KR102060092B1 - Floating sensor and wet tank for scrubber having the same - Google Patents

Abstract

According to an embodiment of the present invention, a floating sensor comprises: a float tank for maintaining a same water level as the wet tank by introducing the water through a pipe connected to a wet tank for a scrubber; a float capsule which moves up and down according to the water level inside the float tank including a floating air bladder and a permanent magnet providing buoyancy; a plurality of level sensors arranged on an outer circumferential surface of the float tank and sensing a magnetic force of the permanent magnet to generate a sensing signal; and a control part for adjusting the water level of the wet tank on the basis of the sensing signal received from the plurality of level sensors. Therefore, the present invention is capable of preventing a water leak accident by accurately measuring the water level of the wet tank.

Description

FLOATING SENSOR AND WET TANK FOR SCRUBBER HAVING THE SAME}

The present invention relates to a floating sensor mounted on a wet tank of a scrubber used for waste gas treatment generated in an electronic component manufacturing process and measuring a water level of the wet tank, and a wet tank for a scrubber including the same.

Gases and chemicals used in the manufacturing process of electronic components such as semiconductors, display devices, solar cells, and OLEDs generally have toxic, corrosive and explosive properties. In addition, the waste gas used and discharged in the electronic component manufacturing process contains a large amount of acidic components, moisture, and dust generated during the manufacturing process.

There are two types of scrubbers for treating hazardous waste gases emitted from semiconductor manufacturing processes and the like. The heat combustion method is a method in which waste gas is decomposed, reacted or combusted by a high temperature flame or plasma, and the wet method is a method in which waste water is contacted with water to dissolve and treat the water-soluble components contained in the waste gas. Heat-burning scrubbers process waste gas using a fuel-burner burner, a plasma burner or a burner burner. For example, a fuel burner burns waste gas introduced into the combustion chamber using a flame generated by fuel, an oxidant (eg, LNG), and oxygen. A scrubber including a fuel burner burner is generally provided with a combustion chamber and a wet tank sequentially below the burner. The fuel combustion scrubber also includes a water treatment tower connected to the combustion chamber via a wet tank. The water treatment tower, like the combustion chamber, is located at the top of the wet tank and the bottom is connected to the wet tank. Fuel-burning scrubbers allow the burned waste gas to flow into the water treatment tower through the combustion chamber and the wet tank. By-product particles produced as the waste gas is burned and decomposed are collected and dropped into a wet tank located primarily at the bottom of the combustion chamber. If the by-product particles are fine, they enter the water treatment tower together with the waste gas, and the incoming by-product particles are further collected into a wet tank together with the water sprayed from the water treatment tower. Alternatively, the water-soluble constituents contained in the burned waste gas are dissolved and collected in the water while the waste gas flows in contact with water in the wet tank.

Wet tanks need to maintain a constant range of levels inside. The wet tank is exposed to high temperatures by a burner located at the top, so the water is continuously evaporated. On the one hand, wet tanks are constantly receiving water from the water treatment tower. Conventionally, a transparent branch pipe is installed on one side of the wet tank, and the water level inside the wet tank is checked by looking at the water level of the branch pipe. However, as described above, the by-product particles resulting from the treatment of the waste gas are continuously introduced into the wet tank. By-product particles are introduced into the interior of the branch pipe has a problem of making the water level difficult to contaminate the inner surface of the branch pipe. In order to clean the branch pipe of the wet tank, it is necessary to disassemble the branch pipe, so there is a problem that the entire scrubber needs to be stopped.

In addition, the method of checking the water level by applying a level sensor to the wet tank has been proposed, but the water level accidents occur because the water level drops below the reference value or exceeds the reference value due to the inaccurate level measurement. there is a problem.

The present invention provides a floating sensor capable of accurately measuring the water level of a wet tank to prevent a water leak, and a wet tank for a scrubber including the same.

The present invention provides a floating sensor capable of remotely checking the water level inside the wet tank and a wet tank for a scrubber including the same.

The present invention provides a floating sensor that is not contaminated by by-product particles introduced into the wet tank and is easy to maintain, and a wet tank for a scrubber including the same.

The floating sensor according to the embodiment of the present invention includes a float tank that maintains the same water level as the wet tank by introducing water through a pipe connected to the wet tank for the scrubber, and a float and a permanent magnet to provide buoyancy. A float capsule moving up and down in the float tank according to the water level, a plurality of level sensors disposed on an outer circumferential surface of the float tank, for sensing a magnetic force of the permanent magnet to generate a sensing signal, and the plurality of level sensors And a controller for adjusting the water level of the wet tank based on the sensing signal received from the controller.

The plurality of level sensors of the floating sensor according to an embodiment of the present invention, the first level sensor disposed at a position corresponding to a first lower limit value for sensing the water shortage of the wet tank, and a lower than the first lower limit value; A second level sensor disposed at a position corresponding to a second lower limit value, a third level sensor disposed at a position corresponding to a first upper limit value for sensing the water filling of the wet tank, and a second upper limit higher than the first upper limit value; And a second level sensor disposed at a position corresponding to the second level sensor.

The first level sensor of the floating sensor according to an embodiment of the present invention, by sensing the magnetic force from the permanent magnet generates a first sensing signal indicating that the water level of the wet tank is below the first lower limit, The first sensing signal is output to the controller.

