RU98119083A - FLUORESCENT-SPECIFIED POLYMERS FOR INTERNAL CLEANING OF A BOILER - Google Patents

Claims (24)

1. A method for determining the concentration of an anionically charged water-soluble polymer for purifying boiler water in a boiler water system, where there is a source of feed water to the system as a first parameter of the system, a source of discharge from the system as a second parameter of the system, and also a source of soluble polymer in the boiler water as the third parameter of the system, and in which the soluble polymer is subjected to a hydrothermal reaction under the operating conditions of the boiler water system, and the soluble polymer contains t at least 0.01% of the monomer units of spectrophotometrically emitting residues associated with the polymer chain, the method comprising the steps of: a. measuring at least one spectrophotometric characteristic of the soluble polymer contained in the sample of boiler water; in. converting the characteristic into an electrical signal corresponding to the concentration of soluble polymer in the boiler water; with. comparing the electrical signal corresponding to the concentration of soluble polymer in the boiler water with the electrical signal corresponding to the required concentration of soluble polymer in the boiler water; and then d. determining the growth or loss of soluble polymer in boiler water.  2. The method according to claim 1, in which a sample of boiler water containing a soluble polymer is continuously passed through a flow measuring cell with continuous measurement of the spectrophotometric characteristics of the polymer, as a result of which the growth or loss of soluble polymer in the system is continuously determined.  3. The method according to claim 1, which, when the comparison in stage (d) shows the increase or loss of soluble polymer, further includes changing at least one of the system parameters: the flow rate of the feed water into the boiler water system, the discharge flow rate flow from the boiler water system and the rate at which the soluble polymer is introduced into the feed water stream of the boiler water system, as a result of which the required concentration of soluble polymer is maintained in the boiler water.  4. The method according to claim 1, in which at least one of the spectrophotometrically emitting residues of the soluble polymer is a styrenesulfonate group.  5. The method of claim 1, wherein the soluble polymer comprises carboxylate-containing monomer units selected from the group consisting of acrylic acid, methacrylic acid, crotonic acid, vinylacetic acid, 4-methyl-4-pentenoic acid, maleic acid, and itaconic acid.  6. The method according to claim 1, in which the soluble polymer contains carboxylate-containing monomer units selected from the group consisting of sodium vinyl sulfonate, vinyl phosphonic acid, isopropenyl phosphate, allyl polyesters, 2-acrylamido-2-methylpropanesulfonic acid, allyl sulfonic acid, allyl hydroxyethylate, allyl hydroxyethylate, allyl hydroxyethylate, hydroxy vinylimidazole, 2-vinylpyrrolidine, 4-vinylpyridine and vinyl acetate.  7. The method according to p. 1, in which the soluble polymer contains at least 10% of the monomer units of acrylic acid or water-soluble salts of acrylic acid.  8. The method of claim 1, wherein the spectrophotometrically perceived characteristic is a fluorescent characteristic.  9. The method of claim 1, wherein the electrical signal corresponding to the concentration of the soluble polymer is continuously compared with the electrical signal corresponding to the required concentration of the soluble polymer.  10. The method of claim 1, wherein the electrical signal corresponding to the concentration of the soluble polymer is periodically compared with the electrical signal corresponding to the required concentration of the soluble polymer.  11. A method for determining the gain or loss and the introduced amount of anionically charged water-soluble polymer for purifying boiler water in a boiler water system, where there is a source of feed water to the system as a first parameter of the system, a source of discharge from the system as a second parameter of the system, and a source of soluble polymer in boiler water as the third parameter of the system, and in which the soluble polymer undergoes a hydrothermal reaction under the operating conditions of the boiler water system us, and the soluble polymer contains at least 0.01% monomer units of spectrophotometrically emitting residues linked to the polymer chain, the method comprising the steps of: a. introducing a substantially inert indicator that is substantially inert to the system in a known ratio to the soluble polymer; in. measuring at least one spectrophotometric characteristic of the soluble polymer and measuring at least one spectrophotometric characteristic of the indicator contained in the sample of boiler water; with. converting each of the characteristics into electrical signals corresponding to the concentration of soluble polymer and the concentration of the indicator, respectively; and d. comparing the electrical signal corresponding to the concentration of the soluble polymer with the electrical signal corresponding to the concentration of the indicator, determining as a result of the increase or loss of the soluble polymer in the system and the amount of dissolved polymer introduced into the system.  12. The method according to claim 11, in which a sample of boiler water containing a soluble polymer is continuously passed through a flow measuring cell with continuous measurement of the spectrophotometric characteristics of the polymer, as a result of which the growth or loss of soluble polymer in the system is continuously determined.  13. The method of claim 11, wherein the alarm is triggered when the comparison in step (d) shows an increase or loss in soluble polymer.  14. The method according to claim 11, which, when the comparison in stage (d) shows the increase or loss of soluble polymer, further includes changing at least one of the system parameters: the flow rate of the supply water to the boiler water system, the discharge flow rate from a boiler water system or a rate at which a soluble polymer is introduced into the boiler water system, whereby the required concentration of soluble polymer is maintained in the boiler water system.  