KR20170132918A - Floating Sensor and Wet Tank for Scrubber having the Same - Google Patents

Abstract

Disclosed are a floating sensor and a wet tank including the same. The floating sensor comprises: a floating unit including a floating rod formed to have a height greater than a management range of a water level, and a plurality of permanent magnets coupled to a height at least corresponding to the management range at a predetermined interval in a downward direction from an upper portion of the floating rod; a floating air bladder having an inner hollow shape formed in a closed cylindrical shape having buoyancy, and coupled to a lower portion of the floating rod; a sensor unit including a plurality of magnetic sensors spaced apart from each other at a predetermined interval in a vertical direction at a height corresponding to the management range to sense a magnetic force of the permanent magnet; an outer cover pipe having an inner hollow portion, formed in a cylindrical shape having an upper portion sealed, and accommodating the sensor unit therein; and a lower flange unit coupled to a lower portion of the outer cover pipe including a first lower flange having a first flange hole formed on a center thereof to allow the floating rod to pass and flow therethrough. According to the present invention, the floating sensor is not contaminated by the byproduct particles flowing into the wet tank, and is able to easily be maintained.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a floating sensor and a wettank for a scrubber including the same,

BACKGROUND OF THE INVENTION 1. Field of the Invention 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 the water level of the wet tank and a wet tank for scrubber including the same.

2. Description of the Related Art Generally, gases and chemicals used in the manufacturing process of electronic parts such as semiconductor display, solar, and LED have characteristics such as toxicity, corrosiveness, and explosiveness. In addition, the waste gas used and discharged in an electronic component manufacturing process contains a large amount of acid components, moisture, dust, etc. generated during the manufacturing process.

The scrubber for treating the harmful waste gas discharged from the semiconductor manufacturing process and the like has a heating combustion system and a wet system. The heating combustion method is a method in which the waste gas is decomposed, reacted, or burned with a high temperature flame or plasma. In the wet type, the waste gas is contacted with water to dissolve the water soluble component contained in the waste gas. The scrubber of the heating combustion type uses a burner of the fuel combustion type, a burner of the plasma type, or a burner of the heating heater type to treat the waste gas. For example, a burner of a fuel combustion type uses a flame generated by fuel, an oxidant (for example, LNG) and oxygen, and burns offgas introduced into the combustion chamber. A scrubber including a burner of a fuel combustion type generally has a combustion chamber and a wet tank sequentially installed at a lower portion of the burner. Further, the scrubber of the fuel combustion type has a water treatment tower connected to the combustion chamber through 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. A fuel-burning scrubber allows the burned offgas to flow through the combustion chamber and the wetting tank to the water treatment tower. The by-product particles generated as the waste gas is burned and decomposed are primarily trapped in a wet tank located at the bottom of the combustion chamber. When the by-product particles are fine, the waste gas flows into the water treatment tower together with the waste gas, and the incoming by-product particles are collected by the wet tank together with the water sprayed from the water treatment tower. Or the water-soluble component contained in the burned waste gas is dissolved in water and collected while the waste gas flows in contact with water in the wet tank.

Wet tanks need to maintain a certain level of water level inside. The wet tank is exposed to high temperatures by the burner located at the top, so that water is constantly evaporated. On the other hand, the wet tank is continuously supplied with water sprayed from the water treatment tower. Conventionally, a transparent branch was installed on one side of a wet tank, and the water level in the wet tank was checked by looking at the water level of the branch pipe. However, as described above, by-product particles following the treatment of waste gas are continuously introduced into the wet tank. The byproduct particles flow into the inside of the branch pipe and contaminate the inner surface of the branch pipe, which makes it difficult to confirm the water level. There is a problem that the operation of the entire scrubber must be stopped because the branch pipe must be disassembled in order to clean the branch tank of the wet tank.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a floating sensor which is not contaminated by by-product particles flowing into the interior of a wet-type tank and is easy to maintain and a wet-type tank for a scrubber including the same.

It is another object of the present invention to provide a floating sensor capable of remotely checking the water level in a wet tank and a wet tank for a scrubber containing the same.