The second level sensor of the floating sensor according to an embodiment of the present invention senses a magnetic force from the permanent magnet to generate a second sensing signal indicating that the water level of the wet tank is less than or equal to the second lower limit. The second sensing signal is output to the controller.

The control unit of the floating sensor according to an embodiment of the present invention, the water discharge pipe disposed in the wet tank based on the first sensing signal input from the first level sensor or the second sensing signal input from the second level sensor. Is closed and the water inlet pipe is opened to replenish water with the wet tank.

The third level sensor of the floating sensor according to an embodiment of the present invention senses a magnetic force from the permanent magnet to generate a third sensing signal indicating that the water level of the wet tank is greater than or equal to the first upper limit value. The third sensing signal is output to the controller.

The fourth level sensor of the floating sensor according to an embodiment of the present invention senses the magnetic force from the permanent magnet to generate a fourth sensing signal indicating that the water level of the wet tank is greater than or equal to the second upper limit value. The fourth sensing signal is output to the controller.

The control unit of the floating sensor according to an embodiment of the present invention, the water discharge pipe disposed in the wet tank based on the third sensing signal input from the third level sensor or the fourth sensing signal input from the fourth level sensor. Is opened and the water inlet pipe is closed to drain the water from the wet tank.

In the inner circumferential surface of the float tank of the floating sensor according to an embodiment of the present invention, a plurality of guide grooves of a predetermined depth are formed from an upper side to a lower side.

A plurality of guide protrusions are formed on an outer circumferential surface of the float capsule of the floating sensor according to an embodiment of the present invention, and the plurality of guide protrusions are inserted into the plurality of guide grooves to guide the vertical movement of the float capsule.

A plurality of rollers are disposed from an upper side to a lower side on an inner circumferential surface of the float tank of the floating sensor according to an embodiment of the present invention to guide the vertical movement of the float capsule.

According to embodiments according to the present disclosure, by sensing the water level of the float tank, it is possible to accurately check the water level inside the wet tank without visually confirming the wet tank, it is possible to check the change in the water level. Through this, the water level of the wet tank can be managed smoothly.

According to embodiments according to the present disclosure, it is possible to accurately measure the water level of the wet tank to prevent a water rack (water leak) accident.

According to embodiments of the present disclosure, a floating sensor that is not contaminated by by-product particles introduced into the wet tank and is easy to maintain can be provided, and a wet tank for a scrubber including the same.

1 is a perspective view of a floating sensor according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view taken along line II ′ of FIG. 1.
3 is a view showing a float capsule according to an embodiment of the present invention.
4 is a partial vertical cross-sectional view of a scrubber in which a wet tank including a floating sensor according to an embodiment of the present invention is mounted.
5A and 5B are views for explaining the operation of the level sensor when the level of the floating tank according to an embodiment of the present invention is below the lower limit.
6A and 6B are diagrams for describing an operation of the level sensor when the level of the floating tank is higher than or equal to an upper limit, according to an exemplary embodiment.
7 is a view showing a float capsule according to another embodiment of the present invention.
8 is a view showing a floating tank according to another embodiment of the present invention.
9 is a view showing a floating tank according to another embodiment of the present invention.

Hereinafter, referring to the accompanying drawings, a floating sensor and a wet tank for a scrubber including the same according to embodiments of the present disclosure will be described.

1 is a perspective view of a floating sensor according to an embodiment of the present invention. FIG. 2 is a cross-sectional view taken along line II ′ of FIG. 1. 3 is a view showing a float capsule according to an embodiment of the present invention. 4 is a partial vertical cross-sectional view of a scrubber in which a wet tank including a floating sensor according to an embodiment of the present invention is mounted.

1 to 4, a floating sensor 100 according to an embodiment of the present invention may include a float tank 110, a float tank 120, a float capsule 120, and a plurality of level sensors 130. , a level sensor) and a controller 140 may be formed.

The float tank 110 may be formed so that the upper end portion has the same height as the upper end portion of the wet tank 200 so as to sense the level of water filled in the wet tank 200. The float tank 110 may have a cylindrical shape, and a connection pipe 112 may be formed at the lower end to protrude in the horizontal direction to be connected to the wet tank 200. The wet tank 200 and the connection pipe 112 may be connected by the connection means 114, and the water filled in the wet tank 200 may be introduced into the float tank 110 through the connection pipe 112. . The water of the wet tank 200 is introduced into the float tank 110 so that the water level of the wet tank 200 and the water level of the float tank 110 may be maintained the same. That is, the float tank 110 may receive water from the wet tank 200 through the connection pipe 112 connected to the wet tank 200, and maintain the same water level as the wet tank 200. In the above description, the float tank 110 has been described as having a cylindrical shape, but is not limited thereto, and may have a polygonal shape such as a triangular pillar, a square pillar, a pentagonal pillar, or a hexagonal pillar.

The float capsule 120 may be disposed in the float tank 110 to measure the water level of the float tank 110. The float capsule 120 may move up and down according to the water level in the float tank 110. The float tank 110 can move in the upper and lower limits of the water level.

The float capsule 120 may be formed in a cylindrical shape having a predetermined height in the vertical direction so that the float capsule 120 may be moved up and down in the float tank 110 according to the water level. The float capsule 120 may include a floating portion 122 that provides buoyancy to float on water. In addition, the float capsule 120 may include a permanent magnet 124 so that the water level can be sensed by the plurality of level sensors 130. The floating portion 122 may be disposed below the float capsule 120, and the permanent magnet 124 may be disposed on the floating portion 122.

