KR20100064757A - Apparatus for preventing error of a level sensor - Google Patents

Abstract

PURPOSE: An error preventing device of a level sensor is provided to minimize inflow of bubbles or sludge in a water level detecting chamber in which the level sensor is located, and to minimize influence of vibration of the water surface in a separation tank. CONSTITUTION: An error preventing device of a level sensor comprises the following: a sludge inlet(120) sucking the floated sludge on the water surface of a serration tank; the separation tank(100) in which coagulated sludge is floated; a water level detection chamber(200) equipped on one side of the separation tank; a water channel(220) located on a direction lower than the location of the sludge inlet; and the level sensor(210) detecting a water level of the water level detection chamber, and is located on the bottom of the water level detection chamber.

Description

Apparatus for Preventing Error of a Level Sensor}

The present invention relates to a level sensor error prevention device, and more particularly, to a level sensor error prevention device for measuring the water level of the circulating water in the coating booth used in the manufacture of automobiles and the like.

As shown in FIG. 1, a painting factory in which a coating process is applied to an exterior of an automobile, etc., is typically provided with an air supply air conditioner 10, a paint booth 20, a sludge separator 30, and a separation tank ( 40). The air conditioner (10) is introduced to the outside air to remove the dust, temperature and humidity, and then supplied to the paint booth 20, the paint booth 20, the coating equipment in a constant atmosphere (temperature, humidity, wind speed, wind direction) 22 ) Is applied to the vehicle body 24. At the lower end of the coating booth 20, the cleaning part 26 is positioned to mix uncoated paint (spray paint) with the circulating water and then flow into the separation tank 40 to be described later, and includes a large amount of volatile organic compounds. Separated air is discharged to the outside through the exhaust duct (50). Here, the circulation water refers to water circulating between the bottom of the paint booth 20 and the separation tank 40, and is circulated by the circulation pump 80.

The washing water mixed with the paint and the circulating water is separated into the sludge and water which are aggregated by the chemicals (coagulant flotation agent) reacting with the paint after flowing into the separation tank 40. Is precipitated. The sludge agglomerated on the water surface is sucked while forming a vortex with the water of the water in the tornado-type suction port 42 having the snail-shaped eccentric suction port. The sucked water and sludge are transferred to the sludge separator 30 and then separated into water and sludge, and the sludge is discharged, and water is introduced into the separation tank 40 again.

The tornado inlet 42 has a horizontal plate 42a extending radially outward at its inlet side, as shown in FIGS. 2A and 2B, and one side of the horizontal plate 42a extends upward from the horizontal plate. The vertical plate 42b is provided, and when the water level is at an appropriate level on the horizontal plate (see FIG. 2A), a vortex occurs in the tornado-type suction port 42 to smoothly suck the sludge 90 from the water surface. However, if the water level is lower than the horizontal plate 42a, suction of the sludge 90 is impossible (see FIG. 2B). If the water level is higher than the vertical plate 42b, only the water is sucked in, the amount of sludge suction on the water surface is significantly reduced.

Therefore, in order to allow the sludge 90 to be continuously sucked smoothly through the tornado inlet 42, the water level in the separation tank 40 is maintained within a predetermined range with respect to the tornado-type intake port (horizontal and vertical plates). There is a need. To this end, a level sensor 44 for detecting the water level in the separation tank 40 is typically provided above the tornado-type suction port 42. The level sensor 44 is generally an ultrasonic sensor, and is operated to detect the distance between the sensor and the surface, that is, the water level, by calculating the time when the ultrasonic wave is reflected back to the surface after firing the ultrasonic wave toward the surface. That is, when the level sensor 44 detects that the water level of the separation tank 40 is low level, the water level is increased by supplying water to the separation tank 40 by the water supply pump 60, and when the level is detected, the drain pump. By operating 70 to lower the level, the separation tank 40 level can be maintained at the reference level.

However, such a conventional level sensor has a high risk of error. That is, when the dosage of the chemicals that aggregate the paint components is not properly managed, excessive foaming occurs on the water surface, so that the ultrasonic reception is diffused and the ultrasonic reception rate may decrease. In addition, if the paint is temporarily concentrated on the surface of the water, the reflectance of the ultrasonic waves may be reduced and the reception rate may be lowered.In addition, waves may be rippled on the surface, causing the surface to bend, resulting in diffuse reflection of the ultrasonic waves or reflection in the wrong direction. do. If the level sensor judges that the water level is insufficient due to a level detection error, the sludge can not be sucked through the tornado inlet as described above, and the water level is not replenished due to the inability of the water supply pump to adjust the water level properly. In the worst case, the pipes or the inside of the pump may be clogged with hardened sludge. On the other hand, if the water level is incorrectly judged as an appropriate level, only the water is sucked into the tornado inlet and the sludge intake amount is remarkably reduced, and the water is not discharged due to the inability of the drain pump to control the water level to an appropriate level.

