JP2012148206A - pH ADJUSTER OF BOILER WATER AND OPERATION METHOD OF BOILER - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pH adjuster of boiler water which can prevent corrosion caused by a used chemical agent even when exerting a pH adjustment function and an electrical conductivity holding function enough, and can prevent water pollution by blow waste water of boiler water.SOLUTION: The pH adjuster of boiler water used as a chemical agent for the pH adjustment and the electrical conductivity holding of boiler water for a boiler in which the water level of boiler water is detected by an electrode method includes a boron based compound in the chemical agent for the electrical conductivity holding of boiler water. The electrical conductivity of the aqueous solution of the boron based compound rises in proportion to the concentration. Moreover, the boron based compound does not cause the corrosion to a boiler can body or the like, and does not become a causative agent of water pollution to cause the eutrophication in the river or the like.

Description

  TECHNICAL FIELD The present invention relates to a boiler water pH adjuster used as a chemical for adjusting the pH of boiler water and maintaining electrical conductivity. The present invention also relates to a boiler operating method using this pH adjuster.

  Corrosion of the boiler can and the like is prevented by performing deoxidation treatment of the boiler water and pH adjustment. Boiler water is deoxygenated by removing dissolved oxygen from boiler feedwater, etc. using a deaerator, or by injecting a deoxidizer into boiler feedwater, etc., and using this deoxygenator to dissolve dissolved oxygen in boiler water. It is done by removing. Moreover, pH adjustment of boiler water is made | formed by inject | pouring a pH adjuster into boiler feed water etc. and maintaining pH of boiler water in a predetermined alkaline range. In the case of a low pressure boiler having a vapor pressure of 3 MPa or less, NaOH, KOH, sodium phosphate or potassium phosphate is used as the pH adjuster. In the case of a boiler with high steam pressure, volatile substances such as volatile amines and ammonia are also used.

  On the other hand, many low-pressure boilers detect the level of boiler water in the boiler can by an electrode rod method using a plurality of electrode rods. In the boiler using this electrode rod system, when the lower end of the electrode rod comes into contact with the boiler water, it is detected that electricity is supplied from the electrode rod to the boiler water side, and the water level of the boiler water is detected. For this reason, in the boiler water of such a boiler, it is necessary to maintain the electrical conductivity to about 5-10 mS / m or more.

  Therefore, the pH adjuster used in such boilers requires the electric conductivity of the boiler water to detect the water level by the electrode rod method in addition to the pH adjusting function for adjusting the pH of the boiler water to the alkaline predetermined range. An electric conductivity holding function that keeps the value is also required.

  By the way, chemicals such as NaOH, KOH, and potassium phosphate have sufficient pH adjustment function and electrical conductivity retention function. However, when this chemical is used, it may cause boiler water for some reason. By concentrating with the above, alkali corrosion is caused in the boiler can or the like, and stress corrosion cracking is caused in the steam pipe by carry-over of boiler water.

  Further, a drug such as sodium phosphate has no problem in the pH adjustment function, but has a slight problem in the electric conductivity holding function. That is, in this chemical, in order to sufficiently exhibit the electric conductivity maintaining function, if the phosphate ion concentration in the boiler water is maintained to exceed 10 mg / L, when the boiler water is blown down, Total phosphorus (Tortal P) in the river causes water pollution due to eutrophication in rivers.

  Furthermore, volatile chemicals such as volatile amines and ammonia have no problem with the pH adjustment function, but have a problem with the electrical conductivity holding function. In other words, in order for this drug to fully exert its electrical conductivity retention function, if it is added in a large amount to boiler water, a large amount of volatile substances will be transferred to the condensate system. As a result, the pH of the condensate system rises excessively, increasing the risk of corrosion on copper heat exchangers and the like. In this case, the amount of total nitrogen (Tortal N) in blow drainage also increases.

