UA113583U - Sweets with high content of protein ingredients - Google Patents

Abstract

Candy with a high content of protein ingredients, consisting of sugar, starch molasses, foaming agent, flavoring. As sugar, the mass contains glucose and fructose, as the foaming agent contains whey protein concentrate, and additionally gelatin, milk powder or cocoa powder.

Description

consumption, termination after the end of the specified time of supplying the nitric acid solution, setting the specified flow of washing water through the cationite filter, termination of post-regeneration washing of the cationite filter, reset after each cycle of regeneration and washing of each regeneration and washing solution for further processing and hydraulic discharge after the last cycle of regeneration and washing of spent cationite, in accordance with the technical solution that is claimed, after the last cycle of regeneration and washing of spent radioactive cationite, before hydraulic discharge of washed spent radioactive cationite, an acidic solution of nitrate of a multivalent metal from the group: Mp», Res», Az» is passed through the working volume of the cationite filter . of regulatory control, i.e. unlimited burial and unlimited reuse, the generated regeneration radioactive solution is neutralized with an alkaline solution from the group: Maon, Kon, Ca(OH)»: or regenerates of anion exchange filters, preferably Maon or regenerates of anion exchange filters, generated as a result of neutralization with an alkaline solution radioactive the suspension is served for solidification.

HK

Fltv | Oh! o p more o et more Shi panii eZAYA

The invention belongs to the field of removal of radioactive cations from the process water of nuclear power plants using cationite filters, in particular to the regeneration of cation exchange resins, and can be used for the deactivation of spent filter materials in the form of cationites used at nuclear power plants and in other industries that deal with solutions radioactive cations.

There is a known method of regenerating cationites (see, for example, the description of the invention to the patent of the Russian Federation KO 2026825 C1, IPC 6 СО2Е1/42, VO 149/00. Method of regenerating cationites dated 09.07.1992). A known method of regeneration of the cationite spent in the process of hydrogen-cationization of water includes a two-part regeneration with a sulfuric acid solution when using as a second portion a hardened acid solution, washing the cationite, filtering the spent regeneration solution and washing water through anionite with subsequent desorption of sulfuric acid from the anionite with water and using of the obtained acid solution for the regeneration of the cationite, while desorption of the acid is carried out at a volume ratio of water and anions of 6...12:1, respectively, and to obtain the first portion of the regeneration solution, 60...80 wt. 95 from the total volume of water, to obtain the second portion - 3...18 wt. 95 from the total volume of water with subsequent strengthening of the specified portion to a sulfuric acid concentration of 4...9 wt. byu, and the rest of the total volume of water that has passed through the anionite is used as the washing water of the cationite.

There is also a known method of regenerating ionic filters of radioactive waste treatment plants of a nuclear power plant (see, for example, the description of the invention to the author's certificate 5 1762666 JSC, IPC 6 C21E9/12 dated 02.11.1990). This method belongs to the field of radioactive waste processing techniques and includes preliminary purification of cationite radionuclides by passing through it a solution of acidic sodium salt of a strong mineral acid with a total concentration of sodium and hydrogen ions of 10...100 g/l and purification of the resulting solution from radionuclides on a ferrocyanide sorbent and further processing of cationite and anionite, respectively, with acidic and alkaline regeneration solutions. A solution of acidic sodium salt of a strong mineral acid can be obtained by displacing spent alkaline and acidic regeneration solutions.

Disadvantages of the known methods of regeneration of cations are a large nomenclature of radioactive waste arising in the form of radioactive solutions and radioactive spent

From filter materials, as well as high financial costs due to the temporary storage of spent radioactive cation exchange resins in temporary storage containers for RRV.

During the regeneration of cationites with acid solutions, even at high concentrations of hydrogen and/or sodium cations (up to 100 g/l), radioactive and non-radioactive cations of divalent metals, whose chemical potential in the cationite is higher than the chemical potential of hydrogen and/or sodium cations, remain undisplaced in the cation exchange resin in the regenerating solution. As a result of repeated cycles of regeneration and washing, the ion exchange capacity of the cationite due to residual (not displaced by hydrogen and/or sodium cations) radioactive and non-radioactive divalent cations decreases to the limit value at which the cationite passes into the discharge of the spent filter material. After the last regeneration and washing, the spent radioactive cationite, containing radioactive and non-radioactive cations, is discharged into the temporary storage capacity of RRV. When applying the known methods of cationite regeneration, two types of radioactive residues are formed: a radioactive solution containing radionuclides, mainly in the form of monovalent cesium cations, which is formed every time during the cationite regeneration process, and radioactive spent cationite, containing radionuclides, mainly in the form of divalent cations cobalt, strontium, manganese, etc., formed during the last regeneration of the cationite. Thus, the use of known methods of cationite regeneration leads to an increase in the range of radioactive waste generated at NPPs, on the one hand, and to increased financial costs for temporary storage of spent cationites, on the other hand.