According to an aspect of the present invention, there is provided a floating sensor comprising: a floating rod formed at a height greater than a control range of a water level; and at least a height corresponding to a management range in a downward direction from an upper portion of the floating rod A plurality of permanent magnets coupled at predetermined intervals; a floating brace formed in a hollow cylindrical shape and having a buoyancy and coupled to a lower portion of the floating bar; And a plurality of magnetic sensors spaced apart from each other by a predetermined distance in the vertical direction to sense the magnetic force of the permanent magnet, and a sensor unit having a hollow inside and a closed upper part, A cover tube and a cover tube coupled to a lower portion of the outer cover tube, Characterized in that it includes a lower flange portion including a first lower flange is provided with a first flange hole is formed so that flow.

The floating sensor may be formed in a hollow cylindrical shape and may include an inner cover tube that is formed to surround the floating rod from a top of the floating rod to a position where at least the permanent magnet is coupled.

The floating bar further includes a floating guide groove formed at a height corresponding to at least the management range from the upper end to the lower end and a magnet groove inserted and coupled with the permanent magnet, Wherein the first lower flange further comprises a floating guide protrusion formed in the shape corresponding to the floating guide groove from the inner surface of the first flange hole and coupled to the floating guide groove, .

The floating bore includes a tubular outer bore tube that opens upward and downward, an inner bore tube that has a cylindrical shape corresponding to the outer bore tube and has an outer surface separated from an inner surface of the outer bore tube to form a spacing space, And an upper baffle plate and a lower baffle plate which are formed in a plate shape corresponding to a planar shape of the spacing space and seal the upper and lower portions of the spaced space, wherein the lower portion of the floating rod is inserted into the inner baffle pipe Wherein a fixing groove is formed at a position corresponding to the upper surface position and the lower surface position of the floating bracket, the fixing groove being formed in a ring shape having a predetermined depth from the outer surface to the inner side, the floating portion being coupled to the upper surface of the floating rib, And a stop ring which is in contact with the lower surface.

The sensor unit may include a sensor support block formed at a height corresponding to at least the management range and positioned outside the inner cover tube and spaced apart from the sensor support block in a vertical direction, And a sensor bracket to which the magnetic sensor is coupled.

Also, the outer cover tube may be formed to penetrate from the outer side to the inner side, and may further include an outer perspective hole having a height and a predetermined width corresponding to the management range.

The first lower flange may further include a flange protruding ring protruding from a center of the upper surface to a predetermined height and having a first flange through hole and a floating guide protrusion formed at a center thereof, And a second lower flange formed on the upper surface of the first lower flange and coupled to a lower portion of the inner cover tube, the second lower flange being formed with a smaller area than the outer cover tube and having a second flange- As shown in FIG.

In addition, the inner cover tube, the outer cover tube, and the lower flange portion may be formed of a non-magnetic material.

The wet type wet scrubber for a scrubber according to the present invention is characterized in that the wet scrubber tank has a tank body formed in a box shape with an open top and a sensor engaging hole penetrating up and down, Wherein the first lower flange is coupled to an upper portion of the body cover such that the first flange hole is in position with the sensor engagement hole and the floating rod is connected to the sensor And the floating float may be coupled to a lower portion of the floating rod to be positioned inside the tank body.

The floating sensor and the wetting tank for scrubber including the same according to an embodiment of the present invention are located only in the inside of the wetting tank and the part for measuring the water level is located outside the wetting tank, Thereby preventing contamination and facilitating maintenance.

In addition, according to the present invention, the floating sensor and the wetting tank for a scrubber including the same can measure the water level by using the permanent magnet and the magnetic sensor, so that the water level can be remotely checked.

1 is a perspective view of a floating sensor according to an embodiment of the present invention.
2 is a vertical cross-sectional view of AA of FIG.
3 is a perspective view of the floating bar shown in Fig.
4 is a vertical sectional view of BB of Fig.
5 is a perspective view of the inner cover tube shown in Fig.
6 is a side view of the sensor unit shown in Fig.
7 is a perspective view of the sensor supporting block mounted on the sensor unit of Fig.
8 is a perspective view of the sensor bracket mounted on the sensor unit of FIG.
9 is a perspective view of the outer cover tube shown in Fig.
Figure 10 is a perspective view of the first lower flange of the lower flange in Figure 1;
11 is a partial vertical cross-sectional view of a scrubber to which a wet tank containing a floating sensor according to an embodiment of the present invention is mounted.
12 is a vertical sectional view of a state in which a water level is highest in a wet tank including a floating sensor according to an embodiment of the present invention.
13 is a vertical cross-sectional view of a state in which the water level in the wet tank including the floating sensor according to the embodiment of the present invention is lowered.