The floating bridle 122 may be formed in a hollow tube or capsule shape with a hollow inside. The floating bure 122 has a buoyancy by itself because it is formed in a hollow, it may be disposed inside the float capsule 120 may allow the float capsule 120 to float on the water surface. The floating bure 122 may move up and down according to the water level, and may be formed in various structures that may float along the water surface.

The permanent magnet 124 may be formed of various magnetic materials capable of generating a magnetic field. For example, the permanent magnet 124 may be formed of an iron oxide magnet, or a rare earth magnet such as a neodium magnet or samarium magnet.

Float capsules 122 should be mounted inside the float tank 110 so that the floating bure 122 is located below and the permanent magnet 124 is located above. Accordingly, the float capsule 120 may be formed of a transparent material so that the positions of the floating bridle 122 and the permanent magnet 124 may be recognized from the outside. In addition, different colors may be displayed on the portion where the floating portion 122 and the permanent magnet 124 are located on the outer surface of the floating capsule 120 so that the position of the floating portion 122 and the permanent magnet 124 may be recognized. Can be. Through this, the floating portion 122 and the permanent magnet 124 can be separated from the outside.

The float tank 110 and the float capsule 120 may be formed of a resin material or a nonmagnetic material such as stainless steel. Therefore, no attraction force due to magnetic force is generated between the permanent magnet 124 and the float tank 110 and the float capsule 120. Through this, the permanent magnet 124 may be moved up and down in accordance with the water level of the float tank 110.

In order to manage the water level of the wet tank 200 to an appropriate level, a plurality of level sensors 130 may be disposed in the float tank 110 at a height corresponding to the upper and lower limits of the water level. Since the water level of the float tank 110 and the water level of the wet tank 200 are the same, the water level of the wet tank 200 may be recognized by sensing the water level of the float tank 110. That is, the water level of the wet tank 200 may be managed by sensing the water level of the float tank 110 having the same water level as that of the wet tank 200 without directly sensing the water level of the wet tank 200. have.

The plurality of level sensors 130 may be disposed to contact the outer surface of the float tank 110, and may output each sensing signal generated by sensing magnetic force to the controller 140. A plurality of level sensors 130 may be disposed at heights corresponding to upper and lower limits of the water level filled in the float tank 110. That is, the plurality of level sensors 130 may sense the vertical movement of the float capsule 120 by sensing the magnetic force of the permanent magnet 124.

As an example, the first level sensor 131 may be disposed at a position corresponding to the first lower limit of the water level of the float tank 110. In addition, the second level sensor 132 may be disposed at a position corresponding to the second lower limit of the water level of the float tank 110. Here, the first lower limit value and the second lower limit value refer to a reference value for water replenishment while warning of water shortage. Even if the water level reaches the first lower limit, there is no problem in the operation of the scrubber, but if the water level is below the first lower limit in order to adjust the water level early, the water level of the wet tank 200 may be adjusted by sensing it. In addition, when the water level reaches the second lower limit, there is no problem in the operation of the scrubber to a certain level, but if the water level is further lowered, a problem may occur in the operation of the scrubber. Therefore, when the water level is less than or equal to the second lower limit, the water level of the wet tank 200 may be adjusted by sensing it.

When one level sensor is disposed at a position corresponding to the lower limit of the water number of the float tank 110, it may be difficult to accurately measure the water level of the float tank 110 due to a failure or a sensing error of the level sensor. In the present invention, the first level sensor 131 is positioned at a position corresponding to the lower limit value so that the lower limit value of the water level filled in the float tank 110 can be accurately measured, and the lower limit value of the water level can be measured in consideration of malfunction of the level sensor. ) And the second level sensor 132. That is, when the water level of the float tank 110 reaches the first lower limit, the magnetic force of the permanent magnet 124 may sense the first level sensor 131. At this time, the first level sensor 131 generates a first sensing signal indicating that the water level of the wet tank 200 is less than or equal to the first lower limit value, and outputs the generated first sensing signal to the controller 140 to provide a wet tank. The water level control of the 200 can be made.

Thereafter, when the water level of the float tank 110 is lowered to reach the second lower limit, the magnetic force of the permanent magnet 124 may sense the second level 132 sensor. At this time, the second level sensor 132 generates a second sensing signal indicating that the water level of the wet tank 200 is less than or equal to the second lower limit, and outputs the generated second sensing signal to the controller 140 to provide a wet tank. The water level control of the 200 can be made. Meanwhile, when the water level of the wet tank 200 is adjusted and the position of the float capsule 120 rises above the first lower limit in the float tank 110, the first level sensor 131 and the second level sensor ( In 132, the magnetic force of the permanent magnet 124 is not sensed.

After the water level of the float tank 110 changes to reach the second lower limit, the permanent magnet 124 may rise to the first lower limit and then move to a position higher than the first lower limit. In this case, the controller 140 controls the float capsule 120 in the float tank 110 through the first sensing signal of the first level sensor 131 and the second sensing signal of the second level sensor 132 which are sequentially input. ) Can sense the movement. Accordingly, the water level of the wet tank 200 may be adjusted. When the water level of the wet tank 200 reaches the lower limit, a detailed description of a method of controlling the water level of the wet tank 200 will be described later.

