Abstract: Provided is a system for adsorbing a gaseous component comprising nitrogen from a pressurized flow of air containing the gaseous component. The system comprises a first adsorption bed, and a second adsorption bed. Each of the adsorption beds are suitable for selectively adsorbing the gaseous component from the flow of air to produce a product gas having a higher oxygen concentration than that of the air. The system includes an adjustable feed gas supply which alternately supplies the first adsorption bed and the second adsorption bed with the air. The first adsorption bed is supplied with air during a first half cycle of operation of the system, and the second adsorption bed is then supplied with air during a second half cycle of operation of the system. The feed gas supply enables adjustment of at least one parameter relating to the amount or respective amounts of air being supplied to the first adsorption bed in the first half cycle and/or to the second adsorption bed in the second half cycle.

Abstract: The invention provides a method for determining a transportation direction (TD) for a user, the method comprising: receiving a current location (CL) of the user; receiving a pollution based input value (PIV) related to air pollution in a geographical area (GA) including the current location (CL); determining the transportation direction (TD) using the pollution based input value such that the user is subjected to a lowest level of pollution and/or such that a predefined maximum level of pollution to which the user is subjected is not exceeded; and retrieving a human activity based input value, wherein the human activity based input value is based on activity data from a portable device (100) configured to sense an activity level of the human wearing the portable device (100); and updating the transportation direction (TD) using the human activity based input value (HAIV).

Abstract: An optical particle sensor comprises at least first and second light sources of different wavelength for sequential operation. An optical detector is used to detect light from the light sources emitted or scattered by particles to be sensed. A current injection compensation signal is also provided which is dependent on which light source of the optical arrangement is in use. The compensation signal means the amplifier does not need to re-settle in response to different background illumination levels associated with the different light sources. In this way, detection signals may be obtained in quick succession from different light sources.

Abstract: Provided is a system for adsorbing a gaseous component comprising nitrogen from a pressurized flow of air containing the gaseous component. The system comprises a first adsorption bed, and a second adsorption bed. Each of the adsorption beds are suitable for selectively adsorbing the gaseous component from the flow of air to produce a product gas having a higher oxygen concentration than that of the air. The system includes an adjustable feed gas supply which alternately supplies the first adsorption bed and the second adsorption bed with the air. The first adsorption bed is supplied with air during a first half cycle of operation of the system, and the second adsorption bed is then supplied with air during a second half cycle of operation of the system. The feed gas supply enables adjustment of at least one parameter relating to the amount or respective amounts of air being supplied to the first adsorption bed in the first half cycle and/or to the second adsorption bed in the second half cycle.

Abstract: A system is provided for warning of a risk of respiratory attack conditions in geographical region. Input data is obtained in the form of historical weather data, current weather data and forecast weather data, and allergen information such as pollen count data in respect of the geographical region. An advance risk warning is based on a probability of a thunderstorm and on the historical weather data. In combination, the historical weather, 5 allergen information and probability of a thunderstorm may be used to provide a risk assessment of the occurrence of an event in which high concentrations of allergen are present. Preventative and/or preparatory measures may then be adopted.

Abstract: A cooking system combines a food cooking unit and a particle detection system. By deriving a ratio between particle concentrations in at least two size ranges, particular particles may be identified, and the food cooking unit may then be controlled to reduce or eliminate the generation of those particles.

Abstract: The invention provides an optical particle sensor which uses light sources of different first and second wavelengths. A first light source is used to detect light scattering and also to determine when a particle reaches a target positional area. In response to the particle being determined to reach the target positional area, a second light source is operated to provide a pulse of light, and light emitted from the particle in response to the pulse of light is detected by the same detector.

Abstract: Presented is a device for detecting particles, comprising: a first light source positioned for illuminating particles passing through a detection region of the particle detector; a first detector positioned and adapted for detecting light signals from particles illuminated by the first light source in the detection region; a processor configured for determining a type of the particles passing through the detection region from light signals detected by the first detector; characterized in that: the particle detector further comprises: a means for detecting when particles pass through the detection region; and a controller coupled to the means and configured to operate the first light source with a first pulsed current when particles pass through the detection region thereby preserving or extending lifetime of the first light source, and wherein the first pulsed current is selected beyond a continuous current damage threshold of the first light source thereby increasing light output of the first light source.