Hereinafter, a floating sensor according to an embodiment of the present invention and a wetting tank for a scrubber including the same will be described in detail with reference to the accompanying drawings and embodiments.

The embodiments of the present invention are described in order to more fully explain the present invention to those skilled in the art, and the following embodiments may be modified into various other forms, It is not limited to the embodiment. Rather, these embodiments are provided so that this disclosure will be more faithful and complete, and will fully convey the scope of the invention to those skilled in the art.

In the following drawings, thickness and size of each layer are exaggerated for convenience and clarity of description, and the same reference numerals denote the same elements in the drawings. As used herein, the term "and / or" includes any and all combinations of one or more of the listed items.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms "a," "an," and "the" include singular forms unless the context clearly dictates otherwise. Also, " comprise "and / or" comprising "when used herein should be interpreted as specifying the presence of stated shapes, numbers, steps, operations, elements, elements, and / And does not preclude the presence or addition of one or more other features, integers, operations, elements, elements, and / or groups.

First, a floating sensor according to an embodiment of the present invention will be described.

1 to 10, a floating sensor 100 according to an embodiment of the present invention includes a floating part 110, a floating part 120, an inner cover pipe 130, a sensor part 140, A tube 150 and a lower flange portion 160. As shown in FIG.

The floating portion 110 is formed to include a floating bar 111, a stop ring 115, a permanent magnet 117, and an upper stopper 119. The floating unit 110 is coupled to the floating boom 120 and flows up and down along with the floating boom 120 according to the water level of the wet tank. That is, the floating unit 110 moves up and down in a height difference range (hereinafter referred to as "management range") between a lower limit of the water level set to manage the water level of the water filled in the wet tank and an upper limit value do.

The floating bar 111 is formed to include a floating guide groove 112 and a magnet groove 113. In addition, the floating bar 111 may further include a fixing groove 114.

The floating bar 111 is formed into a rod shape having a predetermined height larger than the management range, and is formed in a shape such as a cylinder or a square shape as a whole. In addition, the upper portion of the floating bar 111 where the permanent magnet 117 is positioned is formed into a square columnar shape, and the lower portion of the floating bar 111 may have a cylindrical shape. The floating bar 111 is formed of a resin material, and may be formed of a transparent material. Therefore, the floating bar 111 allows the position of the permanent magnet 117 located inside to be identified from outside. The floating bar 111 is separated from the left and right with respect to the central axis so that the permanent magnet 117 can be coupled to the inside of the floating bar 111. [

The floating guide groove 112 is formed in a trench shape from the upper end to the lower end of the floating rod 111. The floating guide groove 112 may be formed at a predetermined height from an upper end of the floating bar 111 and may not be opened to the upper end. The floating guide groove 112 is formed at a height corresponding to at least the management range. The floating guide groove 112 may be formed to have a circular cross section or a rectangular cross section. The floating guide groove 112 guides the floating rod 111 to flow stably in a vertical direction. Further, the floating guide groove 112 can guide the floating rod 111 to move up and down in the area of the management range. That is, the lower end of the floating guide groove 112 can be set to the position of the floating rod 111 when the water level of the wet tank is the highest. The upper end of the floating guide groove 112 may be set to the position of the floating rod 111 when the water level of the wet tank is the lowest.

The magnet grooves 113 are formed in a groove shape at a predetermined interval in the vertical direction from the upper portion to the lower portion of the floating bar 111 in the area of the management range. The magnet groove 113 is formed in a shape corresponding to the shape of the permanent magnet 117. That is, the magnet groove 113 is formed with a groove depth corresponding to at least the height of the permanent magnet 117 and a groove area corresponding to the groove diameter or area of the permanent magnet 117. The magnet groove 113 is formed inside the floating rod 111. That is, the floating bar 111 is divided into left and right unit rods with respect to the central axis, and is formed on the inner surface of one of the unit rods. Since the magnet groove 113 is not exposed to the outer surface of the floating rod 111, the permanent magnet 117 located inside can be prevented from being damaged. Since the magnet 111 and the permanent magnet 117 are not exposed to the outer surface of the floating rod 111, the inner surface of the inner cover tube 130 is not damaged by the step difference when the floating rod 111 flows upward and downward. Meanwhile, the magnet groove 113 may be formed to have a groove depth from the outer surface of the floating rod 111 to the inside.

