JP4876094B2 - Slime control method and apparatus - Google Patents

Description

  The present invention relates to a method and apparatus for slime control by adding a slime control agent having an antibacterial effect to an aqueous system containing a reducing substance, such as white water circulating water and pulp slurry in a paper machine.

  In white water in a paper machine, bacteria and fungi are propagated using cellulose and various additives as nutrients to generate slime, which results in a decrease in product quality, a decrease in production efficiency, etc. A slime control agent such as 2,2-dibromo-3-nitrilopropionamide is added. However, in the white water circulation system in a paper machine, recycled paper is often produced using waste paper as a raw material. In this case, when producing deinked waste paper pulp, this pulp is bleached in a bleaching step. This bleaching process involves bleaching with oxidizing agents such as chlorine, chlorine dioxide, hydrogen peroxide, oxygen, ozone and peracetic acid, and reduction of hydrotalsulfite, sodium polohydride, thiourea dioxide, sodium sulfite, sodium bisulfite, etc. Bleaching with an agent or bleaching using an oxidizing agent-reducing agent in combination is performed. The reducing agent used at this time is usually washed away in the next washing step, but if the washing is insufficient, a reducing substance derived from the reducing agent is formed. Since the deinked waste paper pulp containing the reducing substance is used in the papermaking process, the reducing substance is likely to be mixed in the papermaking system, and it is expensive to treat this by adding a slime control agent. There is a problem that the consumption of the slime control agent is greatly increased.

  On the other hand, in the invention described in Patent Document 1, an organic antibacterial agent is added to an industrial water system containing a reducing substance at the same time or after an amount of hypochlorite in which residual chlorine concentration is not detected. It has been proposed to add.

  Patent Document 2 discloses a slime control agent containing a compound that produces hypochlorous acid and / or hypobromite as an active ingredient so that the redox potential at 30 ° C. of the aqueous system maintains a specific reference value. A method of continuous addition is disclosed.

  In the invention described in Patent Document 1, the quantitative determination of the reducing substance is performed by a colorimetric method using para-rose aniline, which is time consuming and involves the problem of requiring aqueous turbulent flow conditions.

  The slime control agent is added at the same time as hypochlorite or after the addition of hypochlorite. In the former case, the slime control agent is used to neutralize the reducing substance. Therefore, even in the latter case, when the slime control agent is added, the slime control agent is consumed by the reducing substance, so the consumption of the slime control agent is still large. There is a problem that.

JP 2003-164882 A JP 2000-259933 A

  The present invention has been made in view of the above problems, and hypochlorite is added so that the amount of the slime control agent is minimized while quantitatively determining the reducing substance in real time. It is an object of the present invention to provide a slime control method and apparatus.

  That is, the following problems can be solved by the following embodiments.

(1) A slime control method in which hypochlorite is added to an aqueous system containing a reducing substance, and a slime control agent is added at the same time or later. A certain amount of hypochlorite is added to the aqueous system. The process of measuring the redox potential of the aqueous system after a certain time and the process of measuring the redox potential of the aqueous system after increasing the amount of hypochlorite and then measuring the aqueous system after a certain time, However , until the residual chlorine concentration exceeds the predetermined value when it is no longer detected , the amount of hypochlorite added is repeatedly increased stepwise, and the measured redox potential exceeds the predetermined value. When the amount of hypochlorite added is less than the amount added at that stage and above the amount added at the previous stage and the addition is continued, the oxidation-reduction potential exceeds a predetermined value. After that, the slime control agent Slime control method comprising comprises a step of starting the addition to the water system, the.

  (2) The amount of hypochlorite added is 2 as the effective chlorine concentration of hypochlorite at each stage with respect to the amount of water containing reducing substances newly flowing into the water system to be treated. The slime control method according to (1), characterized by increasing at an equal interval or exponentially starting from -10 ppm.

