KR101727858B1 - Capillary suction time evaluating apparatus for sludge and method thereof - Google Patents

Abstract

The present invention relates to a device and a method of evaluating a capillary suction time (CST) of sludge. The device to evaluate a capillary suction time of sludge comprises: a first container collecting and mixing waste water requiring feature analysis; a second container receiving a fixated amount of waste water designated for a CST test from the first container; a chemical injection unit injecting chemicals required for aggregation of the sludge subsiding in the waste water contained in the second container; a third container receiving the sludge subsiding on a lower part of the second container; a CST test unit performing the CST test by receiving the sludge by opening the lower part of the third container unit; and a control unit mixing the waste water in the second container and the chemicals by rotating a paddle of the inside after injecting the chemical required to aggregate the sludge into waste water contained in the second container by the chemical injection unit, settling the sludge on a lower end by finishing a motion of the inner panel of the second container when an aggregate reaction is finished, and performing the CST test by opening the lower part of the third container and injecting sludge into the CST test unit after transferring the settled sludge to the third container by opening the lower part of the second container.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method for evaluating sludge in a sludge,

The present invention relates to an apparatus and a method for evaluating the sludge sludge, and more particularly, to an apparatus and method for evaluating the sludge sludge by collecting only the sedimented sludge after the agitation by automatically reducing the experimental error of the stirring strength and stirring time for collecting the sludge in the coagulating sedimentation process And more particularly to a device and method for evaluating sludge in a sludge that can perform a CST (CAPILLARY SUCTION TIME) evaluation.

Generally, many wastewater is discharged from steel mills. Unlike ordinary wastes, such sludge wastes are difficult to be buried and incinerated. This is mainly due to the water contained in the sludge. As the water content of the sludge increases, the amount of leachate is increased. This is because additional costs are required.

Therefore, a dehydration treatment which recovers moisture from the sludge with high efficiency is essential.

The flocculation process is the operation of the coupling eongkigo to form a flux (floc) which is precipitated in a well that is not precipitated by the addition of chemicals, the colloidal solids and deposition speed is slow suspended solids in the water or waste water.

The efficiency of the coagulation sedimentation varies depending on various conditions such as pH, injection amount of drug, stirring strength, stirring time, etc. However, since the stirring strength and agitation time are hardly changed by the initial design, .

The method used to derive the optimal values of the pH and the drug injection amount is a Jar test, and the optimum pH and injection amount obtained through the self test are applied to the field.

The background art of the present invention is disclosed in Korean Patent Laid-Open No. 10-2011-0075378 (published on Jul. 6, 2011, a method for treating wastewater containing organic matter using steel dust).

According to one aspect of the present invention, an accurate CST evaluation is performed by automatically capturing only sludge precipitated after the stirring, while reducing experimental errors in stirring intensity and stirring time for collecting sludge in the coagulation sedimentation process And to provide a device and a method for evaluating the sludge of the sludge.

According to an aspect of the present invention, there is provided an apparatus for evaluating the sludge of a sludge, comprising: a first vessel for collecting and stirring wastewater that requires characterization; A second vessel for receiving a predetermined amount of waste water required for a CST (Capillary Suction Time) test in the first vessel; A chemical injector for injecting chemicals necessary for agglomeration of sludge into wastewater contained in the second vessel; A third container receiving the sludge settled at the lower end of the second container; A CST test unit for injecting the sludge into the lower end of the third vessel and performing a CST test; And chemical agents necessary for agglomeration of sludge are injected into the wastewater contained in the second vessel through the medicament injecting unit, and the inner paddles are rotated and agitated. When the agglomeration reaction is completed, The sedimented sludge is discharged to the third vessel by opening the lower end of the second vessel and then the lower end of the third vessel is opened to inject the sludge into the CST test unit And a controller for performing a CST test.

In the present invention, the second container has a quadrangular prismatic surface, and a supernatant outlet pipe for discharging the supernatant water is formed on one surface of the second container. The lower end of the second container is in an equilibrium state at the time of coagulation, And the sludge is drained in a downward direction by opening the sludge discharge pipe when the sedimentation of the sludge is completed.

In the present invention, when the sludge settled at the lower end of the second vessel is delivered to the designated third vessel, the control unit returns the water accumulated on the upper part of the third vessel back to the second vessel, After the dehydrating agent is injected into the third vessel, the sludge and dehydrating agent are stirred with an internal stirrer to inject the sludge into the CST test section.