As an example, the third level sensor 133 may be disposed at a position corresponding to the first upper limit of the water level of the float tank 110. In addition, the fourth level sensor 134 may be disposed at a position corresponding to the second upper limit of the water level of the float tank 110. Here, the first upper limit value and the second upper limit value refer to a reference value for water replenishment while warning of water shortage. Even if the water level reaches the first upper limit, there is no problem in the operation of the scrubber, but if the water level is higher than the first upper limit in order to adjust the water level early, the water level of the wet tank 200 may be adjusted by sensing it. In addition, when the water level reaches the second upper limit, there is no problem in the operation of the scrubber to a certain level, but if the water level is further increased, a problem may occur in the operation of the scrubber. Therefore, when the water level is greater than or equal to the second upper limit value, the water level of the wet tank 200 may be adjusted.

When one level sensor is disposed at a position corresponding to an upper limit of the water number of the float tank 110, it may be difficult to accurately measure the water level of the float tank 110 due to a failure or a sensing error of the level sensor. In the present invention, the upper limit of the water level filled in the float tank 110 is accurately measured, and the third level sensor 133 is located at a position corresponding to the upper limit so that the upper limit of the water level can be measured in consideration of a malfunction of the level sensor. ) And a fourth level sensor 134. That is, when the water level of the float tank 110 reaches the first upper and lower limits, the magnetic force of the permanent magnet 124 may sense the third level 133 sensor. At this time, the third level sensor 133 generates a third sensing signal indicating that the water level of the wet tank 200 is greater than or equal to the first upper limit value, and outputs the generated third sensing signal to the controller 140 to provide a wet tank. The water level control of the 200 can be made.

Thereafter, when the water level of the float tank 110 is higher and reaches the second upper limit, the magnetic force of the permanent magnet 124 may sense the fourth level 134 sensor. At this time, the fourth level sensor 134 generates a fourth sensing signal indicating that the water level of the wet tank 200 is greater than or equal to the second upper limit value, and outputs the generated fourth sensing signal to the controller 140 to provide a wet tank. The water level control of the 200 can be made. Meanwhile, when the water level of the wet tank 200 is adjusted and the position of the float capsule 120 in the float tank 110 is lowered below the first upper limit value, the third level sensor 133 and the fourth level sensor ( In 134, the magnetic force of the permanent magnet 124 is not sensed.

After the water level of the float tank 110 is changed to reach the second upper limit, the permanent magnet 124 may be lowered to the first upper limit, and then moved to a position lower than the first upper limit. In this case, the control unit 140 may move the float capsule 120 in the float tank 110 through the third sensing signal of the third level sensor 133 and the fourth sensing signal of the fourth level sensor 134. The sensing may be performed, and accordingly, the water level of the wet tank 200 may be adjusted. When the water level of the wet tank 200 reaches the upper limit, a detailed description of a method of controlling the water level of the wet tank 200 will be described later.

The wet tank 200 includes a tank body 210, a tank cover 220, a water discharge pipe 230, a water inlet pipe 240, and a float tank connection hole 250. Although not shown in the drawings, a pump 40 for supplying water contained in the wet tank 200 to the water treatment unit 30 may be further formed, and a pipe connected to the pump 40 may be further formed. have.

The tank body 210 is formed in a box shape with an open top, and accommodates water supplied from the outside. The tank body 210 may be formed in various shapes and sizes according to the type and shape of the scrubber used.

The tank cover 220 may be formed in a plate shape, and may be formed in various shapes according to the upper shape of the tank body 210. The tank cover 220 is coupled to the upper portion of the tank body 210 to seal the upper portion of the tank cover 220. The tank cover 220 may have a first coupling hole 222 and a second coupling hole 224 to which the combustion unit 10 and the water treatment unit 30 of the scrubber are coupled.

On the other hand, the upper portion of the wet tank 200 may be combined in various configurations depending on the type of scrubber. For example, the combustion tank 10 and the burner unit 30 are sequentially coupled to one upper side of the wet tank 200, and the combustion unit 10 is connected to the wet tank 200 through the first coupling hole 222. ) Is combined. In addition, the water treatment unit 30 is disposed on the other side of the upper portion of the wet tank 200, and the water treatment unit 30 is coupled to the wet tank 200 through the second coupling hole 224. The combustion unit 10, the burner unit 20, and the water treatment unit 30 may be formed in various configurations according to the scrubber. The pump 40 may supply water filled in the wet tank 200 to the water treatment unit 30. Through this, water may be injected into the waste gas flowing into the water treatment unit 30 to collect the water-soluble harmful gas contained in the waste gas together with the water.

5A and 5B are diagrams for describing an operation of the level sensor when the level of the floating tank is lower than or equal to a lower limit according to an embodiment of the present invention.

First, referring to FIGS. 4 and 5A, when the water level of the wet tank 200 is lowered, the water level of the float tank 110 connected to the wet tank 200 is also lowered. As the water level of the float tank 110 is lowered, the float capsule 120 is also lowered. When the water level of the float tank 110 falls below the first lower limit, the magnetic force is applied to the first level sensor 131 disposed such that the permanent magnet 124 included in the float capsule 120 corresponds to the first lower limit. Done. The first level sensor 131 senses a magnetic force applied from the permanent magnet 124 to generate a first sensing signal indicating that the water level of the wet tank 200 is less than or equal to the first lower limit value, and the generated first sensing signal. May be output to the controller 140. In this case, a weak magnetic force may also be applied to the second level sensor 132 disposed adjacent to the first level parser 131. That is, a weak magnetic force may be applied to the second level sensor 132 disposed to correspond to the second lower limit adjacent to the first lower limit. The second level sensor 132 may not generate the sensing signal when the applied magnetic force is less than or equal to the reference value, and may generate the sensing signal when the applied magnetic force exceeds the reference value. The second level sensor 132 may generate a second sensing signal when the applied magnetic force exceeds a reference value, and output the generated second sensing signal to the controller 140.