The present invention is to solve the above problems, an object of the present invention is to generate an excessive bubble in the surface of the separation tank, the ultrasonic wave is diffusely reflected, or the paint is concentrated temporarily on the surface to reduce the reflectance of the ultrasonic wave, or the wave on the surface It is to provide a device that prevents an error in the operation of the level sensor for detecting the water level of the separation tank because the reception rate of the ultrasonic wave is lowered due to the curved surface of the surface is not reflected by the surface.

In order to achieve the above object, in one embodiment of the present invention, a paint that is not attached to a vehicle body is mixed with water and flows from a coating booth for applying the paint to a vehicle body or the like, and the introduced paint is agglomerated by a chemical that reacts with the paint. A part of the sludge which floats to the surface and part of which is settled; A sludge inlet for sucking sludge floating on the surface of the separation tank; A water level sensing chamber provided at one side of the separation tank; A water flow passage connecting the water level detection chamber and the separation tank so that the water level detection chamber and the separation tank communicate with each other and installed at a position higher than the sludge settled below the separation tank and lower than the sludge intake port; And a level sensor installed at an upper side of the level sensing chamber, the level sensor configured to sense the level of the level sensing chamber.

The level sensor error prevention device may further include a buoyancy bucket floating on the water surface of the water level detection chamber and filled with clear water therein.

The level sensor error prevention device may further include a guide means for allowing the buoyancy bucket to move freely up and down according to the change in the water level of the water level sensing chamber, but suppressing the front, rear, left and right movement of the buoyancy bucket.

The guide means includes a guide rail; And a guide roller engaged with the guide rail.

The guide rail may be provided outside the buoyancy bucket, and the guide roller may be provided inside the water level sensing chamber.

The level sensor error prevention device may further include an upper limit stopper for regulating the maximum rising position of the buoyancy bucket, and may further include a lower limit stopper for regulating the maximum descending position of the buoyancy bucket.

The level sensor error prevention device may further include a ventilation hole is provided on the water level sensing chamber to communicate with the water level sensing chamber and the outside.

According to the level sensor error prevention device according to the present invention, by having a water level detection chamber that is distinct from the separation tank, it is possible to minimize the inflow of sludge or foam into the water level detection chamber in which the level sensor is located, and occurred on the surface of the separation tank Since the impact of the fluctuations can be minimized on the surface of the level sensor chamber, the obstacles of ultrasonic sensing can be significantly reduced, thereby preventing the error of the level sensor and always detecting the correct level.

In addition, according to the level sensor error prevention device according to the present invention, by providing a buoyancy bucket in the water level detection chamber and filling the fresh water inside the buoyancy bucket, sludge, foam, etc. causing the error of the level sensor into the buoyancy bucket. By not penetrating, it is possible to fundamentally block the factor causing the error of the level sensor. Furthermore, by installing a guide rail and a guide roller to allow the buoyancy bucket to move freely up and down, it is possible to more completely block the fluctuation of the surface of the water level sensing chamber according to the fluctuation of the surface of the separation tank, so that more accurate level detection is possible. It is effective.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to an embodiment of the level sensor error prevention device of the present invention.

Figure 3 is a schematic diagram of a level sensor error prevention device according to the present invention, showing a separation tank and a water level sensing chamber provided at one side thereof.

Separation tank 100, like the separation tank according to the prior art, is a place where the circulating water mixed with the splash paint at the bottom of the coating booth (not shown). When chemicals (flocculation flotations) are added to the circulating water, the paint mixed with the circulating water aggregates in the form of sludge and floats to the surface of the separation tank, and part of the sludge is settled at the bottom of the separation tank. One side of the separation tank 100 is provided with a tornado-type sludge inlet 120 for sucking and transporting the sludge floated into the water to a sludge separator (not shown), which is similar to a conventional sludge inlet. A horizontal plate 122 and a vertical plate 124 are provided. The separation tank 100 is connected to the water supply pump 140, the drain pump 150, and the circulation pump 160, the water supply pump 140 is water from the outside when the separation tank 100 level is lower than the reference water level It is used to increase the level of the separation tank 100 by supplying the water, the drain pump 150 is used to discharge the circulating water in the separation tank 100 to the outside when the level of the separation tank 100 is higher than the reference level, the circulation pump 160 is used to circulate the circulation water in the separation tank 100 with the paint booth.

