A stirring element device, in particular for mixing media with a wide range of viscosities, in particular for a polycondensation reactor, includes at least one inner stirring blade and at least one outer stirring blade which are rotatable about a common axis of rotation, wherein at least the inner stirring blade is inclined at least section-wise relative to the axis of rotation. The inner stirring blade is arranged entirely in a subregion around the axis of rotation which is equivalent to a cylinder sector with a circular sector of less than 360 as base area.

A exhaust gas mixing apparatus includes an outer cylinder being configured to an insulating ceramic; fins being configured to an insulating ceramic, the fins being provided on an inner side of the outer cylinder; and an electric heating portion embedded in at least a part of the outer cylinder and/or the fins.

A cleaning liquid includes a static liquid (13), a second fine gas bubble group (26) contained in the static liquid (13) and formed by a gas at a first temperature, a dynamic liquid (22) that flows toward an object to be cleaned (W) that is held in the static liquid (13), and a second fine gas bubble group (26) formed by a gas at a second temperature different from the first temperature, the second fine gas bubble group (26) being entrapped by a flow of the dynamic liquid (22) and flowing toward the object to be cleaned (W). This makes it possible to provide a cleaning liquid that exhibits a cleaning effect remarkably better than ever before.

A dental irrigation device for heating a solution and mixing solutes within the solution. The present invention utilizes an oscillator and inductive coil to heat and/or mix the solution. A pump then delivers the heated and mixed pressurized solution from a basin ultimately into a dispenser.

A sink is configured to attach to a bottom surface of a flowline that is configured to flow a mixture of at least two immiscible fluids. One of the immiscible fluids is water. The water is more dense than the other of the at least two immiscible fluids. An outlet formed at a bottom portion of the sink. A valve system is connected to the opening. The valve system is configured to open the outlet in response to the water occupying at least a portion of the sink.

A beverage maker includes a receptacle, a piston, a fluid circuit, a first heater, and a second heater. The receptacle is configured to receive a flavoring capsule. The piston is configured to compress the flavoring capsule to direct flavoring fluid from the beverage flavoring capsule and into a container via a channel. The fluid circuit has an outlet configured to direct water into the container adjacent to the channel. The first heater is disposed within the receptacle and is configured to heat the beverage flavoring capsule. The second heater is disposed along the circuit and is configured to heat the water flowing through the circuit.

A beverage maker includes a receptacle, a piston, a fluid circuit, a first heater, and a second heater. The receptacle is configured to receive a flavoring capsule. The piston is configured to compress the flavoring capsule to direct flavoring fluid from the beverage flavoring capsule and into a container via a channel. The fluid circuit has an outlet configured to direct water into the container adjacent to the channel. The first heater is disposed within the receptacle and is configured to heat the beverage flavoring capsule. The second heater is disposed along the circuit and is configured to heat the water flowing through the circuit.

A tumbler crystallizer for crystallizing pelleted, tacky, polymeric materials includes a housing for rotatably supporting a removable paneled drum on rollers. The removable panels may be made of a transparent, heat-insulating material. The drum receives a flow of hot pellets through an inlet chute, and a tumbling action of the drum and internal agitators keeps the pellets in motion relative to each other to prevent agglomeration until they reach a desired level of crystallinity and are no longer tacky. Baffle plates are provided at intervals along the length of the drum to slow the flow of pellets therethrough to increase residence time. Damper plates are provided near the exit end of the drum to aid in building a bed of pellets within the drum, and also to control residence time of the pellets within the drum.

An extrusion apparatus configured to releasably secure therein a filter and two syringes so as to provide stability during the extrusion process. The extrusion apparatus includes a body that is rectangular in form. The body includes a top surface wherein the top surface has formed therein a filter receiving member. The filter receiving member is centrally located on the body. Operably coupled to the filter receiving member on opposing sides thereof is a first syringe channel and a second syringe channel. The first syringe channel and the second syringe channel include a passage having an outer wall. The outer wall of the passage of the first syringe channel and the second syringe channel is annular in form and has a circumferential radius that requires longitudinal insertion of syringes and inhibits the upward movement thereof once the syringes are disposed therein. A heating assembly is further included in the body.

A laboratory device (4, 9), in particular a magnetic stirrer, comprises at least one adjustable operating parameter for controlling at least one laboratory device function, and an outer housing (2). The outer housing (2) has a coupling device (11a, 11b) for coupling the laboratory device (4, 9) to at least one further laboratory device (5, 9) for the same at least one laboratory device function, at which further laboratory device the at least one operating parameter can also be adjusted, and the coupling device (11a, 11b) is configured such that by means of the coupling device (11a, 11b) the laboratory device (4, 9) and the at least one further laboratory device (5, 9) can be operated simultaneously and by means of a common adjustment device the at least one operating parameter can be adjusted in a central manner independently and/or consistently for the laboratory device (4, 9) and the at least one further laboratory device (5, 9).