  (3) The amount of hypochlorite to be reduced after the measured oxidation-reduction potential exceeds a predetermined value is half of the difference between the addition amount when the measured value exceeds the predetermined value and the addition amount in the immediately preceding stage. The slime control method as described in (1) or (2) characterized by having performed.

  (4) A certain time after adding the slime control agent, measuring the aqueous redox potential, and stopping the addition of the slime control agent when it rises 200 to 450 mV above the predetermined value. The slime control method as described in (1), (2) or (3) characterized by these.

  (5) The water system is a white water circulation system in a paper machine, and the white water circulation system extends from the drain pan below the wire part, the white water silo, and the white water silo discharge side to the inlet of the wire part. The main flow path and a circulation pump provided at a position near the white water silo of the main flow path are configured to include at least a seed supply from a seed box for supplying a seed to the downstream side of the circulation pump in the main flow path. A seed agent confluence is provided to which a pipe is connected, and the hypochlorite is added to the water system at a position between the seed confluence and the circulation pump in the main flow path, and the redox potential is The slime control method according to any one of (1) to (4), wherein measurement is performed at a position immediately before the inlet in the main channel.

  (6) The water system is a white water circulation system in a paper machine, and the white water circulation system extends from the drain pan below the wire part, the white water silo, and the inlet of the wire part from the discharge side of the white water silo. The main flow path is configured to include at least a circulation pump provided near the white water silo in the main flow path and a second circulation pump provided upstream of the inlet, and downstream of the circulation pump in the main flow path. On the side, a seed confluence is connected to which a seed supply pipe is connected from a seed box for supplying the seed, and the hypochlorite is passed between the seed confluence in the main flow path and the circulation pump. (1) to (4), characterized in that the oxidation-reduction potential is added to the water system at a position in between and the oxidation-reduction potential is measured at a position between the circulation pump and the second circulation pump in the main flow path. Either Slime control method according to.

  (7) The time from the addition of the hypochlorite to the oxidation-reduction potential measurement is made equal to the flow-down time from the hypochlorite addition position to the oxidation-reduction potential measurement position in the aqueous system. The slime control method according to any one of (1) to (6).

(8) A slime control device for adding hypochlorite to an aqueous system containing a reducing substance and adding a slime control agent simultaneously or with delay, and adding hypochlorite to the main flow path of the aqueous system Hypochlorite addition device, slime control agent addition device for adding a slime control agent to the main channel, oxidation-reduction potential measuring device for measuring an aqueous oxidation-reduction potential in the main channel, and this oxidation-reduction potential measurement A control device for controlling the hypochlorite addition device and the slime control agent addition device based on a signal of the measured value of the device, the control device comprising the hypochlorite addition device at predetermined time intervals, by increasing the addition amount stepwise, the addition of hypochlorite to the aqueous, the measurement value is beyond a predetermined value when the residual chlorine concentration becomes not to be detected When it becomes a stage, the slime control is performed so as to reduce the addition amount to less than the addition amount of the stage and more than the addition amount of the immediately preceding stage, and after the measured value exceeds a predetermined value. The slime control device, wherein the agent addition device controls to start the addition of the slime control agent to the aqueous system.

  (9) The water system is a white water circulation system in a paper machine, and the white water circulation system includes a drain pan below the wire part, a white water silo, a main flow path from the discharge side of the white water silo to the inlet of the wire part on the inlet side, The main flow path is configured to include a circulation pump provided near the white water silo, and a seed supply pipe is connected to a downstream side of the circulation pump in the main flow path from a seed box for supplying a seed. The hypochlorite addition device has an agent confluence, and is arranged to add hypochlorite to the aqueous system at a position between the seed agent confluence and the circulation pump in the main channel. The slime control device according to (8), wherein the redox potential measuring device is arranged to measure a redox potential at a position immediately before the inlet in the main channel.

