To provide an exhaust gas sampling mechanism which can prevent condensed water droplets in exhaust gas from being sampled by a sampling probe and advantageously sample only the gas components of the exhaust gas to be measured, thereby maintaining a high response speed in analyzing the exhaust gas, the exhaust gas sampling mechanism includes the sampling probe disposed in a flow path through which the exhaust gas flows, for sampling the exhaust gas; and a gas-permeable cover which covers at least an upstream portion or a lateral surface portion of the sampling probe in the flow path, and has a water droplet removing structure.

A device and method for correcting emissions can include a first sensor that measures a sample of air not containing an exhaust gas, and a second sensor, wherein the exhaust gas enters a settling chamber and a relative humidity of the exhaust gas is measured by the second sensor. A microcomputer can calculate a mass of water vapor in the sample of air measured by the first sensor and in the exhaust gas measured by the second sensor and can determine a dilution factor of the measured exhaust gas. The dilution factor can be used for correcting emissions based on the measurements of the exhaust gas made by the first sensor and the second sensor. The first and second sensors can comprise one or more of, for example, a relative humidity sensor, a dew point sensor, a trace water vapor sensor and/or other types of sensors.

An emission detection system an enclosed combustion device stack is disclosed. The detection system has a sampling line having a first end exposed to a combusted gas passing through the stack exit port, to receive an undiluted gas sample from the stack exit port. The detection system has an electrostatic particulate matter sensor coupled to a second end of the sampling line, the second end positioned lower than and downstream of the first end, to analyze the undiluted gas sample. The detection system has an exhaust outlet coupled to and downstream of the electrostatic particulate matter sensor, to receive the undiluted gas sample from the electrostatic particulate matter sensor and feed the undiluted gas sample to the primary gas intake line upstream of the enclosed combustion device stack burner.

A method of obtaining the concentration of one component in a fluid mixture of a plurality of components, comprising leading to one side of a sensing element from a source of said mixture a sample of said mixture, leading to another side of said sensing element from said source another sample of said mixture after having substantially removed said one component therefrom, thereby to cause a monitoring device to which said sensing element is connected to signal the ratio between the concentrations of the one component in the samples at the respective sides of the sensing element.

A device and method for correcting emissions can include a first sensor that measures a sample of air not containing an exhaust gas, and a second sensor, wherein the exhaust gas enters a settling chamber and a relative humidity of the exhaust gas is measured by the second sensor. A microcomputer can calculate a mass of water vapor in the sample of air measured by the first sensor and in the exhaust gas measured by the second sensor and can determine a dilution factor of the measured exhaust gas. The dilution factor can be used for correcting emissions based on the measurements of the exhaust gas made by the first sensor and the second sensor. The first and second sensors can comprise one or more of, for example, a relative humidity sensor, a dew point sensor, a trace water vapor sensor and/or other types of sensors.

A built-in multi-zone fast evenly mixed sampling device of a Selective Catalytic Reduction (SCR) outlet flue is provided. The device includes: a sampling component, comprising a sampling branch pipe disposed on an outer wall of the SCR outlet flue, a sampling pool connected with the sampling branch pipe and a slanting branch pipe connected between the sampling pool and the sampling branch pipe, wherein a sampling probe is disposed on the sampling pool; a dust cleaning component, comprising a flange disposed on an upper end of the sampling branch pipe, a connecting line disposed on the flange and a suspension iron disposed on a lower end of the connecting line, wherein a lower end of the suspension iron extends out of the sampling branch pipe; and a replacement component, disposed at the sampling pool.

A sample fluid stream can be received from a main fluid stream through a nozzle of a probe located at least partially in the main fluid stream. The sample fluid stream can travel into the nozzle and a portion of the main fluid stream adjacent to the sample fluid stream can flow past the probe without entering the probe. The sample fluid stream can flow downstream within the probe, and a portion of the main fluid stream can flow downstream outside the probe. While receiving the sample fluid stream, a gas sheet can be directed from the probe, with the gas sheet flowing upstream against the main fluid stream.

The apparatus for diluting exhaust gas according to an exemplary embodiment of the present invention includes a stagnant air forming unit configured to form stagnant air by decelerating a flow velocity of introduced exhaust gas, an ejector unit connected to a front end of the stagnant air forming unit and configured to discharge the exhaust gas to a front, and a dilution unit coupled to a front end of the ejector unit.

The invention relates to a sampling apparatus and method. In the sampling method, a sample is led through a flowline (20) to a pump (5) and from there on to sampling means (12, 13). According to the invention, the pump (5) is formed of an actual pump (5) and magnetic valves (4, 6) located on either side of it, which are controlled in such a way that the pumping is pulse-like.

A sample fluid stream can be received from a main fluid stream through a nozzle of a probe located at least partially in the main fluid stream. The sample fluid stream can travel into the nozzle and a portion of the main fluid stream adjacent to the sample fluid stream can flow past the probe without entering the probe. The sample fluid stream can flow downstream within the probe, and a portion of the main fluid stream can flow downstream outside the probe. While receiving the sample fluid stream, a gas sheet can be directed from the probe, with the gas sheet flowing upstream against the main fluid stream.