A method for determining additive manufacturing parameters for the manufacture of an additive manufacturing support (1) for a target part exhibiting an overhang comprises the steps of: (a) additive manufacture of a plurality of supports for each supporting an overhang (2) of a test part (3), each support (1) being associated with a collection of manufacturing parameters and a collection of geometric parameters pertaining to the overhang (2); (b) manufacturing the test part (3) and observing, for each support (1), a collection of mechanical parameters pertaining to the support (1); (c) determining the additive manufacturing parameters for the manufacture of the support (1) of the target part on the basis of the geometric parameters pertaining to the overhang of the target part and of the mechanical parameters pertaining to the support.

The present invention relates to a method for characterizing a coating, in which method a mass and/or a volume of a basic body is/are measured prior to coating; a mass and a volume of the basic body with the applied coating are measured; for characterizing the coating, a density of the coating is determined from the volume and mass measurements; wherein the volume is optically measured.

A portable moisture trap for use with a vacuum pump includes: a housing; a cooling chamber positioned at least partially within the housing including a first inlet port and a second outlet port; a lid that sealably attaches to a top portion of the cooling chamber to seal the cooling chamber; a heat sink residing under the cooling chamber; a thermoelectric device having an upper cooling side and a lower heat generating side residing between the cooling chamber and the heat sink; a fan oriented to blow air upwardly toward the heat sink; and a baffle extending downwardly in the cooling chamber from a location proximate the lid to a location proximate an inner bottom surface of the cooling chamber, with the baffle configured to define a physical barrier to urge air received through the first port to flow down toward the inner bottom surface of the cooling chamber before exiting through the second port, to thereby remove moisture from air traveling through the cooling chamber in response to a vacuum pump in fluid communication with the second port.

The method of predicting a formed body density includes: a correlation calculating step of obtaining the correlation between the formed body density of the formed body and the porosity of the fired body; and a formed body density predicting step including: in a case of preparing a kneaded material A from a ceramic raw material having substantially the same composition as a ceramic raw material used for preparing a kneaded material, preparing a formed body B by forming the kneaded material A, preparing a dried body C by drying the formed body B, and preparing a fired body D having a desired porosity by firing the dried body C, calculating a predicted value of the formed body density of the formed body B corresponding to the desired porosity of the fired body D using the correlation.

A device for measuring powder bed density (PBD) (powder density for a layer) in additive manufacturing (AM) during operation. The device comprises means for determining a mass of the powder and means for determining a volume of the powder during spreading, thereby allowing determination of the powder bed density (powder density for the layer). The means for determining a volume of the powder comprises a laser assembly adapted to move a laser across a powder layer surface in both left and right directions for scanning. The device further allows for the determination of the layer surface profile as well as static and dynamic powder characteristics of the processes involved in the AM operation.

The present disclosure relates to devices and methods for determining the density of insulation. For example, one aspect of the disclosure is a device that includes a sound generator and one or more sound sensors configured to detect sound that is generated by the sound generator and transmitted through the insulation to the one or more sound sensors. The device also includes a control system configured to cause the sound generator to generate the sound and use the sound detected by the one or more sound sensors to generate output that represents the density of the insulation. Another aspect of the disclosure is a method for using the device to determine the density of insulation.

An arrangement for measuring a volume of a solid or liquid sample includes a first chamber for accommodating the sample; at least one second chamber connectable to the first chamber; a third chamber connectable to a gas supply source and connected to a gas entry path leading to at least one of the first chamber and the second chamber; a pressure sensor; plural gas paths comprising plural valves; a temperature equalization system configured to temper at least the first chamber, the second chamber and the third chamber to substantially a same temperature, wherein the gas paths and the valves are arranged and connected such as to allow, filling gas out of the third chamber into at least one of the first chamber and the second chamber, and measuring a pressure in at least one of the first chamber and the second chamber.

A rubber detection system for rubber raw material includes a controller, a rubber sampling module, a rubber calender, a temperature control module, a mooney sensor, a power meter, an expansion ratio detection module, a rotation counter, and a specific gravity detection module. The rubber sampling module obtains a rubber to be tested consistent with a weight value. After the temperature control module determines that the rubber to be tested has reached a temperature value, the rubber calender outputs the rubber to be tested having a thickness value. The power meter records and obtains a power consumption value form the rubber calender. The expansion ratio detection module obtains an expansion ratio based on the thickness value and a roller spacing. The rotation counter obtains the number of rotations of the rubber calender. The specific gravity detection module obtains an actual specific gravity value of the rubber to be tested.

A method for controlling a material flow rate from a metering system of an agricultural system includes receiving at a controller, a weight of a material in a storage tank. The method also includes receiving, at the controller, a volume of the material in the storage tank. The method also includes determining, via the controller, a density of the material in the storage tank using the weight of the material in the storage tank and the volume of the material in the storage tank. The method further includes determining, via the controller, a calibration of the metering system based on the density of the material in the storage tank.

An arrangement for measuring a volume of a solid or liquid sample includes a first chamber for accommodating the sample; at least one second chamber connectable to the first chamber; a third chamber connectable to a gas supply source and connected to a gas entry path leading to at least one of the first chamber and the second chamber; a pressure sensor; plural gas paths comprising plural valves; a temperature equalization system configured to temper at least the first chamber, the second chamber and the third chamber to substantially a same temperature, wherein the gas paths and the valves are arranged and connected such as to allow, filling gas out of the third chamber into at least one of the first chamber and the second chamber, and measuring a pressure in at least one of the first chamber and the second chamber.