According to another aspect of the present invention, there is provided a method for evaluating the sludge quality of a sludge, comprising: a control unit collecting wastewater to be analyzed in a first vessel and stirring the collected wastewater; Injecting a predetermined amount of wastewater into the second vessel from the first vessel, the predetermined amount of water required for a CST (Capillary Suction Time) test; Injecting chemicals necessary for agglomeration of sludge into the wastewater contained in the second vessel through the medicament injecting unit, rotating the inner paddles and stirring the medicines; Terminating the operation of the internal paddles of the second vessel when the flocculation reaction of the wastewater contained in the second vessel is terminated; After the operation of the inner padding is completed, when the sludge starts to settle at the lower end of the second vessel and the sedimentation is completed, the control unit transfers the sludge settled at the lower end of the second vessel to the designated third vessel step; And the sludge settled at the lower end of the second vessel is transferred to a designated third vessel, and when a predetermined time has elapsed, the control unit opens the lower end of the third vessel to inject sludge into the CST test unit, The method comprising the steps of:

In the present invention, after the control unit injects a predetermined amount of waste water required for the CST test from the first container to the second container, the waste water remaining in the injection pipe from the first container to the second container is returned to the first container And then sucking it into the container.

In the present invention, when the operation of the internal paddles of the second container is completed, the control unit may transform the shape of the lower end of the second container from the flat shape to the funnel shape with the central portion being concave downward .

According to the present invention, after the operation of the inner padding is terminated, when the sludge starts to settle at the lower end of the second vessel and the precipitation is completed, the control unit opens the upper outlet pipe of the second vessel, And measuring the turbidity of the supernatant through the turbidity measuring unit while discharging the turbid water to the fourth container.

In the present invention, when the sludge settled at the lower end of the second vessel is transferred to the designated third vessel, the control unit returns the water accumulated on the upper part of the third vessel back to the second vessel, Injecting the drug into the third container, and stirring the sludge and the dehydrating agent with an internal stirrer.

According to one aspect of the present invention, an accurate CST evaluation is performed by automatically capturing only sludge precipitated after the stirring, while reducing experimental errors in stirring intensity and stirring time for collecting sludge in the coagulation sedimentation process To be performed.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an exemplary diagram showing a schematic configuration of a sludge evaluation apparatus according to an embodiment of the present invention; FIG.
FIG. 2 is an exemplary view for explaining the shape of a second container for a Jar test in FIG. 1; FIG.
3 is a flow chart for explaining a method of evaluating the sity of a sludge according to an embodiment of the present invention.

Hereinafter, an embodiment of an apparatus and method for evaluating the sludge sludge according to the present invention will be described with reference to the accompanying drawings.

In this process, the thicknesses of the lines and the sizes of the components shown in the drawings may be exaggerated for clarity and convenience of explanation. In addition, the terms described below are defined in consideration of the functions of the present invention, which may vary depending on the intention or custom of the user, the operator. Therefore, definitions of these terms should be made based on the contents throughout this specification.

FIG. 1 is a schematic view showing a schematic configuration of a sludge evaluation apparatus for sludge according to an embodiment of the present invention. FIG. 2 is a view for explaining the shape of a second vessel for a jar test FIG.

1, the sludge evaluation device of the sludge according to the present embodiment includes a first container C1, a second container C2, a third container C3, a fourth container C4, 1 includes a pump P1, a second pump P2, a chemical injection unit 110, a turbidity measurement unit 120, a CST test unit 130, and a control unit 140.

The first vessel (C1) is a large capacity tank for collecting wastewater samples that need to be analyzed.

The first container (C1) is a large capacity tank of at least 20 L, and the collected wastewater is stirred at a predetermined speed so as to be uniformly mixed.

The second container C2 receives a predetermined amount of waste water required for the test in the first container C1.

The first pump P1 injects a predetermined amount of wastewater into the second container C2 from the first container C1 and sucks the wastewater remaining in the pipe back into the first container C1.

The chemical injector 110 injects chemicals necessary for agglomeration of the sludge into the wastewater contained in the second vessel C2 under the control of the controller 140, It is washed and injected with ultra pure water for repeated experiment.

At this time, the injection amount of the injected chemical (for example, polymer, NaOH, hydrochloric acid, coagulant, etc.) is stored, and the rotational speed of the pellets before or after the injection of the chemical may be changed.

As shown in FIG. 2, the second container C2 is a container having a capacity of, for example, 2 L, and a surface is formed in a square pillar shape, and a supernatant discharge pipe for discharging the supernatant is formed on one surface .

For example, the length of one side of the second container C2 is about 115 mm, and the height of the outlet pipe is about 50 mm at the lower end (or the base) to have a slight margin considering the normal height at which the sludge is settled , And the thickness of the tube is about 8 mm.

2 (a)), the lower end (or the basal plane) of the second container C2 is in an equilibrium state at the time of agglomeration (see Fig. 2 (a) The center portion is changed concave downwardly (i.e., in a funnel shape), and when the settling of the sludge is completed, the sludge outflow pipe is opened to drain the sludge downward.

