A dissolving and mixing unit for automatically dissolving and mixing medicines includes: a support; a dissolving and mixing device mounted on the support and including two piercer bases and at least one dissolving and mixing channel, wherein each dissolving and mixing channel includes two piercers and an elastic infusion hose connecting the two piercers, and the two piercers of each dissolving and mixing channel are mounted on the two piercer bases respectively; a peristaltic pump mounted on the support and configured to squeeze the elastic infusion hose; first and second bottle-containing modules mounted on the support and configured to hold first and second medicine containers respectively; and a movement mechanism configured to drive at least one of the first bottle-containing module and one piercer base to move, and configured to drive at least one of the second bottle-containing module and the other piercer base to move.

Provided are an enclosed stirrer using intermittent resonance and a method. The enclosed stirrer comprises: two pairs of parallel tension springs (1), a fixing bracket (2), an elastic cantilever beam (3), a cantilever beam pressure clamping device (6), an eccentric motor (4), an arc-shaped cushion block (5), and an enclosed container (8). The enclosed container (8) is mounted on the fixing bracket (2) by the tension spring (1). The elastic cantilever beam (3) is installed below the enclosed container (8) and is axially parallel to the enclosed container (8). One end of the elastic cantilever beam (3) is mounted on the fixing bracket (2) as a clamping end, the other end of the elastic cantilever beam (3) is connected to the eccentric motor (4) as a movable end. The arc-shaped cushion block (5) is connected above the eccentric motor (4). The arc-shaped cushion block (5) reciprocally strikes the bottom of the enclosed container (8) during operation of the eccentric motor (4).

Method and apparatus to agitate a liquid are disclosed herein. An example apparatus includes a carrier having a base that includes a ridge extending from the base and a collar extending from the base. The example apparatus also includes a container supported on the base, the container movable between (A) a locked positon in which the ridge fixedly engages the container to non-rotatably couple the container to the base and (B) an unlocked position in which the container is disengaged from the ridge and the container is rotatable about the collar.

A method of heating and mixing contents is disclosed that combines heating and agitating of a bottle and its contents in order to achieve even warming, as well as, mixing the contents of the bottle.

A method of heating and mixing contents is disclosed that combines heating and agitating of a bottle and its contents in order to achieve even warming, as well as, mixing the contents of the bottle.

A pressurized container assembly includes a pressurized container, a valve, and a shearing chamber. A flowable product and propellant are also provided within the container. The propellant is substantially non-soluble in the flowable product. Methods of producing a foamed flowable product using shearing chambers are also disclosed.

The present disclosure provides a device for assisting agitation of liquid. The device includes a frame having a bottom and a sidewall forming an angle with the bottom; a first flexible film attached to the frame at a periphery portion of the first flexible film; a first magnetic field generator at the sidewall of the frame and adjacent to the periphery portion of the first flexible film; and a second magnetic field generator at the bottom of the frame, wherein the first magnetic field generator and the second magnetic field generator are configured to provide a magnetic field parallel to at least a portion of the first flexible film, and wherein a portion of the frame and the first flexible film are configured to be in contact with the solution.

A mixing device comprising a multi-element spring system in which an eccentric load, coupled to a rotor of a motor, is located towards a first end of a first beam realising a backbone for the mixing device. One or more connections interconnect the backbone respectively to one or more other beams to produce the multi-element spring system. A load, such as a vial or other container in which is located a diluent, is located remotely from the motor. As such, the spring system supports two independent but complementary eccentric load generating subsystems arising from, respectively, the controlled rotation of the rotor (and its eccentric load) and then, in response to rotation of the connected eccentric load on the rotor, swirling of the diluent in the vial/container. Both these eccentric loads contribute to a complex multidirectional flexing of the multi-element spring system relative to a fixed anchor point, with this multidirectional flexing working to induce a swirling motion in the contents of the container.

A mixing device comprising a multi-element spring system in which an eccentric load, coupled to a rotor of a motor, is located towards a first end of a first beam realising a backbone for the mixing device. One or more connections interconnect the backbone respectively to one or more other beams to produce the multi-element spring system. A load, such as a vial or other container in which is located a diluent, is located remotely from the motor. As such, the spring system supports two independent but complementary eccentric load generating subsystems arising from, respectively, the controlled rotation of the rotor (and its eccentric load) and then, in response to rotation of the connected eccentric load on the rotor, swirling of the diluent in the vial/container. Both these eccentric loads contribute to a complex multidirectional flexing of the multi-element spring system relative to a fixed anchor point, with this multidirectional flexing working to induce a swirling motion in the contents of the container.

A disposable fluid transfer and mixing device is disclosed and includes an injector support surface for receiving an injection device thereon. A lyophilized drug vial, a diluent vial and a syringe are also attached to the device. The device features fluid passageways and a manual valve that may be manipulated so that the syringe may be used to transfer diluent from the diluent vial to the lyophilized drug vial, for reconstitution of the drug. The valve may also be configured so that the reconstituted drug is transferred from the lyophilized drug vial to the injection device. An automated transfer and mixing device receives an injection device, a lyophilized drug vial and a diluent vial and transfers diluent from the diluent vial to the lyophilized drug vial and shakes or vibrates the lyophilized drug vial to reconstitute the drug. The device then transfers the reconstituted drug from the lyophilized drug vial to the injection device.