The present invention relates to a method for producing test pieces in which the thickness of the samples of homogeneous water-insoluble material is uniform, and to a method for quantitative analysis of water-insoluble material by analyzing such test pieces using MALDI mass spectrometry. Specifically, the test pieces can be produced by: adding a volatile solvent to a mixture of water-insoluble material and matrix; placing, in a pellet cup made of water-soluble material, and pressing, with even pressure, the sample obtained by mixing the mixture of water-insoluble material and matrix until the solvent has evaporated; and melting the pellet cup with water.

Systems and methods related to preparing foamed cement for laboratory analysis are provided. A prepared cement slurry is placed in a cement reservoir cell configured to pressurize the cement slurry contained within the cement reservoir cell to a capture pressure. After pressurization, the cement slurry and a compressed gas are introduced into a foam generator. Foamed cement generated in the foam generator is introduced from the tee into a foam capture cell where it can cure prior to analysis.

Various beverage preparation systems and methods are disclosed. The beverage preparation system can include a container assembly configured to receive beverage, such as a milk. The container assembly can be removably engaged with a base. The container assembly can be temporarily removed from the base to facilitate transport of the beverage residing therein. The container assembly can be configured to receive a flow of steam, air, or additional gasses and vapors when the container assembly is mounted on the base.

A multifunctional C.sub.4F.sub.7N/CO.sub.2 mixed gas preparation system is disclosed. The C.sub.4F.sub.7N heat exchanger is used to heat and vaporize C.sub.4F.sub.7N input through the C.sub.4F.sub.7N input port; the CO.sub.2 heat exchanger is used to heat and vaporize CO.sub.2 input through the CO.sub.2 input port; the C.sub.4F.sub.7N/CO.sub.2 mixing pipeline structure is used to mix the heated C.sub.4F.sub.7N and heated CO.sub.2, and the C.sub.4F.sub.7N/CO.sub.2 mixed gas output pipeline structure is used to output the C.sub.4F.sub.7N/CO.sub.2 mixed gas. The C.sub.4F.sub.7N/CO.sub.2 mixing pipeline structure comprises a C.sub.4F.sub.7N/CO.sub.2 dynamic gas preparation pipeline structure and a C.sub.4F.sub.7N/CO.sub.2 partial pressure mixing pipeline structure; the C.sub.4F.sub.7N/CO.sub.2 partial pressure mixing pipeline structure includes partial pressure mixing tanks for mixing the CO.sub.2 and the heated C.sub.4F.sub.7N of certain pressures; and a plurality of partial pressure mixing tanks are arranged in parallel. A multifunctional C.sub.4F.sub.7N/CO.sub.2 mixed gas preparation method is also disclosed.

Various beverage preparation systems and methods are disclosed. The beverage preparation system can include a container assembly configured to receive beverage, such as a milk. The container assembly can be removably engaged with a base. The container assembly can be temporarily removed from the base to facilitate transport of the beverage residing therein. The container assembly can be configured to receive a flow of steam, air, or additional gasses and vapors when the container assembly is mounted on the base.

A mixing system is configured to mix and discharge a paste. The mixing system includes a base-medium subsystem that provides a base fluid-medium. The mixing system further includes an additive-medium subsystem that provides one or more additive fluid-mediums. The mixing system further includes a density-reducing medium subsystem that provides a density-reducing medium.

The present invention relates to a method for producing test pieces in which the thickness of the samples of homogeneous water-insoluble material is uniform, and to a method for quantitative analysis of water-insoluble material by analyzing such test pieces using MALDI mass spectrometry. Specifically, the test pieces can be produced by: adding a volatile solvent to a mixture of water-insoluble material and matrix; placing, in a pellet cup made of water-soluble material, and pressing, with even pressure, the sample obtained by mixing the mixture of water-insoluble material and matrix until the solvent has evaporated; and melting the pellet cup with water.

A dispense tap with integral gas/liquid infusion for dispensing a beverage at a given dispensing point inside a restaurant, a coffee shop, a bar, or a convenience store, features a mixing chamber having at least one gas input port configured to receive at least one incoming gas stream; at least one liquid input port configured to receive at least one incoming liquid or concentrate stream; and an infuser configured to mix the at least one incoming gas stream and the at least one incoming liquid or concentrate stream at the given dispensing point within the dispensing tap, and provide a mixing chamber stream containing a gas infused liquid mixture of the at least one incoming gas stream and the at least one incoming liquid or concentrate stream for dispensing as a beverage. The degree of absorption of the at least one incoming gas stream and the at least one incoming liquid or concentrate stream in the gas infused liquid mixture depends at least in part on sensed gas, liquid or concentrate pressure characteristics of one or more of the at least one incoming gas stream received by the infuser, the at least one incoming liquid or concentrate stream received by the infuser, or the gas infused liquid mixture provided from the infuser.

An insert for a liquid-holding container may include a body comprising a wall, an open top end and a bottom end, and a generally tubular lumen extending from the open top end to the open bottom end. The insert may include a plurality of first openings formed in the wall, the first openings being situated between the top and bottom ends, wherein each of the plurality of first openings defines an area, and wherein the plurality of first openings have substantially the same dimensions. The insert may include one or more second openings formed in the wall, the one or more second openings being situated between the top and bottom ends, wherein each of the one or more second openings defines an area that is greater than the area defined by any of the first openings, wherein the one or more second openings have substantially the same dimensions.

Systems and methods are described for dissolving ammonia gas in deionized water. The system includes a deionized water source and a gas mixing device including a first inlet for receiving ammonia gas, a second inlet for receiving a transfer gas, and a mixed gas outlet for outputting a gas mixture comprising the ammonia gas and the transfer gas. The system includes a contactor that receives the deionized water and the gas mixture and generates deionized water having ammonia gas dissolved therein. The system includes a sensor in fluid communication with at least one inlet of the contactor for measuring a flow rate of the deionized water, and a controller in communication with the sensor. The controller sets a flow rate of the ammonia gas based on the flow rate of the deionized water measured by the sensor, and a predetermined conductivity set point.