  In view of the above points, the present invention can prevent corrosion caused by the chemicals used, even when the electrical conductivity maintaining function is sufficiently exhibited together with the pH adjustment function, and the water quality by blow-off of boiler water It aims at providing the pH adjuster of boiler water which can also prevent pollution.

  Moreover, this invention can prevent the corrosion resulting from the chemical | medical agent used even if it makes a pH adjuster fully exhibit an electrical conductivity maintenance function with a pH adjustment function, and is by the blow drainage of boiler water. It aims at providing the operation method of a boiler which can also prevent water pollution.

  According to the first aspect of the present invention, the boiler water used as a chemical for adjusting the pH of the boiler water and maintaining electric conductivity is used in a boiler in which the water level of the boiler water is detected by an electrode rod system. A regulator, wherein the chemical for maintaining the electrical conductivity of the boiler water contains a boron-based compound.

  In a boiler that detects the boiler water level by the electrode rod method, the lower end of the electrode rod comes into contact with the boiler water, thereby detecting that electricity is passed from the electrode rod to the boiler water side. In order to be detected, it is necessary to maintain the electric conductivity of boiler water at a predetermined value or higher. Therefore, in the case of a boiler in which the water level is detected by the electrode rod method, the boiler water pH adjuster maintains the electric conductivity of the boiler water at a predetermined value or more in addition to the pH adjustment function for adjusting the pH of the boiler water. An electrical conductivity holding function is also required.

  Although NaOH, KOH, and potassium phosphate used as boiler water pH adjusters have the above-mentioned two functions sufficiently, they are concentrated in boiler water, so that boiler cans and the like Cause alkaline corrosion, and stress corrosion cracking in the steam pipe. In addition, sodium phosphate used as boiler water pH adjuster has no problem in pH adjustment function, but if it has an electrical conductivity maintaining function, the phosphate ion concentration of boiler water increases. And water pollution due to total phosphorus (P) in blown waste water. Furthermore, volatile substances such as volatile amines used as boiler water pH adjusters have no problem in pH adjustment function, but if they are to have electrical conductivity retention function, the amount used increases. As a result, a large amount of volatile substances migrate to the condensate system, the pH of the condensate system rises excessively, and the copper heat exchanger is corroded.

  On the other hand, for example, in the case of boron compounds such as borax, boric acid, and ammonium borate, the electrical conductivity of the aqueous solution increases in proportion to the concentration. Further, such boron compounds do not cause causative substances that cause corrosion in boiler cans and the like, and do not cause caustic substances that cause eutrophication in rivers and the like.

  In this invention, since the boron-based compound is contained in the agent for maintaining the electrical conductivity of the boiler water in the pH adjuster, the electrical conductivity maintaining function of the boiler water is shared by the boron-based compound. Can do. Therefore, for example, when a boron compound and sodium phosphate are used as the pH adjuster, the electrical conductivity holding function can be strengthened by the boron compound, and the amount of sodium phosphate can be reduced accordingly. For this reason, since the amount of sodium phosphate used can be reduced, water pollution due to total phosphorus in blown wastewater can be prevented. For example, when a boron compound and a volatile amine (volatile substance) are used as a pH adjuster, the amount of volatile amine (volatile substance) for maintaining electric conductivity can be reduced. Can prevent copper corrosion in the condensate system.

  According to a second aspect of the present invention, in the case of the first aspect, the boron compound is borax.

  Borax has a pH adjusting function in addition to a function of maintaining electric conductivity because the pH of an aqueous solution increases in proportion to the concentration until a certain concentration. For this reason, borax can be used alone as a pH adjuster. In addition, when borax is mixed with other chemicals (for example, NaOH, sodium phosphate, or volatile amine) and used as a pH adjuster, the amount of other chemicals used can be reduced. Corrosion and water pollution caused by chemicals can be prevented.

  In the invention according to claim 3 of the present invention, a boiler for detecting the water level of the boiler water by an electrode rod system is used as a pH adjusting agent for adjusting the pH of the boiler water and maintaining electric conductivity. The boiler operation method is characterized in that a boron compound is used as a chemical for maintaining the electrical conductivity of the boiler water.