  (10) A recovery system hypochlorite addition device and a slime control agent for receiving hypochlorite into a preparation pit that receives surplus water from the white water silo in the paper machine and discharges it to a raw material recovery system And a recovery system slime control agent adding device for adding a recovery system, and a recovery system redox potential measuring device for measuring the oxidation-reduction potential of surplus white water from the preparation pit. When the chlorite addition device increases the addition amount step by step at regular intervals, hypochlorite is added to the preparation pit, and when the measured value exceeds the predetermined value, The recovery-type slime control agent is controlled so as to be reduced to an addition amount less than the addition amount of the stage and more than the addition amount of the immediately preceding stage, and after the measured value exceeds a predetermined value. Additive dressing But slime control device having the constitution (9) that is adapted to control to start the addition of the slime control agent to tone forming pits.

Prior to the addition of the slime control agent to the aqueous system, the present invention measures the redox potential each time while increasing the amount of hypochlorite added so that the residual chlorine concentration is not detected. When it reaches the predetermined value, the amount of hypochlorite added is reduced to the previous level, and the slime control agent is added while continuing to add, so overshoot of hypochlorite addition The slime control agent is added while maintaining the water system in a stable state and reducing the effects of reducing substances with hypochlorite while reducing the amount of the slime control agent. it can.

  Embodiments of the present invention will be described below in detail with reference to the drawings.

  In this embodiment, the slime control device 10 according to the present invention is used in the water system of the paper machine 30.

  The slime control device 10 includes a hypochlorite addition device 12 that adds hypochlorite to the main flow path 32A of the paper machine 30, a slime control agent addition device 14 that adds a slime control agent, and a redox in an aqueous system. Based on the oxidation-reduction potential measuring device 16 for measuring the potential, and the oxidation-reduction potential signal measured by the oxidation-reduction potential measuring device 16, the hypochlorite addition device 12 and the slime control agent addition device 14 And a control device 18 for controlling the control. In FIG. 1, the hypochlorite addition device 12 and the slime control agent addition device 14 are collectively shown as a drug addition device 20.

  The paper machine 30 supplies white water mixed with the raw material and dilution water from the main flow path 32B to the wire part 34 for making paper using a wire, receives the white water after paper making by the drain pan 36, and supplies it to the white water silo 38. After the storage, it is configured so as to be circulated as white water toward the wire part 34 together with the white water supplied from the seed box 42 through the main flow path 32 </ b> A and sent again to the main flow path 32 </ b> B by the circulation pump 40.

  1 is a press part for pressing the paper squeezed by the wire part 34 with a roll to squeeze out moisture contained in the paper, and 48 is in the middle of the main flow path 32B on the downstream side of the seed box 42. A decurator for vacuum degassing of white water, 50 is a second circulation pump for pumping white water that has passed through the decumulator 48, 52 is a screen for filtering white water, and 54 is a rectifier for white water. Inlet for supplying the wire part 34 is shown.

  Also, a couch pit 58 for collecting white water from a drain pan 56 that collects white water squeezed in the press part 46 is provided, and the white water from the couch pit 58 is returned to the white water silo 38 and surplus water in the white water silo 38. Is allowed to flow down to the raw material recovery system 62 through the adjustment seal pit 60.

  The water system in the paper machine 30 is provided with a seed agent junction 43 to which a seed agent supply pipe 42A for supplying white water from the seed box 42 is connected to the main channel 32A.

  The oxidation-reduction potential measuring device 16 constituting a part of the slime control device 10 according to this embodiment is provided so as to measure the oxidation-reduction potential of white water immediately before the inlet 54.

  The redox potential signal measured by the redox potential measuring device 16 is output to the control device 18.

  The hypochlorite and the slime control agent from the hypochlorite addition device 12 and the slime control agent addition device 14 pass through the oxidant supply pipe 15 and are substantially at the same position as the seed agent confluence 43 in the main flow path 32B. To be supplied.

  The control device 18 is configured to control the hypochlorite addition device 12 so as to increase the addition amount in steps at regular time intervals. At this time, the amount of hypochlorite added is 2 as the effective chlorine concentration of hypochlorite at each stage with respect to the amount of water containing reducing substances newly flowing into the water system to be treated. Starting from -10 ppm, it is increased at regular intervals or exponentially.

