Abstract: A gas measuring device (100) and a gas measuring process measure a concentration of a combustible target gas (CH4). A detector (10), having a detector heating segment (20), oxidizes combustible target gas. A compensator (11) having a compensator heating segment (30) oxidizes less or no target gas. A temperature sensor (14) measures the ambient temperature. A first detection variable (?U_B) depends on the detector temperature, a second detection variable (U11) depends on the compensator temperature. An evaluation unit (9) applies a first and a second functional relationship in order to determine, depending on the two detection variables (?U_B, U11), both the target gas concentration and a further environmental condition, particularly the ambient humidity. The second functional relationship, a dependence between the further environmental condition on the one hand and the detection variables and the ambient temperature on the other hand, is valid if no target gas is present.

Abstract: A device and process monitor a spatial area for a target gas. A sensor of the gas detection device used has a detection variable (?Ukorr,0) that is affected by the concentration of target gas. A detection variable sensor measures this detection variable (?Ukorr,0). The influence of a slower influencing variable and of a faster influencing variable, on the detection variable (?Ukorr,0), are computationally compensated to determine an influence-corrected detection variable (?Ukorr,1). Depending on the influence-corrected detection variable (?Ukorr,1), the target gas concentration is determined. For computational compensation, the time course (Dr[?Ukorr,0]) of the respective influence of the two influencing variables is estimated, for which a measurement value series from the detection variable sensor is used.

Abstract: A heat tone sensor includes a housing with a gas inlet and with a gas outlet as well as a device for generating a gas stream of a gas to be tested between the gas inlet and the gas outlet. A measuring element, around and/or through which the gas stream flows, is configured to catalytically burn at least a portion of the gas stream and to send a measurement signal. The measurement signal indicates a quantity of heat released in the process.

Abstract: A gas detection device and a process monitor an area for a combustible target gas. A heating segment of a detector (10) is heated when electrical current flows therethrough. A heating segment of a compensator (1) is heated when electrical current flows therethrough. An electrical voltage is applied to both the detector and the compensator. The heating of the detector (10) causes a combustible target gas to be oxidized in an interior of the gas detection device. A detection variable, which depends on the temperature (Temp_10) of the detector, and a detection variable, which depends on the temperature (Temp_11) of the compensator, are measured. A presence and/or a concentration of a target gas are determined as a function of the detection variables. A quality parameter is measured and increases as the detection variable depending on the detector temperature increases and as the detection variable depending on the compensator temperature decreases.

Abstract: A gas detection device and a gas detection process monitor an area for a combustible target gas. A detector (10), a compensator (11.1), a sensor array (40, 41) and an analysis unit (9) are arranged in a gas detection device housing. The detector includes an electrically conductive wire with a heating segment (20), electrical insulation around the wire and a catalytic material in the electrical insulation. The compensator extends in a plane and includes an electrical strip conductor (32) with a heating segment and a carrier plate for the strip conductor. The gas detection device applies an electrical voltage to the detector and to the compensator. The detector oxidizes the target gas with the heating segment. The sensor array measures detection variables (U10, U11) for the detector and the compensator. The analysis unit compares the two detection variables to determine if a combustible target gas is present.

Abstract: A gas detection device and process detect a combustible target gas. A detector chamber (6) encloses a detector (10), and a modulator chamber (5) encloses a modulator (15). The target gas can flow from an area to be monitored through into the modulator chamber and from the modulator chamber into the detector chamber. An electrical voltage is applied to the modulator and to the detector to heat them, oxidizing the target gas in the modulator chamber and in the detector chamber. Heat energy is released bringing about an increase of the temperature of the detector. A detector sensor measures a detection variable which depends on the detector temperature. The voltage is applied to the modulator such that the temperature of the modulator oscillates. An analysis unit checks whether the detection variable oscillates synchronously with the modulator temperature, indicating the target gas is present.

Abstract: A gas sensor 100 includes a housing 110 and with a measuring element 10. The measuring element 10 has a heating coil 20, which is coated with a catalytically active or inactive ceramic 30. The ceramic 30 contains a fibrous material. The fibrous material may be, for example, a glass fiber material.

Abstract: A heat tone sensor includes a housing with a gas inlet and with a gas outlet as well as a device for generating a gas stream of a gas to be tested between the gas inlet and the gas outlet. A measuring element, around and/or through which the gas stream flows, is configured to catalytically burn at least a portion of the gas stream and to send a measurement signal. The measurement signal indicates a quantity of heat released in the process.

Abstract: A filter material is for the selective removal of siloxanes from a gas. The filter material contains a titanium compound, which is an organotitanate and/or a compound, which can be obtained by hydrolysis of an organotitanate. A method for the production of the filter material is also provided to use the filter material for the selective removal of siloxanes from a gas. A gas sensor is provided which includes the filter material.

Abstract: A filter material is for the selective removal of siloxanes from a gas. The filter material contains a titanium compound, which is an organotitanate and/or a compound, which can be obtained by hydrolysis of an organotitanate. A method for the production of the filter material is also provided to use the filter material for the selective removal of siloxanes from a gas. A gas sensor is provided which includes the filter material.

Abstract: A gas sensor 100 includes a housing 110 and with a measuring element 10. The measuring element 10 has a heating coil 20, which is coated with a catalytically active or inactive ceramic 30. The ceramic 30 contains a fibrous material. The fibrous material may be, for example, a glass fiber material.

Abstract: A gas sensor is provided for use in a hazardous explosive atmosphere present continuously or for a long time. The gas sensor is not provided with a pressure-proof housing and is provided with at least one catalytic or semiconductor measuring element (3) in a hollow body (6) defining the measuring element (3) against the environment. The hollow body has breathing openings (4) and wherein the ratio of the area of the breathing openings to the total area of the hollow body equals, furthermore, at most 0.8 or the hollow body is porous with a porous hollow body material having a pore size according to ISO 4003 equal to at most 2 mm.

Abstract: Selective hydrogenation of unsaturated hydrocarbon compounds, e.g. of acetylene to ethylene, uses a hydrogenation catalyst comprising an ordered intermetallic compound. The ordered intermetallic compound comprises at least one metal of type A capable of activating hydrogen, and at least one metal of type B not capable of activating hydrogen. The structure of the ordered intermetallic compound is such that the type A metal is mainly surrounded by atoms of the type B metal.

Abstract: A gas sensor is provided for use in a hazardous explosive atmosphere present continuously or for a long time. The gas sensor is not provided with a pressure-proof housing and is provided with at least one catalytic or semiconductor measuring element (3) in a hollow body (6) defining the measuring element (3) against the environment. The hollow body has breathing openings (4) and wherein the ratio of the area of the breathing openings to the total area of the hollow body equals, furthermore, at most 0.8 or the hollow body is porous with a porous hollow body material having a pore size according to ISO 4003 equal to at most 2 mm.

Abstract: The present invention relates to a process for the hydrogenation, in particular the selective hydrogenation of unsaturated hydrocarbon compounds using a hydrogenation catalyst comprising an ordered intermetallic compound. The ordered intermetallic compound comprises at least one metal of type A capable of activating hydrogen, and at least one metal of type B not capable of activating hydrogen, and the structure of the ordered intermetallic compound is such that at least one king of type A metals is mainly surrounded by atoms of the metal of type B. According to another aspect, the present invention is concerned with a catalyst comprising a support and the above ordered intermetallic compound supported on the support. According to still another aspect, the invention pertains to the use of a binary Pd—Ga ordered intermetallic compound as a catalyst. The hydrogenation process and catalysts of the present invention achieve a selectivity to the target compounds, e.g.