Abstract: A salt cavern flow battery system includes: stack; salt cavern, including n positive salt caverns for storing a positive electrolyte with different valence states separately, and m negative salt caverns for storing a negative electrolyte with different valence states separately; a first closed loop being formed by connecting the positive electrode of the stack and the n positive salt caverns in series through a pipeline; a second closed loop being formed by connecting the negative electrode of the stack and the m negative salt caverns in series through a pipeline; a first pusher being arranged in the first closed loop to push the positive electrolyte to flow cyclically in the first closed loop, a second pusher being arranged in the second closed loop to push the negative electrolyte to flow cyclically in the second closed loop.

Abstract: An apparatus of salt cavern gas storage without cushion gas includes: a salt cavern; sediments; a drainage assembly; a gas injection and production pipe; a debrining string, one end of which is connected to the drainage assembly, and the other end of which protrudes from the ground to be connected to a water source assembly; a communicating assembly, which is used to make the gas injection and production pipe be in communication with the debrining string on the ground. A closed loop is formed by making the gas injection and production pipe and the debrining string be in communication with each other on the ground through the communicating assembly, thus the non-cushion gas injection-production operation of sediment particles in the salt cavern is realized.

Abstract: Salt caverns with an inner container for storing electrical energy as a flow battery are provided. The salt caverns with an inner container for storing electrical energy as a flow battery comprises an air bag, a second pipeline and a first pipeline. The airbag is located in an underground salt cavern, the salt cavern is full of brine, and a liquid electrolyte is stored in the airbag. One end of the second pipeline is connected with the airbag while the other end thereof is located on the ground, and the second pipeline is used for filling the liquid electrolyte into the airbag. The first pipeline sleeves the second pipeline, one end of the first pipeline is connected with a shaft inlet of the salt cavern while the other end thereof is located on the ground, and the first pipeline is used for discharging the brine from the salt cavern.

Abstract: The present disclosure discloses a method for detecting gas-storing performance of solution-mined salt cavern in a high-insoluble salt mine, comprising: detecting water-tightness of the cavern and water-tightness of a wellbore; arranging a gas sealing tubing in a production casing for the wellbore, and arranging a packer; detecting gas-tightness of the wellbore; injecting test gas into the cavern through the gas sealing tubing at a gas-injection well; calculating a volume of a discharged brine; closing the debrining well, and injecting the test gas into the cavern through the gas sealing tubing at the gas-injection well; after a pressure value above a gas-liquid interface in the cavern reaches a set pressure value, closing the gas-injection well; and detecting gas-tightness of the cavern. The method can be used for effectively, accurately and economically detecting the available gas storing space volume and the gas-tightness of the solution-mined salt cavern in salt mine.

Abstract: The disclosure provides a liquid taking device and a liquid taking method. The liquid taking device comprises a liquid taking bottle, a heavy ball and liquid taking ropes. The liquid taking bottle has a first mouth and a bottom opposite to the first mouth. The heavy ball is arranged in the liquid taking bottle. The liquid taking device can be controlled to reach different depths under the ground by the action of two liquid ropes. When the first mouth of the bottle is placed facing downward, the heavy ball blocks the first mouth of the bottle under its own gravity to prevent liquid leakage; when the first mouth of the bottle is turned upwards under the action of the liquid taking rope, the heavy ball falls onto the bottom of the bottle, such that an external liquid can flow into the liquid taking device, which has a good practical utility.

Abstract: The disclosure relates to sewage treatment, and more particularly to a method and a system for treating molybdenum-containing sewage in molybdenum ore area. In the method, the molybdenum-containing sewage is preliminarily treated in the preliminary precipitation tank to allow the impurities to settle, and then the supernatant sequentially flows into the reaction system and the filtration system for filtration. The effluent discharged from the filtration system has a molybdenum content less than 1.5 mg/L.

Abstract: The present invention relates to salt caverns with an inner container for storing electrical energy as a flow battery. The salt caverns with a inner container for storing electrical energy as a flow battery comprises an air bag, a second pipeline and a first pipeline. The airbag is located in an underground salt cavern, the salt cavern is full of brine, and a liquid electrolyte is stored in the airbag. One end of the second pipeline is connected with the airbag while the other end thereof is located on the ground, and the second pipeline is used for filling the liquid electrolyte into the airbag. The first pipeline sleeves the second pipeline, one end of the first pipeline is connected with a shaft inlet of the salt cavern while the other end thereof is located on the ground, and the first pipeline is used for discharging the brine from the salt cavern.

Abstract: The disclosure provides a liquid taking device and a liquid taking method. The liquid taking device comprises a liquid taking bottle, a heavy ball and liquid taking ropes. The liquid taking bottle has a first mouth and a bottom opposite to the first mouth. The heavy ball is arranged in the liquid taking bottle. The liquid taking device can be controlled to reach different depths under the ground by the action of two liquid ropes. When the first mouth of the bottle is placed facing downward, the heavy ball blocks the first mouth of the bottle under its own gravity to prevent liquid leakage; when the first mouth of the bottle is turned upwards under the action of the liquid taking rope, the heavy ball falls onto the bottom of the bottle, such that an external liquid can flow into the liquid taking device, which has a good practical utility.

Abstract: The present invention discloses a device, system and method triaxial compression test with/without jacket by gas confining pressure on rock, and belongs to the technical field of rock mechanics tests. The device includes a container, wherein an accommodating cavity is disposed in the container for placing a core sample, a first through hole and a second through hole are respectively disposed at an upper end of the container, the first through hole is used for penetration of an end cap for loading an axial pressure to the core sample, the second through hole is used for injecting a gas into the accommodating cavity so as to apply a gas confining pressure on the core sample, a third through hole is disposed at a lower end of a side wall of the container, and the third through hole is used for communicating the accommodating cavity with the triaxial cell so as to achieve pressure transfer and balance between the accommodating cavity and the triaxial cell.

Abstract: The present invention discloses a device, system and method triaxial compression test with/without jacket by gas confining pressure on rock, and belongs to the technical field of rock mechanics tests. The device includes a container, wherein an accommodating cavity is disposed in the container for placing a core sample, a first through hole and a second through hole are respectively disposed at an upper end of the container, the first through hole is used for penetration of an end cap for loading an axial pressure to the core sample, the second through hole is used for injecting a gas into the accommodating cavity so as to apply a gas confining pressure on the core sample, a third through hole is disposed at a lower end of a side wall of the container, and the third through hole is used for communicating the accommodating cavity with the triaxial cell so as to achieve pressure transfer and balance between the accommodating cavity and the triaxial cell.