The disclosure relates in particular to an apparatus for disinfecting at least one room, in particular for one or more persons, preferably a dwelling space or treatment room, for example a treatment room in a building, in particular a sickroom, a patient room and/or an operating theatre, by means of an atomiser. Specifically, the apparatus is characterised in that the atomiser includes a rotatable bell cup for atomising a disinfectant into the room. The disclosure relates to an associated method and furthermore to the use of a bell cup for atomising a disinfectant in a room for, in particular, one or more persons.

An electronic device includes a mouthpiece, a bladder, and a mesh assembly having a mesh material and a piezoelectric material. The mesh material is in contact with a liquid of the bladder. The mouthpiece, the bladder, and the mesh assembly are located in-line along a longitudinal axis of the device between opposite longitudinal ends of the device, with the mesh assembly extending between and separating the mouthpiece and the bladder. A liquid-filled cartridge also is disclosed for use with an electronic device for delivery of a substance into a body through respiration includes a liquid container; and a liquid contained within the container for aerosolizing and inhaling by a person using the electronic device. The liquid includes a plurality of nanoparticles in a nanoemulsion, the nanoparticles including the encapsulation of the substance to be delivered into the body through respiration. The nanoemulsion preferably is produced using a microfluidizing machine.

A method removes a follower plate of a device for transporting viscous material out of a barrel-like container. The device has the follower plate for closing the container, which is open at the top and has a container base and a container casing extending upwards from the base, the follower plate being movable toward and away from the base. A force measuring sensor measures a force exerted by a container onto a placement surface; the controller switches the ventilation mode to the lifting mode if the force exerted by the container onto the placement surface exceeds a first target force value; and the controller switches the lifting mode to the ventilation mode if the force exerted by the container onto the placement surface falls below a second target force value, and/or the at least one sensor measures the position of the container relative to a stationary point.

A method removes a follower plate of a device for transporting viscous material out of a barrel-like container. The device has the follower plate for closing the container, which is open at the top and has a container base and a container casing extending upwards from the base, the follower plate being movable toward and away from the base. A force measuring sensor measures a force exerted by a container onto a placement surface; the controller switches the ventilation mode to the lifting mode if the force exerted by the container onto the placement surface exceeds a first target force value; and the controller switches the lifting mode to the ventilation mode if the force exerted by the container onto the placement surface falls below a second target force value, and/or the at least one sensor measures the position of the container relative to a stationary point.

Systems and methods for a container for decreasing the thawing time for a liquid, gel or other fluid material is described herein. The systems can include a container with a body. The body can include a cavity with a dispensing nozzle and a plunger disposed within the cavity. The body can further include one or more channels separate from the cavity. The channel(s) increases the rate of heat transfer associated with the container and, thus, increases the cooling or heating rate of the material within the container.

Systems and methods for a container for decreasing the thawing time for a liquid, gel or other fluid material is described herein. The systems can include a container with a body. The body can include a cavity with a dispensing nozzle and a plunger disposed within the cavity. The body can further include one or more channels separate from the cavity. The channel(s) increases the rate of heat transfer associated with the container and, thus, increases the cooling or heating rate of the material within the container.

An underground charging pile for new energy vehicle has a green plant, a buried pit, and a charging pile. The buried pit has a water storage device having two water storage tanks, each tank is communicated with the buried pit, a group of propulsion springs are fixed to the two water storage tanks, the two propulsion springs are fixedly provided with a pushing, an upper end of the charging pile is fixedly provided with a cover plate, a bottom of the charging pile is fixedly provided with a supporting plate, a lifting rod is fixed between a lower of the supporting plate and a lower of the buried pit, a water spraying device is arranged to two side walls of the buried pit.

Methods and systems for coating with shear and moisture sensitive materials are disclosed. A method of coating a product includes filling an inner bellows chamber of a bellows, which is provided within and isolated from an outer bellows chamber of a tank, with a predetermined amount of the coating material. The method of coating the product further includes supplying a pressurized material to the outer bellows chamber to pressurize the coating material within the inner bellows chamber to an operating pressure, and supplying the coating material within the inner bellows chamber to a spray gun at the operating pressure. The method of coating also includes determining that a measured actual pressure is within a predetermined control range of the target pressure and subsequently coating the product by spraying the product with the coating material from the spray gun.

A liquid film cartridge includes: a nozzle section 10 which ejects a foamable solution 100 and generates a liquid film in a space; and a liquid leading section 20 which leads the foamable solution 100 to the nozzle section 10, in which when an outermost portion of a liquid ejecting port 11 of the nozzle section 10 and an inner wall 21 of the liquid leading section 20 are disposed with a gap therebetween so as to satisfy a condition of a predetermined separation relationship, a distance from the inner wall 21 generating air bubbles 103 to the liquid ejecting port 11 in the liquid leading section 20 corresponding to a flow path immediately before the foamable solution 100 reaches the nozzle section 10 is increased and the amount of the air bubbles 103 entering from the liquid leading section 20 into the nozzle section 10 can be reduced.

A coating material cartridge includes an enclosure, a coating material storage bag received in the enclosure, and a coating material storage bag orientation clip secured within the enclosure. The clip engages a portion of the coating material storage bag to maintain the storage bag in a predetermined fixed orientation within the enclosure during filling of the coating material storage bag with coating material, and also during movement of the coating material cartridge.