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Delivery: <= 4 days. True-PDF full-copy in English will be manually translated and delivered via email. HJ 2023-2012: Technical specifications of expanded granular sludge bed(EGSB)reactor for wastewater treatment Status: Valid
Basic dataStandard ID: HJ 2023-2012 (HJ2023-2012)Description (Translated English): Technical specifications of expanded granular sludge bed(EGSB)reactor for wastewater treatment Sector / Industry: Environmental Protection Industry Standard Classification of Chinese Standard: Z23 Word Count Estimation: 19,154 Date of Issue: 12/24/2012 Date of Implementation: 3/1/2013 Quoted Standard: GB 3836; GB 12348; GB 12801; GB 50011; GB 50014; GB 50015; GB 50016; GB 50017; GB 50037; GB 50040; GB 50046; GB 50052; GB 50053; GB 50054; GB 50057; GB 50069; GB 50187; GB 50202; GB 50203; GB 50204; GB 50205; GB 50209; GB 50222; GB 50268; GB 50275; GB/T 1 Regulation (derived from): Ministry of Environmental Protection Notice 2012 No. 72 Issuing agency(ies): Ministry of Ecology and Environment Summary: This standard specifies the process design of anaerobic expanded granular sludge bed reactor wastewater treatment engineering, testing and control, construction and acceptance, operation and maintenance of technical requirements. This standard applies to HJ 2023-2012: Technical specifications of expanded granular sludge bed(EGSB)reactor for wastewater treatment---This is a DRAFT version for illustration, not a final translation. Full copy of true-PDF in English version (including equations, symbols, images, flow-chart, tables, and figures etc.) will be manually/carefully translated upon your order. Technical specifications of expanded granular sludge bed(EGSB)reactor for wastewater treatment National Environmental Protection Standard of the People's Republic Technical specification for wastewater treatment of anaerobic granular sludge expanded bed reactor Technical specifications of expanded granular sludge bed(EGSB) Reactor for wastewater treatment Published on.2012-12-24 2013-3-1 implementation Ministry of Environmental Protection released ContentForeword.ii 1 Scope..1 2 Normative references..1 3 Terms and definitions. 2 4 Design water quantity and design water quality 3 5 General requirements..4 6 Process Design..5 7 Detection and process control 11 8 Major auxiliary projects.12 9 Construction and acceptance..12 10 Operation and maintenance 15 Appendix A (Informative Appendix) Design Load Statistics for Actual Engineering EGSB Reactors.17ForewordStandardize anaerobics for the implementation of the Environmental Protection Law of the People's Republic of China and the Law of the People's Republic of China on Water Pollution Prevention Construction and operation management of granular sludge expanded bed reactor wastewater treatment project, prevention and control of environmental pollution, protection of the environment and human health Kang, the development of this standard. This standard specifies the process design, testing and control, construction and acceptance, and operation of anaerobic granular sludge expanded bed reactor. Technical requirements such as maintenance. This standard is a guiding standard. This standard is the first release. This standard was formulated by the Science and Technology Standards Department of the Ministry of Environmental Protection. This standard is mainly drafted by. China Environmental Protection Industry Association, Tsinghua University, Beijing Municipal Academy of Environmental Sciences, Shandong Shifang Environmental Energy Co., Ltd. This standard was approved by the Ministry of Environmental Protection on December 24,.2012. This standard has been implemented since March 1,.2013. This standard is explained by the Ministry of Environmental Protection. Technical specification for wastewater treatment of anaerobic granular sludge expanded bed reactor1 Scope of applicationThis standard specifies the process design, detection and control, and construction of anaerobic granular sludge expanded bed reactor wastewater treatment project. Technical requirements for acceptance, operation and maintenance. This standard applies to the design, construction and operation of industrial organic wastewater engineering using anaerobic granular sludge expanded bed reactor. Bank management can be used as the technical basis for environmental impact assessment, design, construction, acceptance and operation and management after completion. The design, operation and the like of the internal circulation anaerobic reactor and the anaerobic fluidized bed reactor can be referred to this standard.2 Normative referencesThe contents of this standard refer to the terms in the following documents. For undated references, the valid version applies to this standard. GB 3836 Electrical equipment for explosive gas atmosphere GB 12348 Environmental noise emission standards for industrial enterprises General rules for safety and health requirements of GB 12801 production process GB 50011 seismic design code for buildings GB 50014 Outdoor Drainage Design Code GB 50015 Building Water Supply and Drainage Design Code GB 50016 Building Design Fire Code GB 50017 steel structure design specification GB 50037 Building Ground Design Specification GB 50040 power machine basic