Abstract: A vehicle-mounted device and method for delivering a traction enhancing material to a road surface directly in front of one or more tires is disclosed. The device delivers the traction enhancing material when an electronic controller detects a loss of traction. The device uses an air duct to collect air incident on the vehicle and direct the air to the road surface. The device further comprises a hopper to hold the traction enhancing material. The hopper is coupled to the air duct at an aperture. When activated, a valve assembly selectively opens and closes the aperture in response to controller commands. When opened, the traction enhancing material accelerates from the hopper into the duct and becomes entrained in the air stream where it is then delivered to the road surface. Once delivered, the traction enhancing material is introduced between the tires and the road surface to effectively increase the coefficient of friction therebetween.

Abstract: A vehicle-mounted device and method for delivering a traction enhancing material to a road surface directly in front of one or more tires is disclosed. The device delivers the traction enhancing material when an electronic controller detects a loss of traction. The device uses an air duct to collect air incident on the vehicle and direct the air to the road surface. The device further comprises a hopper to hold the traction enhancing material. The hopper is coupled to the air duct at an aperture. When activated, a valve assembly selectively opens and closes the aperture in response to controller commands. When opened, the traction enhancing material accelerates from the hopper into the duct and becomes entrained in the air stream where it is then delivered to the road surface. Once delivered, the traction enhancing material is introduced between the tires and the road surface to effectively increase the coefficient of friction therebetween.

Abstract: An optical seed flow monitoring system for monitoring seed flow through the primary and secondary seed tubes in an air seeding system. The primary seed tubes include a primary seed sensor having a plurality of emitter lens bodies and receiver lens bodies. Optical fibers connect the emitter lens body to an optical beam generating device and the receiver lens body to an optical beam detecting device both positioned remotely from the seed tubes. Alternately, one or more of the secondary seed tubes can include a secondary seed sensor having an emitter lens body and a receiver lens body.

Abstract: An improvement in a light collecting system for an agricultural seed monitor is disclosed. The light collecting system includes three optical surfaces: a convex lens surface, a planar surface, and a total internal reflection, cone condenser surface. The convex lens surface is designed to collect light from a seed sensing area of a seed tube and form a converging light beam. The converging beam is then incident onto the planar reflecting surface, which folds the optical axis of the converging light. The converging light beam is then incident onto a non-imaging, total internal reflection cone condenser surface. In a preferred embodiment all three optical surfaces are formed on a single prism made of plastic, with the convex lens being a spherical surface having a radius of curvature of about 20 mm, and the cone condenser surface having an input aperture diameter of about 6 mm and an output aperture diameter of about 0.9 mm.

Abstract: A particle blockage monitoring system employs a flexible piezoelectric particle sensor element in a portion of a particle flow path so that a number of particles traveling in the particle flow path strike the flexible particle sensor element while preventing damage to the particles and maintaining the forward momentum of all the particles in the particle flow path. In order to provide flexibility in monitoring particles of different types and to increase the information rate, the use of a one-shot multivibrator to temporarily store a particle detection signal as in the prior art is avoided. Also, serial sampling of the particle sensor data is avoided to increase the information rate. Instead, a comparator that includes a diode in a feedback loop so as to function as a latch is used in conjunction with a serial shift register that has parallel data input lines.

Abstract: A seed blockage monitoring system employs a flexible, generally flat piezoelectric seed sensor element inserted at an acute angle of about 13 degrees into a seed flow path so that a portion of seeds traveling in the seed flow path strike the seed sensor element, preventing damage to the seeds and maintaining forward momentum of all seeds in the seed flow path. In order to provide flexibility in monitoring seeds of different types and to increase the data rate that information can be obtained from numerous multiple seed sensor elements, the use of a one-shot to temporarily store a seed detection signal and serial sampling of the temporarily stored signals from the sensors as in the prior art is avoided. Instead, a comparator that includes a diode in a feedback loop so as to function as a latch is used in conjunction with a serial shift register that has parallel data input lines.