Abstract: The invention provides a method for determining a transportation direction (TD) for a user, the method comprising: receiving a current location (CL) of the user; receiving a pollution based input value (PIV) related to air pollution in a geographical area (GA) including the current location (CL); determining the transportation direction (TD) using the pollution based input value such that the user is subjected to a lowest level of pollution and/or such that a predefined maximum level of pollution to which the user is subjected is not exceeded; and retrieving a human activity based input value, wherein the human activity based input value is based on activity data from a portable device (100) configured to sense an activity level of the human wearing the portable device (100); and updating the transportation direction (TD) using the human activity based input value (HAIV).

Abstract: The present invention relates to a heating device. In order to allow heating essentially without any latency period and with low costs, the heating device comprises: at least one container (12) having an inlet opening (14) and an outlet opening (16) and comprising an adsorbent agent (18) being provided between said inlet opening (14) and outlet opening (16) and being capable of adsorbing an adsorbate thereby releasing adsorption energy; and a gas conveying device (21) for conveying an adsorbate comprising gas through the interior of the container (12); wherein a gas conduit (22) is provided being connected to the outlet opening (16) of the container (12) for guiding the gas heated by adsorption energy inside the container (12) to a location to be heated with elevated temperature. The present invention further relates to a heating method.

Abstract: The invention provides an optical particle sensor which uses light sources of different first and second wavelengths. A first light source is used to detect light scattering and also to determine when a particle reaches a target positional area. In response to the particle being determined to reach the target positional area, a second light source is operated to provide a pulse of light, and light emitted from the particle in response to the pulse of light is detected by the same detector.

Abstract: An optical particle sensor comprises at least first and second light sources of different wavelength for sequential operation. An optical detector is used to detect light from the light sources emitted or scattered by particles to be sensed. A current injection compensation signal is also provided which is dependent on which light source of the optical arrangement is in use. The compensation signal means the amplifier does not need to re-settle in response to different background illumination levels associated with the different light sources. In this way, detection signals may be obtained in quick succession from different light sources.

Abstract: Presented is a device (100) for detecting particles, comprising: a first light source (101) positioned for illuminating particles (120) passing through a detection region (130) of the particle detector; a first detector (104) positioned and adapted for detecting light signals from particles illuminated by the first light source (101) in the detection region (130); a processor (110) configured for determining a type of the particles passing through the detection region (130) from light signals detected by the first detector (104); characterized in that: the particle detector (100) further comprises: a means (105) for detecting when particles pass through the detection region (130); and a controller (103) coupled to the means (105) and configured to operate the first light source (101) with a first pulsed current when particles pass through the detection region (130) thereby preserving or extending lifetime of the first light source (101), and wherein the first pulsed current is selected beyond a continuous cur

Abstract: An oxygen separator for generating an oxygen-enriched gas from an oxygen comprising gas, said oxygen separator comprising: a) an oxygen separator device comprising i) a sorbent material for sorbing at least one component of the oxygen comprising gas; and ii) at least two controllable interfaces, comprising a first controllable interface and a second controllable interface, for controlling the communication of gas between the inside and the outside of the oxygen separator device, b) a processor for controlling the oxygen separator such that a plurality of phases are sequentially carried, amongst them a purging phase; wherein the processor is configured to control the at least two controllable interfaces such that a flow of gas is generated between the first controllable interface and the second controllable interface during at least the purging phase, wherein the second controllable interface is located and/or controlled such that it controls the fluidic coupling between the inside of the oxygen separator devi