Meanwhile, since the water level of the float capsule 120 is less than or equal to the first lower limit and the float capsule 120 is positioned according to the water level, the third level sensor 133 disposed to correspond to the first upper limit of the float capsule 120. ), No magnetic force is applied. In addition, magnetic force is not applied to the fourth level sensor 134 disposed to correspond to the second upper limit of the float capsule 120. Therefore, the third level sensor 133 and the fourth level sensor 134 do not output the sensing signal to the controller 140.

The controller 140 may recognize the water level of the wet tank 200 based on a sensing signal input in real time from the first to fourth level sensors 131 to 134. When the first sensing signal is applied from the first level sensor 131, the controller 140 determines that the water level of the wet tank 200 is less than or equal to the first lower limit value. The controller 140 may stop the water discharge by closing the water discharge pipe 230 by controlling a lever disposed in the water discharge pipe 230 according to the water level determination result. That is, the controller 140 may stop the water discharge by closing the water discharge pipe 230 based on the first sensing signal. In addition, the controller 140 may control the lever disposed in the water inlet tube 240 to open the water inlet tube 240 so that water may be introduced into the wet tank 200.

When the sensing signal is applied from not only the first level sensor 131 but also the second level sensor 132, the controller 140 receives the first sensing signal and the second level sensor 132 from the first level sensor 131. The second sensed signal from can be compared. When the first sensing signal input from the first level sensor 131 is greater than the second sensing signal input from the second level sensor 132, it may be determined that the float capsule 120 is positioned adjacent to the first lower limit. have. Accordingly, the controller 140 may recognize that the water level is lowered below the first lower limit in the normal range, and thus adjust the water level of the wet tank 200.

In addition, the controller 140 may include a display means, and may display the water level state through the display means. The controller 140 may generate a graph or an image of the water level corresponding to the change of the water level, and display the same through the display means. When the water level is lowered below the first lower limit in the normal range, the controller 140 may indicate that the water replenishment is necessary by displaying the water level change through the display means.

4 and 5B, when the water level of the wet tank 200 is lowered, the water level of the float tank 110 connected to the wet tank 200 is also lowered. As the water level of the float tank 110 is lowered, the float capsule 120 is also lowered. When the water level of the float tank 110 falls below the second lower limit after the first lower limit, the second level sensor 132 disposed such that the permanent magnet 124 included in the float capsule 120 corresponds to the second lower limit. Magnetic force). The second level sensor 132 senses a magnetic force applied from the permanent magnet 124 to generate a second sensing signal indicating that the water level of the wet tank 200 is less than or equal to the second lower limit value, and the generated second sensing signal. May be output to the controller 140. In this case, a weak magnetic force may be applied to the first level sensor 131 disposed adjacent to the second level parser 132. That is, a weak magnetic force may be applied to the first level sensor 131 disposed to correspond to the first lower limit adjacent to the second lower limit. The first level sensor 131 may not generate the sensing signal when the applied magnetic force is less than or equal to the reference value, and may generate the sensing signal when the applied magnetic force exceeds the reference value. The first level sensor 131 may generate a first sensing signal when the applied magnetic force exceeds a reference value, and output the generated first sensing signal to the controller 140.

Meanwhile, since the water level of the float capsule 120 is less than or equal to the second lower limit and the float capsule 120 is positioned according to the water level, the third level sensor 133 disposed to correspond to the first upper limit of the float capsule 120. ), No magnetic force is applied. In addition, magnetic force is not applied to the fourth level sensor 134 disposed to correspond to the second upper limit of the float capsule 120. Therefore, the third level sensor 133 and the fourth level sensor 134 do not output the sensing signal to the controller 140.

The controller 140 may recognize the water level of the wet tank 200 based on a sensing signal input in real time from the first to fourth level sensors 131 to 134. When the second sensing signal is applied from the second level sensor 132, the controller 140 determines that the water level of the wet tank 200 is less than or equal to the second lower limit. The controller 140 may stop the water discharge by closing the water discharge pipe 230 by controlling a lever disposed in the water discharge pipe 230 according to the water level determination result. That is, the controller 140 may stop discharging water by closing the water discharge pipe 230 based on the second sensing signal. In addition, the controller 140 may control the lever disposed in the water inlet tube 240 to open the water inlet tube 240 so that water may be introduced into the wet tank 200. In this case, the controller 140 may continuously maintain the state in which the water discharge pipe 230 is closed when the water level falls below the first lower limit, and may maintain the state in which the water inlet pipe 240 is opened. . The controller 140 may control the water discharge pipe 230 to be closed until the water level of the wet tank 200 reaches a normal range, and control the water inlet pipe 240 to be opened.

