An manufacturing device for amino acid coordination complexes, containing a reaction mechanism including a paddle drying reaction kettle, a motor, a rotation shaft, and paddles; a wet-type dust collector; a vacuum pump, and an ozone generator; one end of the rotation shaft is connected to the motor; another end of the rotation shaft extends into the paddle drying reaction kettle; a plurality of paddles are disposed on an outer wall of the rotation shaft and are rotatable along with the rotation shaft; the paddle drying reaction kettle is connected to one end of a vacuum pump through a gas discharging pipe; another end of the vacuum pump is connected with the ozone generator; a middle part of the gas discharging pipe is connected with the wet-type dust collector; the wet-type dust collector has a first wet filter tank and a second filter tank.

A mixing paddle that is configured to rotate about a horizontal rotation axis and includes at least one eccentric arm which includes a first portion inclined with respect to a plane containing the rotation axis, so as to cause the ingredients contained in the mixing chamber to move in a first axial direction when the mixing paddle rotates in a first direction of rotation, a second portion having a cross section oriented radially with respect to the rotation axis in order, when the mixing paddle rotates in a second direction of rotation, to bring about a radial movement of the ingredients towards the outside of the mixing chamber.

The invention provides a feed-mixing wagon (1) for animal feed, comprising a frame with a drive, a container (4) with a continuous wall (5) with a feed-unload opening, a feed auger which is arranged in the container for mixing and cutting animal feed and comprising an auger shaft (8) and an auger body (10) which is arranged around it in a spiral which has several blades, wherein the blades comprise at least one blade (11) of a first, long type and at least one blade (12) of a second, short type, and wherein at least one blade of the short type is situated closer to the bottom (6) than at least one blade of the long type. As a result of the various blades in the described configuration, the cutting and mixing behaviour can be adjusted in an optimum way.

A feed-mixing device for receiving, mixing and dispensing animal feed includes a frame with a mixing bin for receiving and mixing the animal feed therein and dispensing it therefrom, at least one mixing device rotatably drivable in the mixing bin using a drive, in particular a vertical mixing auger, for mixing the received animal feed, and a weighing device for determining the weight of the animal feed received in the mixing bin, comprising N weighing elements, with N≥2, each of which emits a weighing signal, and a control system for controlling the feed-mixing device and for processing the weighing signals from the weighing elements to produce the determined weight. The control system is configured to perform an, in particular fully automatic, calibration action of the weighing elements. The calibration action includes driving the at least one mixing device, reading out the respective weighing signal of each of the N weighing elements in each of M different positions of the mixing device, with M≥N, calibrating the weighing elements on the basis of the read-out weighing signals, wherein the calibrating at least includes determining a respective correction factor for the weighing signal of each weighing element by analysing the read-out weighing signals of all weighing elements. Thus, all weighing elements may be calibrated without having to detach the weighing elements, which provides very reliable weight measurements in a very simple manner.

A feed mixer and liner therefor. The feed mixer including: a container formed from two side walls, two end walls, wherein the end walls have a slope and curvature and are connected to the side walls to form an auger well, and a base connected with the side walls and end walls at a lower end thereof; and a liner configured to have a truncated conical shape that matches the slope and curvature of the end walls and fits within the auger well such that: a bottom of the liner contacts the base and has a diameter similar to a diameter of the path of the auger at the base; and a top of the liner contacts with the end walls and side walls. The auger well may include two auger wells and the liner may include two truncated conical shapes fitting in each of the two auger wells.

High thermal transfer, hollow core extrusion screws (50, 52, 124, 126, 190) include elongated hollow core shafts (54, 128, 130, 192) equipped with helical fighting (56, 132, 134, 194) along the lengths thereof. The fighting (132, 134, 194) may also be of hollow construction which communicates with the hollow core shafts (54, 128, 130, 192). Structure (88, 90) is provided for delivery of heat exchange media (e.g., steam) into the hollow core shafts (54, 128, 130, 192) and the hollow fighting (132, 134, 194). The fighting (56, 132, 134, 194) also includes a forward, reverse pitch section (64, 162, 216). The extrusion screws (50, 52, 124, 126, 190) are designed to be used as complemental pairs as a part of twin screw processing devices (20), and are designed to impart high levels of thermal energy into materials being processed in the devices (20), without adding additional moisture.

Fodder mixing wagon with a mixing container and at least one mixing member arranged rotatable therein for fodder components and a sensor system arranged to co-rotate on the mixing member for examining at least one of the fodder components and/or a fodder mixture formed therefrom. A data transmission system with a transmitter a receiver which are associated with one another in a co-rotating and not co-rotating arrangement for wireless data transmission to and/or from the sensor system; and/or an electrical generator for supplying power to the sensor system. The transmitter and receiver are arranged such that the wireless data transmission is within the mixing container; and the generator is arranged on the stator side to co-rotate with the mixing member and on the rotor side is coupled not to co-rotate. Data transmission is provided with a low transmission power. Inductive data and power transmission may be used.

A feed mixer apparatus that includes a mixing chamber for receiving feed, and having a mixing element situated therein for mixing the feed, a transmission having a plurality of gears and connected with a mixing element, a drive system having a plurality of drive system components, including the transmission, a torque sensor interconnected with at least one drive system component, a control unit having a display and a plurality of user inputs, wherein the control unit is in at least indirect communication with the transmission and the torque sensor, and wherein the control unit receives a plurality of outputs from one or more of the transmission and torque sensor, and based at least in part on the plurality of outputs, provides an output command to effectuate a gear change in the transmission.

An elevating feed mixing system and method are provided. The system includes a support frame and a raisable platform raisable relative to the support frame. A mixing tub disposed on the raisable platform is configured to receive constituent ingredients of a feed and further configured to raise to release the feed after it is mixed.

A weigh hopper assembly including a plurality of adjacently aligned weigh hoppers connected via a frame, and longitudinal conveyor mechanism extending along a top portion of the weigh hopper assembly. Each weigh hopper has independent load cells in order to individually weigh the material discharged into the weigh hopper. The conveyor mechanism includes a plurality of gates along a bottom surface of the conveyor mechanism, each gate being aligned with a corresponding weigh hopper of the plurality of weigh hoppers. The conveyor mechanism is in turn connected to a plurality of product bins. A top portion of the conveyor mechanism is in communication with a plurality of product bins via a series of inlet chutes and gates. The weigh hoppers are aligned adjacent to each other and spaced so that each weigh hopper aligns with the transport vehicle.