15. The method according to claim 11, in which at least one of the spectrophotometrically emitting residues of the soluble polymer is a styrene sulfonate group.  16. The method according to p. 11, in which the soluble polymer contains at least 10% of the monomer units of acrylic acid or water-soluble salts of acrylic acid.  17. The method of claim 11, wherein the electrical signal corresponding to the concentration of the soluble polymer is continuously compared with the electrical signal corresponding to the concentration of the indicator.  18. The method according to p. 11, in which the electrical signal corresponding to the concentration of soluble polymer is periodically compared with an electrical signal corresponding to the concentration of the indicator.  19. A method for determining boiler concentration cycles in a boiler water system containing an anionically charged water-soluble polymer for purifying boiler water, where there is a source of feed water to the system as a first parameter of the system, a source of discharge flow from the system as a second parameter of the system, and also a source soluble polymer in boiler water as a third parameter of the system, and in which the soluble polymer undergoes a hydrothermal reaction under the operating conditions of the boiler water system, and the soluble polymer contains at least 0.01% of the monomer units of spectrophotometrically emitting residues associated with the polymer chain, the method comprising the steps of: a. introducing a soluble polymer into the feed water stream entering the water boiler system; in. measuring at least one spectrophotometric characteristic of the soluble polymer contained in the sample feed water stream; with. enabling at least a portion of the soluble polymer to undergo a hydrothermal reaction with a transition to the reaction product when the soluble polymer passes through the boiler water system; d. measuring at least one spectrophotometric characteristic of the rest of the soluble polymer and measuring at least one spectrophotometric characteristic of the reaction product contained in the discharge flow sample; e. converting each of the measured characteristics into electrical signals corresponding to the concentration of soluble polymer in the feed water stream, the concentration of the remaining soluble polymer in the waste stream and the concentration of the reaction product with the waste stream, respectively; and f. using the concentration of soluble polymer in the feed water stream, the concentration of the remaining soluble polymer in the waste stream and the concentration of the reaction product in the waste stream to determine the concentration boiler cycles in the boiler system.  20. The method according to p. 19, in which a sample of a feed stream of water containing a soluble polymer is continuously passed through a flow measuring cell with continuous measurement of at least one spectrophotometric characteristic of the soluble polymer, as a result of which boiler concentration cycles in the system are continuously determined.  21. The method according to p. 19, in which the sample discharge stream containing the rest of the soluble polymer and the reaction product is continuously passed through a flow measuring cell with continuous measurement of at least one spectrophotometric characteristic of the remaining soluble polymer and the measurement of at least one spectrophotometric characteristics of the reaction product, as a result of which boiler concentration cycles in the system are continuously determined.  22. The method of spectrophotometric control of the extraction value of soluble polymer in a boiler water system containing an anionically charged water-soluble polymer for treating boiler water, where there is a source of feed water to the system as the first parameter of the system, a source of discharge flow from the system as the second parameter of the system, and also a source of soluble polymer as a third parameter of the system, and in which the soluble polymer passes through the boiler water system under operating conditions oh aqueous system, and the soluble polymer contains at least 0.01% monomer units of spectrophotometrically emitting residues linked to the polymer chain, the method comprising the steps of: a. introducing a soluble polymer into the feed stream of the boiler system; in. enabling at least a portion of the soluble polymer to undergo a hydrothermal reaction with a transition to the reaction product when the soluble polymer passes through the boiler water system; with. measuring at least one spectrophotometric characteristic of the rest of the soluble polymer and at least one spectrophotometric characteristic of the reaction product in the discharge flow sample; d. converting each of the measured characteristics into electrical signals corresponding to the concentration of the remaining soluble polymer in the effluent stream and the concentration of the reaction product in the effluent, respectively; and e. using the concentrations of the remaining soluble polymer in the effluent stream and the concentration of the reaction product in the effluent stream to determine the recovery value of the soluble polymer in the boiler water system.  23. The method according to p. 22, in which a sample of the waste stream containing the remaining soluble polymer and the reaction product is continuously passed through a flow measuring cell with continuous measurement of at least one spectrophotometric characteristic of the remaining soluble polymer and at least one spectrophotometric characteristics of the reaction product, as a result of which the extraction value of the soluble polymer in the boiler water system is continuously determined.  24. The method according to p. 22, in which the value of the extraction of soluble polymer for the boiler water system is used to determine the optimal concentration of soluble polymer necessary for effective cleaning of the boiler water system.