The fixing groove 114 is formed in a ring shape having a predetermined depth from the outer side to the inner side at a position corresponding to the position where the floating rib 120 is coupled from the lower part of the floating rod 111. The fixing groove 114 is formed by two upper and lower fixing grooves 114a formed at a height corresponding to the lower surface of the floating bracket 120 and an upper fixing groove 114b formed at a height corresponding to the upper surface . On the other hand, the fixing grooves 114 can be omitted when the floating rib 120 is coupled with the floating rod 111 by another method such as bolt connection or welding.

The stop ring 115 is formed in a ring shape and is detachably coupled to the fixing groove 114. The stop ring 115 is formed of two pieces and is engaged with the lower fixing groove 114a and the upper fixing groove 114b and is in contact with the upper surface and the lower surface of the floating plate 120, respectively. The stop ring 115 fixes the floating rib 120 to the bottom of the floating rod 111.

The permanent magnets 117 are formed in a block shape having a predetermined height, diameter or area. The permanent magnets 117 are coupled to the floating rod 111 at predetermined intervals in the vertical direction. More specifically, the permanent magnets 117 are formed at a predetermined distance in the downward direction from the top of the floating bar 111 in a region corresponding to at least the management range. A plurality of the permanent magnets 117 are inserted into the magnet grooves 113 of the floating bar 111, respectively. The permanent magnet 117 is formed of various permanent magnets 117 capable of generating a magnetic field. For example, the permanent magnet 117 is formed of an iron oxide magnet, or a rare earth magnet such as a neodymium magnet or a samarium magnet.

The upper stopper 119 is formed in a ring shape having a larger diameter or a horizontal area than the floating bar 111 and is coupled to the upper end of the floating bar 111. The upper stopper 119 controls the lowering position when the floating bar 111 descends. That is, the upper stopper 119 prevents the floating rod 111 from completely separating from the inner cover tube 130.

The floating bearing 120 is hollow and has a closed cylindrical shape. Since the inside of the floating boom 120 is hollow, the floating boom 120 itself has buoyancy and floats on the water surface of the water filled in the wet tank. Further, the floating float 120 flows up and down according to the water level of the water. Accordingly, the floating boom 120 may have various structures that float along the water surface of the water.

For example, the floating boom 120 may include an external boom pipe 121, an internal boom pipe 123, an upper boom plate 125, and a lower boom plate 127. The outer bore tube 121 is formed in a cylindrical shape having a predetermined height opened up and down. For example, the outer borehole pipe 121 may be formed in a cylindrical shape having upper and lower openings or a rectangular shape. The inner bore tube 123 is formed in a cylindrical shape having a predetermined height opened up and down. The inner bore tube 123 has a shape corresponding to the outer bore tube 121 and is formed such that its outer surface is spaced apart from the inner surface of the outer bore tube 121. For example, the inner bore tube 123 may be formed in a cylindrical shape or a square shape with open top and bottom. The outer bore tube 121 and the inner bore tube 123 are spaced from each other to form a spacing space therein, and the floating bureau 120 is filled with air necessary for buoyancy in the spacing space. The upper baffle plate 125 and the lower baffle plate 127 are formed in a plate shape corresponding to the planar shape of the spacing space between the outer baffle pipe 121 and the inner baffle pipe 123. For example, the upper and lower baffles 125 and 127 may be formed as a circular ring or a square ring. The upper baffle plate 125 and the lower baffle plate 127 are respectively coupled to the upper and lower portions of the outer bore pipe 121 and the inner bore pipe 123 to seal the upper and lower portions of the spaced space.

