在環(huán)保技術(shù)領(lǐng)域，生物脫硫工藝憑借其綠色、經(jīng)濟的特性，逐漸成為工業(yè)廢氣治理的主流方案。作為該工藝的核心要素，脫硫菌種的活性狀態(tài)與系統(tǒng)穩(wěn)定性息息相關(guān)。菌種是否需要定期更換或補充，以及如何確定補給周期，是保障脫硫效率的關(guān)鍵問題。

　　In the field of environmental protection technology, biological desulfurization process has gradually become the mainstream solution for industrial waste gas treatment due to its green and economical characteristics. As the core element of this process, the activity state of desulfurization bacteria is closely related to system stability. Whether the bacterial strains need to be replaced or replenished regularly, and how to determine the supply cycle, are key issues to ensure desulfurization efficiency.

　　生物脫硫菌種通過代謝活動將硫化物轉(zhuǎn)化為單質(zhì)硫或硫酸鹽，其活性直接決定反應(yīng)速率與轉(zhuǎn)化效率。在連續(xù)運行過程中，菌種會面臨多重挑戰(zhàn)：廢氣中的硫化氫濃度波動可能超出菌種耐受范圍，導(dǎo)致部分菌體失活；重金屬離子、有機溶劑等有毒物質(zhì)會破壞細(xì)胞結(jié)構(gòu)，引發(fā)菌群衰退；溫度、pH值等環(huán)境參數(shù)偏離適宜區(qū)間時，酶活性受到抑制，代謝速率下降。這些因素共同作用，使菌種活性呈現(xiàn)動態(tài)衰減趨勢。

　　Biological desulfurization bacteria convert sulfides into elemental sulfur or sulfate through metabolic activities, and their activity directly determines the reaction rate and conversion efficiency. During continuous operation, bacterial strains will face multiple challenges: fluctuations in hydrogen sulfide concentration in exhaust gas may exceed the strain's tolerance range, leading to partial bacterial inactivation; Toxic substances such as heavy metal ions and organic solvents can damage cell structure and cause bacterial decline; When environmental parameters such as temperature and pH deviate from the appropriate range, enzyme activity is inhibited and metabolic rate decreases. These factors work together to cause a dynamic decline in bacterial activity.

　　菌種補充的必要性源于微生物群落的自然演替規(guī)律。在長期運行中，優(yōu)勢菌種可能因環(huán)境壓力被其他菌屬替代，導(dǎo)致脫硫?qū)Ｒ恍詼p弱。同時，菌體自然死亡形成的生物膜脫落，會降低反應(yīng)器內(nèi)的生物量。當(dāng)出氣硫化氫濃度突破預(yù)警閾值，或壓差傳感器顯示填料層堵塞加劇時，表明菌種活性已不足以維持系統(tǒng)效能。此時需通過鏡檢觀察菌體形態(tài)，結(jié)合活性檢測數(shù)據(jù)，判斷是否需要啟動菌種補給程序。

　　The necessity of supplementing bacterial strains stems from the natural succession laws of microbial communities. In long-term operation, dominant bacterial strains may be replaced by other bacterial genera due to environmental pressure, leading to a decrease in desulfurization specificity. At the same time, the shedding of biofilm formed by the natural death of bacterial cells will reduce the biomass inside the reactor. When the concentration of hydrogen sulfide in the exhaust gas exceeds the warning threshold, or when the pressure difference sensor shows that the blockage of the packing layer is worsening, it indicates that the bacterial activity is no longer sufficient to maintain system efficiency. At this point, it is necessary to observe the morphology of the bacterial cells through microscopic examination, combined with activity detection data, to determine whether the strain supply program needs to be initiated.

　　補給周期的確定需建立動態(tài)監(jiān)測體系。實時監(jiān)測進出口硫化物濃度，計算脫硫效率衰減率，當(dāng)效率下降超過15%時觸發(fā)評估機制。定期采集生物膜樣本，通過平板計數(shù)法測定活菌濃度，結(jié)合ATP生物發(fā)光法評估代謝活性。對于高負(fù)荷工況，建議每3-6個月進行全面菌群分析，采用高通量測序技術(shù)檢測菌種多樣性指數(shù)，當(dāng)優(yōu)勢菌屬相對豐度低于30%時，需制定針對性補給方案。

　　The determination of supply cycle requires the establishment of a dynamic monitoring system. Real time monitoring of import and export sulfide concentration, calculation of desulfurization efficiency attenuation rate, triggering evaluation mechanism when efficiency drops by more than 15%. Regularly collect biofilm samples, measure the concentration of viable bacteria using plate counting method, and evaluate metabolic activity using ATP bioluminescence assay. For high load conditions, it is recommended to conduct a comprehensive microbiota analysis every 3-6 months and use high-throughput sequencing technology to detect the diversity index of bacterial strains. When the relative abundance of dominant bacterial genera is less than 30%, a targeted supply plan needs to be developed.

　　菌種補給策略包含活性復(fù)蘇與定向強化兩種模式。對于因環(huán)境波動導(dǎo)致的暫時性失活，可通過投加營養(yǎng)劑、調(diào)節(jié)pH值等方式恢復(fù)菌種代謝能力。當(dāng)菌群結(jié)構(gòu)發(fā)生根本性改變時，需引入脫硫菌劑進行定向強化。補給量應(yīng)根據(jù)反應(yīng)器容積、菌種濃度衰減幅度確定，通常按生物膜量的5%-10%進行補充，采用多點投加方式確保分布均勻。

　　The strain supply strategy includes two modes: active recovery and targeted reinforcement. For temporary inactivation caused by environmental fluctuations, the metabolic ability of bacterial strains can be restored by adding nutrients, adjusting pH values, and other methods. When the structure of the microbial community undergoes fundamental changes, it is necessary to introduce desulfurizing agents for targeted reinforcement. The supply amount should be determined based on the reactor volume and the attenuation amplitude of bacterial concentration. It is usually supplemented by 5% -10% of the biofilm amount, and a multi-point feeding method is used to ensure uniform distribution.

　　生物脫硫系統(tǒng)的穩(wěn)定運行，依賴于對菌種活性的精準(zhǔn)把控。通過建立包含過程參數(shù)監(jiān)測、菌群結(jié)構(gòu)分析、活性檢測在內(nèi)的綜合評估體系，可科學(xué)制定菌種補給周期與策略。這種動態(tài)管理方式，既能避免過度補給造成的成本浪費，又能防止菌種衰退引發(fā)的系統(tǒng)崩潰，為工業(yè)廢氣生物治理提供可持續(xù)的技術(shù)保障。

　　The stable operation of biological desulfurization systems relies on precise control of bacterial activity. By establishing a comprehensive evaluation system that includes process parameter monitoring, microbial community structure analysis, and activity detection, it is possible to scientifically formulate the supply cycle and strategy of bacterial strains. This dynamic management approach can not only avoid cost waste caused by excessive supply, but also prevent system collapse caused by bacterial decline, providing sustainable technical support for the biological treatment of industrial waste gas.

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