According to an embodiment of the level sensor error prevention device of the present invention, one side of the separation tank 100 is provided with a water level detection chamber 200, the level sensor 210 for detecting the water level in the water level detection chamber 200 Is installed. The level sensor 210 may be a conventional ultrasonic sensor or another suitable sensor, and the position of the level sensor 210 may be at a sufficient distance from the reference level so that there is no problem in accurately detecting the water level. It would have to be installed higher than that. The water level detection chamber 200 may be installed to occupy a portion of the separation tank 100, or may be manufactured separately from the separation tank 100 and connected to the separation tank 100. The water level detection chamber 200 and the separation tank 100 are connected between the water level detection chamber 200 and the separation tank 100 so that water can freely pass between the water level detection chamber 200 and the separation tank 100. The water movement passage 220 is provided. The water passage 220 should be provided at a higher position so that sludge deposited on the bottom of the separation tank 100 does not penetrate into the water level detection chamber 200. In addition, the water movement path 220 should be provided at a lower position so that sludge floating on the surface of the separation tank does not penetrate into the water level detection chamber 200. By connecting the water level detection chamber 200 and the separation tank 100 through the water movement passage 220 provided as described above, sludge, bubbles, etc., which float on the surface of the separation tank 100, are transferred to the water level detection chamber 200. It may be prevented from penetrating and contaminating the water surface in the water level detection chamber 200. In addition, thanks to the installation position of the water passage (220), even if the surface of the separation tank 100, the occurrence of oscillation on the surface of the water level sensing chamber 200 can be minimized accordingly. Therefore, by installing the water level detection chamber 200 is connected to the separation tank 100 by the water movement passage 220 as described above, and just to install the level sensor 210 inside the water level detection chamber 200. Therefore, the problem of the level sensor malfunction according to the prior art can be largely solved.

Furthermore, the buoyancy bucket 230 is provided on the surface of the water reaching the ultrasonic wave emitted from the level sensor 210 to float on the surface of the water level sensing chamber 200, and foreign substances such as sludge and foam inside the buoyancy bucket 230. By filling the clear water 235 without water, it is possible to ensure that the ultrasonic wave emitted from the level sensor 210 is always reflected in the clear water 235 in the buoyancy bucket 230, thereby eliminating ultrasonic reception errors due to sludge, bubbles, etc. It can be prevented more thoroughly.

On the other hand, rather than allowing the buoyancy bucket 230 to float freely in the water level detection chamber 200 by the appropriate guide means to move freely in the vertical direction, but also to restrain the movement in the front, rear, left and right directions, buoyancy bucket 230 It is preferable to prevent the wave from flowing on the surface of the clear water 235 in the buoyancy bucket due to unnecessary movement, inclination, or shaking. In the illustrated embodiment, guide rails 243 and guide rollers 245 are used as such guide means. In this embodiment, the guide rail 243 is attached to the outer side wall of the buoyancy bucket 230, the guide roller 245 is attached to the inner side wall of the water level sensing chamber 200, the guide attached to the buoyancy bucket 230 Meshes with rail 243. By this guide means, the rocking of the water surface in the separation tank 100 causes only the vertical movement of the buoyancy bucket 230, and thus it is possible to extremely suppress the rocking of the clear water 235 in the buoyancy bucket.

An upper limit stopper 251 and a lower limit stopper 253 may be provided on the upper side and the lower side of the buoyancy bucket 230, respectively, to regulate the maximum ascending and maximum descending positions of the buoyancy bucket 230. In this case, it is preferable that the maximum rising position of the buoyancy bucket 230 is set higher than the high water level alarm command position of the level sensor so that the high water level alarm is issued before the buoyancy bucket 230 reaches the upper limit stopper 251. Similarly, it is preferable to set the maximum descending position of the buoyancy bucket 230 to be lower than the low water level alarm command position of the level sensor so that the low water level alarm is issued before the buoyancy bucket 230 reaches the lower limit stopper 253. The upper limit stopper 251 and the lower limit stopper 253 may be directly fixed to the side wall of the water level sensing chamber 200 as in the illustrated embodiment, or may be fixed in another suitable method.