  According to a fourth aspect of the present invention, in the case of the third aspect, the boron compound is borax.

  According to a fifth aspect of the present invention, in the case of the third or fourth aspect of the present invention, treated water having an electric conductivity of 1 mS / m or less is used for water supply to the boiler. To do.

  In this invention, since the electrical conductivity of the feed water to the boiler is suppressed to be as low as 1 mS / m or less, the boron-based compound in the pH adjuster can effectively exhibit the electrical conductivity holding function.

According to a sixth aspect of the present invention, in the case of the fourth aspect, the pH adjuster is a phosphorous compound having a boron compound and a molar ratio of Na to PO ₄ of 2.6 to 3.0. In the case of a mixed drug with sodium acid, this sodium phosphate is used so that the phosphate ion concentration in the boiler water is 10 mg / L or less.

  In this invention, since the phosphate ion concentration in boiler water can be lowered, it is possible to prevent water pollution of rivers and the like due to blow drainage caused by total phosphorus (P).

  According to the invention of the boiler water pH adjuster, since the boron-based compound is included in the chemical for maintaining the electrical conductivity of the boiler water, the boiler chemical has the electrical conductivity maintaining function as well as the pH adjusting function. Even when it is sufficiently exerted, corrosion caused by the chemicals used can be prevented, and water pollution due to boiler water blow drainage can also be prevented.

  In addition, according to the invention of the boiler operation method, since a boron-based compound is used as an agent for maintaining the electrical conductivity of boiler water, the electrical conductivity maintaining function as well as the pH adjusting function are included in the pH adjuster. Even when fully exhibiting the above, it is possible to prevent corrosion due to the chemicals used, and to prevent water pollution due to blow-off of boiler water.

It is a figure which shows an example of the boiler apparatus for implementing this invention. It is a graph which shows the relationship between the density | concentration of borax pentahydrate, and pH (25 degreeC). It is a graph which shows the density | concentration of a borax pentahydrate, and the relationship of electrical conductivity. It is the figure which showed the outline | summary of the implementation examination example in the table | surface.

Embodiments of the present invention will be described below.
First, an example of the boiler apparatus to which the pH adjuster according to the present invention is added will be described.

  Boiler apparatus A is, for example, a multi-tube small once-through boiler, and as shown in FIG. 1, around boiler boiler body 1 in which a large number of water pipes 12 are arranged between ring-shaped upper and lower headers 10 and 11, A steam / water separator 2, a water supply line 3, a blow-down line 4, a water level detection device 5, a water level control device 6, a chemical injection device 7, and the like are provided.

  The water level detection device 5 is of an electrode bar type that detects the water level of the boiler water W1 in the boiler can 1 using a plurality (for example, three) of electrode bars 50A, 50B, 50C. By detecting that the lower end of the boiler is in contact with the boiler water W1, it is detected that electricity is supplied from the electrode rod 50A to the boiler water W1 side, and the water level of the boiler water W1 is detected.

  The chemical injection device 7 includes a pH adjuster injection device 7A for injecting a pH adjuster P, which is a boiler agent, into an aqueous solution into the boiler feed water W2, and an oxygen scavenger Q, which is a boiler agent, in the boiler feed water W2. And an oxygen scavenger injection device 7B for injection.

  In this boiler apparatus A, deionized and ion-exchanged water having an electric conductivity of 1 mS / m or less is supplied to the boiler can body 1 as boiler feed water W2, and the boiler water W1 in the water pipe 12 is used as the boiler can body. 1 After being heated by the upper burner 13 and converted into steam S, the steam S is supplied to the outside through the steam separator 2. In this case, for example, when the lower end of the short electrode rod 50A detects the water surface of the boiler water W1, the water level detection device 5 issues a signal for stopping the pump 30 in the water supply line 3, and the intermediate length electrode rod 50B. When the lower end of the boiler detects that the boiler water W1 is lowered, a signal for operating the pump 30 is generated. Further, when the lower end of the long electrode rod 50C detects the lowering of the water level of the boiler water W1, a signal for stopping the combustion of the burner 13 is issued. These signals are transmitted to the pump 30 and the burner 13 through the water level control device 6.