In addition, the bottom of the floating bar 111 is inserted and coupled to the inner side of the inner bore tube 123. Accordingly, the inner bore tube 123 is formed with an inner diameter corresponding to the outer diameter of the floating rod 111. [

 The inner cover tube 130 is formed in a hollow cylindrical shape and is formed into a cylindrical shape or a rectangular tube shape. The inner cover tube 130 is formed to have an inner diameter that is spaced apart from the outer surface of the floating rod 111. In addition, the inner cover tube 130 is formed at a height larger than the management range of the floating bar 111. [ The inner cover tube 130 is formed so as to cover at least the position where the permanent magnet 117 is coupled from the upper portion of the floating rod 111. That is, the floating rod 111 is inserted from the lower portion of the inner cover tube 130, and the permanent magnet 117 positioned at the lowermost portion is inserted to be positioned below the inner cover tube 130.

The inner cover tube 130 is made of a resin material or a non-magnetic material such as stainless steel. Accordingly, the permanent magnets 117 coupled to the floating bar 111 are easily moved up and down without attraction due to the magnetic force between the permanent magnets 117 and the inner cover tube 130. In addition, the inner cover tube 130 is preferably made of a transparent material so that the position of the permanent magnet 117 can be identified from outside.

The reference numeral 130a is a through hole for allowing air to flow smoothly into the space between the upper inner surface of the inner cover tube 130 and the upper surface of the floating rod 111 when the floating rod 111 moves up and down.

The sensor unit 140 includes a sensor support block 141, a sensor bracket 143, and a magnetic sensor 145. The sensor unit 140 is installed on the outer side of the inner cover tube 130. The magnetic sensor 145 senses the position of the permanent magnet 117 and senses that the floating rod 111 moves up and down.

The sensor support block 141 may include a block hole 141a and a bracket coupling hole 141b. The sensor support block 141 is formed in a substantially plate-like shape and has a height corresponding to a predetermined width and at least a management range. The sensor support block 141 is located outside the inner cover tube 130. The upper and lower ends of the sensor supporting block 141 are curved and arc shaped. The sensor support block 141 has an end that is in contact with the outer surface of the inner cover tube 130 and a side of the sensor support block 141 that faces the inner cover tube 130 is coupled to the outer surface of the inner cover tube 130. The sensor supporting block 141 is formed of a resin material or a non-magnetic material such as stainless steel, and preferably a transparent material such as transparent PVC. Therefore, the sensor support block 141 does not affect the vertical movement of the permanent magnet 117.

The block hole 141a is formed to extend in the height direction while passing through the sensor supporting block 141 from one surface to the other surface. The block hole 141a is formed to have a height corresponding to the management range, and the movement of the permanent magnet 117 of the floating bar 111 is observed.

The bracket coupling hole 141b is formed through one side of the sensor supporting block 141 to the other side. The bracket coupling hole 141b is formed at a position where the sensor bracket 143 is engaged.

The sensor bracket 143 includes a sensor hole 143a and a bracket hole 143b. The sensor bracket 143 may be a general bracket to which the magnetic sensor 145 can be coupled. A plurality of the sensor brackets 143 are separated from each other in the vertical direction in the area of the management range and are coupled to the sensor supporting block 141. For example, the sensor brackets 143 may be separated from each other by four in the management range.

Like the sensor support block 141, the sensor bracket 143 is formed of a non-magnetic material and may be formed of stainless steel for firmly supporting the magnetic sensor 145.

The sensor hole 143a is formed to penetrate from one side to the other side in a substantially central region, and provides a path through which the magnetic sensor 145 is coupled.

The bracket holes 143b are formed on both sides of the bracket hole 143b from one side to the other side to provide a path through which a separate bolt and a nut coupled to the bracket coupling hole 141b pass.

The magnetic sensor 145 is formed of a general magnetic sensor capable of sensing a magnetic force. A plurality of the magnetic sensors 145 are coupled to the sensor brackets 143, respectively. Accordingly, the magnetic sensors 145 are spaced apart from each other by a predetermined distance in the vertical direction at a height corresponding to the management range, and are coupled to the sensor bracket 143. A plurality of the magnetic sensors 145 sense the magnetic force of the permanent magnet 117 and sense the up and down movement of the floating bar 111.

On the other hand, reference numeral 147 denotes a bracket for fixing the signal lines connected to the magnetic sensor.