design specification GB 50046 industrial building anti-corrosion design specification GB 50052 design specification for power distribution system GB 50053 10kV and below substation design specifications GB 50054 Low Voltage Distribution Design Specification GB 50057 lightning protection design code for buildings GB 50069 Water supply and drainage engineering structure design specification GB 50187 General Plan for Design of Industrial Enterprises GB 50202 Code for construction quality acceptance of building foundation engineering GB 50203 Masonry Construction Quality Acceptance Specification GB 50204 Concrete Structure Engineering Construction Quality Acceptance Specification GB 50205 Steel Structure Engineering Construction Quality Acceptance Specification GB 50209 Construction Ground Engineering Construction Quality Acceptance Specification GB 50222 Building interior decoration design fire protection specification GB 50268 Water supply and drainage pipeline engineering construction and acceptance specifications GB 50275 Compressor, fan, pump installation engineering construction and acceptance specifications GB/T 18883 indoor air quality standard GB J 19 Industrial enterprises heating, ventilation and air conditioning design specifications GB J 22 Factory Mine Road Design Code GB J 87 Industrial Enterprise Noise Control Design Specification GBZ 1 industrial enterprise design hygiene standard GBZ 2 workplace occupational exposure limit CJJ 60 Urban Wastewater Treatment Plant Operation, Maintenance and Safety Technical Regulations HGJ 212 metal welded structure wet gas cabinet construction and acceptance specification HJ/T 91 Surface Water and Wastewater Monitoring Technical Specifications JGJ 80 Safety Specifications for Construction Work Heights NY/T 1220.1 Technical Specifications for Biogas Engineering Part 1. Process Design NY/T 1220.2 Technical Specifications for Biogas Engineering Part 2. Gas Supply Design Measures for Completion and Acceptance of Construction Projects (Engineering) (National Planning Commission (1990) No. 1215) Measures for the Administration of Environmental Protection Acceptance for Completion of Construction Projects (Order of the State Environmental Protection Administration (2001) No. 13)3 Terms and definitionsThe following terms and definitions apply to this standard. 3.1 anaerobic granular sludge expanded bed reactor expanded granular sludge blanket reactor (referred to as EGSB reactor) Refers to the combination of gas, liquid and solid three-phase separation zones in the bottom sludge zone and the middle and upper sections, through reflow and structural design. The effluent reactor has a higher ascending flow rate in the reactor, and the granular sludge inside the reactor is in an expanded state of anaerobic reactor. 3.2 outer loop external the circle Refers to a cycle that will be boosted by the power of the effluent from the top three-phase separator and mixed with the incoming water. 3.3 inner loop internal the circle Refers to a cycle in which the effluent that has not passed through the top three-phase separator is boosted by power and mixed with the incoming water.4 Design water quantity and design water quality4.1 Design water quantity 4.1.1 The designed water volume shall be designed according to the actual wastewater flow measured at the total discharge of the plant or industrial park. Test method should be consistent HJ/T 91 regulations. 4.1.2 The change of wastewater flow rate should be measured according to the characteristics of the process, and the flow coefficient of variation should be determined. 4.1.3 When the actual measurement data cannot be obtained, it can be determined by referring to the current national final water consumption conversion, or according to the same The same scale is determined by the analogy of the existing plant drainage data. 4.1.4 Lifting pump house, grille well and grit chamber should be designed according to the highest daily maximum wastewater volume. 4.1.5 The design flow rate of the EGSB reactor and the water delivery facilities such as pumps and pipelines before and after the EGSB reactor should be at the highest level. Mean time wastewater volume design. 4.2 Design water quality 4.2.1 The design water quality should be determined according to the actual measurement data of the industrial wastewater entering the wastewater treatment plant (station), and its determination method and The data processing method shall comply with the provisions of HJ/T 91. When there is no actual measurement data, refer to the emission data analogy of similar factories. determine. 4.2.2 The EGSB reactor water inlet shall meet the following conditions. a) pH should be 6.0 ~ 8.0; b) Normal temperature anaerobic temperature should be 20 °C ~ 25 °C, medium temperature anaerobic temperature should be 35 °C ~ 40 °C, high temperature anaerobic temperature It should be 50 °C ~ 55 °C; c) nutritional combination ratio COD. N. P should be 100 ~ 500. 5. 1; d) the suspended matter content in the EGSB reactor inlet water should be less than.2000 mg/L; e) the ammonia nitrogen concentration should be less than.2000 mg/L; f) the sulfate concentration should be less than 1000 mg/L, the COD/SO42 - ratio should be greater than 10; g) COD concentration should be greater than 1000 mg/L; h) Strictly control the concentration of heavy metals, cyanides, phenols and other substances into the anaerobic reactor. 