Abstract: The invention relates to an a sensor system (100) for quantitatively detecting at least one compound in a fluid mixture, said fluid mixture comprising the compound to be detected, wherein the sensor system (100) comprises a sorbent material (102) being capable of sorbing the at least one compound to be detected, wherein the sorbent material (102) undergoes a temperature change when sorbing the at least one compound; at least a first temperature sensor (104) for measuring the temperature of the sorbent material (102); and a control unit (110) being adapted for quantitatively determining the at least one compound to be detected based on the temperature change of the sorbent material (102). Such a sensor system (100) provides an improved measurement especially in the field of oxygen concentrators. The invention further relates to an oxygen concentrator (10) for generating oxygen enriched gas as well as to a method of quantitatively detecting at least one compound in a fluid mixture.

Abstract: The invention relates to an oxygen separator for generating a flow of oxygen-enriched gas, said oxygen separator comprising at least two oxygen separation devices arranged to separate oxygen from an oxygen comprising gas, said at least two oxygen separation devices each comprising a first end for receiving the oxygen comprising gas and a second end for delivering an oxygen-enriched gas. The oxygen separator further comprising an equalization duct fluidically coupled to the respective second end of said at least two oxygen separation devices, a first gas sensor is provided in the equalization duct such that the first gas sensor is arranged to monitor at least one component of the oxygen-enriched gas in the equalization duct; and control device arranged to control the oxygen separator based on the monitoring by the first gas sensor.

Abstract: An oxygen separator for generating an oxygen-enriched gas from an oxygen comprising gas, said oxygen separator comprising: a) an oxygen separator device comprising i) a sorbent material for sorbing at least one component of the oxygen comprising gas; and ii) at least two controllable interfaces, comprising a first controllable interface and a second controllable interface, for controlling the communication of gas between the inside and the outside of the oxygen separator device, b) a processor for controlling the oxygen separator such that a plurality of phases are sequentially carried, amongst them a purging phase; wherein the processor is configured to control the at least two controllable interfaces such that a flow of gas is generated between the first controllable interface and the second controllable interface during at least the purging phase, wherein the second controllable interface is located and/or controlled such that it controls the fluidic coupling between the inside of the oxygen separator devi

Abstract: The present invention refers to an oxygen separation system (10), comprising a support (12) for accommodating a plurality of autonomous oxygen separation units (14), wherein the support (12) comprises a plurality of fastening positions having fastening means for receiving an oxygen separation unit (14); and a plurality of autonomous oxygen separation units (14) being attached to said support (12), each oxygen separation unit (14) comprising at least one oxygen separation device (28) with an oxygen separation sorbent (30) being capable of separating oxygen from an oxygen comprising gas by sorbing at least one component of the oxygen comprising gas apart from oxygen, and a gas conveying device (44) for guiding a flow of oxygen comprising gas through the oxygen separation device (28). Such an oxygen separation system (10) may have significant improvements against the systems of the prior art, particularly referring to space, weight, energy consumption, variability, flexibility and maintenance behavior.

Abstract: The invention relates to an oxygen separator (10), comprising at least one oxygen separation device (12, 14) comprising an oxygen separation sorbent (16, 18) for separating oxygen from an oxygen comprising gas, wherein the oxygen separation device (12, 14) comprises a gas inlet (24, 28) at a primary side being connected to an inlet conduct (20) for guiding a flow of oxygen comprising gas into the oxygen separation device (12, 14) and having a gas outlet (34, 36) at a secondary side being connected to an outlet conduct (30, 32) for guiding a flow of oxygen enriched gas out of the oxygen separation device (12, 14), wherein the secondary side of the oxygen separation device (12, 14) is further connected to a source of purging gas for guiding purging gas through the oxygen separation device (12, 14) and wherein the primary side of the oxygen separation device (12, 14) is connected to an exhaust conduct (70, 72) for guiding exhaust gas out of the oxygen separator (10), wherein the oxygen separator (10) further com

Abstract: Skin monitoring device for application near the skin includes a processing circuit and at least one photosensor configured to detect at least one approximate wavelength of light reflected and/or emitted by the skin. A signal receiving circuit receives signals from the photosensor.