  Moreover, in this boiler apparatus A, the boiler water W1 in the boiler can 1 is blown down by a certain amount (for example, about 3% of the flow rate of the boiler feed water W2) via the regulating valve 40 of the blow-down line 4. The impurity concentration in the boiler water W1 is kept below a certain value. In this case, the blow waste water W3 is discharged to the outside.

  Furthermore, the pH adjusting agent injection device 7A of the chemical injection device 7 injects the pH adjusting agent P in the tank 70A into the boiler feed water W2 via the pump 71A, and adjusts the pH and the like of the boiler water W1. Further, the oxygen scavenger injection device 7B injects the oxygen scavenger Q in the tank 70B into the boiler feed water W2 via the pump 71B, and reduces dissolved oxygen in the boiler water W1. The pH adjuster P and the oxygen scavenger Q should be supplied in an amount substantially proportional to the flow rate of the boiler feed water W2, but in general, the amount required for the operation of the boiler device A is 2 ~ 3 times the amount is injected.

Next, the pH adjuster P used in the boiler apparatus A will be described.
In this boiler apparatus A, since the water level of the boiler water W1 is detected by the electrode rod method, the pH adjuster P requires an electric conductivity holding function in addition to the pH adjusting function.

  Examples of the pH adjuster P include borax which is one of boron compounds, a mixed agent of borax and sodium phosphate, a mixed agent of borax and volatile substances (for example, ammonia and volatile amine), or borax. For example, any one of NaOH, KOH, potassium phosphate, or a mixture thereof (hereinafter referred to as NaOH or the like) is used. In addition, the pH adjuster P includes a mixed agent of a boron compound other than borax (hereinafter referred to as other boron compound) and sodium phosphate, a mixed agent of another boron compound and a volatile substance, or Any of the mixed agents of other boron compounds and NaOH is used. These will be described below.

When pH adjuster P is borax:
Borax includes borax pentahydrate (Na ₂ B ₄ O ₇ .5H ₂ O) and borax decahydrate (Na ₂ B ₄ O ₇ .10H ₂ O). As shown in FIG. 2, borax (for example, pentahydrate) has a pH (25 ° C.) value that is approximately proportional to this concentration when the concentration in the aqueous solution increases from 0 to 100 mg / L. Is raised from 7 to 9 or more. For example, the pH of a 100 mg / L aqueous solution of borax has a value of 9.2. Moreover, this borax raises the electrical conductivity of aqueous solution so that it may be substantially proportional to the density | concentration of the aqueous solution, as FIG. 3 shows. For example, the electrical conductivity of a 100 mg / L aqueous solution of borax shows a value of about 7 mS / m, and this value satisfies the value required by the water level detection device 5 for the boiler water W1. That is, borax has a pH adjusting function and an electrical conductivity maintaining function required for the pH adjusting agent P of the boiler apparatus A whose water level is detected by the electrode rod method.

  Furthermore, even if the borax is contained in the boiler water W1, the boiler can 1, the steam system, the condensate system metal and the like will not be corroded. Moreover, even if the boiler water W1 containing this is blown down and this blow drainage W3 flows into a river etc., borax does not cause water pollution by eutrophication in the river etc.

  Therefore, when borax is used as the pH adjuster P, the pH value of the boiler water W1 can be properly maintained, corrosion of the boiler can 10 and the like can be prevented, and the electrical conductivity of the boiler water W1 can also be appropriately maintained. The water level of the boiler water W1 can be properly detected by the water level detection device 5 using the electrode rod method. Further, borax does not cause various corrosion caused by the pH adjusting agent, and does not cause water pollution due to blow water W3 of the boiler water W1.

