A soil irrigation and restoration system comprises a water transmitting device having a water containing tank, a water pumping element, and a pipe. The water containing tank has a containing space formed therein. The water pumping element is disposed in the containing space and has at least one water inlet, a water outlet, and an overflow portion. The water outlet is spaced apart from the at least one water inlet. The overflow portion is disposed between the at least one water inlet and the water outlet, and is disposed at a position higher than that of the at least one water inlet and the water outlet. The pipe has a connecting end connected to the water outlet. A portion of the pipe away from the connecting end extends downwardly and is buried in the soil layer. A soil irrigation and restoration method executed with syphon effect is also provided.

A soil irrigation and restoration system comprises a water transmitting device having a water containing tank, a water pumping element, and a pipe. The water containing tank has a containing space formed therein. The water pumping element is disposed in the containing space and has at least one water inlet, a water outlet, and an overflow portion. The water outlet is spaced apart from the at least one water inlet. The overflow portion is disposed between the at least one water inlet and the water outlet, and is disposed at a position higher than that of the at least one water inlet and the water outlet. The pipe has a connecting end connected to the water outlet. A portion of the pipe away from the connecting end extends downwardly and is buried in the soil layer. A soil irrigation and restoration method executed with syphon effect is also provided.

Provided is a ultrafine bubble generating apparatus capable, when generating nanobubbles in a liquid, of appropriately mixing a gas into a liquid ejected from a liquid ejector. The ultrafine bubble generating apparatus comprises a liquid ejector for ejecting a liquid, a gas mixer for pressurizing and mixing a gas into the liquid ejected from the liquid ejector, and an ultrafine bubble generator for generating nanobubbles in the liquid by passing the liquid with intermixed gas therethrough. Between the liquid ejector and the ultrafine bubble generator, the gas mixer pressurizes and mixes the gas into the liquid, which is flowing in a pressurized state toward the ultrafine bubble generator.

Provided is a ultrafine bubble generating apparatus capable, when generating nanobubbles in a liquid, of appropriately mixing a gas into a liquid ejected from a liquid ejector. The ultrafine bubble generating apparatus comprises a liquid ejector for ejecting a liquid, a gas mixer for pressurizing and mixing a gas into the liquid ejected from the liquid ejector, and an ultrafine bubble generator for generating nanobubbles in the liquid by passing the liquid with intermixed gas therethrough. Between the liquid ejector and the ultrafine bubble generator, the gas mixer pressurizes and mixes the gas into the liquid, which is flowing in a pressurized state toward the ultrafine bubble generator.

A subsurface irrigation system for a sports field includes a substantially water impermeable layer, a compacted subgrade below the water impermeable layer, a plurality of water distribution boards positioned on top of the water impermeable layer, a porous layer overlaying the plurality of water distribution boards, and a sports field layer on top of the porous layer. The porous layer is configured to move water from the plurality of water distribution boards upwards to the sports field layer using capillary action to keep it damp. The sports field layer may be sand, dirt, clay, or a combination thereof. In addition, the system may include a water control basin in fluid communication with at least one water distribution board of the plurality of water distribution boards and configured to control the flow of water to the plurality of water distribution boards.

A subsurface irrigation system for a sports field includes a substantially water impermeable layer, a compacted subgrade below the water impermeable layer, a plurality of water distribution boards positioned on top of the water impermeable layer, a porous layer overlaying the plurality of water distribution boards, and a sports field layer on top of the porous layer. The porous layer is configured to move water from the plurality of water distribution boards upwards to the sports field layer using capillary action to keep it damp. The sports field layer may be sand, dirt, clay, or a combination thereof. In addition, the system may include a water control basin in fluid communication with at least one water distribution board of the plurality of water distribution boards and configured to control the flow of water to the plurality of water distribution boards.

A tubing marking system is provided primarily for tubing utilized in drip irrigation processes. The tubing marking system includes a tube, a plurality of elongated markings, and a plurality of elongated covers. The tube is preferably made of a flexible material and includes an outer diameter of 0.5 inches or larger. More specifically, the tube is preferably made of polyethylene material. The plurality of elongated markings may be a set of any type of markings that can be easily identified by a user. The plurality of elongated covers may be a set of any type of material able to partially or fully conceal the plurality of elongated markings. When the tubing marking system is in use, at least one cover from the plurality of elongated covers is detached from the tube in order to expose the corresponding marking. This allows one tube to be visually distinguished from another tube.

A subterranean irrigation system (100) has a plurality of fluid conduit (130) for applying a liquid from a source to an area of ground, to which said liquid is to applied while avoiding interference with the above-ground use of such area, wherein the fluid conduits (130) are connected (140; 500) relative to one another and wherein the plurality of fluid conduits (130) comprise a plurality of outlets to effect the distribution of the liquid to the ground area, wherein the plurality of outlets (600;621, 622, 623; 800; 821, 822, 823) are provided at an underside (602, 802) of a nose-shaped spout attachment (600, 800), wherein the spout attachment (600; 800) is attached at the side in the upper half of the fluid conduit (130; 230; 720) and wherein the underside (602; 802) comprises a rounded surface starting tangentially from the outer diameter of the fluid conduit (130; 230; 720) and ends in the nose-shaped free end of the spout attachment (600; 800).

A subterranean irrigation system (100) has a plurality of fluid conduit (130) for applying a liquid from a source to an area of ground, to which said liquid is to applied while avoiding interference with the above-ground use of such area, wherein the fluid conduits (130) are connected (140; 500) relative to one another and wherein the plurality of fluid conduits (130) comprise a plurality of outlets to effect the distribution of the liquid to the ground area, wherein the plurality of outlets (600;621, 622, 623; 800; 821, 822, 823) are provided at an underside (602, 802) of a nose-shaped spout attachment (600, 800), wherein the spout attachment (600; 800) is attached at the side in the upper half of the fluid conduit (130; 230; 720) and wherein the underside (602; 802) comprises a rounded surface starting tangentially from the outer diameter of the fluid conduit (130; 230; 720) and ends in the nose-shaped free end of the spout attachment (600; 800).

An intelligent planting apparatus an intelligent planting management method controls planting processes of plants in a plurality of planting devices within different environments, and includes data collection step, classification-marking step, and regulation step. Collected data comprise: plants' planting information, environment information of planting devices, planting condition information and plant features. Classifying the collected data, scoring and comparing the plant features in each planting devices according to preset conditions under same category, and marking and storing respective planting condition information of the planting device with high planting feature score in a plant growing cycle. Comparing the current planting condition information with the stored marked planting condition information according to planting and environment information of respective planting device. If difference therebetween exceeds threshold, a regulation data is generated according to the stored marked planting condition information and the current planting condition information to regulate planting condition of respective planting device.