  Specifically, the control device 18 adds the hypochlorite addition device 12 to the main flow path 32B and adds a certain amount of hypochlorite, and the measurement is performed from the oxidation-reduction potential measurement device 16 after a certain time. When the redox potential signal is received and does not exceed the predetermined value, the amount of hypochlorite added is increased, and after a certain time, the redox potential measured by the redox potential measuring device 16 is increased. The process of reading the signal is repeated until the oxidation-reduction potential exceeds a predetermined value, and the amount of hypochlorite added is increased stepwise.

  Here, the predetermined value of the oxidation-reduction potential refers to the oxidation-reduction potential when the residual chlorine concentration is not detected. This may result in excessive hypochlorite addition and, if the residual chlorine concentration increases, may oxidize raw materials to reduce product quality and / or corrode metal materials such as equipment and piping. Because there is.

  Further, when the measured redox potential exceeds the predetermined value, the control device 18 controls the hypochlorite addition device 12 to add less than the addition amount at that stage and the addition at the immediately preceding stage. The amount of hypochlorite added is reduced more than the amount. In order to simplify the control, the amount added in the immediately preceding stage is used.

  The control device 18 is arranged such that when the oxidation-reduction potential measured by the oxidation-reduction potential measuring device 16 exceeds the predetermined value, the slime control agent adding device 14 starts adding the slime control agent. Yes.

  Here, the hypochlorite uses at least one of sodium hypochlorite, potassium hypochlorite, and calcium hypochlorite.

  The slime control agent is a harmful microorganism eradicating agent having a function of preventing and / or killing harmful microorganisms such as bacteria in the aqueous system, and is a compound that increases the redox potential when added to the aqueous system. There is a need. Examples of such compounds include 2,2-dibromo-3-nitrilopropionamide, 2,2-dichloro-3-nitrilopropionamide, 5-chloro-2-methyl-3-isothiazolone, bisbromoacetoxybutene, Halogenated nitroalcohols such as bisbromoacetoxyethane, 2,2-dibromo-2-nitroethanol, 2,2-dichloro-2-nitroethanol, dichlorodimethylhydantoin, dibromodimethylhydantoin, bromo-chloro-dimethylhydantoin, etc. Organic harmful microorganism eradication agents such as halogenated dimethylhydantoin, dimethylhydantoin, hypobromite, sodium hypobromite, potassium hypobromite, calcium hypobromite, brolamines, chloramines, persulfate, peracetic acid Inorganic harmful substances such as hydrogen peroxide Biological eradication agents, as well as their organic harmful microorganisms eradication agent and inorganic harmful microorganisms eradication agent and ammonium bromide, potassium bromide, sodium bromide, and the like reaction product of calcium bromide and the like.

  These may be used alone or in combination of two or more. In addition, the slime control agent used in the present invention is an organic harmful microorganism eradication agent such as 2,2-dibromo-3-nitrilopropionamide and halogenated dimethylhydantoin, as well as hypoxia, because addition control with high accuracy can be performed. An inorganic harmful microorganism eradicating agent comprising a reaction product of a halogenate salt and a bromide salt is preferred.

  Furthermore, after the start of addition of the slime control agent, the control device 18 stops the addition of the slime control agent when the oxidation-reduction potential signal from the oxidation-reduction potential measuring device 16 increases by 200 to 450 mV after the start of addition of the slime control agent. Has been.

  Further, a recovery system hypochlorite addition device 64 for adding hypochlorite and a recovery system slime control agent addition device 66 for adding a slime control agent are provided for the preparation pit 60. . Furthermore, a recovery system redox potential measuring device 68 for measuring the redox potential of surplus white water sent from the preparation pit 60 to the raw material recovery system 62 is provided.

