A vehicle and method of tending to an elevated agriculture includes a base extending from a forward base portion to a rearward base portion, a support frame, an elevated platform, a guide rail, and a drive unit. The elevated platform is connected to the support frame such that the elevated platform is positioned vertically above the base and horizontally between the forward and rearward base portions. The elevated platform is configured to selectively, vertically raise upward from a lower height toward a higher height. The guide rail extends vertically upward from the elevated platform and horizontally surrounds at least a portion of the elevated platform for bounding an operator atop the elevated platform. The drive unit is configured to selectively direct horizontal movement of the base with the elevated platform thereon for supporting the operator on the elevated platform while moving the elevated platform within the agriculture facility.

A poultry holding system that can be erected tool-free by assembling lengthwise and crosswise members on support posts. Multiple upright support posts are set up in an evenly spaced grid. The crosswise members and lengthwise members are constructed as U-profile rails, with through-holes in the horizontal sections of the U-profiles that allow the members to be assembled and supported on the support posts. The poultry holding system thus constructed can have at least two tiers, one above the other. The assembly components are designed to be particularly economical, which allows greater flexibility in the design and construction of the poultry holding system to accommodate the constraints of the particular facility.

A poultry holding system that can be erected tool-free by assembling lengthwise and crosswise members on support posts. Multiple upright support posts are set up in an evenly spaced grid. The crosswise members and lengthwise members are constructed as U-profile rails, with through-holes in the horizontal sections of the U-profiles that allow the members to be assembled and supported on the support posts. The poultry holding system thus constructed can have at least two tiers, one above the other. The assembly components are designed to be particularly economical, which allows greater flexibility in the design and construction of the poultry holding system to accommodate the constraints of the particular facility.

The invention relates to an airtight poultry house and an intelligent monitoring automatic control system thereof that collects large data related to growth factor correlation. The intelligent monitoring automatic control system includes: at least one detection module disposed in a processing unit for generating a farming area data according to the airtight state of at least one poultry farming area; at least one control module disposed in the processing unit, wherein each of the at least one control module is provided with a processing unit automatic control rule, and each of the at least one control module is used to automatically control the desired airtight state for the farming environment according to the processing unit automatic control rule and the farming area data and to put the at least one poultry farming area in a negative pressure state; and a database storing the farming area data.

The invention relates to an airtight poultry house and an intelligent monitoring automatic control system thereof that collects large data related to growth factor correlation. The intelligent monitoring automatic control system includes: at least one detection module disposed in a processing unit for generating a farming area data according to the airtight state of at least one poultry farming area; at least one control module disposed in the processing unit, wherein each of the at least one control module is provided with a processing unit automatic control rule, and each of the at least one control module is used to automatically control the desired airtight state for the farming environment according to the processing unit automatic control rule and the farming area data and to put the at least one poultry farming area in a negative pressure state; and a database storing the farming area data.

The frames of the Inlets have endcaps and profiles that allow an inlet to be made to different lengths to provide an inlet of a size to provide the proper amount of air needed. Each inlet also has fully insulated blades, sides, and center profiles. The components are preferably foam filled with insulation and have an insulated foam insert on the endcaps together with a center pull so that only a single pull line is needed to operate the inlet.

The frames of the Inlets have endcaps and profiles that allow an inlet to be made to different lengths to provide an inlet of a size to provide the proper amount of air needed. Each inlet also has fully insulated blades, sides, and center profiles. The components are preferably foam filled with insulation and have an insulated foam insert on the endcaps together with a center pull so that only a single pull line is needed to operate the inlet.

A circular grazing system for poultry and/or livestock. The circular grazing system including a center pivot structure installed at a field. The center pivot structure may have a center pivot axis. The field may be a poultry and/or livestock grazing field. The circular grazing system for poultry and/or livestock may include an enclosure for containing poultry and/or livestock. The enclosure may extend generally radially from the center pivot structure to a circumference of the field. The enclosure may be rotably coupled to the center pivot structure such that the enclosure rotates around the center pivot axis.

A circular grazing system for poultry and/or livestock. The circular grazing system including a center pivot structure installed at a field. The center pivot structure may have a center pivot axis. The field may be a poultry and/or livestock grazing field. The circular grazing system for poultry and/or livestock may include an enclosure for containing poultry and/or livestock. The enclosure may extend generally radially from the center pivot structure to a circumference of the field. The enclosure may be rotably coupled to the center pivot structure such that the enclosure rotates around the center pivot axis.

Various apparatus and associated methods involve a light source that provides light at wavelengths that substantially correlate to local maxima in the spectral sensitivity of a diurnal avian. In an illustrative example, the light source may output light primarily in wavelength bands that are not substantially absorbed by colored oil droplets and/or visual pigment in at least one type of cone in the eye of a diurnal avian. In some embodiments, the light source may include a light-emitting diode (LED) light source. Exemplary light sources may output spectral components to illuminate diurnal avians with local maxima of intensity at wavelengths that substantially correspond to local maxima in a spectral sensitivity visual response characteristic of the diurnal avians.