Meanwhile, in order to prevent foreign matter from penetrating into the water level sensing chamber 200 and accumulated foreign matter on the surface of the circulating water in the water level sensing chamber or the clear water 235 in the buoyancy bucket, an upper cover 260 is provided. Can be covered with However, in this case, the vent cover 265 is provided in the upper cover to allow the air in the water level detection chamber 200 to freely enter and exit the water level detection chamber 200 according to the change in the water level. It is preferable that the air in the air does not affect the water level in the water level detection chamber 200.

4 to 6, looks at the operation of one embodiment of the level sensor error prevention device of the present invention according to the level change of the separation tank. 4 to 6 show the operation of one embodiment of the level sensor error prevention device of the present invention according to the change of the water level of the separation tank, each showing when the separation tank level is the reference level, low water level, high water level.

Figure 4 shows when the water level in the separation tank is a reference level, the water level of the water level detection chamber 200 also represents the reference level, the level sensor 210 detects that the reference level and the reference level signal controller (shown Not displayed). Accordingly, the water supply pump 140 and the drain pump 150 all maintain the operation stop state, and only the circulation pump 160 continues to operate.

5 shows when the water level in the separation tank is lower than the reference level, the water level of the water level detection chamber 200 also becomes a low level, the level sensor 210 detects that the low level and outputs it to the controller. Accordingly, the water supply pump 140 is operated (the drainage pump 150 stops) to supply water to the separation tank 100, and the water supply pump 140 until the water level in the water level detection chamber 200 reaches the reference level. ) Operation continues. The circulation pump 160 continues to operate at this time.

6 shows when the water level in the separation tank is higher than the reference level, the water level of the water level detection chamber 200 also becomes a high level, the level sensor 210 detects that the high level and outputs it to the controller. Accordingly, the drain pump 150 is operated (the water supply pump 140 stops) to discharge the water in the separation tank 100 to the outside, and when the water level in the water level detection chamber 200 goes down to the reference level, the drain pump ( 150) Operation stops. The circulation pump 160 continues to operate even in this case.

While the level sensor error preventing device of the present invention has been described with reference to the accompanying drawings, those skilled in the art of the present invention without departing from the scope of the technical spirit of the present invention It will be appreciated that various modifications, changes, and variations may be made to the embodiments. Therefore, it should be noted that the scope of the present invention is defined only by the following claims.

1 shows a coating process for applying a paint to the exterior of an automobile or the like.

2A and 2B show a tornado-type suction port provided in a separation tank, and FIG. 2A shows a case of normal water level and FIG. 2B shows a case of low water level.

Figure 3 is a schematic diagram of a level sensor error prevention device according to the present invention, showing a separation tank and a water level sensing chamber provided at one side thereof.

4 to 6 show the operation of one embodiment of the level sensor error prevention device of the present invention according to the change of the water level of the separation tank, each showing when the separation tank level is the reference level, low water level, high water level.

Claims (8)

From the coating booth to apply paint to the car body, the paint which is not attached to the car body is mixed with water and flows in, and some of the sludge agglomerated by the chemicals reacted with the paint floats to the surface and part is settled. article; A sludge inlet for sucking sludge floating on the surface of the separation tank; A water level sensing chamber provided at one side of the separation tank; A water flow passage connecting the water level detection chamber and the separation tank so that the water level detection chamber and the separation tank communicate with each other and installed at a position higher than the sludge settled below the separation tank and lower than the sludge intake port; And Level sensor error prevention device is installed above the water level detection chamber and comprises a level sensor for detecting the level of the water level detection chamber. The method of claim 1, The level sensor error prevention device further comprises a buoyancy bucket floating on the water surface of the water level detection chamber and filled with clear water therein. The method of claim 2, The level sensor error prevention device further comprises a guide means for allowing the buoyancy bucket to move freely up and down in accordance with the change in the water level of the water level sensing chamber, but suppressing the front, rear, left and right movement of the buoyancy bucket. The method of claim 3, The guide means Guide rails; And Level sensor error prevention device, characterized in that consisting of a guide roller in engagement with the guide rail. The method of claim 4, wherein The guide rail is provided on the outside of the buoyancy bucket, the guide roller is a level sensor error prevention device, characterized in that provided inside the water level sensing chamber. The method according to claim 1 or 4, And an upper limit stopper for regulating a maximum rising position of the buoyancy bucket. The method according to claim 1 or 4, And a lower limit stopper for regulating the maximum descending position of the buoyancy bucket. The method of claim 1, Level sensor error prevention device is provided on the water level detection chamber further comprises a vent for communicating with the water level detection chamber and the outside.

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