There is provided a method for manufacturing a catalyst ink for fuel cell electrodes that allows simultaneously performing fineness of a catalyst and adjustment of viscosity of the catalyst ink. The method for manufacturing a catalyst ink for fuel cell electrodes containing a catalyst, a solvent, and an ionomer includes stirring and mixing the catalyst, the solvent, and the ionomer by a high-shear thin-film spin mixer. The ionomer contains a gel-like ionomer. The high-shear thin-film spin mixer includes a cylindrical stirring tank, a rotary vane, and a shaft. The cylindrical stirring tank has unevennesses on an inner peripheral surface. The rotary vane is concentric with the stirring tank and has an outer diameter slightly smaller than an inner diameter of the stirring tank. The shaft includes the rotary vane on an end portion and is rotatable at high speed in forward and reverse directions.

The present disclosure relates to an aerosol delivery device filling system. The system includes multiple source containers each respectively including a differing aerosol precursor composition. The system further includes a mixing container configured to engage the source containers to receive and mix the aerosol precursor compositions to form a mixed aerosol precursor composition. An aerosol delivery device may engage the mixing container to receive at least a portion of the mixed aerosol precursor composition. A related method for customizing an aerosol precursor composition is also provided.

A process for making an oligonucleotide, the process including reacting a oligonucleotide precursor with a solid phase support within a reaction vessel, the reaction vessel being coupled to an actuator and having a resting position and inverting the reaction vessel via the actuator such that the reaction vessel is inverted relative to the resting position, wherein the inversion of the reaction vessel results in stirring of the solid phase support within the reaction vessel.

A process for making an oligonucleotide, the process including reacting a oligonucleotide precursor with a solid phase support within a reaction vessel, the reaction vessel being coupled to an actuator and having a resting position and inverting the reaction vessel via the actuator such that the reaction vessel is inverted relative to the resting position, wherein the inversion of the reaction vessel results in stirring of the solid phase support within the reaction vessel.

The mixing or dispersing device and assembly equipped with such a device are proposed for optimizing the processing of mixed or dispersed substances, in particular tablets and/or capsules for medicinal drugs. The mixing or dispersing device includes in a mixing chamber, a motor-driven rotor having at least one cutting projection that has at least one cutting edge. A flow-disturbing element is further provided on an inner circumferential wall of the mixing chamber that surrounds the axis of rotation. Furthermore, a deflection surface is provided between the inner circumferential wall and a bottom of the mixing chamber. The at least one flow-disturbing element is spaced from the bottom of the mixing chamber, from the at least one cutting projection and from the circular path on which the at least one cutting projection is movable about the axis of rotation.

A mug including a stirring unit connected to the liquid space of the mug, for stirring a beverage contained in the liquid space of the mug simultaneously by the same hand in which the mug is held, and in which mug the stirring unit includes a pumping space separate from the liquid space, and a pumping device connected to the pumping space, configured to increase and to decrease the pressure of air inside the pumping space in an alternating manner. In the mug according to the invention, a flow channel extends from the pumping space to the liquid space, enabling the flow of the beverage contained in the liquid space from the liquid space to the pumping space and from the pumping space to the liquid space, whereby a liquid flow can be formed in the flow channel, for stirring the beverage in the liquid space by the pumping device.

In one example, a liquid container includes an expandable and collapsible bag having a first interior chamber and a second interior chamber separated by a barrier; a passage through the barrier for liquid to pass between the chambers; a first opening between the first chamber and an exterior of the bag; and a second opening between the second chamber and the exterior of the bag.

A dynamic mixer comprises a mixing chamber having a plurality of inlets and an outlet as well as a mixing element rotatably arranged in the mixing chamber. The mixing takes place by a to and fro movement of the mixing element.

A food preparation appliance has a base, a blade member rotatable in a direction of rotation, and a container with a closed bottom, an open top and a tubular sidewall together defining an interior space of the container. The top of the container is configured for releasable connection with the base, with the blade member disposed within the interior space of the container. The sidewall has a rib projecting inward of the interior space of the container and extending lengthwise along at least a portion of the sidewall from the top of the container toward the bottom of the container. The rib has, in the direction of rotation of the blade member, a peak defined as the shortest transverse dimension measured from the center of the container to the sidewall at a respective height along the portion of the sidewall having the rib, the rib being asymmetric in transverse cross-section.

Provided is a method for producing an organic compound, the method making it possible to ensure an adequate reaction time and obtain a targeted substance at a high yield even in an organic reaction that requires a relatively long time to complete the reaction. A method for producing an organic compound, wherein the method is characterized in that: a fluid processing apparatus F used in the production method is equipped with an upstream processing unit that processes a fluid to be processed between at least two processing surfaces 1 and 2 that relatively rotate, and a downstream processing unit disposed downstream of the upstream processing unit, the downstream processing unit being provided with a plurality of labyrinth seals that function to retain and stir the fluid to be processed that has been processed by the upstream processing unit; due to the fluid to be processed, which contains at least one type of organic compound, being passed through the upstream processing unit, the fluid to be processed is subjected to upstream processing; due to the fluid to be processed that has been subjected to upstream processing being passed through the downstream processing unit, the fluid to be processed that has been subjected to upstream processing is subjected to downstream processing; and the upstream processing and the downstream processing are performed continuously.