When the pH adjuster P is a mixed agent of borax and sodium phosphate:
Sodium phosphate is a pH adjuster used mainly to prevent alkali corrosion due to free alkali, and has a pH adjusting function and an electrical conductivity maintaining function. However, as a result, when the electrical conductivity of the boiler water W1 is increased only as required by the water level detection device 5, water pollution due to the blow drainage W3 is caused due to the total phosphorus (P). In addition, a sodium phosphate having a Na / PO ₄ molar ratio of 2.6 to 3.0 is used.

  In this pH adjuster P, borax and sodium phosphate were mixed to reduce the proportion of sodium phosphate in the pH adjuster P to compensate for the weakness caused by sodium phosphate. That is, the pH adjuster P composed of a mixed agent of borax and sodium phosphate can maintain the pH and electric conductivity of the boiler water W1 at necessary values in a state where the amount of sodium phosphate is reduced. Water pollution caused by total phosphorus (P) can be prevented by reducing the amount of sodium phosphate while exhibiting the adjustment function and the electrical conductivity holding function.

  In addition, when the phosphate ion concentration in the boiler water W1 is set to 10 mg / L or less, water pollution due to total phosphorus (P) can be sufficiently prevented. The amount of sodium phosphate used may be reduced so that the acid ion concentration is 10 mg / L or less, and a necessary amount of borax may be added to compensate for the decrease in sodium phosphate.

When the pH adjuster P is a mixed agent of borax and volatile substances:
Volatile substances such as volatile amines and ammonia are pH adjusters for preventing alkaline corrosion due to free alkalis, and have a pH adjustment function, but not so much an electric conductivity holding function. . Therefore, if the electric conductivity of the boiler water W1 is increased as much as required by the water level detection device 5 by increasing the amount of such volatile substances used more than usual, the pH of the condensate system will rise excessively. As a result, the risk of corroding the copper heat exchanger increases.

  In this pH adjuster P, borax and a volatile substance were mixed, and the weak point (electric conductivity holding function) due to the volatile substance was compensated with borax. That is, the pH adjuster P made of a mixed agent of borax and volatile substances can maintain the electrical conductivity of the boiler water W1 at a necessary value without greatly increasing the amount of volatile substances. Condensate copper corrosion can be prevented while performing the adjustment function and the electrical conductivity maintaining function.

When the pH adjuster P is a mixed agent of borax and NaOH or the like:
NaOH and the like have a sufficient pH adjustment function and electrical conductivity holding function, but when they are used, if they are concentrated in the boiler water W1 for some reason, the boiler can body 1 or the like is used. Causes alkaline corrosion.

  In this pH adjuster P, borax and NaOH were mixed to reduce the proportion of NaOH and the like in the pH adjuster P, thereby preventing alkali corrosion due to free alkali.

When the pH adjuster P is a mixed drug of another boron compound and sodium phosphate:
Other boron compounds such as boric acid (H ₃ BO ₃ ) and ammonium borate (NH ₄ B ₅ O ₈ .4H ₂ O) have no pH adjustment function, but have the same electrical conductivity as borax. As well as borax, the boiler can 1, the steam system, and the condensate metal are not corroded, and the blow drain W3 flows into the river etc. Does not cause water pollution due to eutrophication.

  In this pH adjuster P, the other boron compound and sodium phosphate are mixed to give the other boron compound a part of the electrical conductivity retaining function, and the phosphoric acid in the pH adjuster P The proportion of sodium was decreased to compensate for the weakness caused by sodium phosphate. That is, the pH adjuster P composed of another boron compound and sodium phosphate can maintain the pH and electric conductivity of the boiler water W1 at necessary values in a state where the amount of sodium phosphate is reduced. Water pollution caused by total phosphorus (P) can be prevented by reducing the amount of sodium phosphate while exhibiting the adjustment function and the electrical conductivity holding function.

