The present disclosure relates to an application apparatus for mixing a plurality of components for producing a multicomponent mixture, in particular a polyurethane foam, and for introducing and/or applying the multicomponent mixture into and/or onto an object, in particular a lithium-ion battery, comprising: a mixing tube having a first closed end and a second end for discharging the multicomponent mixture from the mixing tube, wherein the mixing tube has a mixing space, a plurality of injection units arranged on the mixing tube, each configured to inject one of the plurality of components into the mixing space, a mixer arranged in the mixing space, configured to mix the injected components with one another, and a moving device configured to move the mixer between the first end and the second end. Furthermore, an application system comprising the application apparatus and a method for mixing a plurality of components for producing a multicomponent mixture and for introducing and/or applying the multicomponent mixture into and/or onto an object is disclosed.

The disclosure relates to an application system for mixing a plurality of components for producing a multicomponent mixture, in particular a polyurethane foam, and for introducing and/or applying the multicomponent mixture into and/or onto an article, in particular a lithium-ion battery, wherein the application system comprises an application device. Furthermore, a method for mixing a plurality of components for producing a multicomponent mixture and for introducing and/or applying the multicomponent mixture into and/or onto an article is disclosed.

In a device and a method for mixing components of a ceramic starting material, a flowable powdered ceramic material as a first component can be supplied via a first inlet opening and a flowable powdered additive as a second component can be supplied via at least one further inlet opening, each in a meterable manner, to a mixing system in such a way that the first component and the second component mix homogeneously in the mixing system to form a mixed material variably enriched with the additive, which can be supplied as a ceramic starting material for further processing.

We disclose an apparatus (2) for supplying a particulate material (4) at a target mass flow rate, the apparatus comprising an entrainment region (6) configured to entrain the particulate material (4) in a gas or gas mixture flowing through the entrainment region (6), a cross-sectional area of at least a part of the entrainment region being adjustable based on the particulate material (4) and a supply device (8) configured to supply the particulate material (4) to the entrainment region (6) at approximately or at the target mass flow rate.

A method for converting material within a vacuum tank that contains a mixture of liquid and solid material into a solidified batch of material. The method utilizes various devices to measure different features and properties of the tank and its contents to determine an amount of drying agent to be added to the tank. The method further utilizes various devices and methods for adding the drying agent to the tank and mixing the drying agent with the material within the tank. The method described herein may be completed automatically in response to human input on a handheld display device.

A batching system involves a vessel, a mixer, a pump, and an optical sensor, wherein the vessel, the mixer, the pump and the optical sensor are coupled together by piping so as to form a circuit within which materials will re-circulate while being mixed by the mixer until at least one reading from the optical sensor indicates that the materials are fully mixed. An associated batching method involves introducing into a vessel, via gravity feed through mass flow meters, multiple materials to be mixed, repeatedly circulating the materials through a mixer, a pump, a spectroscope and the vessel until a reading from the optical sensor indicates that the multiple materials are fully mixed, and once the multiple materials are fully mixed, dispensing the fully mixed materials into at least one package container using an articulated arm.

The system, in one aspect, includes a first bulk storage container for holding a first bulk dry flowable material having a first dispensing assembly coupled with a first outlet, and a second bulk storage container for holding a second bulk dry flowable material having a second dispensing assembly coupled with the second outlet. The system, in one aspect, may further include a mixed storage vessel, as well as a controller in communication with the first dispensing assembly and the second dispensing assembly, the controller programmed to cause the first dispensing assembly to discharge the first amount of the first dry flowable material to the mixed storage vessel and cause the second dispensing assembly to discharge the second amount of the second dry flowable material to the mixed storage vessel over a comparable time period based upon weight based readings the controller receives from first and second load cells.

An apparatus for mixing and/or conditioning powdery materials through fluid-free fluidization comprises a movably supported container that defines a first processing chamber for receiving powdery material; an oscillation generator by which a powdery material located in the processing chamber can be subjected to an oscillation, in particular a sinusoidal oscillation, during operation; and a control unit that controls the oscillation generator.

According to an example, a mixing device comprises a first chamber including a solute addition member and a first mixer, a second chamber including a second mixer, a printing fluid pump, and a controller operatively connected to the solute addition member, the pump, the first mixer, and the second mixer. The controller is to control the pump to move printing fluid towards the printing fluid tank based on a printing fluid density level in the printing fluid tank, to control the solute addition member to add solids based on the printing fluid density level, and to control the first mixer and the second mixer to mix the added solids with the printing fluid moved by the pump.

The system, in one aspect, includes a first bulk storage container for holding a first bulk dry flowable material having a first dispensing assembly coupled with a first outlet, and a second bulk storage container for holding a second bulk dry flowable material having a second dispensing assembly coupled with the second outlet. The system, in one aspect, may further include a mixed storage vessel, as well as a controller in communication with the first dispensing assembly and the second dispensing assembly, the controller programmed to cause the first dispensing assembly to discharge the first amount of the first dry flowable material to the mixed storage vessel and cause the second dispensing assembly to discharge the second amount of the second dry flowable material to the mixed storage vessel over a comparable time period based upon weight based readings the controller receives from first and second load cells.