The invention belongs to ecological revetments in the technical field of river ecology, which particularly involves an ecological revetment to regulate wandering rivers. The ecological revetment is composed of porous concrete-piles, ecological connecting-plates, an ecological viewing-corridor and a slope green-belt. The ecological landscape-corridor and anchor rod are placed on the upper and middle parts of the pile structure, respectively. In virtue of the innovative structure, the ecological revetment will strengthen the revetment structure, reduce the revetment settlement, prevent the revetment from moving, and enhance the overall stability of the revetment project. The ecological holes exist on the ecological connecting-plates, which is beneficial to the exchange of material and energy from the river course and the bank slope, and the holes could greatly enhance the self-cleaning capacity of the water body. Not only do the plants on the ecological viewing-corridor provide the habitats for the organisms, but also green the revetment.

A method for watering plants using a self-contained high pressure distribution system with a water reservoir. A mini gear pump is used for pumping water to pressure compensated drip emitters at individual plants. A method for monitoring soil moisture content and programming of individual watering of plants through an energy efficient wireless networking system. The high-pressure water in the plant watering system is used as a communication physical channel for the wireless networking for improving wireless communication range and battery life of wireless terminals. Chip-level Differential Encoding based Spread Spectrum signaling is used for reducing wireless networking solution cost, improving wireless link budget, improving immunity to interference, and increasing battery life of wireless terminals.

A thermally regulated enclosure system which includes apparatuses and methods of making and using a thermally regulated enclosure system, including one or more of a vessel having a bottom aperture element which defines a bottom open area, a top aperture element which defines a top open area, one or more stakes detachably fastenable to the peripheral margin of the bottom aperture element of the vessel, and a closure element adjustable in relation to the top aperture element to increase or decrease the top open area.

A bowl is attached to a drip irrigation system at an emitter, so that the bowl can be filled with water in an automated fashion, using the control timer and solenoid valves of the existing irrigation system. The emitter has a stem and a head. The stem extends through a hole in the sidewall of the bowl so that the head rests against the sidewall of the bowl. Preferably the head is flush with the sidewall of the bowl and forms a water-tight seal with the sidewall of the bowl. Drip irrigation tubing is attached to the stem of the emitter and connected to the drip irrigation system. A through-hole runs through the emitter to permit water to flow from the drip irrigation tubing through the stem and head into the bowl. An in-line valve between the water source and the emitter improves control of the water through the emitter.

A body through which a medium can flow, in particular a body through which a fluid and/or gas can flow, with at least one exterior, wherein the body through which a medium can flow is self-supporting or includes at least one supporting body that provides mechanical stability, as well as a greenery system with at least one greenery element for installation on a surface, including at least one such body through which a medium can flow, in particular a body through which a fluid and/or gas can flow.

A stack planter reservoir retains a volume of water to be pumped through a hydroponic system. The stack planter reservoir includes a reservoir base, a lateral wall, a lid-receiving lip, and a planter-supporting lid. The reservoir base and the later wall define a storage volume for water. The lid-receiving lip is perimetrically connected to the lateral wall to receive the planter-supporting lid. The planter-supporting lid supports a single planter or a plurality of stacking planters. The planter-supporting lid includes a pump outlet to allow fluid transport from the storage volume to the planter or plurality of stacking planters.

A flowerpot assembly is provided a support including a plurality of equally spaced openings from top to bottom; and a plurality of flowerpots each disposed on the opening and including a container and a conduit wherein the container includes a storing section for anchoring a plant and a water distribution device on a bottom of the storing section, the water distribution device including a coupling, a wall, an inlet, and an overflow exit; wherein a bottom of the conduit is connected to the water distribution device; wherein the inlet communicates the conduit with the storing section; wherein the wall is around the coupling; and wherein the overflow exit is between the water distribution device and the wall and extends out of the container.

The present invention is a plant cultivation device. The water tank supplies cultivation water to the cultivation tank via an irrigation conduit. The water tank also suctions cultivation water from the cultivation tank via a water-sucking pipe. The heat-collecting part receives sunlight, and the pressure of air that is heated inside the air-storage part presses the surface of the water inside the water tank. The water tank supplies cultivation water that has been pressed by said air to a culture medium material. The heat-collecting part raises the surface of the water inside the water tank as a result of the heated air being cooled by a decrease in the sunlight. The water tank suctions cultivation water from a bottom section of the cultivation tank.

The present invention is a plant cultivation device. The water tank supplies cultivation water to the cultivation tank via an irrigation conduit. The water tank also suctions cultivation water from the cultivation tank via a water-sucking pipe. The heat-collecting part receives sunlight, and the pressure of air that is heated inside the air-storage part presses the surface of the water inside the water tank. The water tank supplies cultivation water that has been pressed by said air to a culture medium material. The heat-collecting part raises the surface of the water inside the water tank as a result of the heated air being cooled by a decrease in the sunlight. The water tank suctions cultivation water from a bottom section of the cultivation tank.

A system for the fertigation of a plant vessel and method of use for the same is disclosed. The system comprises a grow module containing a plurality of growing trays additionally containing plants, and/or shoots of plants in various stages of development. The growing trays are individually extracted from the grow module via a tray movement system and tray elevator controlled by a control system and precisely placed in a fertigation system, wherein they are aligned over and lowered onto an at least one nozzle which penetrate the plant vessels containing the plants and fertigate them with a combination of water, nutrients, and/or pressurized air. The individual growing tray is then replaced in the grow module and the process is repeated for all growing trays and plant vessels in the grow module.