A mixer includes a mixing container held in a machine stand, with an outlet opening in the bottom of the mixing container, and a closure cover which can be reciprocated between a closed position in which the closure cover closes the outlet opening and an opened position in which the closure cover does not close the outlet opening. The closure cover is connected to the machine stand by way of a four-bar linkage including four rotary joints, wherein a first and a second rotary joint of the four-bar linkage are arranged on the closure cover and a third and a fourth rotary joint of the four-bar linkage are arranged on the machine stand.

A mixing device includes a mixing container for receiving mixing material and a mixer cover, wherein a first seal and a second seal is provided between the mixing container and the mixer cover. The first seal and the second seal are so arranged that a first air space is formed between the first seal and the second seal.

The present invention, which is entitled mixture-based composite product processing machine, mixing element, and mixing assembly, relates to a mixed product dispensing machine of the type that dispenses a mixture of liquid or powder components or ingredients into a mixing element onto which a leak-tight cover is subsequently placed and inside which, as a result of its particular configuration, the liquid and/or powder portions are mixed by spinning them in a coordinated manner on at least one spinning head of the machine to which said container is coupled.

The present invention, which is entitled mixture-based composite product processing machine, mixing element, and mixing assembly, relates to a mixed product dispensing machine of the type that dispenses a mixture of liquid or powder components or ingredients into a mixing element onto which a leak-tight cover is subsequently placed and inside which, as a result of its particular configuration, the liquid and/or powder portions are mixed by spinning them in a coordinated manner on at least one spinning head of the machine to which said container is coupled.

A mixer device 1 includes a drum 3 configured to store materials to be mixed; a device body 4 configured to rotatably support the drum 3; an electric motor 6 configured to apply a rotational driving force to the drum 3; and a battery 8 configured to supply electric power to the electric motor 6, wherein the battery 8 is arranged below the drum 3.

A mixer device 1 includes: a drum 3 configured to store materials to be mixed; a device body 4 configured to rotatably support the drum 3; an electric motor 6 configured to apply a rotational driving force to the drum 3; and a battery 8 configured to supply electric power to the electric motor 6, wherein a wheel 29 is attached to the device body 4, and the battery 8 is arranged above the wheel 29.

A mixer device 1 includes: a drum 3 configured to store materials to be mixed; a device body 4 configured to rotatably support the drum 3; an electric motor 6 configured to apply a rotational driving force to the drum 3; and a battery 8 configured to supply electric power to the electric motor 6, wherein a wheel 29 is attached to the device body 4, and the battery 8 is arranged above the wheel 29.

A mixing device for a magnetic bead reagent includes a magnetic member, a container storage mechanism, and a drive mechanism. The container storage mechanism includes a mounting part for mounting a magnetic bead liquid container storing a magnetic bead reagent, and the mounting part corresponds to the magnetic member, enabling the container on the mounting part to be located within the magnetic field. The drive mechanism has a drive structure capable of driving at least one of the magnetic member, the mounting part, and the container to move, and thus generating a relative movement between the container and the magnetic field. The direction of the magnetic force acting on the magnetic beads is changed by the relative movement between the magnetic bead reagent and the magnetic field, such that the magnetic beads flow along different directions under the magnetic force, thereby increasing mixing efficiency of magnetic bead reagent.

A mixing device for a magnetic bead reagent includes a magnetic member, a container storage mechanism, and a drive mechanism. The container storage mechanism includes a mounting part for mounting a magnetic bead liquid container storing a magnetic bead reagent, and the mounting part corresponds to the magnetic member, enabling the container on the mounting part to be located within the magnetic field. The drive mechanism has a drive structure capable of driving at least one of the magnetic member, the mounting part, and the container to move, and thus generating a relative movement between the container and the magnetic field. The direction of the magnetic force acting on the magnetic beads is changed by the relative movement between the magnetic bead reagent and the magnetic field, such that the magnetic beads flow along different directions under the magnetic force, thereby increasing mixing efficiency of magnetic bead reagent.

A production process includes: feeding the recycled coarse aggregates and new aggregates into the hot recycled material drying drum simultaneously through the cold material bin for heating; adding the recycled fine aggregates to the mixing cylinder of the cold recycled material mixer through the existing cold addition system for recycled materials, and then being mixed and stirred with the recycling agent after dry mixing for a certain period of time, and placing the oil-rich fine aggregates in the cold recycled material batching machine and conveyed to the cold recycled material hoist through a conveyor belt.