4.2.3 It is advisable to reduce the toxic substances in the influent (such as heavy metals, cyanides, phenols, etc.) by appropriately increasing the reflux ratio of the effluent. The concentration that mitigates or eliminates its toxic effects. 4.2.4 If the water ingress requirements are not met, appropriate pretreatment measures should be used. 4.2.5 Pollutant removal rate Refer to Table 1 for the removal of contaminants from the EGSB reactor. Table 1 Removal rate of pollutants in EGSB reactor Contaminant Removal rate (%) Chemical Oxygen Demand (COD) 5 Day Biochemical Oxygen Demand (BOD5) Suspended Matter (SS) Easy degradation wastewater 70~90 60~80 30~50 Refractory wastewater 50~70 40~60 20~40 (Note. B/C>0.3 is easy to degrade wastewater; B/C< 0.1 is difficult to degrade wastewater.)5 General requirements5.1 General provisions 5.1.1 EGSB reactor design should comply with the current national standards and technical specifications in addition to the implementation of this standard. set. 5.1.2 Treatment of waste gas, waste water, solid waste and other pollutants generated during the construction and operation of wastewater treatment plants (station) Regulation and discharge shall comply with the provisions of national environmental protection regulations and relevant standards, and shall not cause secondary pollution. 5.1.3 The design and construction of wastewater treatment plants (stations) shall adopt effective sound insulation, noise reduction, greening and other measures to reduce noise. The noise and vibration control design shall comply with the provisions of GB J87 and GB 50040, and the environmental noise emission at the boundary shall comply with GB 12348. It is stipulated that green belts should be built around the wastewater treatment plant (station) and have a certain protective distance. The evaluation is determined. 5.1.4 The wastewater treatment plant (station) shall install an automatic pollutant monitoring system in accordance with national or local environmental protection management requirements. 5.1.5 Wastewater treatment plants (stations) shall set up standardized sewage outlets in accordance with relevant national and local regulations. 5.1.6 Occupational health and labor safety should be highly valued during the design, construction and operation of wastewater treatment plants (stations). Execute the provisions of GBZ 1, GBZ 2 and GB 12801. 5.1.7 The EGSB reactor shall be equipped with safety measures such as protective railings and anti-skid ladders in accordance with relevant regulations, and shall be fireproof and explosion-proof. And prevention work against heat stroke and anti-poisoning. 5.1.8 The EGSB reactor should be sealed to reduce the pollution of the odor to the surrounding environment. The odor concentration should be in accordance with GB/T 18883. Provisions. The EGSB wastewater treatment plant (station) should be equipped with a centralized treatment facility for malodor, which can be chemical deodorization or biological deodorization. 5.2 Plant (station) site selection and general layout 5.2.1 The site and overall layout of the wastewater treatment plant (station) shall comply with the relevant provisions of GB 50014, and the general plan design shall comply with GB 50187. Provisions. 5.2.2 The flood control standard of wastewater treatment plant (station) should not be lower than the urban flood control standard. 5.2.3 When the wastewater treatment plant (station) is constructed in phases, the overall layout and reserved space shall be carried out according to the scale of long-term treatment. Pipe network and Underground structures should be built at one time. 5.2.4 All kinds of pipelines of wastewater treatment plant (station) should be arranged in an integrated manner to avoid mutual interference, easy to clear and maintain, and reasonably clothed Set the override and vent line. 5.2.5 The vertical design of the treatment unit should make full use of the original terrain, as far as possible to achieve earthwork balance and reduce the number of wastewater upgrades. number. 5.3 Project composition 5.3.1 Wastewater treatment plant (station) using EGSB reactor mainly consists of pretreatment, EGSB reactor, subsequent treatment, sludge Storage, biogas purification and utilization system. Subsequent processing generally refers to aerobic treatment and this part is outside the scope of this specification. 5.3.2 EGSB wastewater treatment plant (station) auxiliary engineering includes. power supply and distribution, water supply and drainage, fire protection, HVAC, detection and control Wait.6 Process design6.1 Process The process flow that should be used in a wastewater treatment plant (station) using an EGSB reactor is shown in Figure 1. Influent pretreatment discharge subsequent treatment Biogas purification and utilization EGSB Sludge storage Figure 1 process flow chart 6.2 Pretreatment 6.2.1 Pretreatment includes grid, grit chamber, sedimentation tank, conditioning tank and mixing heating tank or cooling measures. Enter the EGSB reactor sink Water grid pH adjustment nutrient salt dosing Legend. Optional process unit Figure 2 Pretreatment process 6.2.2 Thick and fine grids should be provided as needed. The design of the grille shall comply with the provisions of GB 50014. 