JP2003144895A - Water treating agent dissolution equipment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a water treating agent dissolution equipment which reliably dissolves a powdery polymer coagulant at an appropriate concentration. SOLUTION: A feeder 12 is arranged on the bottom part of a hopper 10 and the polymer coagulant of a predetermined quantity is dropped therefrom. A belt conveyor 14 is arranged on the under part of the feeder 12 and a scraper 16 is arranged above the end part of the belt conveyor 14. Further, a first mixing tank 22 is arranged on the down side of the end part of the belt conveyor 14. The belt conveyor 14 is operated at a constant speed, a feed quantity of the feeder 12 and a height of the scraper 16 are controlled by a computing element 40 in accordance with feed water quantity to the first mixing tank 22 and, thereby, the dissolution of the polymer coagulant at an exact concentration is attained.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a continuous water treatment chemical dissolving device for continuously dissolving water treatment chemicals, and more particularly to a type in which water treatment chemicals are transported by a belt conveyor.

[0002]

2. Description of the Related Art Conventionally, organic polymer flocculants have been used for coarsening flocs in water purification treatment, industrial water treatment, wastewater treatment and the like.

Here, the organic polymer coagulant is usually supplied in the form of powder, dissolved in water and then added to the water to be treated. There are various equipments for dissolving this organic polymer flocculant, but there are roughly classified into a batch type and an organic polymer flocculant which mix the organic polymer flocculant with water and discharge the solution after dissolution. There is a continuous system in which water is continuously supplied and a dissolved solution is continuously discharged.

The advantage of the continuous method compared with the batch method is that the capacity of the polymer solution storage tank is small, and the disadvantage is that the accuracy of the dissolved concentration is low. Therefore, in order to make the dissolution concentration more accurate, many efforts have been made to accurately control the feeder of the powdery polymer flocculant and the flow rate of the dissolution water. For example, there are a method of making the supply amount from the feeder proportional to the flow rate of the dissolved water, and a method of making the powder finer to reduce the unevenness of the powder to be supplied from the feeder.

[0005]

When an organic polymer coagulant is used in water purification treatment, the organic polymer coagulant should be more accurately adjusted so that the concentration of the organic polymer coagulant does not exceed a set value. Dissolution of the flocculant must take place. Therefore, it is conceivable to strengthen monitoring by humans, but it is desired to improve the accuracy of automatic supply of the polymer flocculant.
In addition, even in water treatment agents other than organic polymer flocculants,
There are similar challenges.

The present invention has been made in view of the above problems, and an object of the present invention is to provide a water treatment chemical dissolving device capable of dissolving powdery water treatment chemicals with high accuracy.

[0007]

According to the present invention, in a continuous water treatment chemical dissolving device for continuously dissolving a powder water treatment chemical, the powder water treatment chemical supplied from a feeder is received and conveyed. A belt conveyor, a water treatment agent that receives the water treatment chemicals transported on the belt conveyor, mixes and dissolves in the supplied dissolution water, and a water treatment chemical that is installed above the belt conveyor and is mounted on the belt conveyor. It is characterized in that a scraper that regulates the height of the tray and a tray that receives the water treatment chemical scraped off the belt conveyor by the scraper are installed.

Therefore, when the powdered water treatment chemical is excessively supplied, the scraper serves to scrape off the excess powder, and the excessive supply of the water treatment chemical can be reliably prevented. Further, since the powdered water treatment chemicals scraped off fall on the tray installed below the belt conveyor, it can be easily recovered.

Further, the number of revolutions of the belt conveyer is constant, the amount of powder supplied from the feeder is proportional to the amount of dissolved water supplied, and the height of the scraper on the belt conveyer depends on the amount of dissolved water supplied. It is preferable to raise and lower it. In this way, since the rotation speed of the belt conveyor is constant, stable transportation of the polymer flocculant can be achieved. Then, the amount of powder supplied from the feeder was made proportional to the flow rate of the dissolved water, and the installation height of the scraper was raised or lowered according to the supplied flow rate of the dissolved water. As a result, when the flow rate of dissolved water is small, the scraper position has a large scraping amount at the lower side, and when the flow rate of dissolved water is large, the scraper position has a small scraping amount at the upper side, ensuring reliable dissolution of water treatment chemicals. The concentration can be controlled.

The water treatment agent is preferably an organic polymer flocculant.

[0011]

BEST MODE FOR CARRYING OUT THE INVENTION Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 shows the overall configuration of the apparatus of the embodiment, and FIG. 2 is a diagram showing the installation position of the scraper and the like.

The powdery organic polymer flocculant is contained in the hopper 10. The accommodation in the hopper 10 may be performed automatically or manually. The bottom of the hopper 10 is narrowed and a rotary paddle type feeder 12 is provided therein. Therefore, the polymer coagulant reaching the bottom of the hopper 10 by its own weight is
By the rotation of, it drops downward by a predetermined amount.

Below the feeder 12, a belt conveyor 14 is arranged. Therefore, the polymer coagulant dropped from the feeder 12 is carried on the belt conveyor 14 and is transported as the belt of the belt conveyor 14 moves.
In this example, the polymeric flocculant is carried to the right side of the figure.

