An apparatus for roughage processing includes a first platform for placing of a first type of roughage, a first cutting mechanism for processing the first type of roughage, a first chain for cutting the first type of roughage from the first platform to the first cutting mechanism; and a second platform, a second cutting mechanism, and a second chain for performing similar tasks with a second type of roughage. The first chain and the first cutting mechanism and the second chain and the second cutting mechanism are driven at a different speed to provide concurrent cutting of the first and second types of roughages at different cut sizes. The apparatus further includes a conveyor or an auger for concurrently collecting the first type of roughage and the second type of roughage after respective processing by the first cutting mechanism and the second cutting mechanism for effective blending of the two types of roughages, each of which has been cut differently to obtain its optimum particle size for ruminant consumption. The apparatus can be powered by a very small horse power motor. It also includes a mechanism that will stop the floor chains carrying the roughage into the knife drums when the power load force that is detected by the knife drum power load reading device reaches a predetermined amount. This predetermined amount is still within, but near the upper limits of, the available horsepower range of the small motor powering it.

An apparatus for roughage processing includes a first platform for placing of a first type of roughage, a first cutting mechanism for processing the first type of roughage, a first chain for cutting the first type of roughage from the first platform to the first cutting mechanism; and a second platform, a second cutting mechanism, and a second chain for performing similar tasks with a second type of roughage. The first chain and the first cutting mechanism and the second chain and the second cutting mechanism are driven at a different speed to provide concurrent cutting of the first and second types of roughages at different cut sizes. The apparatus further includes a conveyor or an auger for concurrently collecting the first type of roughage and the second type of roughage after respective processing by the first cutting mechanism and the second cutting mechanism for effective blending of the two types of roughages, each of which has been cut differently to obtain its optimum particle size for ruminant consumption. The apparatus can be powered by a very small horse power motor. It also includes a mechanism that will stop the floor chains carrying the roughage into the knife drums when the power load force that is detected by the knife drum power load reading device reaches a predetermined amount. This predetermined amount is still within, but near the upper limits of, the available horsepower range of the small motor powering it.

A riding lawn care vehicle (10, 310) may include a frame (30, 330), an engine (340, 40), a steering assembly, a support platform (20, 30, 320) and a front platform (348, 48). At least a pair of drive wheels may be operably coupled to the frame (30, 330). The engine (340, 40) is operably coupled to the frame (30, 330) via an engine platform (342, 42). The engine (340, 40) is disposed substantially between the drive wheels to selectively provide drive power to the drive wheels via respective hydraulic pumps (346, 46). The steering assembly includes control levers (50) operably coupled to respective ones of the drive wheels via the respective hydraulic pumps (346, 46). The steering assembly enables steering of the riding lawn care vehicle (10, 310) based on drive speed control of the drive wheels responsive to positioning of the control levers (50). The support platform (20, 30, 320) is operably coupled to the frame (30, 330) at a rear portion of the riding lawn care vehicle (10, 310) to support a standing operator. The front platform (348, 48) is operably coupled to the frame (30, 330) forward of the engine platform (342, 42). The front platform (348, 48) supports the hydraulic pumps (346, 46).

A riding lawn care vehicle (10, 310) may include a frame (30, 330), an engine (340, 40), a steering assembly, a support platform (20, 30, 320) and a front platform (348, 48). At least a pair of drive wheels may be operably coupled to the frame (30, 330). The engine (340, 40) is operably coupled to the frame (30, 330) via an engine platform (342, 42). The engine (340, 40) is disposed substantially between the drive wheels to selectively provide drive power to the drive wheels via respective hydraulic pumps (346, 46). The steering assembly includes control levers (50) operably coupled to respective ones of the drive wheels via the respective hydraulic pumps (346, 46). The steering assembly enables steering of the riding lawn care vehicle (10, 310) based on drive speed control of the drive wheels responsive to positioning of the control levers (50). The support platform (20, 30, 320) is operably coupled to the frame (30, 330) at a rear portion of the riding lawn care vehicle (10, 310) to support a standing operator. The front platform (348, 48) is operably coupled to the frame (30, 330) forward of the engine platform (342, 42). The front platform (348, 48) supports the hydraulic pumps (346, 46).

A distributed electrohydraulic system includes an electrical power source, electrohydraulic modules, and a control system. Each of the electrohydraulic modules includes one or more hydraulic components and one or more electrically-operated components which affect an operation of the one or more hydraulic components. The one or more hydraulic components of each of the electrohydraulic modules is hydraulically isolated from the one or more hydraulic components of another one of the electrohydraulic modules The one or more electrically-operated components of each of the electrohydraulic modules is electrically coupled to the electrical power source to receive electrical power. The control system includes one or more processors and memory devices electrically coupled to the electrical power source and the one or more electrically-operated components of the electrohydraulic modules. The control system is configured to execute commands to operate independently the one or more electrically-operated components of each of the electrohydraulic modules.

An agricultural work machine is provided comprising a surroundings detection device for detecting a surroundings in sections, and one or more controllable working elements, wherein the surroundings detection device generates surroundings detection signals, which can be processed in a control and regulating device assigned to the agricultural work machine, wherein the surroundings detection device is designed as a scanner, which scans the surroundings in scanning planes, and wherein each scanning plane is assigned to the control of working elements.

An agricultural work machine is provided comprising a surroundings detection device for detecting a surroundings in sections, and one or more controllable working elements, wherein the surroundings detection device generates surroundings detection signals, which can be processed in a control and regulating device assigned to the agricultural work machine, wherein the surroundings detection device is designed as a scanner, which scans the surroundings in scanning planes, and wherein each scanning plane is assigned to the control of working elements.

A standing ride on mower includes a frame, a right drive wheel, a left drive wheel, a prime mover, a cutting deck assembly, a right side integrated transaxle operating under influence of the prime mover to drive rotation of the right drive wheel, the right side integrated transaxle including a right side housing, a right hydraulic pump within the housing, and a right hydraulic motor within the housing, a left side integrated transaxle operating under the influence of the prime mover to drive rotation of the left drive wheel, the left side integrated transaxle including a left side housing, a left hydraulic pump within the housing, and a left hydraulic motor within the housing, and an operator platform to support a standing operator of the mower. The operator platform extends beneath the left housing and beneath the right housing.

A standing ride on mower includes a frame, a right drive wheel, a left drive wheel, a prime mover, a cutting deck assembly, a right side integrated transaxle operating under influence of the prime mover to drive rotation of the right drive wheel, the right side integrated transaxle including a right side housing, a right hydraulic pump within the housing, and a right hydraulic motor within the housing, a left side integrated transaxle operating under the influence of the prime mover to drive rotation of the left drive wheel, the left side integrated transaxle including a left side housing, a left hydraulic pump within the housing, and a left hydraulic motor within the housing, and an operator platform to support a standing operator of the mower. The operator platform extends beneath the left housing and beneath the right housing.

An arrangement for control of the drive speed of a harvester comprises an internal control loop for control of the drive speed of the harvester, to which can be sent a set value and an actual value of a throughput-dependent parameter, and also an external control loop to make available the set value of the throughput-dependent parameter for the internal control loop, to which set and actual values regarding the power output of a drive of the harvester can be sent as input parameters.