KR102452592B1 - Apparatus for treatmening condensate water - Google Patents

Abstract

The present invention relates to a condensate treatment device which can prevent reverse flow due to clogging of a filter and easily and accurately determine the filter replacement time, as the condensate treatment device separating oil and water contained in condensate. The condensate treatment device of the present invention comprises: a main storage tank (100) having condensate (P1) flowing into the inside stored in a state of being separated vertically into oil (P2) and separated water (P3) by specific gravity; an oil collection tank (200) having the oil discharged from the main storage tank stored; a filtering tank (300) filtering and discharging the separated water discharged from the main storage tank to the outside; and a reverse flow detection unit (400) installed between the main storage tank and the filtering tank to block a reverse flow of the separated water flowing into the filtering tank (300) into the main storage tank. Accordingly, a reverse flow accident can be prevented in advance.

Description

Condensate treatment device {Apparatus for treatmening condensate water}

The present invention relates to a condensate treatment apparatus that separates oil and water contained in condensate, which prevents backflow due to clogging of a filter and can easily and accurately determine when to replace the filter.

In general, a large amount of condensed water composed of oil and water in an emulsion state is generated when mechanical equipment is used.

As industrial wastewater, this condensate causes serious pollution in soil, groundwater, rivers, lakes, and the ocean, causing a great problem in environmental conservation. are regulating

Therefore, most workplaces use a small-scale condensate treatment device that separates condensate into water and oil.

Conventional condensed water treatment device is formed so that condensed water is stored therein so that it can be vertically separated into oil and separated water by specific gravity, and an oil discharge port from which oil disposed in the upper layer can be discharged and separated water disposed in the lower layer can be discharged A main storage tank each having a separated water discharge port, an oil collection tank connected through the oil discharge port and an oil discharge hose so that the oil discharged through the oil discharge port of the main storage tank can be stored therein; The separated water discharge port and the separated water discharge hose are connected so that the separated water discharged through the separated water discharge port of the storage tank flows in, and a plurality of filters are mounted therein to sequentially filter the separated water. It consists of a filtering tank in which a filtered water discharge port is formed so as to be discharged in a filtered state.

Accordingly, after the condensed water introduced into the main storage tank is separated into oil and separated water by specific gravity, the separated water moves to the filtering tank through the separated water discharge port, and the oil is discharged to the oil collection tank through the oil discharge port. Then, the separated water becomes filtered water in a clean state while passing through the filtering tank and is discharged to the outside through the filtered water discharge port.

Such a conventional condensate treatment device is configured such that the filtering tank that receives the separated water separated from the oil from the main storage tank and filters it is configured so that only the filtering tank can be independently changed and replaced separately from the main storage tank. The effect is recognized to some extent in that it can be conveniently changed and applied to an appropriate capacity and maintenance work is also made easy.

However, in the conventional condensate treatment apparatus, if the filters installed in the filtering tank are clogged due to long-term use and the replacement is not made in a timely manner, smooth filtering is not performed, and in severe cases, the separated water is stored in the main storage in the filtering tank. Accidents of backflow into the tank often occur, and improvement is required.

Domestic Patent Publication No. 1139933

The present invention has been devised to solve the above problems, and it is an object of the present invention to provide a condensate treatment device that prevents an accident in which separated water flows back from the filtering tank to the main storage tank and can easily and accurately identify the filter replacement time of the filtering tank. .

In order to achieve the above object, the condensed water treatment apparatus of the present invention includes a main storage tank in which the condensed water flowing into the inside is stored in a state in which the oil and the separated water are vertically separated by specific gravity, and the oil discharged from the main storage tank is stored. An oil collection tank, a filtering tank for filtering the separated water discharged from the main storage tank and discharging to the outside, and installed between the main storage tank and the filtering tank to monitor whether the separated water flowing into the filtering tank flows back into the main storage tank It includes a backflow detection unit.

In addition, the backflow sensing unit includes a housing, a separated water inlet pipe connected to the housing to introduce separated water from the main storage tank, a strainer installed inside the housing, and the separated water passing through the strainer to the filtering tank. It may include a separated water discharge pipe connected to the housing, and a first water level sensor for detecting the level of the separated water flowing into the housing.

In addition, a purified water discharge pipe for discharging the filtered purified water to the outside is connected to the filtering tank, and the purified water filter for filtering the discharged purified water and the purified water that has passed through the purified water filter are finally measured. A measurement sensor may be provided.

