A turf sports field with a plurality of turf modules (100) having an upper turf surface and peripheral turf edges (5). The turf modules are deployed by means of a remotely operated or autonomously operated lifting and transport vehicle (103), which is provided with a lifting arrangement. When installed, the turf modules (100) are positioned adjacent previously installed turf modules, with a tolerance gap (105) between adjacently positioned turf edges (5) of different turf modules.

A method of stacking sod rolls can include the steps of: a) moving a head of a sod handling apparatus into a sod pickup location containing a plurality of sod rolls; b) picking-up a first sod roll with a first sod carrier, picking-up a second sod roll with a second sod carrier, and picking-up a third sod roll with a third sod carrier; c) moving the head to a sod drop-off location; d) releasing the first sod roll from the first sod carrier at the sod drop-off location; e) after releasing the first sod roll, moving the second sod carrier toward the first sod carrier and moving the third sod carrier toward the first sod carrier to reduce the spacing between the second and third rolls of sod; and f) depositing the second sod roll and third sod roll at the drop-off location.

The present invention discloses a hydroponic field irrigation system comprising a field module for growing turfgrass. The field module comprises an energy absorbing mechanism comprising a horizontal spring layer and a growth medium comprising a steel grid layer, wherein the horizontal spring layer absorbs vertical forces exerted by external loads, and the steel grid layer is positioned on top of the horizontal spring layer for holding a plurality of turf sods. The hydroponic field irrigation system further comprises a used water tank for receiving water from the field module, an ultra-violet (UV) unit for disinfecting the water received from the used water tank, a water quality management unit for adjusting quality of the water received from the ultra-violet (UV) unit, a geothermal unit for conditioning temperature of water received from the water quality management unit and plurality of solenoid valves for pumping water into and out of the field module.

The present invention discloses a hydroponic field irrigation system comprising a field module for growing turfgrass. The field module comprises an energy absorbing mechanism comprising a horizontal spring layer and a growth medium comprising a steel grid layer, wherein the horizontal spring layer absorbs vertical forces exerted by external loads, and the steel grid layer is positioned on top of the horizontal spring layer for holding a plurality of turf sods. The hydroponic field irrigation system further comprises a used water tank for receiving water from the field module, an ultra-violet (UV) unit for disinfecting the water received from the used water tank, a water quality management unit for adjusting quality of the water received from the ultra-violet (UV) unit, a geothermal unit for conditioning temperature of water received from the water quality management unit and plurality of solenoid valves for pumping water into and out of the field module.

A sod harvester and a method for maintaining the integrity of a sod roll during sod roll transfer with the sod harvester having a first power assist rotatable sod roll cradle containing a set of spokes with opposed faces that laterally engage and dynamically cradle a sod roll as the sod roll falls from an upper conveyor to a lower conveyor so that a further set of opposed faces on the rotatable spokes laterally engage a further sod roll on an upper conveyor through a torque applied to the sod cradle by a low power hydraulic motor as the sod roll falls from the upper conveyor to the lower conveyor with the cycle repeated with each sod roll that is discharged from the upper conveyor to thereby maintain the integrity of the sod rolls within the sod harvester.

An eco-friendly netting for growing and/or harvesting sod and/or plants is disclosed herein. The eco-friendly netting includes a plurality of fibers arranged in a woven configuration or a substantially non-woven configuration. Each of the plurality of fibers is formed from a substantially natural material, which may also be biodegradable. The eco-friendly netting may be preseeded. The eco-friendly netting may be treated or processed with anti-rot agents, degrading accelerators, nutrients, fertilizers, pesticides, fungicides, algaecides, herbicides, water absorption/retention enhancers or any combination thereof. Methods of growing sod and harvesting sod, which utilize the eco-friendly netting, are also disclosed herein. In one or more embodiments, the eco-friendly netting may be treated or processed to increase or decrease its functional longevity.

A turf management system includes a wireless receiver that is configured to receive respective wireless signals comprising sensor data from wireless sensors positioned in a soil profile at respective depths below a green surface. A control circuit is coupled to the wireless receiver and is configured to determine soil profile conditions at the respective depths below the green surface responsive to the sensor data. The control circuit is coupled to a subsoil environmental control mechanism and is configured to automatically control operation of the subsoil environmental control mechanism responsive to the soil profile conditions at the respective depths below the green surface. The subsoil environmental control mechanism may include an airflow mechanism that is configured to alter airflow below the green surface, and/or a hydronic mechanism that is configured to circulate fluid through a hydronic tubing network below the green surface.

A turf management system includes a wireless receiver that is configured to receive respective wireless signals comprising sensor data from wireless sensors positioned in a soil profile at respective depths below a green surface. A control circuit is coupled to the wireless receiver and is configured to determine soil profile conditions at the respective depths below the green surface responsive to the sensor data. The control circuit is coupled to a subsoil environmental control mechanism and is configured to automatically control operation of the subsoil environmental control mechanism responsive to the soil profile conditions at the respective depths below the green surface. The subsoil environmental control mechanism may include an airflow mechanism that is configured to alter airflow below the green surface, and/or a hydronic mechanism that is configured to circulate fluid through a hydronic tubing network below the green surface.

A turf sports field with a plurality of turf modules (100) having an upper turf surface and peripheral turf edges (5). The turf modules are deployed by means of a remotely operated or autonomously operated lifting and transport vehicle (103), which is provided with a lifting arrangement. When installed, the turf modules (100) are positioned adjacent previously installed turf modules, with a tolerance gap (105) between adjacently positioned turf edges (5) of different turf modules.

A turf sports field with a plurality of turf modules (100) having an upper turf surface and peripheral turf edges (5). The turf modules are deployed by means of a remotely operated or autonomously operated lifting and transport vehicle (103), which is provided with a lifting arrangement. When installed, the turf modules (100) are positioned adjacent previously installed turf modules, with a tolerance gap (105) between adjacently positioned turf edges (5) of different turf modules.