  The control device 18 controls the recovery system hypochlorite addition device 64 and the recovery system slime control agent addition device 66. Specifically, the control device 18 is configured such that the recovery system hypochlorite addition device 64 increases the amount of addition stepwise at regular intervals to add hypochlorite to the preparation pit 60, and the recovery system When the value measured by the oxidation-reduction potential measuring device 68 exceeds a predetermined value, control is performed to reduce hypochlorite to the amount added immediately before.

  Further, for the recovery system slime control agent adding device 66, after the measured value exceeds a predetermined value, the recovery system slime control agent adding device 66 adds the slime control agent to the preparation pit 60. Control to start.

  That is, the control device 18 controls the recovery system hypochlorite addition device 64 and the recovery system slime control agent addition device 66 in the same manner as in the hypochlorite addition device 12 and the slime control agent addition device 14. Has been.

  In addition, the addition of the slime control agent by the recovery system slime control agent adding device 66 is stopped when the measured redox potential by the recovery system redox potential measuring device 68 is increased by 200 to 450 mV from the start of the addition of the slime control agent. Has been.

  Next, a process of performing the water-based slime control in the paper machine 30 will be described with reference to FIG.

  This process also serves as explanation of slime control for surplus white water sent from the preparation pit 60 to the raw material recovery system 62.

  First, in step 101, the hypochlorite addition device 12 is driven by the control device 18, and from here, a certain amount of hypochlorite is added to the seed material confluence 43 of the main flow path 32B of the paper machine 30. Is added.

  Next, in step 102, it is determined whether or not the ORP (redox potential) exceeds a predetermined value. If the determination result is negative, the process proceeds to step 103.

  In step 103, hypochlorite is added to the main flow path 32B by a certain amount greater than the amount added in step 101. Returning to step 102, the process from step 103 to step 102 is repeated until the ORP exceeds a predetermined value again.

  If the ORP exceeds a predetermined value in step 102, the process proceeds to step 104. In step 104, the amount of hypochlorite added is returned to the previous stage. In the next step 105, the slime control agent adding device 14 is driven by the control device 18, and the addition of the slime control agent is started from the seed material confluence 43 to the main flow path 32 </ b> B.

  In the next step 106, it is determined whether or not the ORP has increased by 200 to 450 mV from the start of the addition of the slime control agent. If the determination result is negative, the process from step 105 to step 106 is repeated. If the determination result is positive, the process proceeds to the next step 107, the addition of hypochlorite and the slime control agent is stopped, and the slime control process is terminated.

  As described above, when the redox potential is increased by 200 to 450 mV due to the addition of the slime control agent, the addition of the slime control agent is stopped. This is because when the increase in the redox potential is less than 200 mV, This is because the antibacterial performance of white water tends to deteriorate due to slight fluctuations in the amount of reducing substances contained in white water, and when it exceeds 450 mV, quality deterioration such as oxidation of raw materials tends to occur.

  In this example, the hypochlorite is added in addition to the hypochlorite, and the slime control agent is added to the hypochlorite while continuing the addition immediately before the white water is in an oxidized state. Therefore, slime control can be performed with the addition amount of the slime control agent minimized.

  Further, in this embodiment, hypochlorite and a slime control agent are added in the vicinity of the seed agent confluence 43 with respect to the main flow path 32B of the white water from the seed box 42, and the redox potential of the white water is changed to the inlet portion. Therefore, it is possible to control the slime of white water with the optimal addition and measurement cycle. If the time of this addition / measurement cycle is too long, the amount of increase per step in the stepwise addition of hypochlorite increases, and the redox potential may greatly exceed the predetermined value. Can do. In addition, if the time of the addition / measurement cycle is too short, accurate measurement cannot be performed, so the reliability of the measurement value immediately after the addition becomes low, and the time from the addition until the first accurate measurement value is obtained becomes long. End up.

  Therefore, it is better that the hypochlorite addition position and the oxidation-reduction potential measurement position are as close as possible. However, a distance is required until the hypochlorite is uniformly mixed with white water, and this distance is minimum in the examples. When the time of the addition / measurement cycle may be long, the installation position of the oxidation-reduction potential measuring device may be between the circulation pump 40 and the second circulation pump 50.