On the other hand, it is preferable that a second water level sensor for detecting the level of the separated water is provided inside the main storage tank.

In addition, a third water level sensor for detecting the level of the separated water may be provided inside the filtering tank.

In the present invention configured as described above, since the backflow detection unit is installed between the main storage tank and the filtering tank, it is possible to prevent a backflow accident in advance by easily and reliably determining whether the separated water flowing into the filtering tank flows back to the main storage tank. there is an effect

In addition, the present invention has an effect that can easily and reliably determine whether there is a reverse flow of the separated water and the filter replacement time in multiple because the water level sensor capable of grasping the level of the separated water is installed in the main storage tank and the inside of the filtering tank, respectively.

1 is a cross-sectional view of a condensate treatment apparatus according to the present invention.

The features and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments, taken in conjunction with the accompanying drawings.

Prior to this, the terms or words used in the present specification and claims are based on the principle that the inventor can appropriately define the concept of the term in order to describe his invention in the best way to the technical idea of the present invention. It must be interpreted with a corresponding meaning and concept.

In addition, the terms or words used in the specification and claims are used only to describe specific embodiments, and are not intended to limit the present invention.

For example, the singular expression includes the plural expression unless the context clearly dictates otherwise. In addition, terms such as "comprises" or "comprising" or "having" are intended to designate the presence of a feature, number, step, operation, component, part, or combination thereof described in the specification, but one or more It should be understood that this does not preclude the possibility of addition or existence of other features or numbers, steps, operations, components, parts, or combinations thereof.

Also, when a part of a layer, film, region, plate, etc. is said to be "on" another part, this includes not only the case where it is "directly on" another part, but also the case where there is another part in between. Conversely, when a part of a layer, film, region, plate, etc. is said to be "under" another part, this includes not only cases where it is "directly under" another part, but also a case where another part is in between.

In addition, terms including an ordinal number such as "first", "second", etc. used herein may be used to describe various elements, but the elements are not limited by the terms, and the terms are It is used only for the purpose of distinguishing one component from another.

Hereinafter, in describing an embodiment of the present invention in detail with reference to the drawings, the same reference numerals are used for the same components, and for the sake of clarity, only different parts are mainly described so as not to overlap as much as possible.

As shown in FIG. 1 , the condensate treatment apparatus according to the present invention includes a main storage tank 100 , an oil collection tank 200 , a filtering tank 300 , and a backflow detection unit 400 .

The main storage tank 100 is stored in a state in which the condensed water P1 flowing into the inside is vertically separated into oil P2 and separated water P3 by specific gravity.

In this case, the interior of the main storage tank 100 is formed to communicate with the first chamber 110 through the first chamber 110 and the first drain pipe 111 into which the condensed water P1 is introduced ( 120).

The condensed water P1 introduced into the first chamber 110 is stored in a state in which the oil P2 and the separated water P3 are vertically separated by specific gravity.

In addition, an oil discharge pipe 210 for discharging the oil P2 located at the top of the first chamber 110 to the oil collection tank 200 is connected to the upper portion of the first chamber 110 , and the first drain pipe Reference numeral 111 discharges the separated water P3 of the first chamber 110 to the second chamber 120 .

Separation water P3 flowing in through the first drain pipe 111 is stored in the second chamber 120, and separated water P3 stored in the second chamber 120 is discharged to the backflow sensing unit 400 on one side. A second drain pipe 121 is installed.

On the other hand, it is preferable that the pressure relief unit 130 is provided in the first chamber 110 .

The pressure relief unit 130 relieves the inflow pressure of the condensed water P1 flowing into the first chamber 110 to stabilize the condensed water P1 stored in the first chamber 110, so that the oil P2 and the separated water ( It helps to make the upper and lower separation into P3) smooth.

The oil collection tank 200 is installed outside the main storage tank 100 to store the oil P2 discharged from the main storage tank 100 .

The filtering tank 300 filters the separated water P3 discharged from the main storage tank 100 and discharges it to the outside. A carbon filter and a pre-filter may be built in the filtering tank 300 .

The backflow detection unit 400 is installed between the main storage tank 100 and the filtering tank 300 to monitor whether the separated water P3 flowing into the filtering tank 300 flows back into the main storage tank 100 .

In this case, the backflow detection unit 400 may include a housing 410 , a separated water inlet pipe 420 , a strainer 430 , a separated water discharge pipe 440 , and a first water level sensor 450 . .