6.2.3 When dealing with more sand-containing wastewater such as slaughter and distiller's grains, a grit chamber should be provided. The design of the grit chamber should conform to GB 50014 Provisions. 6.2.4 When treating wastewater containing a large amount of suspended solids such as paper, starch, etc., a sedimentation tank shall be provided. The design of the sedimentation tank should be consistent The provisions of GB 50014. 6.2.5 The adjustment tank should be set. The design of the conditioning tank should meet the following requirements. a) The capacity of the adjustment tank should be determined according to the change curve of the wastewater flow; when there is no flow curve, the capacity of the adjustment tank should be To meet the requirements of water quality and water equalization in the production drainage cycle, the residence time should be 6 h to 12 h; for batch production, wastewater For intermittent discharge, the capacity of the adjustment tank should be set in 1~2 cycles; b) the conditioning tank can also be used as a neutralization tank, and a nutrient salt replenishing device can also be provided therein; c) The mixing facility should be set in the adjustment tank, and the power of the mixer should be 4 W/m3 pool capacity ~ 8 W/m3 pool capacity; d) The slag removal device shall be installed at the outlet end of the adjustment tank, and the sand removal and sludge discharge device shall be installed at the bottom of the tank. 6.2.6 The pH adjustment and dosing device should be located in the dosing room and should be designed to meet the following requirements. a) Adjust and control the pH in the EGSB reactor by adding alkaline or acidic materials. Alkaline substances can be used. Na2CO3, NaHCO3, etc.; acidic substances may be selected from hydrochloric acid; b) The chemical should have a certain storage capacity, the storage time of the acidic substance should be more than 7 days, and the storage time of the alkaline substance should be 15 d or more; c) It is advisable to use a special solvent-dissolving tank and mixing equipment for the dissolution of the drug, and the metering pump should be used for automatic quantitative dosing; d) The pH value should be adjusted in the adjustment tank by adding acidic or alkaline substances. The pH should be finely adjusted to adopt the pipeline mixer and Add acid and alkali pump; e) It is advisable to set up a drug dissolving and dosing device such as nutrient salt (nitrogen, phosphorus, etc.) in the dosing room. 6.2.7 If the temperature of the wastewater does not meet the design temperature requirements, a heating or cooling device shall be provided. The specific requirements are as follows. a) heating method can use outside the pool heating and pool heating, the pool heating should use hot water circulation heating mode; b) The heat exchanger selection shall be based on the characteristics of the wastewater, the temperature of the medium and the temperature of the outlet medium of the heat exchanger. Heat exchanger The heat exchange area should be calculated according to the heat balance, and the calculation result should have a margin of 10% to 20%; c) the heat demand of the heating device is calculated according to formula (1); Dht QQQ = (1) In the formula. Qt--total heat demand, kJ/h; Qh--heat required to heat the wastewater to the design temperature, kJ/h; Qd - the amount of heat required to maintain the reactor temperature, kJ/h. d) It is advisable to use cooling facilities such as cooling pools or cooling towers. 6.3 EGSB reactor 6.3.1 EGSB reactor composition The EGSB reactor is mainly composed of water distribution device, three-phase separator, water collection device, circulation device, sludge device and gas. The liquid separation device is composed. The structure of the EGSB reactor is shown in Figure 3. Three-phase separator Three-phase separator (optional) Sludge bed Water Biogas Draining mud Influent Sludge bed Gas-liquid separator mixing (optional) Heating pool pressurization Figure 3 Schematic diagram of EGSB reactor structure 6.3.2 EGSB reactor cell design 6.3.2.1 The volume of the EGSB reactor should be calculated by the volumetric load method and calculated according to formula (2). SQV × ×= (2) In the formula. V--reactor effective volume, m3; Q--EGSB reactor design flow, m3/d; NV--volume load, kgCOD/(m3·d); SO--Influent organic matter concentration, mgCOD/L. 6.3.2.2 The volumetric load of the reactor shall be determined by test or by reference to similar works. Refer to the appendix in the absence of relevant information. The relevant content of A determines that the volumetric load of the EGSB reactor should be 10 kgCOD/(m3·d) to 30 kgCOD/(m3·d). 6.3.2.3 The number of EGSB reactors should not be less than two, and should be designed in parallel with flexible adjustment. It also facilit......Tips & Frequently Asked Questions:Question 1: How long will the true-PDF of HJ 2023-2012_English be delivered?Answer: Upon your order, we will start to translate HJ 2023-2012_English as soon as possible, and keep you informed of the progress. The lead time is typically 2 ~ 4 working days. 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