Abstract: There are disclosed monitoring and advanced asset recovery devices and systems (“MAARS”). In an embodiment, a MAARS device includes a housing, a circuit board fixedly attached to the housing, affixed to the circuit board is a processor/microcontroller/minicomputer, electronic components to support the microcontroller, sensor modules, wireless modules, a power source, and an antenna. Each of the microcontroller, electronic components, sensor modules, wireless modules, and power source form an integrated circuit and are in communication with one another. The monitoring and advanced asset recovery device is configured to be installed inside a container where the device will measure and monitor a number of variables to determine the status, condition, and location of the container. Other embodiments are also disclosed.

Abstract: A fuel pump for a direct injection internal combustion engine having a housing defining a pump chamber. Driven and idler toothed gears are rotatably mounted within the pump chamber so that the driven and idler gears are in mesh with each other at a predetermined location in the pump chamber. A fluid inlet is formed through the housing and open to an inlet subchamber in the pump chamber. A fluid outlet is also formed through the housing and open to an outlet subchamber in the pump chamber. A pressure relief passageway fluidly connects the inlet subchamber to the outlet subchamber and a valve is disposed in series with the pressure relief passageway. A control circuit controls the actuation of the valve to control the pump pressure at the pump outlet.

Abstract: A system with a first analytical testing device configured collect a first and second signal associated with a characteristic parameter of a sample material, wherein the characteristic parameter is capable of enabling evaluation of ethanol production yield for plant material corresponding to the sample material. A drying unit is configured to drive the sample material to a substantially standard moisture level. A fermentation unit is configured to ferment the sample material. A second analytical testing device is configured to collect a reference measurement associated with the characteristic parameter. The reference measurement is capable of being correlated to the first and second signals for building a calibration model used to evaluate ethanol production yield of plant material corresponding in composition to the sample material. Associated methods are also provided.

Abstract: A fuel pump for a direct injection internal combustion engine having a housing defining a pump chamber. Driven and idler toothed gears are rotatably mounted within the pump chamber so that the driven and idler gears are in mesh with each other at a predetermined location in the pump chamber. A fluid inlet is formed through the housing and open to an inlet subchamber in the pump chamber. A fluid outlet is also formed through the housing and open to an outlet subchamber in the pump chamber. A pressure relief passageway fluidly connects the inlet subchamber to the outlet subchamber and a valve is disposed in series with the pressure relief passageway. A control circuit controls the actuation of the valve to control the pump pressure at the pump outlet.

Abstract: Provided herein are high throughput methods for converting starch-containing plant material to ethanol, wherein the conversion process is performed at a small scale. This high-throughput screening platform permits the evaluation of the ethanol obtained from starch-containing plant material in a rapid and efficient manner. The methods include obtaining a plurality of samples of starch-containing plant material and drying the samples to achieve a desired moisture level. The dried samples are liquefied under conditions sufficient to hydrolyze the starch-containing plant material to soluble dextrinized substrates. The liquefied samples are fermented in small volume headspace vials for a period of less than about 96 hours, and fermentation is terminated by pasteurization. Ethanol production is evaluated using headspace gas chromatography.

Abstract: Provided herein are high throughput methods for converting starch-containing plant material to ethanol, wherein the conversion process is performed at a small scale. This high-throughput screening platform permits the evaluation of the ethanol obtained from starch-containing plant material in a rapid and efficient manner. The methods include obtaining a plurality of samples of starch-containing plant material and drying the samples to achieve a desired moisture level. The dried samples are liquefied under conditions sufficient to hydrolyze the starch-containing plant material to soluble dextrinized substrates. The liquefied samples are fermented in small volume headspace vials for a period of less than about 96 hours, and fermentation is terminated by pasteurization. Ethanol production is evaluated using headspace gas chromatography.

Abstract: A system is provided to calibrate for a near infrared analytical testing device configured to screen for ethanol production yield of an ethanol-producing material. The system comprises a first analytical testing device configured collect a first and second signal associated with a characteristic parameter of a sample material, wherein the characteristic parameter is capable of enabling evaluation of ethanol production yield for plant material corresponding to the sample material. A drying unit is configured to drive the sample material to a substantially standard moisture level. A fermentation unit is configured to ferment the sample material. A second analytical testing device is configured to collect a reference measurement associated with the characteristic parameter. The reference measurement is capable of being correlated to the first and second signals for building a calibration model used to evaluate ethanol production yield of plant material corresponding in composition to the sample material.