  Using an organic slime control agent (containing 2,2-dibromo-3-nitrolylopropioamide and bisbromoacetoxybutene at a mass ratio of 30:10) in the main flow path of the paper machine, a redox potential measuring device ( The oxidation-reduction potential of white water was continuously measured at a position immediately before the inlet using HORIBA, Ltd. (model number: F-16 type).

  As a comparative test, only the same organic slime control agent as described above was added to the same white water containing a reducing substance as described above, and the oxidation-reduction potential was measured in the same manner as described above.

  As a result, when sodium hypochlorite is first added and the slime control agent is added simultaneously when the redox potential exceeds a predetermined value, the redox potential increases by 200 to 450 mV from here. The amount of the slime control agent used was significantly reduced as compared with the case where only the slime control agent was added until the oxidation-reduction potential reached the same value.

  In addition, the time from the start of the addition of the slime control agent to the increase of the oxidation-reduction potential to the predetermined value could be greatly shortened in the case of this example compared to the comparative example.

  In the above embodiment, the slime control method and apparatus are applied to a paper machine, but the present invention is not limited to this, and an aqueous system containing a reducing substance, for example, latex, color, starch slurry. , Pulp slurry, size system and the like.

  Furthermore, the addition position of the hypochlorite and the slime control agent and the measurement position by the oxidation-reduction potential measuring device are not limited to the examples, and may be white water or other parts of the water system.

  In the above embodiment, sodium hypochlorite and a slime control agent are added to the recovery system, and the redox potential of white water in the recovery system is measured. This includes cases where slime control is not performed.

  Furthermore, in the above examples, after the oxidation-reduction potential exceeds a predetermined value due to the addition of hypochlorite, the amount of hypochlorite added is reduced to the previous stage. It is not limited, and it is reduced to an intermediate addition amount between the addition amount of the previous step and the addition amount when the oxidation-reduction potential reaches a predetermined value (less than the addition amount of this step, or more than the addition amount of the previous step). You may do it.

The block diagram which shows the paper machine for enforcing the slime control method of this invention Flow chart showing the process of the slime control method

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Slime control apparatus 12 ... Hypochlorite addition apparatus 14 ... Slime control agent addition apparatus 16 ... Redox potential measurement apparatus 18 ... Control apparatus 30 ... Paper machine 32A, 32B ... Main flow path 34 ... Wire part 36 ... Drain pan 38 ... white water silo 40, 50 ... circulation pump 42 ... seed box 43 ... seed agent confluence 54 ... inlet 58 ... couch pit 60 ... preparation pit 62 ... raw material recovery system 64 ... recovery system hypochlorite addition device 66 ... recovery system Slime control agent addition device 68 ... Recovery redox potential measurement device

Claims (10)