When the sensing signal is applied from not only the first level sensor 131 but also the second level sensor 132, the controller 140 receives the first sensing signal and the second level sensor 132 from the first level sensor 131. The second sensed signal from can be compared. When the second sensing signal input from the second level sensor 132 is greater than the first sensing signal input from the first level sensor 131, it may be determined that the float capsule 120 is positioned adjacent to the second lower limit. have. Accordingly, the controller 140 may recognize that after the water level is lowered from the normal range to the first lower limit, the water level is further lowered and lowered below the second lower limit. The controller 140 may adjust the water level of the wet tank 200 based on the second control signal input from the second level sensor 132.

In addition, the controller 140 may generate a graph or an image of the water level corresponding to the change of the water level, and display the same through the display means. When the water level is lowered below the second lower limit in the normal range, the controller 140 may indicate that the water replenishment is necessary by displaying the water level change through the display means.

On the other hand, even when the water level is lower than the first lower limit due to a failure or a sensing error of the first level sensor 131, the water shortage state may not be sensed. In this case, when the water level is continuously lowered below the second lower limit, the water shortage state may be sensed using the second level sensor 132. In addition, the controller 140 recognizes that the water level is lowered below the second lower limit value, controls the water discharge pipe 230 of the wet tank 200 to be closed, and controls the water inlet pipe 240 to be opened to control the water. Replenishment can be made.

6A and 6B are diagrams for describing an operation of the level sensor when the level of the floating tank according to an embodiment of the present invention is greater than or equal to an upper limit.

First, referring to FIGS. 4 and 6A, when the water level of the wet tank 200 rises, the water level of the float tank 110 connected to the wet tank 200 also rises in the same manner. As the water level of the float tank 110 rises, the float capsule 120 also rises together. When the water level of the float tank 110 rises above the first upper limit, the magnetic force is applied to the third level sensor 133 disposed such that the permanent magnet 124 included in the float capsule 120 corresponds to the first upper limit. Done. The third level sensor 133 senses a magnetic force applied from the permanent magnet 124 to generate a third sensing signal indicating that the water level of the wet tank 200 is greater than or equal to the first upper limit value, and the generated third sensing signal. May be output to the controller 140. In this case, a weak magnetic force may also be applied to the fourth level sensor 134 disposed adjacent to the third level parser 133. That is, a weak magnetic force may be applied to the fourth level sensor 134 disposed to correspond to the second upper limit value adjacent to the first upper limit value. The fourth level sensor 134 may not generate the sensing signal when the applied magnetic force is less than or equal to the reference value, and may generate the sensing signal when the applied magnetic force exceeds the reference value. When the applied magnetic force exceeds the reference value, the fourth level sensor 134 may generate a fourth sensing signal and output the generated fourth sensing signal to the controller 140.

Meanwhile, since the water level of the float capsule 120 is greater than or equal to the first upper limit and the float capsule 120 is positioned according to the water level, the first level sensor 131 disposed to correspond to the first lower limit of the float capsule 120. ), No magnetic force is applied. In addition, magnetic force is not applied to the second level sensor 132 disposed to correspond to the second lower limit of the float capsule 120. Therefore, the first level sensor 131 and the second level sensor 132 do not output the sensing signal to the controller 140.

The controller 140 may recognize the water level of the wet tank 200 based on a sensing signal input in real time from the first to fourth level sensors 131 to 134. The controller 140 determines that the water level of the wet tank 200 is greater than or equal to the first upper limit value when the third sensing signal is applied from the third level sensor 133. The controller 140 may control the lever disposed in the water discharge pipe 230 to open the water discharge pipe 230 according to the water level determination result, thereby allowing the water discharge to be performed. In addition, the controller 140 may control the lever disposed in the water inlet tube 240 to close the water inlet tube 240 to stop the water replenishment. That is, the controller 140 may prevent the water from flowing into the wet tank 200 by closing the water inlet pipe 240 based on the third sensing signal. In addition, the controller 140 may open the water discharge pipe 230 to discharge water based on the third sensing signal.

When the sensing signal is applied from the fourth level sensor 134 as well as the third level sensor 133, the controller 140 may include the third sensing signal and the fourth level sensor 134 from the third level sensor 133. The fourth sensed signal from can be compared. When the third sensing signal input from the third level sensor 133 is greater than the fourth sensing signal input from the fourth level sensor 134, it may be determined that the float capsule 120 is positioned adjacent to the first upper limit value. have. Accordingly, the controller 140 may recognize that the water level rises above the first upper limit value in the normal range, and may adjust the water level of the wet tank 200 accordingly.

In addition, the controller 140 may generate a graph or an image of the water level corresponding to the change of the water level, and display the same through the display means. When the water level rises above the first upper limit in the normal range, the controller 140 may indicate that the water discharge is necessary by displaying the water level change through the display means.

4 and 6B, when the water level of the wet tank 200 rises, the water level of the float tank 110 connected to the wet tank 200 also rises in the same manner. As the water level of the float tank 110 rises, the float capsule 120 also rises together. When the water level of the float tank 110 rises above the second upper limit beyond the first upper limit, the fourth level sensor 134 disposed such that the permanent magnet 124 included in the float capsule 120 corresponds to the second upper limit. Magnetic force). The fourth level sensor 134 senses a magnetic force applied from the permanent magnet 124 to generate a fourth sensing signal indicating that the water level of the wet tank 200 is greater than or equal to the second upper limit value, and the generated fourth sensing signal. May be output to the controller 140. In this case, a weak magnetic force may be applied to the third level sensor 133 disposed adjacent to the fourth level parser 134. That is, a weak magnetic force may be applied to the third level sensor 133 disposed to correspond to the first upper limit value adjacent to the second upper limit value. The third level sensor 133 may not generate the sensing signal when the applied magnetic force is less than or equal to the reference value, and may generate the sensing signal when the applied magnetic force exceeds the reference value. When the applied magnetic force exceeds the reference value, the third level sensor 133 may generate a third sensing signal and output the generated third sensing signal to the controller 140.