The closest technical solution chosen as a prototype for the proposed method of regeneration of spent ABS cation-exchange resins with deactivation by mixing is a method of wastewater treatment (see, for example, Instructions for the operation of the wastewater treatment system. 10.ХЦ.ТАК.ИЕ. 09 Zh. // Ministry of Fuel and Energy of Ukraine.

State enterprise "National Atomic Energy Generating Company "Energoatom". VP

Zaporizhzhia NPP. Chemical shop. - 2007). A well-known method of wastewater treatment includes the reception and preliminary treatment of wastewater, purification of wastewater at the evaporation unit and the distillate purification unit, the release of the cubic residue, acid-alkaline washing of the evaporator, acid washing of the condenser-degasser, loosening and washing of cationic and anionite filters, regeneration cationic and anionic filters.

Reception and pre-treatment of rainwater is carried out continuously or periodically, depending on the arrival of rainwater. In the mode of normal operation of the system, trapped water from the sump tank is pumped by pumps into the sump tank. Trapped water enters the decantation tank by gravity from the sedimentation tank. From the tank of the decanter, the tap water is pumped by pumps through the pre-cleaning filters into the tap tanks. The filtered water is sent to one of three tanks, in one of which (when the tank is full) the hydrogen pH is determined and, if necessary, the pH is adjusted from 11.0 to 11.5 units. The pH is adjusted with sodium hydroxide solution. When processing trap water containing ammonia compounds, pH adjustment is carried out taking into account the evaporation of ammonia during the evaporation process, as a result of which the true value of pH in the evaporator may be significantly lower than after correction in the trap water tanks. Next, the clarified trapped water is pumped into the circulation pipe of the evaporator.

Purification of trapped water in the evaporation unit and the distillate aftertreatment unit is carried out as follows. Through the regulating valve, pre-purified tap water is fed into the circulation pipe of the evaporator. Normal operation of the evaporator is ensured by: continuous removal of secondary steam from the evaporator to the condenser-degasser; continuous supply of heating steam to the evaporative apparatus; continuous removal of heating steam condensate from the evaporator; continuous supply of phlegm to the evaporative apparatus; continuous flow of part of the evaporated solution from the evaporator to the re-evaporator. Normal operation of the co-evaporator is ensured by: continuous removal of secondary steam from the co-evaporator to the separator of the evaporator; continuous supply of heating steam to the co-evaporator; continuous removal of heating steam condensate from the re-evaporator; continuous supply of salt concentrate from the evaporator. Normal operation of the condenser-degasser is ensured by: continuous supply of secondary steam from the evaporator; continuous supply and discharge of cooling water; continuous discharge of gases into the blow-off dephlegmator; continuous removal of degassed distillate from the condenser-degasser. The normal operation of the blow-off dephlegmator is ensured by: continuous supply and discharge of cooling water; continuous removal of cooled gases to the system of gas blowers; continuous drainage of condensate. After the condenser-degasser, the distillate is fed by pumps to mechanical filters and then to one of the control tanks. Refinement of the distillate from the control tanks is carried out by passing it through ion exchange filters. The unit of evaporation and ion-exchange purification is included in the work as water accumulates in the tanks of clarified trapped water.

Loosening by washing the filter material of cationic and/or anionic filters is carried out in the presence of one of the following factors: new filter material is loaded into the filter; the pressure drop is more than 1.0 kgf/cm; before regeneration of cationic and/or anionic filters.