That is, when the lower end (i.e., bottom) of the second container C2 is concave (i.e., funnel shape) in the coagulation step, accurate stirring intensity and stirring time are not applied and thus experimental errors are increased.

Therefore, it is preferable that the lower end (i.e., bottom) is flat in the flocculation step, but it is difficult to collect only the sludge when the lower end (i.e., bottom) is flat in the collecting step of the precipitated sludge.

Therefore, when collecting the sludge using a jar having a lower end (i.e., bottom), the sludge is collected at the upper end of the second container C2 using a pipette or other testing instrument, Can not be accurately measured.

However, in the present embodiment, the second container C2 maintains a flat state at the time of agglomeration, and at the time of agglomeration, the central portion of the lower end (i.e., bottom) is changed into a funnel shape recessed downward, And the sedimented sludge can be easily collected.

The control unit 140 terminates the operation of the paddles (or blades) in the second container C2 and controls the shape of the lower end of the second container C2 Change it. After the lower end of the second vessel C2 is changed to a funnel shape as described above, sedimentation of the sludge starts.

When the sedimentation of the sludge is finished after a certain period of time, the controller 140 opens the upper outlet pipe of the second container C2 and discharges it to the fourth container C4, Turbidity is measured. This completes the general chemical treatment assessment.

The fourth container C4 uses a large capacity tank of about 20L.

Next, the controller 140 opens the lower sludge outlet pipe of the second container C2 and slowly pumps the sludge to the designated third container C3 at a very low speed (for example, 1 mL per minute). The second pump P2 pumps the sludge precipitated at the lower end of the second container C2 to the third container C3 gradually.

After the completion of the transfer of the sludge from the second container C2 to the third container C3 after a predetermined period of time (about 10 minutes), the controller 140 repeats the water accumulated on the upper portion of the third container C3 A predetermined amount of dehydrating agent is injected into the third container C3 while returning to the second container C2 and then the sludge and the dehydrating agent are stirred by a fine stirrer (not shown) inside.

When the next predetermined time has elapsed, the controller 140 opens the lower end of the third vessel C3 and inputs the sludge mixed with the dehydrating agent to the CST (Capillary Suction Time)

The CST test unit 130 performs a CST test of the sludge charged.

After that, the controller 140 injects ultrapure water into the second container C2, cleans the inside of the second container C2, and repeats the above-described test of the sludge. In washing the third container C3, the washing water is transferred to the fourth container C4 through valve switching, thereby washing the second container C2 and the third container C3. And the water is transferred to the fourth container C4.

FIG. 3 is a flowchart illustrating a method for evaluating a sushi rate of a sludge according to an embodiment of the present invention.

As shown in FIG. 3, the control unit 140 collects wastewater to be analyzed in the first container C1 and stirs the wastewater uniformly at a predetermined speed (S101).

Next, the controller 140 injects a predetermined amount of waste water required for the CST test from the first container C1 to the second container C2 (S102).

Then, the wastewater remaining in the injection pipe from the first container C1 to the second container C2 is again sucked into the first container C1 (S103). Accordingly, only the wastewater of exactly the designated capacity can be injected into the second vessel C2.

Next, the controller 140 injects chemicals necessary for agglomeration of the sludge into the wastewater contained in the second vessel C2 through the medicament injecting unit 110, rotates the inner paddle (or the blade) And stirred (S104).

At this time, the amount of the chemicals injected into the second container C2 and the rotational speed information of the paddles are stored in an internal memory (not shown).

When the coagulation reaction of the wastewater contained in the second container C2 is terminated (YES in S105) (or the time for which the coagulation reaction is performed has elapsed), the controller 140 controls the inside of the second container C2 The operation of the paddles is terminated (S106).

At the same time as the operation of the paddles is completed, the agglomerated sludge starts to settle.

Thereafter, the controller 140 changes the shape of the lower end of the second container C2 from a flat shape to a downward concave shape in a funnel shape (S107).

The mechanical shape for changing the shape of the lower end of the second container (C2) is not particularly limited as it is possible to apply any known method.

When the dew point of the sludge contained in the second vessel C2 is terminated (YES in step S108) (or the time required for sedimentation has elapsed), the control unit 140 controls the flow of the liquid in the second vessel C2 The turbidity of the supernatant is measured through the turbidity measuring unit 120 while discharging the supernatant to the fourth container C4 by opening the tube (S109).

Thus, the performance of the chemical aggregation evaluation is completed, and the dehydration test can be performed immediately.

That is, the controller 140 opens the sludge outlet pipe at the lower end of the second container C2 and slowly transfers the sludge to the designated third container C3 at a very low speed (for example, 1 mL per minute). At this time, the water accumulated in the upper part of the third container C3 is returned to the second container C2. The controller 140 injects a predetermined amount of dehydrating agent into the third container C3, The sludge and the dehydrating agent are stirred with a fine internal stirrer (not shown) (S110).