Meanwhile, since the water level of the float capsule 120 is greater than or equal to the second upper limit and the float capsule 120 is positioned according to the water level, the first level sensor 131 disposed to correspond to the first lower limit of the float capsule 120. ), No magnetic force is applied. In addition, magnetic force is not applied to the second level sensor 132 disposed to correspond to the second lower limit of the float capsule 120. Therefore, the first level sensor 131 and the second level sensor 132 do not output the sensing signal to the controller 140.

The controller 140 may recognize the water level of the wet tank 200 based on a sensing signal input in real time from the first to fourth level sensors 131 to 134. The controller 140 determines that the water level of the wet tank 200 is greater than or equal to the second upper limit value when the fourth sensing signal is applied from the fourth level sensor 134. The controller 140 may control the lever disposed in the water discharge pipe 230 to open the water discharge pipe 230 according to the water level determination result, thereby allowing water discharge.

In addition, the controller 140 may control the lever disposed in the water inlet tube 240 to close the water inlet tube 240 to stop the water replenishment. That is, the controller 140 may prevent the water from flowing into the wet tank 200 by closing the water inlet pipe 240 based on the fourth sensing signal. In addition, the controller 140 may open the water discharge pipe 230 to discharge water based on the fourth sensing signal. In this case, the controller 140 continuously maintains the state in which the water discharge pipe 230 is opened when the water level of the wet tank 200 rises above the first upper limit value, and closes the water inlet pipe 240. It can be maintained continuously. The controller 140 may control the water discharge pipe 230 to open until the water level of the wet tank 200 reaches a normal range, and control the water inlet pipe 240 to be closed.

When the sensing signal is applied from the fourth level sensor 134 as well as the third level sensor 133, the controller 140 may include the third sensing signal and the fourth level sensor 134 from the third level sensor 133. The fourth sensed signal from can be compared. When the fourth sensing signal input from the fourth level sensor 134 is greater than the third sensing signal input from the third level sensor 133, it may be determined that the float capsule 120 is positioned adjacent to the second upper limit value. have. Accordingly, the controller 140 may recognize that after the water level rises from the normal range to the first upper limit, the water level rises further and falls below the second upper limit. The controller 140 may adjust the water level of the wet tank 200 based on the fourth control signal input from the fourth level sensor 134.

In addition, the controller 140 may generate a graph or an image of the water level corresponding to the change of the water level, and display the same through the display means. When the water level rises above the second upper limit in the normal range, the controller 140 may indicate that the water discharge is necessary by displaying the water level change through the display means.

On the other hand, even when the water level becomes greater than or equal to the first upper limit due to a failure or a sensing error of the third level sensor 133, the water fullness state may not be sensed. In this case, when the water level continuously rises to be greater than or equal to the second upper limit value, the water filling state may be sensed using the fourth level sensor 134. In addition, the controller 140 recognizes that the water level has risen above the second upper limit value, controls the water discharge pipe 230 of the wet tank 200 to be opened, and controls the water inlet pipe 240 to be closed to control the water. Emissions can be made.

As such, by sensing the water level of the float tank 110, the water level inside the wet tank 200 can be accurately identified without even visually checking the wet tank 200 directly, and even changes in the water level can be confirmed. Through this, the water level of the wet tank 200 can be managed smoothly.

7 is a view showing a float capsule according to another embodiment of the present invention. 8 is a view showing a floating tank according to another embodiment of the present invention.

Referring to FIGS. 7 and 8, the float capsule 120 may be formed in a cylindrical shape having a predetermined height in a vertical direction so as to be moved up and down in the float tank 110 according to the water level. The float capsule 120 may include a floating portion 122 that provides buoyancy to float on water. In addition, the float capsule 120 may include a permanent magnet 124 so that the water level can be sensed by the plurality of level sensors 130. The floating portion 122 may be disposed below the float capsule 120, and the permanent magnet 124 may be disposed on the floating portion 122. In addition, a plurality of guide protrusions 126 may be formed on an outer surface of the float capsule 120.

A plurality of guide protrusions 126 may be formed at an intermediate position of the outer surface of the float capsule 120 in the vertical direction. In the horizontal direction, the plurality of guide protrusions 126 may be formed to be spaced apart by an equidistant distance. As an example, four guide protrusions 126 may be formed on an outer surface of the float capsule 120, and four guide protrusions 126 may be spaced equidistantly.

A plurality of guide grooves 116 may be formed on the inner circumferential surface of the float tank 110. Each of the plurality of guide grooves 116 is formed in a trench shape having a predetermined depth from the top to the bottom of the float tank 110. Each of the plurality of guide protrusions 126 may be inserted into a plurality of guide grooves 116 formed on the inner surface of the float tank 110.