When the pH adjuster P is a mixed drug of other boron compounds and volatile substances:
Even in this pH adjuster P, the electric conductivity of the boiler water W1 is necessary even if other boron-based compounds have a part of the electric conductivity holding function and the amount of volatile substances is not significantly increased. Since it can be maintained at the value, it is possible to prevent the copper corrosion of the condensate system while exhibiting the pH adjusting function and the electrical conductivity maintaining function.

When the pH adjuster P is a mixed agent of another boron compound and NaOH:
When other boron compounds and NaOH are mixed at a molar ratio of 2: 1, borax or a chemical close to borax is formed. Therefore, with this mixed medicine, the effect of using borax as the pH adjuster P is obtained, and alkali corrosion due to NaOH hardly occurs.

  As described above, in this pH adjuster P, since the boron-based compound (for example, borax, boric acid, ammonium borate) is included in the agent for maintaining the electrical conductivity of the boiler water W1, the boiler agent In addition, even when the electrical conductivity retention function is fully exhibited together with the pH adjustment function, it is possible to prevent corrosion caused by the pH adjustment agent used, and also prevent water pollution caused by the boiler water blow drain W3. it can.

  Moreover, in this boiler apparatus A, since the boron-type compound is used as a chemical | medical agent for holding | maintaining the electrical conductivity of boiler water in the operation | movement, the electrical conductivity holding | maintenance is carried out to the pH adjuster P with the pH adjustment function. Even when the function is sufficiently exerted, corrosion due to the chemicals used can be prevented, and water pollution caused by boiler water blow drainage W3 can also be prevented.

  In particular, when a boron compound borax having not only an electric conductivity maintaining function but also a pH adjusting function is used as the pH adjuster P, the boron compound can be used alone as the pH adjuster P. At the same time, even when this is mixed with other pH adjusting agents, the amount of other pH adjusting agents used can be reduced from the viewpoint of the pH adjusting function in addition to the electrical conductivity maintaining function. Corrosion caused by this chemical can be prevented.

  Moreover, in the boiler apparatus A, the electric conductivity holding function by the boron-based compound in the pH adjuster P is achieved by operating in a state where the electric conductivity of the boiler feed water W2 is kept low (1 mS / m or less). Can be effectively exhibited.

  Further, in the boiler apparatus A, when a mixed agent of borax and sodium phosphate is used as the pH adjuster P, an operation is performed such that the phosphate ion concentration in the boiler water W1 is 10 mg / L or less. By doing so, the phosphate ion concentration in the boiler water can be made sufficiently low, so that it is possible to prevent water pollution of rivers and the like due to blow drainage caused by total phosphorus (P).

  The pH adjuster P may be used in combination with the oxygen scavenger Q, or may be used in combination with other boiler water treatment agents (for example, softeners, furnace adjustment agents). Of course, the boron-based compound may be injected into the boiler apparatus A separately from other pH adjusting agents.

  Further, the pH adjusting agent P may be directly injected into the boiler can body 1 instead of the water supply line 2.

  Further, the boiler apparatus A may be any type of boiler such as a round boiler, a water tube boiler, or a once-through boiler as long as the water level is detected by an electrode rod method.

  Next, an implementation study example when various pH adjusters are added to the boiler apparatus A will be described with reference to FIG. In this case, the steam pressure of the boiler apparatus A is 0.8 MPa, the dissolved oxygen concentration of the boiler feed water W2 is 0.5 mg / L, and the electrical conductivity is 1 mS / m. Further, the blowdown rate in the blowdown line 6 is 3% of the feed water flow rate, and the transition rate of the boiler water W1 (canned water) to the steam S is considered to be about 2%.

  Example 1 of implementation examination is a case where NaOH is used as a pH adjuster at a concentration of 3 mg / L with respect to boiler feed water W2. In this implementation study example, the pH value of the boiler water W1 is 11.4, the electrical conductivity of the boiler water W1 is 62 mS / m, and the pH value of the condensate is 9.7. Therefore, the risk of alkali corrosion due to free alkali increases in the boiler can 1 and the like, and the risk of stress cracking also increases on the steam pipe side.