The outer cover tube 150 is formed to include an outer viewing hole 150a and an outer receiving hole 150b. The outer cover tube 150 is formed in a cylindrical shape having a hollow inside and an upper closed shape, and is formed into a cylindrical shape or a rectangular tube shape. The outer cover tube 150 is formed to have an inner diameter or a width spaced apart from the sensor unit 140. The outer cover tube 150 is formed to have a height larger than the height of the inner cover tube 130. The outer cover tube 150 receives the inner cover tube 130 and the sensor unit 140 from the bottom. The inner cover tube 130 and the sensor unit 140 are inserted and coupled from the lower portion of the outer cover tube 150.

The outer cover tube 150 is made of a resin material or a non-magnetic material such as stainless steel. Therefore, the permanent magnets 117 coupled to the floating bar 111 are easily moved up and down without attraction due to magnetic force between the permanent magnets 117 and the outer cover pipe 150. In addition, the outer cover tube 150 is preferably made of a transparent material so that the position of the permanent magnet 117 can be identified from outside.

The outer viewing hole 150a is formed to penetrate from the outer side to the inner side, and is formed to have a height and a predetermined width corresponding to the management range. The outer viewing hole 150a allows the vertical movement of the permanent magnet 117 to be ascertained from the outside.

The external lead-in hole 150b provides a path through which the signal lines connected to the magnetic sensor 145 are led. The outer inlet hole 150b is preferably formed at the lower portion of the outer cover tube 150 to pass from the outer side to the inner side.

The lower flange portion 160 is formed to include a first lower flange 161 and a second lower flange 165. The first lower flange 161 and the second lower flange 165 may be integrally formed. The lower flange portion 160 is coupled to the lower portions of the inner cover pipe 130 and the outer cover pipe 150 to shield the lower portions of the inner cover pipe 130 and the outer cover pipe 150. The lower flange portion 160 provides a path through which the floating rod 111 penetrates and moves up and down.

The lower flange portion 160 is formed of a resin material or a non-magnetic material such as stainless steel. Therefore, the permanent magnet 117 coupled to the floating bar 111 does not generate attractive force between itself and the lower flange portion 160, and thus moves easily up and down.

The first lower flange 161 is formed to include a first flange through hole 162, a floating guide protrusion 163, and a flange protruding ring 164. The first lower flange 161 is formed in a shape corresponding to the lower shape of the outer cover pipe 150. For example, the first lower flange 161 may be formed in a disc shape or a rectangular plate shape having a predetermined thickness. The first lower flange 161 is coupled to the lower portion of the outer cover tube 150. More specifically, the first lower flange 161 is engaged with the lower surface or the lower inner surface of the outer cover pipe 150 to shield the lower portion of the outer cover pipe 150.

A reference numeral 161a is a through hole through which a bolt for fixing the screw hole or the second lower flange 165 for fixing the bolt for fixing the first lower flange 161 to the wet tank is passed.

The first flange through hole 162 is formed to penetrate from the upper surface to the lower surface of the first lower flange 161 and has a shape corresponding to the horizontal cross-sectional shape of the upper portion of the floating bar 111. The first flange through-hole 162 is inserted with the floating rod 111, and provides a path through which the floating rod 111 flows upward and downward.

The floating guide protrusion 163 protrudes from the inner surface of the first flange through hole 162 in the center direction. The floating guide protrusion 163 is formed to have a height corresponding to the height of the first flange through-hole 162. The floating guide protrusion 163 has a horizontal cross section corresponding to a horizontal cross section of the floating guide groove 112 of the floating bar 111. For example, the floating guide protrusion 163 may be formed to have a circular or rectangular cross section. The floating guide protrusion 163 is inserted into the floating guide groove 112 and guides the floating rod 111 to stably float up and down. The floating guide protrusion 163 may be integrally formed with the first lower flange 161 or may be formed separately.

The flange protruding ring 164 protrudes upward from the center of the upper surface of the first lower flange 161 to a predetermined height and outer diameter. The flange protruding ring 164 is formed by extending a first flange through hole 162 and a floating guide protrusion 163 at the center. The flange protruding ring 164 increases the height of the floating guide hole and the floating guide protrusion 163 so that the floating bar 111 floats more stably. The flange projecting ring 164 may be omitted when the first lower flange 161 is formed to a sufficient thickness so that the floating rod 111 floats more stably.

