately determine left and right and front and rear inclinations of the inclined surface to be measured according to the numerical data inputted from the data converting unit and output them separately.

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