The implementation study example 2 is a case where Na ₃ PO ₄ is used as a pH adjuster at a concentration of 3 mg / L with respect to the boiler feed water W2. In this implementation study example, the pH value of the boiler water W1 is 10.7, and the electrical conductivity of the boiler water W1 is 9.7 mS / m. Moreover, the pH value of the condensate is 9.11, and the phosphate ion concentration of the boiler water W1 is 50 mg / L. Therefore, in the case of this implementation study example, since the phosphate ion concentration of the boiler water W1 is high, when the boiler water W1 is blown down, the value of total phosphorus (Tortal P) in the blow drainage W3 increases, and rivers, etc. The risk of water pollution due to eutrophication increases.

    The implementation study example 3 is a case where 2-aminoethanol, which is one of volatile alkanolamines, is used as a pH adjuster at a concentration of 3 mg / L with respect to the boiler feed water W2. In this implementation study example, the pH value of the boiler water W1 is 9.9, and the electric conductivity of the boiler water W1 is 2 mS / m. The pH value of the condensate is 9.4, and the total nitrogen (Tortal N) concentration in the blown waste water W3 is increased to 4 to 5 mg / L. In the case of this implementation study example, since the electrical conductivity of the boiler water W1 is low, it becomes difficult for the water level detection device 5 to detect the water level of the boiler water W1, the fluctuation of the boiler water W1 becomes severe, and the water level control of the boiler water W1. Can not work well.

    Implementation Example 4 is a case where borax (borax pentahydrate) is used as a pH adjuster at a concentration of 3 mg / L with respect to boiler feed water W2. In this implementation study example, the pH value of the boiler water W1 is 9.2, the electrical conductivity of the boiler water W1 is 6.9 mS / m, and the pH value of the condensate is 7 to 7.5. . In the case of this implementation study example, the pH and electrical conductivity of the boiler water W1 can be increased without causing corrosion caused by the pH adjusting agent or water pollution due to the blow drainage W3. In this case, the pH value of the boiler water W1 is slightly low, but when corrosion prevention based on the pH is insufficient, sodium phosphate, volatile amine, or the like may be mixed and used within the range of drainage regulations. be able to.

DESCRIPTION OF SYMBOLS 1 Boiler can body 2 Steam separator 3 Water supply line 4 Blow down line 5 Water level detection device 6 Water level control device 7 Chemical injection device 7A pH dispensing device 7B Oxygen scavenger injection device 50A, 50B, 50C Electrode rod A Boiler device P pH adjuster Q Oxygen scavenger S Steam W1 Boiler water W2 Boiler feed water W3 Blow drainage

Claims (6)

The boiler water level is a boiler water pH adjuster used as an agent for adjusting the pH of the boiler water and maintaining electric conductivity in the boiler detected by the electrode rod method,
A boiler water pH adjuster, wherein the chemical for maintaining the electrical conductivity of the boiler water contains a boron-based compound.   The boiler water pH adjuster according to claim 1, wherein the boron-based compound is borax. The boiler water level is detected by the electrode rod method, and the boiler operation method uses a chemical for pH adjustment and electrical conductivity maintenance of the boiler water as a pH adjuster,
A boiler operating method, wherein a boron-based compound is used as the chemical for maintaining the electrical conductivity of the boiler water.   The boiler operation method according to claim 3, wherein the boron-based compound is borax.   The method for operating a boiler according to claim 3 or 4, wherein treated water having an electrical conductivity of 1 mS / m or less is used for water supply to the boiler. When the pH adjuster is a mixed drug of the boron compound and sodium phosphate having a molar ratio of Na and PO ₄ of 2.6 to 3.0, the sodium phosphate is phosphoric acid in boiler water. The boiler operation method according to claim 4, wherein the ion concentration is 10 mg / L or less.

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