When the next predetermined time has elapsed, the controller 140 opens the lower end of the third vessel C3 to inject the sludge mixed with the dehydrating agent into the CST (Capillary Suction Time) The test is performed (S111).

Then, the controller 140 injects ultrapure water into the second container C2 to clean the inside of the second container C2, and then repeats the above-described process.

In this embodiment, the chemical agglomeration evaluation is completed, the dehydration test can be performed immediately, and only the sludge can be accurately collected (that is, the data error due to denaturation of the sludge can be minimized) ), It is possible to more accurately confirm the internal characteristics of the actual sludge in an automated manner.

For example, in the CST measurement of the sludge, an error occurring due to floc cracking may be as low as several tens to hundreds percent. However, when the operation for minimizing the sludge change is uniformed by applying the present embodiment, %, And it is confirmed that the measurement accuracy is improved.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, I will understand the point. Accordingly, the technical scope of the present invention should be defined by the following claims.

C1: first container C2: second container
C3: third container C4: fourth container
P1: first pump P2: second pump
110: drug injection unit 120: turbidity measurement unit
130: CST test unit 140:

Claims (8)

A first vessel for collecting and stirring wastewater which requires characteristic analysis;
A second vessel for receiving a predetermined amount of waste water required for a CST (Capillary Suction Time) test in the first vessel;
A chemical injector for injecting chemicals necessary for agglomeration of sludge into wastewater contained in the second vessel;
A third container receiving the sludge settled at the lower end of the second container;
A CST test unit for injecting the sludge into the lower end of the third vessel and performing a CST test; And
The pellets are rotated and agitated after the chemicals necessary for agglomeration of the sludge are injected into the wastewater contained in the second vessel through the medicament injecting unit. When the agglomeration reaction is completed, the inner paddles of the second vessel are moved The sludge is settled on the lower end of the second container, the lower end of the second container is opened and transferred to the third container, and the lower end of the third container is opened to inject sludge into the CST test section, And a control unit for performing a test,
Wherein the second container comprises:
A surface is formed in a square pillar shape,
On either side, an effluent outlet pipe is formed to drain the supernatant,
When the sedimentation of the sludge is completed, the central portion of the sludge is changed into a funnel shape in a downward direction. When the sedimentation of the sludge is completed, the sludge drainage pipe is opened and the sludge is moved downward Wherein the sludge is formed into a shape capable of flowing out.
delete The apparatus of claim 1,
When the sludge settled at the lower end of the second vessel is transferred to the designated third vessel,
The sludge and the dehydrating agent are stirred by an internal stirrer, and the sludge is fed to the CST test section. The sludge is fed into the third container, Is fed into the sludge tank.
Collecting and stirring the wastewater to be analyzed by the control unit in the first vessel;
Injecting a predetermined amount of wastewater into the second vessel from the first vessel, the predetermined amount of water required for a CST (Capillary Suction Time) test;
Injecting chemicals necessary for agglomeration of sludge into the wastewater contained in the second vessel through the medicament injecting unit, rotating the inner paddles and stirring the medicines;
Terminating the operation of the internal paddles of the second vessel when the flocculation reaction of the wastewater contained in the second vessel is terminated;
After the operation of the inner padding is completed, when the sludge starts to settle at the lower end of the second vessel and the sedimentation is completed, the control unit transfers the sludge settled at the lower end of the second vessel to the designated third vessel step;
The sludge settled at the lower end of the second container is transferred to the designated third container, and when the predetermined time has elapsed, the control unit opens the lower end of the third container to put the sludge into the CST test unit, ; And
And deforming the shape of the lower end of the second container into a funnel shape having a flat shape and a center concave downward when the operation of the inner paddles of the second container is completed, Tee evaluation method.
5. The apparatus according to claim 4,
After injecting a certain amount of wastewater for the CST test from the first vessel to the second vessel,
Further comprising the step of sucking the wastewater remaining in the injection piping from the first vessel to the second vessel back into the first vessel.
delete 5. The method of claim 4,
After terminating the operation of the inner paddles,
When the sludge starts to settle on the lower end of the second vessel and the precipitation is completed,
And measuring the turbidity of the supernatant through the turbidity measuring unit while the control unit opens the supernatant discharge pipe of the second container and discharges the supernatant to the fourth container.
5. The method of claim 4,
When the sludge settled at the lower end of the second vessel is transferred to the designated third vessel,
Returning the water accumulated in the upper portion of the third container to the second container, injecting a predetermined amount of the dehydrating agent into the third container, and stirring the sludge and the dehydrating agent with an internal stirrer; The method of claim 1, wherein the sludge is sludge.

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