A portable vacuum pressure graphing gauge device enabling users of vacuum systems the ability to see trends of vacuum systems through real time plotting of a pressure vs. time curve on a hand held instrument, enabling them to understand what is going on in their system, or the like. A device may include several graphical modes designed to even more easily interpret vacuum data, and packaging that is rugged and versatile including a magnet, kickstand, wireless connectivity, visual and audible set points, automatic sensor fault detection, and several vacuum pressure measurement units to choose from, or the like.

A manner to determine pressure (e.g. inside a vacuum package, such as a MEMS die), without prior calibration, is provided using a model and a set of one or more gauges (e.g. Pirani, thermistor, thermocouple gauges) with distinct geometries. In order to calculate pressure from the electrical measurements performed on the gauges, there are several intermediate steps and an analytical model describes each of these steps. Besides the electrical measurements, other inputs are required, such as material properties and certain dimensions, which may not be known accurately. Several different gauge geometries are proposed which can be combined in order to determine the vacuum (pressure) level without knowing the values of these inputs beforehand.

A manner to determine pressure (e.g. inside a vacuum package, such as a MEMS die), without prior calibration, is provided using a model and a set of one or more gauges (e.g. Pirani, thermistor, thermocouple gauges) with distinct geometries. In order to calculate pressure from the electrical measurements performed on the gauges, there are several intermediate steps and an analytical model describes each of these steps. Besides the electrical measurements, other inputs are required, such as material properties and certain dimensions, which may not be known accurately. Several different gauge geometries are proposed which can be combined in order to determine the vacuum (pressure) level without knowing the values of these inputs beforehand.

A vacuum insulator (10) includes: a core (13); a pressure sensor (51) that detects a pressure; a transmitter (52) that transmits, by wireless communication, the detected pressure detected by the pressure sensor (51); a power feeder (53) that feeds electric power to the pressure sensor (51) and the transmitter (52); and an outer skin (14), an inside of which is decompressed, the outer skin (14) accommodating therein the core (13), the pressure sensor (51), the transmitter (52), and the power feeder (53), the outer skin (14) having gas barrier capability.

A portable vacuum pressure graphing gauge device enabling users of vacuum systems the ability to see trends of vacuum systems through real time plotting of a pressure vs. time curve on a hand held instrument, enabling them to understand what is going on in their system, or the like. A device may include several graphical modes designed to even more easily interpret vacuum data, and packaging that is rugged and versatile including a magnet, kickstand, wireless connectivity, visual and audible set points, automatic sensor fault detection, and several vacuum pressure measurement units to choose from, or the like.

An improved method for determining pressure in a lyophilisation system containing a lyophilisation chamber and a condenser chamber wherein a freeze drying operation is being performed is provided for. The improved method uses a temperature measuring device such as a thermocouple or a temperature resistance device to measure temperature and from this measurement the pressure of the components in the lyophilisation chamber can be calculated using a predetermined relationship between temperature and pressure.

A thermal conductivity gauge measures gas pressure within a chamber. A sensor wire and a resistor form a circuit coupled between a power input and ground, where the sensor wire extends into the chamber and connects to the resistor via a terminal. A controller adjusts the power input, as a function of a voltage at the terminal and a voltage at the power input, to bring the sensor wire to a target temperature. Based on the adjusted power input, the controller can determine a measure of the gas pressure within the chamber.

A thermal conductivity gauge measures gas pressure within a chamber. A sensor wire and a resistor form a circuit coupled between a power input and ground, where the sensor wire extends into the chamber and connects to the resistor via a terminal. A controller adjusts the power input, as a function of a voltage at the terminal and a voltage at the power input, to bring the sensor wire to a target temperature. Based on the adjusted power input, the controller can determine a measure of the gas pressure within the chamber.

A thermal conductivity gauge measures gas pressure within a chamber. A sensor wire and a resistor form a circuit coupled between a power input and ground, where the sensor wire extends into the chamber and connects to the resistor via a terminal. A controller adjusts the power input, as a function of a voltage at the terminal and a voltage at the power input, to bring the sensor wire to a target temperature. Based on the adjusted power input, the controller can determine a measure of the gas pressure within the chamber.

A thermal conductivity gauge measures gas pressure within a chamber. A sensor wire and a resistor form a circuit coupled between a power input and ground, where the sensor wire extends into the chamber and connects to the resistor via a terminal. A controller adjusts the power input, as a function of a voltage at the terminal and a voltage at the power input, to bring the sensor wire to a target temperature. Based on the adjusted power input, the controller can determine a measure of the gas pressure within the chamber.