Humidity transmitters provide electrical outputs that are proportional to humidity inputs. They measure variables such as relative humidity, absolute humidity, specific humidity, moisture content, dew point, temperature, and pressure. Relative humidity is a measure of the amount of water in the air compared with the amount of water that the air can hold at the measured temperature. Absolute humidity is the mass of water vapor in a given volume of air. Specific humidity is absolute humidity divided by the total mass of the given volume of air. Moisture content or water content is the ratio of water mass to total mass. Dew point is the temperature to which air must be cooled in order for saturation to occur. Some humidity transmitters measure pressure. Others measure temperature. Typically, devices that measure pressure or temperature include additional probes.
Humidity transmitters use several technologies. Capacitive devices contain a dielectric material whose properties change as humidity is detected and capacitance increases. Resistive devices exhibit changes in impedance in response to humidity. Humidity transmitters that use chilled mirrors are cooled to a specific temperature, the dew point, at which moisture begins to condense on the surface. Electrolytic devices measure moisture proportional to the current needed to electrolyze it from a desiccant. Infrared (IR) instruments use the infrared spectrum to measure the absorption of moisture. With microwave-based devices, the amplitude and phase of a microwave signal is affected directly by the amount of moisture in a material. Psychrometers determine relative humidity by measuring the temperature difference between two thermometers, one wet and one dry. Strain gauges or piezoresistive elements measure the expansion of materials that absorb water. Nuclear humidity transmitters measure how neutrons are slowed by the presence of moisture in a material.
Selecting humidity transmitters requires an analysis of performance specifications and features. Performance specifications include operating temperature, relative humidity range, relative humidity accuracy, dew point range, and dew point accuracy. Relative humidity range and dew point range are ambient ranges that can be measured with a linear response. Relative humidity accuracy and dew point accuracy are percentages that indicate the closeness of a computed amount to its true value. Some humidity transmitters are temperature-compensated and maintain constant output readings across a range of temperatures. Other devices are pressure-compensated. Features for humidity transmitters include self-calibration, self-testing, diagnostics, and data logging. Event-triggered humidity transmitters can be configured to capture or log data when an event occurs. Battery-powered devices use batteries for full operation, not just backup.
Humidity transmitters differ in terms of display type, electrical outputs, and digital outputs. There are three basic types of displays. Analog meters or gauges use needles or light emitting diode (LED) indicators. Digital readouts are numerical or application-specific displays. Video display terminals (VDT) include cathode ray tubes (CRT) and flat panel displays (FPD). Electrical outputs for humidity transmitters include analog currents, analog voltages, frequencies or pulses, and switches or relays. Digital outputs include Ethernet, modems, parallel interfaces, serial interfaces, small computer systems interface (SCSI), transistor-transistor logic (TTL), and universal serial bus (USB).
Sebastian
G.M. Technical
Nunes Instruments
645 Hundred Feet Road,
Coimbatore. 641012.
Tamil Nadu
India,
Web: www.nunesinstruments.com
Web: www.nunesinstruments.asia
Mail: info@nunesinstruments.com
Mobile: 09345226022
Experienced Instrumentation Engineer shares technical information and tips to be used by Instrumentation Professionals, Students and Educators.
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