A scraper 16 for controlling the height of the polymer coagulant on the belt conveyor 14 is arranged above the right side of the belt conveyor 14. The scraper 16 can be set to an arbitrary height by an elevator 18. The height of the polymer coagulant on the belt conveyor 14 is regulated to be constant by the scraper 16,
Anything more than that is scraped off around the belt conveyor 14.

Below the belt conveyor 14, a tray 20 is arranged so as to accommodate the periphery of the belt conveyor 14 and accommodate the same. Therefore, the polymer coagulant scraped off around the belt conveyor 14 is received by the tray 20.

On the other hand, the polymer coagulant that has passed under the scraper 16 drops downward from the end portion of the belt conveyor 14, and a first mixing tank 22 is arranged therein. Dissolved water (usually city water) is supplied to the first mixing tank 22, and the supplied polymer coagulant and dissolved water are mixed in the first mixing tank 22 to form a polymer coagulant. Is dissolved. The first mixing tank 22 is divided by a baffle 24 into an inlet chamber 22a communicating at the bottom and a mixing chamber 22b, and the polymer flocculant and the dissolved water are separated from each other by the baffle 24.
It is supplied to the upper part of 2a, passes through this inlet chamber 22a in a descending flow, and reaches the mixing chamber 22b from the bottom. A stirrer 26 is disposed in the mixing chamber 22b, and the stirrer 26 mixes and dissolves the polymer coagulant in the dissolved water.

The upper part of the mixing chamber 22b of the first mixing tank 22 is connected to the second mixing tank 28. The second mixing tank 28 is provided with a baffle 30 which is divided into an inlet chamber 28a communicating at the bottom and a mixing chamber 28b.
The stirrer 32 is arrange | positioned at 8b. Therefore, the solution in which the polymer flocculant is stirred and mixed in the first mixing tank 22 reaches the mixing chamber 28b from the inlet chamber 28a, and is agitated by the stirrer 32, where the dissolution of the polymer flocculant is further promoted. .

Further, another baffle 34 is provided in the second mixing tank to form a discharge chamber 28c whose upper portion communicates with the mixing chamber 28b. And this discharge chamber 28
A pump 50 is provided to discharge the solution in c, and the solution of the polymer flocculant is supplied to the injection point by the pump 50.

A flow meter 36 and a regulating valve 38 are provided on the supply line of the dissolved water to the first mixing tank 22, and the detection result is supplied to the computing unit 40. Further, a level switch 42 is installed in the second mixing tank 28, and the detection result is also supplied to the calculator 40.

Based on the detection result of the flow meter 36, the calculator 40 controls the discharge amount of the polymer coagulant by the feeder 12 and the height of the scraper 16 by the elevator 18, and according to the output of the level switch 42, The regulating valve 38 is controlled.

That is, in this embodiment, the speed of the belt conveyor 14 is basically controlled to be constant. And
The feeder 12 is controlled according to the output of the flow meter 36 so that the supply amount of the polymer coagulant with respect to the flow rate of the dissolved water becomes constant. Furthermore, the amount of the polymer coagulant passing below the scraper 16 is constant with respect to the amount of the dissolved water supplied,
The height of the scraper 16 is controlled.

As a result, control is performed so that the flow rate of the dissolved water is small, the scraper 16 position is downward, the scraping amount by the scraper 16 is large, and the flow rate of the dissolved water is large, the scraper 16 position is upward, and the scraping amount is small. . When the second mixing tank 28 reaches the upper limit water level by the level switch 42, the adjustment valve 38 reduces the amount of dissolved water, and when the level switch 42 reaches the lower limit water level, the adjustment valve 38 increases the amount of dissolved water. By this, the second mixing tank 2
The water level of the polymer coagulant solution in 8 can be maintained within a predetermined range. The supply and dissolution of the dissolved water and the polymer coagulant may be stopped when the upper limit water level is detected by the level switch 42, and may be restarted when the lower limit water level is reached.

As described above, according to the apparatus of this embodiment,
The high-molecular coagulant (powder) supplied from the feeder 12 is temporarily received by the belt conveyor 14 and is supplied to the first mixing tank 22 which mixes and dissolves with water.
The scraper 16 was installed above. Therefore, when the powdery polymer coagulant is excessively supplied, the scraper 16 serves to scrape off the excess powder, and the excessive supply of the polymer coagulant can be reliably prevented. Further, since the powdered polymer coagulant scraped off falls on the tray 20 installed below the belt conveyor 14, it can be easily collected. Further, since the rotation speed of the belt conveyor 14 is constant, stable transportation of the polymer flocculant can be achieved. The amount of powder supplied from the feeder 12 was made proportional to the flow rate of the dissolved water, and the installation height of the scraper 16 was raised or lowered according to the supplied flow rate of the dissolved water. As a result, when the flow rate of the dissolved water is small, the scraper 16 position has a large scraping amount at the lower position, and when the flow rate of the dissolved water is large, the scraper 16 position has a small scraping amount at the upper position. It is possible to control the dissolution concentration of the coagulant, and it is possible to reliably prevent the supply amount of the polymer coagulant from increasing by a mechanical means called a scraper.