The second lower flange 165 is formed to include a second flange through-hole 166. The second lower flange 165 is formed in a shape corresponding to the shape of the first lower flange 161 and has a smaller area than the outer cover pipe 150. For example, the second lower flange 165 is formed in the shape of a disk or a square plate, and is formed with an inner diameter or width smaller than the inner diameter or width of the outer cover tube 150. The second lower flange 165 is located on the upper surface of the first lower flange 161 and is coupled to the lower portion of the inner cover tube 130. The second lower flange 165 shields the lower portion of the inner cover tube 130. The second lower flange 165 may be integrally formed with the first lower flange 161.

The second flange through-hole 166 is formed to penetrate from the upper surface to the lower surface at the center of the second lower flange 165. The second flange through-hole 166 is formed with an inner diameter or a width corresponding to the outer diameter or width of the flange protruding ring 164 of the first lower flange 161. A flange protruding ring 164 is inserted and coupled to the second flange through hole 166. Therefore, when the flange protruding ring 164 is omitted, the second lower flange 165 can also be omitted.

Next, a wet tank including a floating sensor according to an embodiment of the present invention will be described.

11 is a partial vertical cross-sectional view of a scrubber to which a wet tank containing a floating sensor according to an embodiment of the present invention is mounted.

11, a wet tank 10 including a floating sensor 100 according to an embodiment of the present invention includes a tank body 11, a body cover 13, and a floating sensor 100. The wet tank 10 includes a tank body 11, do. Although not shown in detail, the wet tank 10 is further provided with a pump for discharging the water contained therein, a pipe connected to the pump, and a water supply pipe for supplying water from the outside.

The tank body 11 is formed in a box shape with an open top, and water supplied from the outside is accommodated inside. The tank body 11 may have various shapes and sizes depending on the type and shape of the scrubber used.

The main body cover 13 is formed in a substantially plate-like shape and may be formed in various shapes according to the top shape of the tank body 11. [ The main body cover 13 is coupled to an upper portion of the tank main body 11 to seal the upper portion of the main body cover 13. The body cover 13 is vertically penetrated to form a sensor coupling hole 14 to which the floating sensor 100 is coupled. The main body cover 13 may have one side fitting hole 15 and another side fitting hole 16 to which the combustion part of the scrubber and the water treatment section are coupled.

The floating sensor 100 is formed as described above. The lower flange portion 160 of the floating sensor 100 is coupled to the upper portion of the main cover 13 by a separate bolt. At this time, the first lower flange 161 is coupled to the upper portion of the main body cover 13 such that the first flange hole is aligned with the sensor engagement hole 14. The floating rod 111 of the floating sensor 100 is inserted into the sensor coupling hole 14 and flows up and down. The floating float 120 is coupled to the lower portion of the floating rod 111 and is located inside the tank body 11. The floating float 120 floats on the water surface of the water contained in the tank main body 11.

In the meantime, various configurations can be combined with the upper part of the wet tank 10 according to the type of the scrubber. 11, the combustion unit 20 and the burner unit 30 are sequentially connected to one side of the wet tank 10, and the combustion unit 20 is connected to the one side coupling hole 15 (Not shown). The water treatment section 40 is coupled to the other side of the wet tank 10 through the other coupling hole 16. The combustion unit 20, the burner unit 30, and the water treatment unit 40 may be formed in various configurations according to the scrubber, and a detailed description thereof will be omitted.

The following describes the operation of a wet tank including a floating sensor according to one embodiment of the present invention.

12 is a vertical sectional view of a state in which a water level is highest in a wet tank including a floating sensor according to an embodiment of the present invention. 13 is a vertical cross-sectional view of a state in which the water level in the wet tank including the floating sensor according to the embodiment of the present invention is lowered.

Referring to FIG. 12, when the water level of the wet tank 10 is the highest, the floating float 120 rises together with the floating rod 111. The permanent magnet 117 positioned above the floating bar 111 applies a magnetic force to the magnetic sensor 145 located at the uppermost position of the sensor unit 140. Therefore, when four magnetic sensors 145 of the sensor unit 140 are configured, the four magnetic sensors 145 sense the magnetic force. Meanwhile, the sensor unit 140 can transmit a signal about the sensed magnetic force to a separate controller to inform that the water level of the wet tank 10 is being managed normally.