The procedure for regeneration and washing of the cationic filter includes the following sequence of operations: drawing up a scheme for supplying washing water from the tank of own needs through the nitric acid mixer and the cationic filter to the tank of trapped water; removal of air from the cationic filter; setting the specified flow of washing water per filter; supplying a concentrated solution of nitric acid to the mixer with a specified flow rate; after the end of the specified time, stopping the supply of the nitric acid solution and disassembling the supply scheme of the concentrated nitric acid solution; setting the specified flow rate of washing water through a cationic filter; carrying out analyzes of samples after the cationite filter for pH, Ma: and acidity after one hour of washing and then every 15 minutes; termination of post-regeneration washing if it is necessary to carry out regeneration of the anionite filter upon reaching acidity after the cationite filter of 500 μg-eq/l or if there is no need to carry out regeneration of the anionite filter until the following analyzes are obtained after the filter: hydrogen pH indicator - not less than 4.5 units, mass concentration of Ma" - no more than 0.1 mg/l, acidity - no more than 100 μg-eq/l.

Regeneration of the anionite filter is carried out in the presence of one of the following factors: a new filter material, which is in salt form, is loaded into the filter; the hydrogen pH indicator after the anionite filter would be less than b units; the mass concentration of SI after the anionic filter is more than 0.05 mg/l.

The procedure for regeneration and washing of anionite filters includes the following sequence of operations: drawing up a scheme for supplying washing water from the self-needs tank through the mixer and anionite filter to the trap water tank; removing air from the anionite filter and setting the specified flow of washing water per filter; feeding a concentrated solution of sodium hydroxide to the mixer at a given rate; termination after the end of the specified time of passing the sodium hydroxide solution of the specified concentration and disassembling the scheme for supplying the concentrated sodium hydroxide solution; setting the specified flow of washing water through an anionic filter; carrying out after one hour of washing and further every 15 minutes the analysis of samples after the anionite filter for the hydrogen indicator of pH, mass concentration of Ma", SI and alkalinity; stopping washing when the alkalinity after the anionite filter reaches 500 μg-eq/l; collecting the washing water supply scheme from the tank of own needs through the nitric acid mixer and successively through the cationite filter with a specified flow of washing water; washing to obtain the following analyzes after the cationite and anionite filters: after the cationite filter, the hydrogen pH indicator is not less than 4.5 units, the mass concentration of Ma" is not more than 0 ,1 mg/l, acidity no more than 100 μg-eq/l and after the anionite filter, the hydrogen pH indicator is no more than 8.2 units, the mass concentration of Ma" is no more than 0.1 mg/l, the mass concentration of SI- is no more than 0, 05 mg/l, alkalinity no more than 100 μg/l, end of washing and disassembly of the washing scheme.

Hydraulic unloading of the filter material is carried out after the end of the service life of the material or according to the results of the analysis of the operation of the filters, as well as if it is necessary to repair the lower distribution system of the filter. Hydrodischarge of filter material into the capacity of filter materials includes the following sequence of operations: drawing up a scheme for receiving the sorbent into the capacity of filter materials of low-activity or high-activity sorbents; setting the specified flow rate of washing water; periodic monitoring of the discharge of sorbent through filter air vents; completion of hydraulic discharge of filter material within 2 hours; drainage of residual water into a special sewer.

The procedure for loading the filter material includes the following sequence of operations: preparation of the filter material in the given volume; loading the appropriate amount of filter material into the filter through the hatch or through the loading nozzle in the upper part of the filter; measurement of the level of filter material in the filter; sealing of the filter hatch; filling the filter with water and checking the filter seal. After loading the filter with new filter material, the filter is filled with washing water to swell the sorbent within 16-24 hours. After that, loosening is carried out by washing the filter material and its regeneration, while the regeneration time is passed

The solutions are doubled.

The essential features of the selected prototype (a method of regenerating ionite filters of radioactive waste treatment plants of a nuclear power plant), which coincide with the claimed method of regenerating spent ABS cation exchange resins with deactivation by displacement, are: - regeneration and washing of the cationite filter by: - feeding into the working environment tank of a cationic filter of a nitric acid solution with a given flow, - after the end of a given time, stopping the feeding of a nitric acid solution, - setting a given flow of washing water through a cationic filter, - stopping the post-regeneration washing of the cationic filter, - resetting after each cycle of regeneration and washing of each regeneration and washing solution for further processing, - hydraulic unloading after the last cycle of regeneration and washing of spent cationite.