[0025]

EXAMPLES Specific examples will be described below.

Dam water was used as raw water in the water purification treatment.・ Raw water flow rate 1,000m ³ / h = 24,000m ³ / d
And・ The raw water turbidity is at least 3.0 degrees, maximum 150 degrees, and average 7.
It was 0 degrees. The coagulant in the coagulation precipitation was polyaluminum chloride (PAC), and the average injection rate was 30 mg / L. -An organic polymer flocculant was used as a flocculation aid in this flocculation and precipitation. This coagulant aid includes a weak anionic organic polymer coagulant (acrylamide monomer content of 0.00
Less than 5%) was used. The average injection rate was 0.2 mg / L = 0.2 g / m ³ . The polymeric flocculant dissolving tank shown in FIG. 1 was used, the dissolving capacity was 1 kg / h, and the dissolving concentration of the polymeric flocculant was 0.1%. Here, 0.2 kg / h on average
Operation (0.2 g / m ³ × 1,000 m ³ /h=0.2
kg / h). Then, the dissolving device was turned on and off depending on the liquid level in the second mixing tank 28. The dissolution concentration was made constant by making the flow rate of the dissolution water proportional to the supply amount of the polymer coagulant in the feeder 12. -Scraper 1 installed above the belt conveyor 14
6 has a function to evenly disperse the powder of the polymer coagulant, and to scrape the powder from the belt conveyor 14 when more than the set amount of powder is supplied due to some error. The powder scraped off on the tray 20 may be automatically or manually returned to the hopper 10 for reuse. The position of the scraper 16 is determined by the dissolved concentration and the amount of dissolved water, but in this example, the dissolved concentration is constant at 0.1%, so the scraper 16 is moved up and down according to the flow rate of the dissolved water. The rotation speed (moving speed) of the belt conveyor 14 is always constant.

By such an operation, the polymer flocculant can be dissolved with higher accuracy. Further, even if a problem occurs in the control device, the concentration does not exceed the set concentration, and the safety is improved. Also, since it is a continuous type, it was confirmed that the equipment as a whole may be smaller than in the case of a batch type.

[0028]

As described above, according to the present invention,
When the powdered water treatment chemical is excessively supplied, the scraper serves to scrape off the excess powder, and the excessive supply of the water treatment chemical can be reliably prevented. Further, since the powdered water treatment chemicals scraped off fall on the tray installed below the belt conveyor, it can be easily recovered.

Further, by keeping the number of rotations of the belt conveyor constant, stable transportation of the polymer flocculant can be achieved.
When the amount of powder supplied from the feeder is proportional to the flow rate of dissolved water and the installation height of the scraper is raised or lowered according to the supplied flow rate of dissolved water, the scraper position can be adjusted when the flow rate of dissolved water is small. The scraping amount of the scraper becomes large in the lower part, and the scraping amount becomes small in the upper part of the scraper position when the flow rate of the dissolved water is large, so that the dissolved concentration of the water treatment chemical can be reliably controlled.

[Brief description of drawings]

FIG. 1 is a diagram showing a configuration of a polymer flocculant dissolving device according to an embodiment.

FIG. 2 is a diagram showing a scraper installation position and the like.

[Explanation of symbols]

10 hoppers, 12 feeders, 14 belt conveyors, 16 scrapers, 18 elevators, 20 trays,
22 first mixing tank, 28 second mixing tank, 36 flow meter,
40 arithmetic unit, 42 level switch.

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) B01F 15/04 B01F 15/04 E B01J 4/02 B01J 4/02 E C02F 1/00 C02F 1/00 K 1/56 1/56 ZF Term (Reference) 4D015 BA04 BA06 BA11 BA16 BA19 BA23 BA28 BB06 BB08 BB12 CA14 DA04 DB02 DC04 DC08 EA03 EA22 FA01 FA11 4G035 AA23 AB46 AE01 AE13 4G037 AA02 AA06 BA05 BC03 BD10 A29A0 4680EA02 4G016A02 AF36

Claims (3)

[Claims] 1. A continuous type water treatment chemical dissolving device for continuously dissolving powdery water treatment chemicals, a belt conveyor for receiving and conveying powdery water treatment chemicals supplied from a feeder, and the belt conveyor A dissolution tank that receives the transported water treatment chemicals and mixes and dissolves it with the supplied dissolution water; and a scraper that is installed above the belt conveyor and that regulates the height of the water treatment chemicals mounted on the belt conveyor. A water treatment chemical dissolving device comprising: a tray for receiving the water treatment chemicals scraped from the belt conveyor by the scraper; 2. The apparatus according to claim 1, wherein the number of revolutions of the belt conveyor is constant, the amount of powder supplied from the feeder is proportional to the amount of dissolved water supplied, and the height of the scraper on the belt conveyor is , A water treatment chemical dissolving device, which is moved up and down according to the flow rate of the dissolved water. 3. The apparatus according to claim 1, wherein the water treatment agent is an organic polymer flocculant.