The housing 410 is a housing in which a strainer 430 is installed therein. A separated water inlet pipe 420 is connected to one side with the strainer 430 interposed therebetween, and a separated water outlet pipe 440 is connected to the other side.

The strainer 430 filters oil residues and foreign substances contained in the separated water P3 introduced into the housing 410 .

The separated water inlet pipe 420 is connected to the second chamber 120 of the main storage tank 100 to introduce the separated water P3 from the second chamber 120 .

The separated water discharge pipe 440 is connected to the filtering tank 300 to discharge the separated water P3 that has passed through the strainer 430 frame to the filtering tank 300 .

The first water level sensor 450 is installed inside the housing 410 to sense the level of the separated water P3 flowing into the housing 410 .

On the other hand, it is preferable that the first water level sensor 450 has a floating body installed therein so as to move up and down according to a change in the water level.

In this case, the operator can easily grasp the water level inside the housing 410 that changes in real time through the position of the first water level sensor 450 that moves up and down according to the change of the water level with the naked eye, and quick action is possible.

In this embodiment, a water level sensor configured to raise and lower the first water level sensor 450 according to a change in water level is illustrated and described as an example, but it is not limited thereto, and various types of water level sensors can be applied.

In addition, a warning light or a speaker is connected to the first water level sensor 450, and when the separated water P3 inside the housing 410 is above a certain level, the warning light or speaker is operated to ventilate the surroundings, or a wired/wireless communication module It may be provided and operated to output a reverse flow signal to the operator's monitor or mobile phone.

Although not shown, a non-return valve for blocking the inflow of the separated water P3 flowing into the housing 410 based on the reverse flow signal output from the first water level sensor 450 is installed in the separated water inlet pipe 420 . can be

On the other hand, it is preferable that a second water level sensor 140 for detecting the level of the separated water P3 flowing into the main storage tank 100 is provided inside the main storage tank 100 .

In addition, it is preferable that a third water level sensor 310 for detecting the level of the separated water P3 flowing into the filtering tank 300 is provided inside the filtering tank 300 .

Since the second water level sensor 140 and the third water level sensor 310 have substantially the same configuration and operation as the above-described first water level sensor 450 , a separate description thereof will be omitted.

In addition, a purified water discharge pipe 320 for discharging filtered purified water to the outside is connected to the filtering tank 300, and a purified water filter 500 for filtering the discharged purified water is connected to the purified water discharge pipe 320, and the purified water filter ( A water quality measurement sensor 600 for finally measuring the water quality of the filtered purified water passing through 500 may be provided.

In this case, the water quality measurement sensor 600 is provided with a wired/wireless communication module and when abnormal water quality out of a preset range is detected, it may be configured to output a water pollution occurrence signal to the operator's monitor or mobile phone through the wired/wireless communication module. have.

In addition, when a water pollution signal is output from the water quality measurement sensor 600 in the purified water discharge pipe 320, an emergency valve 700 is installed to close the purified water discharge pipe 320 to block the purified water from being discharged to the outside. desirable.

The condensate treatment apparatus of the present invention configured as described above operates as follows.

First, the condensed water P1 flows into the first chamber 110 of the main storage tank 100 through the pressure relief unit 130 .

The condensed water P1 flowing into the first chamber 110 is stored in a vertically separated state into oil P2 and separated water P3 due to a difference in specific gravity.

When the water level of the condensed water P1 in the first chamber 110 rises above a certain level, the separated water P3 in the lower part is automatically discharged to the second chamber 120 through the first drain pipe 111, and the oil ( P2) is automatically discharged to the oil collection tank 200 through the oil discharge pipe (210).

Then, the separated water P3 flowing into the second chamber 120 flows into the filtering tank 300 via the backflow detection unit 400 through the second drain pipe 121 .

At this time, the separated water P3 is filtered through a strainer 430 installed inside the housing 410 in the process of passing through the backflow detection unit 400, after which a significant portion of oil residues and foreign substances are filtered, and then the separated water discharge pipe 440 is filtered through the filtering tank. Since it flows into 300, the purification efficiency of the separated water P3 is greatly improved.

Then, the separated water P3 introduced into the filtering tank 300 becomes purified water through a filtering process, and the purified water is discharged to the outside through the purified water discharge pipe 320 .

At this time, since the purified water filter 500 installed in the purified water discharge pipe 320 finally filters the discharged purified water and then discharges it to the outside, the purification reliability is greatly improved.