The guide protrusion 126 of the float capsule 120 may be inserted into the guide groove 116 of the float tank 110 to allow the float capsule 120 to be up and down depending on the water level. Since there is a space between the inner wall of the float tank 110 and the float capsule 120 may move in the horizontal direction when the float capsule 120 moves up and down, the guide protrusion 126 is inserted into the guide groove 116 Thereby, the vertical movement of the float tank 110 can be guided. That is, the guide protrusion 126 and the guide groove 116 may be guided so that the vertical movement of the float tank 110 can be performed in the vertical direction without vibration in the horizontal direction.

9 is a view showing a floating tank according to another embodiment of the present invention.

9, a plurality of guide rollers 118 may be disposed on the inner circumferential surface of the float tank 110. The plurality of guide rollers 118 may be uniformly disposed from the top to the bottom of the float tank 110. After the float capsule 120 is inserted into the float tank 110, the float capsule 120 moves up and down depending on the water level, and a space between the inner wall of the float tank 110 and the float capsule 120. Due to this existence, the float capsule 120 may shake in the horizontal direction when moved up and down. Since a plurality of guide rollers 118 are disposed on the inner surface of the float tank 110, the vertical movement of the float tank 110 may be smoothly performed. That is, when the vertical movement of the float tank 110 through the plurality of guide rollers 118 can be moved straight in the vertical direction without vibration in the horizontal direction. In addition, when the float capsule 120 moves up and down inside the float tank 110, friction may occur while contacting the inner circumferential surface of the float tank 110, and thus foreign substances may be generated. In the present invention, the plurality of guide rollers 118 may be disposed on the inner circumferential surface of the float tank 110 so that the float capsule 120 may be moved straight in the vertical direction without contact with the inner circumferential surface of the float tank 110.

In the above, embodiments of the present disclosure have been described with reference to the accompanying drawings, but a person having ordinary knowledge in the technical field to which the present disclosure belongs may change the present disclosure without changing the technical spirit or essential features thereof. It will be appreciated that the present invention may be practiced as. The above described embodiments are to be understood in all respects as illustrative and not restrictive.

100: floating sensor 110: float tank
112: connecting pipe 114: connecting means
116: a plurality of guide grooves 120: float capsule
122: floating bure 124: permanent magnet
126: a plurality of guide projections 130: a plurality of level sensors
131: first level sensor 132: second level sensor
133: third level sensor 134: fourth level sensor
140: control unit 200: wet tank
210: tank body 220: tank cover
230: water discharge pipe 240: water inlet pipe
250: float tank connection hole

Claims (11)

In the floating sensor for sensing the water level of the wet tank for scrubber,
A float tank in which water is introduced through a pipe connected to the wet tank to maintain the same water level as the wet tank;
A float capsule which moves up and down in accordance with the water level in the float tank, including a float and a permanent magnet to provide buoyancy;
A plurality of level sensors disposed on an outer circumferential surface of the float tank and configured to generate a sensing signal by sensing a magnetic force of the permanent magnet; And
And a controller configured to adjust the water level of the wet tank based on the sensing signals received from the plurality of level sensors.
A plurality of rollers are arranged on the inner circumferential surface of the float tank from the upper side to the lower side to guide the vertical movement of the float capsule,
Floating sensor; According to claim 1,
The plurality of level sensors,
A first level sensor disposed at a position corresponding to a first lower limit for sensing water shortage of the wet tank;
A second level sensor disposed at a position corresponding to a second lower limit lower than the first lower limit to sense water shortage;
A third level sensor disposed at a position corresponding to a first upper limit value for sensing the fullness of the wet tank;
A fourth level sensor disposed at a position corresponding to a second upper limit higher than the first upper limit and configured to sense water filling;
Floating sensor; The method of claim 2,
The first level sensor,
Sensing a magnetic force from the permanent magnet to generate a first sensing signal indicating that the water level of the wet tank is below the first lower limit,
Outputting the first sensing signal to the controller;
Floating sensor; The method of claim 2,
The second level sensor,
Sensing a magnetic force from the permanent magnet to generate a second sensing signal indicating that the water level in the float tank is below the second lower limit,
Outputting the second sensing signal to the controller;
Floating sensor; The method according to claim 3 or 4,
The control unit,
The water discharge pipe disposed in the wet tank is closed based on the first sensing signal input from the first level sensor or the second sensing signal input from the second level sensor, and the water inlet pipe is opened to the wet tank. Replenishing water,
Floating sensor; The method of claim 2,
The third level sensor,
Sensing a magnetic force from the permanent magnet to generate a third sensing signal indicating that the water level of the float tank is greater than or equal to the first upper limit value,
Outputting the third sensing signal to the controller;
Floating sensor; The method of claim 2,
The fourth level sensor,
Sensing a magnetic force from the permanent magnet to generate a fourth sensing signal indicating that the water level of the float tank is greater than or equal to the second upper limit,
Outputting the fourth sensing signal to the controller;
Floating sensor; The method according to claim 6 or 7,
The control unit,
The water discharge pipe disposed in the wet tank is opened based on the third sensing signal input from the third level sensor or the fourth sensing signal input from the fourth level sensor, and the water inlet pipe is closed to close the water tank. Draining water,
Floating sensor; According to claim 1,
The inner peripheral surface of the float tank is formed with a plurality of guide grooves of a predetermined depth from the upper side to the lower side,
Floating sensor; The method of claim 9,
A plurality of guide protrusions are formed on the outer circumferential surface of the float capsule,
The plurality of guide protrusions are inserted into the plurality of guide grooves to guide the vertical movement of the float capsule,
Floating sensor; delete

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