The essential features of the claimed method of regeneration of spent cation-exchange resins of nuclear power plants with deactivation by displacement, which differ from the method of regeneration of ionite filters of radioactive waste treatment plants of a nuclear power plant, are: - passing after the last cycle of regeneration and washing of spent radioactive cationite before hydraulic discharge of washed spent radioactive cationite through the working volume of the cationic filter of an acidic solution of nitrate of a multivalent metal from the group: Mp3», Eez», AIVya, Tit, Mp», mainly Rez», AIZ», of a given concentration and with a given flow to obtain a regeneration solution at the outlet of the cationite filter with a specific level of activity that ensures its release from regulatory control, that is, unlimited burial and unlimited reuse, - neutralization of the generated regenerative radioactive solution with an alkaline solution from the group: Maon, KOH, Ca(OH)" or regenerates of anion exchange filters, important mAon, regenerate anion exchange filters, - feeding the radioactive suspension formed as a result of neutralization with an alkaline solution for solidification.

The invention is based on the task of removing radioactive components from radioactive spent cation exchange resins by displacing them with deactivating solutions with a chemical potential of dissolved cations greater than the chemical potential of radionuclides in the solid phase of cationites, to ensure deactivation of spent cationites to a specific level of activity, which provides freedom from regulatory control, that is, unlimited burial and unlimited reuse.

The expected technical result of the claimed technical solution (method of regeneration of spent NPP cation-exchange resins with deactivation by displacement) is a reduction in the amount of solid waste produced during the regeneration of NPP cation-exchange resins with deactivation by displacement. Due to the decrease in the volume of RRV, the costs for the temporary storage of spent cationites are reduced.

The task is solved by the fact that in the method of regeneration of spent cation exchange resins of nuclear power plants with deactivation by displacement, which includes regeneration and washing of the cationite filter by: feeding a nitric acid solution into the working volume of the cationite filter at a specified rate, stopping after the specified time the supply of the nitric acid solution , setting the specified flow rate of washing water through the cationite filter, stopping the post-regeneration washing of the cationite filter, discharging after each cycle of regeneration and washing each regeneration and washing solution for further processing and hydraulic discharge after the last cycle of regeneration and washing of spent cationite, in accordance with the technical solution that is applied for, - after the last cycle of regeneration and washing of the spent radioactive cationite, before the hydraulic discharge of the washed spent radioactive cationite, an acidic solution is passed through the working volume of the cationite filter of nitrate of a multivalent metal from the group: Mpz:, Rez, AB, Ti, Mp", mainly, Rez", A", of a given concentration and with a given flow to obtain a regeneration solution with a specific level of activity at the exit from the cationite filter, which ensures the release it from regulatory control, i.e. unlimited burial and unlimited reuse, - the generated regenerative radioactive solution is neutralized with an alkaline solution from the group:

Mmaon, con, Ca(OnH)": or regenerates of anion exchange filters, preferably, Maon, regenerates

From anion-exchange filters, the radioactive suspension formed as a result of neutralization with an alkaline solution is submitted for solidification.

The essence of the proposed technical solution (method of regeneration of spent NPP cation exchange resins with deactivation by displacement) is as follows.

When passing after the last cycle of regeneration and washing of the spent radioactive cationite before hydrodischarge of the washed spent radioactive cationite through the working volume of the cationite filter, an acidic solution of nitrate of a multivalent metal from the group: Mp3», Res», AIZ, Tit, Mp», mainly Res» Az", of a given concentration and with a given flow to obtain at the exit from the cationic filter a regeneration solution with a specific level of activity, which ensures its release from regulatory control, i.e. unlimited burial and unlimited reuse, upon neutralization of the generated regeneration radioactive solution with an alkaline solution from the group: Maon, KOH, Ca(OH)" or regenerates of anion exchange filters, mainly mMon, regenerates of anion exchange filters, when the radioactive suspension formed as a result of neutralization with an alkaline solution is fed for solidification, due to removal from radioactive spent cation exchange resins by displacing them where activating solutions with a chemical potential of dissolved cations greater than the chemical potential of radionuclides in the solid phase of cationites ensure the deactivation of spent cationites to a specific level of activity, which provides freedom from regulatory control, i.e. unlimited burial and unlimited reuse.

Thus, the set of distinctive essential features of the claimed technical solution (method of regeneration of spent cation exchange resins of nuclear power plants with deactivation by displacement) leads to a reduction in the amount of solid waste generated during the regeneration of cation exchange resins of nuclear power plants, and to a reduction in costs for temporary storage of spent cationites, i.e. to the achievement of the specified technical result.

