A bale press includes a substantially horizontal main press chamber, the main press chamber incorporating a main press in the form a moveable wall moveably mounted within the main press chamber between retracted and advanced positions in a direction parallel to a longitudinal axis of the main press chamber. A side chamber is positioned along one side of the main press chamber and has a side press mounted for movement within the side chamber between retracted and advanced positions in a direction generally perpendicular to the longitudinal axis of the main press chamber so that material within the side chamber may be compressed into the main press chamber by movement of the side press between the retracted and advanced positions. A feed hopper for material to be baled is positioned above the side chamber for delivering material into the side chamber when the side press is retracted.

A precompression charging chamber for a compactor having a frame, including a bottom wall, a left side wall that is movable from a first position that is perpendicular to the bottom wall to a second position that forms an obtuse angle with the bottom wall, a left top cover that is pivotably mounted to the left side wall and defines a left lock pin receptor, and a left lock pin that is movable from a first position in which the left lock pin is received within a left lock pin receptor defined by the frame and a second position in which the left lock pin is received within the left lock pin receptor of the left top cover, wherein the left side wall is non-pivotably fixed to the frame when the left lock pin is in the first position.

A bale compression device for receiving and compressing a bale of material. The device includes a press configured to compress the bale of material to a required compressed dimension, a binding applicator configured to apply a plurality of bindings around the bale of material prior to the bale being compressed, and a connector for connecting ends of each of the bindings to form a plurality of complete loops around the perimeter of the bale so that the plurality of loops act to hold the bale in a compressed state. The binding applicator acts to withdraw excess binding as the press compresses the bale, prior to the connector connecting the ends of each of the bindings, such that the complete loops are formed when the bale reaches its required compressed dimension.

A dust solidification apparatus that homogenizes dust components having a simple structure and capable of performing dust solidification in a stable manner includes: a storage tank that stores dust; a forming member within the storage tank, the forming member having a forming hole; and a pressurizing rod configured to freely advance and withdraw with respect to the inside of the forming hole, wherein the rod is made to advance into the forming hole to solidify dust filled therein, thereby obtaining a solidified substance, the forming hole has entry and discharge sections for the pressurizing rod and is in communication with the storage tank, and a stirring passage is provided in the outside of the discharge section to guide dust pushed out from the discharge section by the entry of the pressurizing rod into the entry section in a direction different from the discharge direction and to stir the dust.

The present disclosure is for a briquetting machine and method thereof to process loose metal scraps. The method comprises the steps of advancing a pre-extruding punch in a first pathway to push loose metal scraps towards a first entrance leading into a re-extruding cavity; advancing a re-extruding punch in a second pathway perpendicular to the first pathway to further push the loose metal scraps towards a second entrance leading to a final pressing cavity; advancing a final-extruding punch along a third pathway perpendicular to both the pre and re-extruding punches to compress loose metal scraps to form a metal cake in the final extruding cavity. Pressure and overflow release areas are configured adjacent to each entrance. Advancing and retracting sequences of the pre-, re-, and final-extruding punches are monitored and controlled via sensors and switches.

Improved bales may be formed using methods that include using baling equipment with an air blasting crumb chute that may reduce wear and tear and maintenance, and/or improve efficiency by reducing material waste, imperfections, and/or contamination. The crumb chute may include an air inlet and a plurality of apertures in fluid communication with the air inlet. Air may be provided through the apertures to prevent crumbles from accumulating on the baling assembly as they fall through the chute to the press chamber and/or to blast already accumulated residual crumbles from components of the baling assembly, such as a traveling chute, and into the press chamber. The crumb chute may include a polyoxymethylene insert in which the air inlet and apertures are provided. The crumb chute may be provided as a kit for attachment to various baling apparatuses. Additional features and components also are described.

A baler having a compression system for forming a bale. The baler also has a feed system having a pack mode for accumulating the crop in a pre-compression chamber and a lift mode for conveying the crop to the compression system. The baler also has a sensor arrangement having at least one sensor generating a signal, the at least one sensor being coupled to the feed system. The signal corresponds to a crop load on the feed system. A control unit is configured to receive the signal from the sensor arrangement and initiate the lift mode based on at least the signal.

A feed device is for use on a baling press (1) and is for a loose fiber material (2) to be compressed. The feed device (4) has a movable and driven and possibly guided feed element (14, 15). The feed device (4) is assigned a protection device (3), which protects the drive area and possibly the guiding area of the feed device (4), in particular the bearing (19) thereof, against airborne fibers by using an opposing airstream (27).

A method for the operation of a self-propelled agricultural working machine has at least one working element and a driver assistance system for generating control actions within the working machine. A sensor arrangement for generating surroundings information is provided, and the driver assistance system generates the control actions based on the surroundings information. The sensor arrangement comprises a camera-based sensor system and a laser-based sensor system, each of which generates sensor information regarding a predetermined, relevant surroundings area of the working machine. The sensor information of the camera-based sensor system is present as starting camera images. The starting camera images are segmented into image segments by an image processing system according to a segmentation rule, and the segmented camera images are combined by a sensor fusion module with the sensor information from the laser-based sensor system.

A briquetting machine for loose metal scraps comprises a pre-extrusion part, a re-extrusion part and a final pressing part. On the upper portion of a pre-extrusion cavity (14) of the pre-extrusion part, a pre-extrusion releasing area (15) is formed near to one side of a re-extrusion cavity (24). At the front end of a re-extrusion plunger (23) of the re-extrusion part, a lateral gap (28) is formed near to one side of the pre-extrusion cavity. The cross section of the lateral gap is a right-angled trapezoid and the lateral gap is provided with a lateral slope (29). A briquetting method for loose metal scrapes is disclosed. By way of pre-extrusion and step-by-step feeding and triggering resetting loading, not only is a certain pre-pressing effect guaranteed while the loose metal scraps are processed in each feeding and pre-pressing step, but also the stress can be transferred and released timely under the over-pressure condition, which avoids the formation of dense metal block under the over-pressure condition. Therefore a continuous, automatic and safe pressing operation is assured.