This in-line active and reverse calculating mass balance blending system can maintain a chemical at desired control points, such as with respect to concentration, temperature, and/or pressure, while the output flow rate is changing dynamically to a point of use. A blending unit is configured to receive and blend at least two species and deliver a mixture at selected concentrations to points of use. A controller can be configured to determine a mass balance to maintain the concentrations in the mixture using information from metrology systems and a flow in an output to the at least one point of use. The controller also can be configured to maintain a concentration in the mixture within a concentration range by controlling flow rates to the blending unit.

Blending apparatuses and related methods and computer program products are disclosed. In an aspect, blending apparatuses and related methods and computer program products of the present disclosure may include at least one energy source associated with the blending apparatuses such that at least one energy source may be used to provide at least one portion of the energy required for a given blending apparatus to function, thereby reducing or eliminating need for a separate energy source to power the blending apparatus, which reduces the overall spatial footprint required by the blending apparatus and other device(s) associated therewith. Energy generated by the at least one energy source may also be used to power one or more additional devices. Blending apparatuses of the present disclosure may additionally comprise at least one control station that allows one or more users to monitor, adjust, control, interact with the blending apparatuses, thereby increasing efficiency.

Improving health and experience of a cosmetic product user, the robotic cosmetic mix bar of the present invention is disclosed. The robotic cosmetic mix bar allows the user to select safe ingredients tailored to their own unique hair and skincare goals. In one embodiment, the robotic cosmetic mix bar contains a robotic arm surrounded by a dispenser and multiple processing stations. Based on a user input indicating a type of cosmetic product and the ingredients to include in the cosmetic product, the robotic arm obtains the desired ingredients from the dispenser and, by transporting the ingredients from one processing station to another, the robotic arm facilitates the processing of the ingredients. The processing of ingredients can include boiling, cooling, mixing, whisking, blending, etc. Within approximately two minutes, the cosmetic product built according to the user specifications is delivered to the user.

Systems and methods have demonstrated the capability of rapidly cooling the contents of pods containing the ingredients for food and drinks.

A blending device includes a motor, a motor controller, and a wireless controller configured to receive a wireless signal. The motor controller may be configured to alter the operations of the motor based the wireless signal. The wireless signal may include a blending program to be carried out by the blending device. The blending device may include one or more sensors configured to sense parameters of the blending device. The wireless signal may include information related to the sensed parameters. A blending device network may be formed by providing a second blending device having a wireless controller in communication with the first blending device wireless controller. The first and second blending devices may share information over the network.

An integrated system includes a desalination plant including a reverse osmosis (RO) array to produce an RO permeate blending stream and a nanofiltration (NF) array to produce an NF permeate blending stream. The integrated system also includes a blending system. Further, the integrated system includes a control unit. Still further, the integrated system includes an injection system for one or more injection wells that penetrate an oil-bearing layer of a reservoir. Moreover, the integrated system includes a production facility to separate fluids produced from one or more production wells that penetrate the oil-bearing layer of the reservoir and to deliver a produced water (PW) stream to the blending system. The blending system is configured to blend the RO permeate and NF permeate blending streams with the PW stream to produce a blended low salinity water stream. The control unit is configured to dynamically alter operation of the blending system to adjust amounts of at least one of the RO permeate blending stream and the NF permeate blending stream to maintain a composition of the blended low salinity water stream within a predetermined operating envelope.

Disclosed are a fully electric-drive sand-mixing apparatus and an automatic control system therefor. The fully electric-drive sand-mixing apparatus comprises a foundation (01); and a suction pump (02), a suction pump driving electric motor (03), a suction manifold (04), a mixing stirrer (05), a mixing stirrer driving electric motor (06), a dry-ingredient-adding device (07), a dry-ingredient-adding device driving electric motor (08), a liquid-adding device (09), a liquid-adding device driving electric motor (10), a sand-conveying device (11), a sand-conveying device driving electric motor (12), a discharge pump (13), a discharge pump driving electric motor (14), a discharge manifold (15), a frequency converter placement room (16) and an operation room (17), which are fixedly connected to the foundation (01). The suction pump driving electric motor (03), the mixing stirrer driving electric motor (06), the dry-ingredient-adding device driving electric motor (08), the liquid-adding device driving electric motor (10), the sand-conveying device driving electric motor (12) and the discharge pump driving electric motor (14) are fixedly and electrically connected to the suction pump (02), the mixing stirrer (05), the dry-ingredient-adding device (07), the liquid-adding device (09), the sand-conveying device (11) and the discharge pump (13), respectively.

A print material container comprising a body to hold print material, a housing, and a detecting member. The housing being coupled to the body and including a movable mass to move in the housing when a shaking force is applied to the print material container. The detecting member to detect the shaking force and to signal a feedback of the shaking force relative to a shaking force threshold.

Systems and methods have demonstrated the capability of rapidly cooling the contents of pods containing the ingredients for food and drinks.

Systems and methods have demonstrated the capability of rapidly cooling the contents of pods containing the ingredients for food and drinks.