Пурпурные несерные бактерии в двухстадийном процессе получения водорода из органических отходов
Диссертация
Второй фактор — суммарная концентрация азотсодержащих веществ, которые могут быть использованы ПНСБ. В случае синтетических сред эта концентрация известна (раздел 2.2.3) и легко регулируется. В случае ФЖ в состав могут входить ионы аммония и другие азотсодержащие вещества, которые сложно анализировать. При этом трудно предсказать, будут ли они усваиваться ПНСБ и ингибировать выделение водорода… Читать ещё >
Содержание
- СОКРАЩЕНИЯ ОБЗОР ЛИТЕРАТУРЫ
- ГЛАВА 1. ПОЛУЧЕНИЕ ВОДОРОДА БИОЛОГИЧЕСКИМ ПУТЕМ
- 1. 1. Одностадийные биологические методы получения водорода
- 1. 2. Возможные схемы интеграции биологических процессов для получения водорода и электрического тока
- 1. 2. 1. Получение водорода различными биологическими путями и его преобразование в электрический ток ферментным электродом ]
- 1. 2. 2. Совмещение брожения и МТЭ с выделением водорода на обеих стадиях
- 1. 2. 3. Интеграция фотоавтотрофного накопления биомассы и ее двухстадийного разложения ^ д
- 1. 2. 4. Совмещение фотосинтетического накопления и темнового сбраживания углеводов микроводорослями и фотогетеророфного выделения водорода из продуктов брожения
- 1. 2. 5. Интегрированные системы для повышения эффективности улавливания энергии света 2/
- 1. 2. 6. Интеграция процессов получения водорода за счет фотоферментации и гетеротрофного брожения
- 2. 1. Гетеротрофные бактерии как компонент двухстадийной системы
- 2. 1. 1. Метаболические пути и эффективность получения водорода с помощью гетеротрофных бактерий
- 2. 1. 2. Использование различных субстратов и органических сточных вод (органических отходов) для получения водорода
- 2. 2. Пурпурные несерные бактерии как компонент двухстадийной системы
- 2. 2. 1. Фотосинтетический аппарат ПНСБ
- 2. 2. 2. Нитрогеназный комплекс, гидрогеназы и выделение водорода ПНСБ
- 2. 2. 3. Получение водорода с помощью ПНСБ
- 2. 2. 4. Получение бактериохлорофилла, а из биомассы ПНСБ
- 2. 2. 5. Иммобилизация как путь оптимизации выделения водорода пурпурными несерными бактериями $$
- 2. 3. Способы объединения процессов получения водорода за счет фототрофного и гетеротрофного брожения
- 2. 3. 1. Совместные (смешанные) культуры для получения водорода
- 2. 3. 2. Постадийное культивирование
- 2. 3. 3. Одновременное культивирование в разделенных объемах
- 3. 1. Объекты исследований и питательные среды
- 3. 1. 1. Анаэробный клостридиальный консорциум
- 3. 1. 2. Пурпурные несерные бактерии
- 3. 1. 3. Подготовка ферментационной жидкости (ФЖ) в качестве среды для ПНСБ
- 3. 2. Выделение водорода суспензиями пурпурных бактерий в кратковременных и продолжительных экспериментах
- 3. 2. 1. Кратковременные эксперименты
- 3. 2. 2. Продолжительные эксперименты
- 3. 3. Выращивание биомассы ПНСБ богатой бактериолорофиллом а
- 3. 4. Выделение водорода иммобилизованными пурпурными бактериями
- 3. 4. 1. Матрица для иммобилизации и ее активация
- 3. 4. 2. Конструкция фотобиореакторов для иммобилизованных культур (имм-ФБР), процедура иммобилизации и условия культивирования
- 3. 4. 3. Оценка колонизации матриц в процессе работы ФБР
- 3. 5. Выделение водорода в совмещенном двухстадийном реакторе
- 3. 6. Методы биохимических анализов
- 3. 7. Прочие методы
- 3. 8. Методы расчетов и характеристика используемых величин 60 РЕЗУЛЬТАТЫ И ИХ ОБСУЖДЕНИЕ
- 4. 1. Влияние органических кислот
- 4. 1. 1. Влияние органических кислот и их концентраций
- 4. 1. 2. Особенности потребления органических кислот из их смеси
- 4. 2. Влияние прочих возможных продуктов брожения (спирты, ацетон, Н2, С02)
- 4. 3. Влияние ингибиторов метаногенеза и фосфатов
- 4. 4. Влияние источников азота, оптимальных для темновой ферментации
- 5. 1. Использование продуктов темновой ферментации картофеля
- 5. 1. 1. Выделение водорода при разведении ФЖ
- 5. 1. 2. Доля потребления и эффективность преобразования органических кислот в водород $$
- 5. 2. Использование отходов спиртовой промышленности (барды)
- 5. 2. 1. Выделение водорода и накопление бактериохлорофилла, а при разбавлении ферментированной барды, влияние неорганических добавок
- 5. 2. 2. Масштабирование процесса с целью получения водорода
- 5. 2. 3. Получение биомассы ПНСБ, богатой Бхл а, в фотогетеротрофных условиях без получения водорода
- 5. 2. 4. Сравнительная характеристика методов очистки ферментированной барды с помощью
- 6. 1. Иммобилизация пурпурных бактерий
- 6. 2. Характеристики выделения водорода иммобилизованной культурой МойоЬааег $р1шего1(1е$ вЬ при использовании синтетической среды
- 6. 3. Использование ферментационных жидкостей и барды в проточном реакторе с иммобилизованной культурой ЯЬа. ъркаегоЬЛез СЬ ЮЗ
- 6. 3. 1. Использование крахмальных ФЖ ?
- 6. 3. 2. Использование картофельной ФЖ
- 6. 3. 3. Использование барды ¡-д^
- 6. 4. Способы улучшения очистки ФЖ от органических кислот
- 6. 5. Эффективность выделения водорода с применением суспензий или иммобилизованных культур пурпурных бактерий в двухстадийной системе
- 7. 1. Создание совмещенного двухстадийного реактора
- 7. 2. Диффузия веществ через диализную мембрану в совмещенном биореакторе
- 7. 3. Выделение водорода темновым анаэробным консорциумом
- 7. 4. Выделение водорода и потребление органических кислот из искусственных сред в световом реакторе
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