In addition, since the water quality sensor 600 installed in the purified water discharge pipe 320 detects the contamination concentration of the purified water discharged to the outside in real time, and the operator continuously monitors this, the purified water that has not been completely filtered may be discharged to the outside. In this case, prompt action is guaranteed.

In addition, when the emergency valve 700 is installed in the purified water discharge pipe 320, when the contamination concentration of the purified water is outside the set normal range, a water pollution occurrence signal is output from the water quality measurement sensor 600, and the emergency valve opens the purified water discharge pipe ( 320) is automatically closed, so that the polluted purified water is blocked from being discharged to the outside, and the water quality can be reliably prevented from being polluted.

On the other hand, when the life of the filter installed inside the filtering tank 300 is expired, the filtering function decreases and the inflow of the separated water P3 flowing into the filtering tank 300 increases than the discharge of purified water discharged to the outside through filtering. and the separated water P3 in the filtering tank 300 flows back to the backflow detection unit 400 .

When the separated water P3 flows back to the backflow detection unit 400, the separated water P3 level inside the housing 410 rises, and when the separated water P3 level rises, the first water level sensor 450 rises. will do

Therefore, while checking that the first water level sensor 450 rises, the operator can accurately determine the filter replacement time in the filtering tank 300 and the reverse flow of the separated water P3, and through rapid filter replacement, the separated water P3 ) can be prevented in advance and managed reliably so that the treatment efficiency of the condensate (P1) does not fall.

Even if the operator misses the filter replacement time, if the water level of the separated water P3 in the housing 410 is above a certain level, a backflow signal is output from the first water level sensor 450, so that it is possible to quickly cope with a backflow accident.

In addition, in the present invention, not only the first water level sensor 450, but also the third water level sensor 310 installed inside the filtering tank 300, it is possible to determine the filter replacement time and whether the separated water P3 flows backward. .

Even if the operator did not recognize the operation of the first water level sensor 450 and the third water level sensor 310, or a malfunction occurred in the first water level sensor 450 and the third water level sensor 310, the normal operation was performed. Even if it is not lost, it is possible to determine the filter replacement time and whether the separated water P3 flows backward through the second water level sensor 140 .

Therefore, the user can easily determine whether the separated water P3 is backflowing and the filter replacement time through the first water level sensor 450, the second water level sensor 140, and the third water level sensor 310 in multiple ways. Safety is guaranteed.

As such, although the preferred embodiment of the present invention has been described above with reference to the drawings, the present invention is not limited to the above-described embodiment, and a person of ordinary skill in the art to which the present invention pertains can modify it without departing from the spirit of the present invention. It is possible, and such modifications will fall within the scope of the present invention.

100...Main storage tank 140...Second water level sensor
200...oil collection tank 300...filtering tank
310...3rd water level sensor 320...Purified water discharge pipe
400...Backflow detection unit 410...Housing
420...Separated water inlet pipe 430...Strainer
440...Separated water discharge pipe 450...First water level sensor
500...Purified water filter 600...Water quality sensor
P1...Condensate P2...Oil
P3...Separate water

Claims (5)

a main storage tank in which the condensed water flowing into the inside is stored in a state in which the oil and the separated water are vertically separated by specific gravity;
an oil collection tank in which oil discharged from the main storage tank is stored;
a filtering tank for filtering the separated water discharged from the main storage tank and discharging to the outside; and
and a backflow detection unit installed between the main storage tank and the filtering tank to monitor whether the separated water flowing into the filtering tank flows back to the main storage tank,
The inside of the main storage tank is divided into a first chamber into which condensed water flows, and a second chamber in which separated water flowing in from the first chamber is stored,
The reverse flow detection unit,
housing; a separated water inlet pipe connected to the housing to introduce separated water from the second chamber of the main storage tank; a strainer installed inside the housing; a separated water discharge pipe connected to the housing to discharge the separated water that has passed through the strainer to the filtering tank; and a first water level sensor for detecting the level of the separated water inside the housing,
A second water level sensor for detecting the level of the separated water is provided inside the second chamber,
A condensate water treatment device provided with a third water level sensor for detecting the level of the separated water inside the filtering tank. delete The method of claim 1,
A purified water discharge pipe for discharging the filtered purified water to the outside is connected to the filtering tank;
A condensed water treatment device provided with a purified water filter for filtering the purified water discharged from the purified water discharge pipe, and a water quality measurement sensor for finally measuring the water quality of the filtered purified water passing through the purified water filter. delete delete

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