The drawing explains the essence of the invention.

The drawing shows the hardware design of the process of regeneration of spent NPP cation exchange resins with deactivation by displacement. because Conventional designations on the drawing:

DEZR - a solution of nitrate of a multivalent metal, which is introduced into the pore space of the spent cationite to displace univalent and divalent radioactive and non-radioactive cations,

RZAL - radioactive residue in the form of regeneration solutions, neutralized with an alkaline agent, which is discharged for further processing,

H/RK - cationite discharged from a working cationite filter with an activity level that provides exemption from regulatory control, i.e. unlimited burial and unlimited reuse,

FLTR - filter with spent cationite,

THK - a three-way faucet that provides a solution of nitrate of a multivalent metal,

VNT - shut-off valve on the radioactive waste discharge line,

VNT is a shut-off valve on the discharge line of deactivated cationite.

Application of the claimed method of regeneration of spent cation exchange resins

A nuclear power plant with displacement decontamination is explained by the following example of a specific implementation.

Example. After the last cycle of regeneration and washing, the ion exchange capacity of the cationite was 2.65 mg-eq/g, that is, it decreased by 47 95. The average specific activity of the spent cationite, the volume of which was 1.68 m3, was within 1.05... 1.15 Ki/m3. Through the working volume of the filter (FLTR), the pore space of which was 37 95, i.e. 0.621 m3, without unloading the washed spent radioactive cationite, an acidic solution of polyvalent metal nitrate (MMP) was passed for 16 hours, setting the three-way valve (TC) in the position which ensures the submission of DESR. A solution of iron nitrate-3 with a concentration of 8 95 was used as the nitrate of a multivalent metal. The volume of the supplied acidic solution of iron nitrate-3 was 2.712 m3. After 16 hours, the level of specific activity of the spent regeneration solution was 0.215 Ki/m3. Upon reaching such a level of specific radioactivity, the feeding of the iron-3 nitrate solution was stopped. After the end of feeding the iron nitrate-Z3 solution, the obtained regeneration radioactive solution (RZAL) with a volume of 2.712 m" was completely removed for neutralization. The RZAL removed for neutralization had a specific radioactivity of 0.793 Ki/m3.

At the same time, the specific radioactivity of the deactivated cationite was 0.386 Bq/g, which ensured its release from regulatory control, that is, unlimited burial and

Unlimited reuse.

As a result of the deactivation process of spent radioactive cationite, a total radioactive residue was obtained in the form of a radioactive solution with a volume of 2.17 m3 with a specific radioactivity of 0.793 Ki/m3. Further processing of the radioactive regeneration solution (RZAL) removed from the working volume of the FLTR was carried out by neutralization with a sodium hydroxide solution. The resulting radioactive suspension, mainly iron-3 hydroxides with an admixture of divalent metal hydroxides, was sent for solidification.

Claims (1)

FORMULA OF THE INVENTION 40 The method of regeneration of spent cation exchange resins of nuclear power plants with deactivation by displacement, which includes regeneration and washing of the cationite filter by feeding the working volume of the cationite filter with a nitric acid solution at a specified flow rate, stopping after the specified time the supply of the nitric acid solution, setting the specified flow rate of washing water through cationic filter, termination of post-regeneration washing 45 cationite filter, reset after each cycle of regeneration and washing of each regeneration and washing solution for further processing and hydrodischarge after the last cycle of regeneration and washing of spent cationite, which differs in that after the last cycle of regeneration and washing of spent radioactive cationite before hydrodischarge of washed spent radioactive cationite through working 50 volumes of the cationite filter pass an acidic solution of nitrate of a multivalent metal from the group: Mp", Rez", AIZ", Tit, Mp, mainly He", A", of a given concentration and with a given flow rate to obtain a regeneration solution at the exit from the cationite filter with the required level of specific activity, while the generated regenerative radioactive solution is neutralized with an alkaline solution from the group: Mahon, KOH, Ca(OH): or regenerates of anion exchange filters, 55 mainly MaoOnH or regenerates of anion exchange filters, and the radioactive suspension formed as a result of neutralization with an alkaline solution is submitted for solidification. tick Y vlte | about with reAa