A slime control method in which hypochlorite is added to an aqueous system containing a reducing substance, and a slime control agent is added simultaneously or delayed,
A process of adding a certain amount of hypochlorite to the aqueous system and measuring the redox potential of the aqueous system after a certain time, and then increasing the amount of hypochlorite added, The process of measuring the oxidation-reduction potential is repeated while increasing the amount of hypochlorite stepwise until the oxidation-reduction potential exceeds a predetermined value when the residual chlorine concentration is not detected ,
When the measured oxidation-reduction potential exceeds a predetermined value, the addition amount of hypochlorite is reduced to less than the addition amount at that stage and more than the addition amount at the immediately preceding stage, and the addition is continued. The process of
And a process of starting the addition of the slime control agent to the aqueous system after the oxidation-reduction potential exceeds a predetermined value. In claim 1,
The amount of hypochlorite added is 2 to 10 ppm as the effective chlorine concentration of hypochlorite for each stage with respect to the amount of water containing reducing substances newly flowing into the water system to be treated. A slime control method characterized by increasing the starting point at regular intervals or exponentially. In claim 1 or 2,
The amount of hypochlorite to be reduced after the measured oxidation-reduction potential exceeds a predetermined value is half of the difference between the addition amount when the measured value exceeds the predetermined value and the addition amount in the immediately preceding stage. Characteristic slime control method. In claim 1, 2 or 3,
A certain time after adding the slime control agent, a water-based oxidation-reduction potential is measured, and the addition of the slime control agent is stopped when it is increased by 200 to 450 mV from the predetermined value. How to control slime. In any one of Claims 1 thru | or 4,
The water system is a white water circulation system in a paper machine. And a circulation pump provided at a position near the white water silo in the main flow path, and a seed supply pipe is connected to a downstream side of the circulation pump in the main flow path from a seed box for supplying a seed. The hypochlorite is added to the water system at a position between the seed agent confluence and the circulation pump in the main flow path, and the oxidation-reduction potential is added to the main stream. A slime control method comprising measuring at a position immediately before the inlet on a road. In any one of Claims 1 thru | or 4,
The water system is a white water circulation system in a paper machine. A circulation pump provided in the main channel in the vicinity of the white water silo and a second circulation pump provided upstream of the inlet. The downstream of the circulation pump in the main channel is A seed junction where a seed supply pipe is connected from a seed box for supplying the seed is provided, and the hypochlorite is positioned between the seed junction and the circulation pump in the main channel. The slime control method is characterized in that it is added to an aqueous system and the oxidation-reduction potential is measured at a position between the circulation pump and the second circulation pump in the main channel. In any one of Claims 1 thru | or 6.
The slime control characterized in that the time from the addition of the hypochlorite to the oxidation-reduction potential measurement is equal to the flow time from the hypochlorite addition position to the oxidation-reduction potential measurement position in the aqueous system. Method. A slime control device for adding hypochlorite to an aqueous system containing a reducing substance, and adding a slime control agent simultaneously or delayed,
A hypochlorite addition device for adding hypochlorite to the aqueous main channel, a slime control agent addition device for adding a slime control agent to the main channel, and an aqueous redox potential in the main channel. And a control device for controlling the hypochlorite addition device and the slime control agent addition device based on a signal of a measurement value of the oxidation-reduction potential measurement device to be measured, and the measurement value of the oxidation-reduction potential measurement device,
The control device is configured such that the hypochlorite addition device increases the addition amount stepwise at regular intervals, adds hypochlorite to the aqueous system, and the measured value is a residual chlorine concentration. When it becomes a stage that exceeds a predetermined value when it becomes undetected, it is controlled to be reduced to an addition amount that is less than the addition amount of the stage and more than the addition amount of the immediately preceding stage, and The slime control device, wherein after the measured value exceeds a predetermined value, the slime control agent adding device controls to start the addition of the slime control agent to the aqueous system. In claim 8,
The water system is a white water circulation system in a paper machine. A seed supply point where a seed supply pipe is connected from a seed box for supplying a seed to the downstream side of the circulation pump in the main flow path. Have
The hypochlorite addition device is arranged to add hypochlorite to the aqueous system at a position between the seed agent confluence and the circulation pump in the main flow path, and the redox potential measurement The apparatus is arranged to measure the oxidation-reduction potential at a position immediately before the inlet in the main flow path. In claim 9,
Receiving surplus water from the white water silo in the paper machine and adding a hypochlorite addition device and a slime control agent for adding hypochlorite to the preparation pit discharged to the raw material recovery system A recovery system slime control agent addition device is provided, and a recovery system redox potential measuring device for measuring the oxidation-reduction potential of excess white water from the preparation pit is provided.
The control device is configured such that the recovery system hypochlorite addition device increases the addition amount stepwise at regular intervals to add hypochlorite to the preparation pit, and the measured value is a predetermined value. When the measured value exceeds the predetermined value, the control is performed so as to reduce the added amount to less than the added amount of the step and to the added amount equal to or more than the added amount of the immediately preceding step. Thereafter, the recovery-type slime control agent adding device controls to start the addition of the slime control agent to the preparation pit.

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