A makeup fluid management and supply device and method are provided. The method includes the steps of: receiving a cosmetic style template sent from a user device; selecting a makeup bottle by the control module in accordance with a makeup application step of the cosmetic style template and moving the makeup bottle to a using position by the driving module; reading a label information of the makeup bottle; sending the label information to the management unit so as to perform a validation procedure on the makeup bottle; rotating, in response to a positive validation result, the makeup bottle by the driving module so as to perform a makeup fluid mixing procedure on the makeup bottle; and driving, by the driving module, the makeup bottle to move in a first direction until the makeup bottle is squeezed so as to obtain a makeup fluid of the makeup bottle.

A lid, a disposable cup with the lid, and a blending machine for use with the lid and cup which is particularly well-suited for use in a self-service blending environment where material is initially provided in unblended form in the disposable cup, is blended in the disposable cup, and the disposable cup is used by the end user during consumption of the material. The lid is designed to allow for a blade assembly of the blending machine to pass through the lid and into the cup without it having to be removed.

The invention relates to a device for producing and processing a multi-component mixture, the device comprising a mixing chamber which has an outlet, wherein the device has a closure element which can be moved in the direction of a longitudinal axis L of the mixing chamber in order to open or close the outlet of the mixing chamber; wherein the device has an apparatus for controlling an axial speed of the closure element, the apparatus comprising: a hydraulic system in which a hydraulic fluid is guided; a cylinder which is connected to the nozzle closure element and cooperates with at least one chamber of the hydraulic system; and a controllable throttle gap arranged in the hydraulic system.

The invention relates to a device for producing and processing a multi-component mixture, the device comprising a mixing chamber which has an outlet, wherein the device has a closure element which can be moved in the direction of a longitudinal axis L of the mixing chamber in order to open or close the outlet of the mixing chamber; wherein the device has an apparatus for controlling an axial speed of the closure element, the apparatus comprising: a hydraulic system in which a hydraulic fluid is guided; a cylinder which is connected to the nozzle closure element and cooperates with at least one chamber of the hydraulic system; and a controllable throttle gap arranged in the hydraulic system.

Disclosed is a plunger mixer device (307B, 309B, 311B, and 313B) deployable within a hollow shaft injection drill bit system (305B). The plunger mixer device (307B, 309B, 311B, and 313B) includes a motor (313B), a piston (507D), and a plunger motor assembly (403C, 405C, 407C, 409C, 411C, 413C, and 415C). The motor (313B) is connected to a feeder auger tip. The piston (507D) is configured to be driven by the motor (313B). The piston (507D) is connected to a feeder auger (103C, 105A, 109B, and 205A). The plunger motor assembly (403C, 405C, 407C, 409C, 411C, 413C, and 415C) includes a stacked series of panels (503D, 505D, and 507D), and a plurality of motor shafts (311D). The stacked series of panels (503D, 505D, and 507D) has a plurality of ribbed panels (307D) with a rib locking feature. One of the stacked series of the panel (507C) is actuated by the motor (313B). The ribbed panels (303C) lock between each other when the ribbed panels (305D, 307B, 307D, and 309B) are spun into a fully formed deployment. The ribbed panels (303C, 305C, and 307C), upon deployment, serve to mix wet and dry materials by subsurface hollow shaft drilling augers (103A) ascending in communication with a feeder auger ascent and the subsequent descent.

Disclosed is a plunger mixer device (307B, 309B, 311B, and 313B) deployable within a hollow shaft injection drill bit system (305B). The plunger mixer device (307B, 309B, 311B, and 313B) includes a motor (313B), a piston (507D), and a plunger motor assembly (403C, 405C, 407C, 409C, 411C, 413C, and 415C). The motor (313B) is connected to a feeder auger tip. The piston (507D) is configured to be driven by the motor (313B). The piston (507D) is connected to a feeder auger (103C, 105A, 109B, and 205A). The plunger motor assembly (403C, 405C, 407C, 409C, 411C, 413C, and 415C) includes a stacked series of panels (503D, 505D, and 507D), and a plurality of motor shafts (311D). The stacked series of panels (503D, 505D, and 507D) has a plurality of ribbed panels (307D) with a rib locking feature. One of the stacked series of the panel (507C) is actuated by the motor (313B). The ribbed panels (303C) lock between each other when the ribbed panels (305D, 307B, 307D, and 309B) are spun into a fully formed deployment. The ribbed panels (303C, 305C, and 307C), upon deployment, serve to mix wet and dry materials by subsurface hollow shaft drilling augers (103A) ascending in communication with a feeder auger ascent and the subsequent descent.

A module includes a housing, a sealing feature, a locking feature, and an agitator. The housing has an opening separating inner and outer surfaces and a boss that extends through the housing such that part of the outer surface forms an inner bore of the boss having a terminus pointing toward the opening. The agitator has a base, a shaft, and a mixing element coupled to the base such that the base, in cooperation with the sealing feature, circumferentially seals the opening of the housing to form a cavity defined by the inner surface. The shaft passes through the inner bore. The locking feature when engaged permits independent or simultaneous translational and rotational movement of the shaft while an area between the terminus of the boss and the shaft remains mechanically sealed during the movement against liquid or powder encroachment into a clean area of the inner bore.

An individual frozen drink dispenser includes a housing having a base configured to support a blender cup, a dispensing chamber disposed above the blender cup and configured to support a frozen beverage container containing frozen ingredients suitable for preparing a frozen drink, at least one dispensing mechanism configured to move from a pre-dispense position to a dispense position in which the dispensing mechanism drives the frozen ingredients from the frozen beverage container into the blender cup, and a drive mechanism coupled to the housing and configured to drive the movement of the dispensing mechanism from the pre-dispense position to the dispense position. A method of preparing a frozen drink is further disclosed.

A slurry mixing device includes an installation frame, a slurry mixing tank, a slurry feeding tank, a cooling mechanism and a slurry discharging mechanism. The slurry feeding tank is movably arranged under the slurry mixing tank, the cooling mechanism and the slurry discharging mechanism. A mass scale is arranged under the slurry feeding tank. A stirring cavity is formed in the slurry mixing tank, and a stirring paddle is arranged in the stirring cavity. A stirring motor is arranged on the slurry mixing tank. An outlet is arranged on the bottom of the stirring cavity. An oil bath cavity is formed between the slurry mixing tank and the stirring cavity. The cooling mechanism includes a lifting cylinder and a lifting base. The lifting base is provided with a rotating paddle and a rotating motor. The lifting cylinder is arranged on the installation frame.

Disclosed is a blood sample analyzer, including: a sample conveying device for conveying a sample rack loaded with a sample container; a first agitating device having a sample stirring component for stirring a blood sample in the sample container and being capable of driving the sample stirring component to uniformly agitate the blood sample in the sample container; a second agitating device capable of picking up the sample rack or a second sample container on the sample rack, and driving the second sample container containing a common-volume blood sample on a second agitating position to uniformly agitate the blood sample; and a controller configured to communicate with the sample conveying device, the first agitating device and the second agitating device, and control the sample conveying device, the first agitating device and the second agitating device. In addition, the present application further discloses a blood sample agitating device, a blood sample analysis method, and a computer storage medium.