Next, referring to FIG. 13, when the water level of the wet tank 10 drops, the floating rod 111 descends together with the floating boom 120. The magnetic sensor 145 of the sensor unit 140 does not detect three magnetic forces from the top and one of the magnetic sensors 145 detects a magnetic force. The sensor unit 140 senses that the water level of the wet tank 10 is at a low water level and informs the wet tank 10 that it is necessary to replenish the water.

Therefore, the water level of the inside of the wet tank 10 can be confirmed without directly checking with the naked eye, and the water level can be appropriately managed.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. It will be clear to those who have knowledge.

100; Floating Sensor
110: Floating unit 120: Floating bore
130: Inner cover tube 140: Sensor part
150: outer cover tube 160: lower flange portion

Claims (9)

A floating bar including a plurality of permanent magnets coupled at a predetermined interval to a height corresponding to at least the management range in a downward direction from an upper portion of the floating bar;
A floating bush having an inner hollow and formed in a closed cylindrical shape and having buoyancy and being coupled to a lower portion of the floating rod;
A sensor unit having a plurality of magnetic sensors spaced apart from each other by a predetermined distance in a vertical direction at a height corresponding to the management range to sense the magnetic force of the permanent magnet;
An outer cover tube which is formed in a hollow cylindrical shape and whose upper portion is hermetically sealed,
And a lower flange portion coupled to a lower portion of the outer cover tube, the lower flange portion including a first lower flange having a first flange hole formed at a center thereof to flow through the floating rod. The method according to claim 1,
Further comprising an inner cover tube which is formed in a hollow cylindrical shape and is formed so as to surround from the upper portion of the floating rod to a position where at least the permanent magnet is coupled. 3. The method of claim 2,
The floating bar further includes a floating guide groove formed at a height corresponding to at least the management range from the upper end to the lower end, and a magnet groove into which the permanent magnet is inserted and coupled,
Wherein the floating portion further includes a ring-shaped upper stopper coupled to an upper end of the floating rod,
Wherein the first lower flange further comprises a floating guide protrusion formed in the shape corresponding to the floating guide groove from the inner surface of the first flange hole and coupled to the floating guide groove. The method according to claim 1,
Wherein the floating bore includes a cylindrical outer bore tube which is opened upward and downward, an inner bore tube which is cylindrical in shape corresponding to the outer bore tube and whose outer surface is spaced apart from the inner surface of the outer bore tube to form a spacing space, And an upper baffle plate and a lower baffle plate which are formed in a plate shape corresponding to the planar shape of the space and seal the upper and lower portions of the spacing space,
The bottom of the floating rod is inserted and coupled to the inside of the inner borehole, and a fixing groove is formed at a position corresponding to the top and bottom positions of the floating bore, ,
Wherein the floating portion further includes a stop ring which is engaged with the upper surface and the lower surface of the floating rib while being coupled to the fixing groove. 3. The method of claim 2,
The sensor unit
A sensor support block formed of a non-magnetic material and formed at least at a height corresponding to the management range and positioned outside the inner cover tube;
And a sensor bracket coupled to the sensor support block in a vertical direction and coupled with the magnetic sensor. The method according to claim 1,
Wherein the outer cover tube is formed to penetrate from the outer side to the inner side and further includes an outer perforation hole having a height and a predetermined width corresponding to the management range. The method of claim 3,
Wherein the first lower flange further comprises a flange protruding ring formed to protrude from the center of the upper surface to a predetermined height and having the first flange through hole and the floating guide protrusion extended from the center,
The lower flange portion
And a second lower flange formed on the upper surface of the first lower flange and coupled to a lower portion of the inner cover tube, the second lower flange being formed with a smaller area than the outer cover tube and having a second flange- Wherein the sensor comprises: 3. The method of claim 2,
Wherein the inner cover tube, the outer cover tube, and the lower flange portion are formed of a non-magnetic material. A tank body formed in a box shape with an open upper portion;
A main cover having a sensor engagement hole penetrating vertically, the main cover being coupled to an upper portion of the tank main body,
A floating sensor according to any one of claims 1 to 8 coupled to the body cover,
The first lower flange is coupled to the upper portion of the body cover such that the first flange hole is in position with the sensor engagement hole,
The floating rod is inserted into the sensor engagement hole to flow upward and downward,
Wherein the floating float is coupled to a lower portion of the floating rod and positioned inside the tank body.

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