An apparatus and system for separating a liquid from a mixed gas stream includes a porous graphite foam support comprising graphite foam with pores having a first pore size and a membrane support surface. A porous condensation membrane layer is provided on the membrane support surface, and interlocked with the pores of the graphite foam. The condensation membrane layer includes capillary condensation pores having a second pore size that is less than the first pore size. A mixed gas stream passageway is in fluid communication with the condensation membrane layer. A liquid collection assembly collects condensed liquid from the condensation pores and the graphite foam support pores. A gas inlet is provided for flowing the mixed gas stream into the mixed gas stream passageway. A gas outlet is provided for exhausting gas from the mixed gas stream passageway. A method for separating a liquid from a mixed gas stream is also disclosed.

An apparatus and system for separating a liquid from a mixed gas stream includes a porous graphite foam support comprising graphite foam with pores having a first pore size and a membrane support surface. A porous condensation membrane layer is provided on the membrane support surface, and interlocked with the pores of the graphite foam. The condensation membrane layer includes capillary condensation pores having a second pore size that is less than the first pore size. A mixed gas stream passageway is in fluid communication with the condensation membrane layer. A liquid collection assembly collects condensed liquid from the condensation pores and the graphite foam support pores. A gas inlet is provided for flowing the mixed gas stream into the mixed gas stream passageway. A gas outlet is provided for exhausting gas from the mixed gas stream passageway. A method for separating a liquid from a mixed gas stream is also disclosed.

[Problem to be Solved]

The present invention provides a system which can detect/check an underground water vein in a specific ground area and detect/check underground water in the underground water vein at a pinpoint.

[Solution]

The present invention has, while two-dimensionally visualizing an underground water vein in a specific ground area, a large number of electrodes group 22 disposed in the specific ground area, a survey point switching unit 23 having two poles in an electrode 22a with four poles in dipole-dipole arrangement in the electrodes group 22 set to potential electrodes, while the other two poles as current electrodes and combining and switching them so as to execute horizontal exploration and underground vertical exploration, measuring means 25 for each survey point of the entire ground area, specific resistance calculating means 31 for each survey point for calculating a specific resistance value at each survey point for each of high and low two frequencies in the horizontal and vertical directions at each survey point of the ground area, and impedance effect is acquired for each survey point on the basis of the calculated specific resistance value for each of the high and low two frequencies at each survey point so that estimation that a survey point position with the impedance effect>1 has an underground water vein can be made and displayed three-dimensionally.

The present invention provides a system for solar and/or rainwater harvesting to be installed in open spaces to store the rainwater or charge ground water level and/or to harvest solar energy. The system for rainwater harvesting to be installed in open spaces, comprising at least one canopy to be installed for capturing rainwater in the open space, having inverted cone-like structure to capture water and at least one discharge opening for outflow of the captured water; a storage unit for storing the captured water; a connecting means extending from the discharge opening of the canopy to the storage unit for allowing flow of the captured water from the canopy to the storage unit; and at least two filtration means adapted between the canopy and the storage unit for filtering the captured water.

The present invention relates to collection of water after being exposed to the moonlight. The water resource for exposure under moonlight over any period of time and the storage of such collected water so obtained from any resource. The water resource collected and composed of but not limited to collection of water from resources like river, spring, rain, snow, well water, tap water, distilled bottled water, that is accumulated. The period during which water is exposed to the moonlight can have a combination of significance but not limited to: zodiac, religious, astronomical, calendar, astrological, numerology etc. Further, the exposed water obtained is packed and labeled based on the religious, astronomical, astrological, numerological significance classified or falling under the time when the water resource or the water stored in the container is exposed to the source of moonlight. The water resource collected and composed of but not limited to collection of water from resources like river, spring, rain, snow, tap water, dew, distilled bottled water, well water that is accumulated or placed.

The cubical support for a foot valve is configured for use with a foot valve. The cubical support for a foot valve is an openwork framework structure. The cubical support for a foot valve elevates the foot valve above the bed of a body of water. The framework structure forms a protected space around the foot valve. The openwork structure allows for the free flow of water. The cubical support for a foot valve comprises a plurality of pipes, a plurality of tee connectors, a plurality of 90-degree elbow tees, and an adhesive. The plurality of tee connectors and the plurality of 90-degree elbow tees assemble the plurality of pipes into the framework structure. The adhesive secures each congruent end of each pipe selected from the plurality of pipes to a fitting selected from the group consisting of the plurality of tee connectors, and the plurality of 90-degree elbow tees.

Tubular segments may be nestably interconnected, with the lower end of one tubular segment inserted into the upper end of another tubular segment. A mat formed of such tubular segments, and a system formed of a plurality of such vertically stacked mats for containing fluids and particulate material, are also disclosed.

Tubular segments may be nestably interconnected, with the lower end of one tubular segment inserted into the upper end of another tubular segment. A mat formed of such tubular segments, and a system formed of a plurality of such vertically stacked mats for containing fluids and particulate material, are also disclosed.

An apparatus and system for separating a liquid from a mixed gas stream includes a porous graphite foam support comprising graphite foam with pores having a first pore size and a membrane support surface. A porous condensation membrane layer is provided on the membrane support surface, and interlocked with the pores of the graphite foam. The condensation membrane layer includes capillary condensation pores having a second pore size that is less than the first pore size. A mixed gas stream passageway is in fluid communication with the condensation membrane layer. A liquid collection assembly collects condensed liquid from the condensation pores and the graphite foam support pores. A gas inlet is provided for flowing the mixed gas stream into the mixed gas stream passageway. A gas outlet is provided for exhausting gas from the mixed gas stream passageway. A method for separating a liquid from a mixed gas stream is also disclosed.

An apparatus and system for separating a liquid from a mixed gas stream includes a porous graphite foam support comprising graphite foam with pores having a first pore size and a membrane support surface. A porous condensation membrane layer is provided on the membrane support surface, and interlocked with the pores of the graphite foam. The condensation membrane layer includes capillary condensation pores having a second pore size that is less than the first pore size. A mixed gas stream passageway is in fluid communication with the condensation membrane layer. A liquid collection assembly collects condensed liquid from the condensation pores and the graphite foam support pores. A gas inlet is provided for flowing the mixed gas stream into the mixed gas stream passageway. A gas outlet is provided for exhausting gas from the mixed gas stream passageway. A method for separating a liquid from a mixed gas stream is also disclosed.