An inspection apparatus comprises a first channel that passes an aqueous sample therethrough, a second channel that passes a phosphate eluent therethrough, a separation device that separates by size a group of substances contained in the aqueous sample, and a TOC device that oxidizes each substance separated by the separation device by size and measures organic carbon contained in each substance. The separation device includes a column for size-exclusion chromatography and a sample injection unit that introduces the aqueous sample into a mobile phase passed through the first channel. The second channel is connected to the first channel between the column and the sample injection unit, and causes the phosphate eluent to merge with the aqueous sample between the sample injection unit and the column.

A device for measuring the total organic carbon content (TOC) of a sample fluid comprises a measuring cell (2) defining a volume (3) for containing a sample fluid and an excimer lamp (20) arranged to cause an oxidation reaction of the sample fluid by emitting radiation onto the sample fluid in the volume (3). A pair of electrodes is arranged to measure the conductivity of the sample fluid during the oxidation reaction and at least one temperature senor (31) is arranged on the measuring cell (2) to measure a temperature that is related to the sample fluid. The total organic carbon content (TOC) of the sample fluid is determined on the basis of the measured conductivity compensated by the temperature related to the sample fluid.

An instrument and a method for simultaneously testing a molecular weight distribution and an organic nitrogen level of a water sample are provided. The instrument comprises: a tail-end injection valve, a chromatographic column, a pressure relief valve, an acid-adding injection valve, an oxygen-adding injection valve, a helical tube for an acid-oxygen reaction, a CO.sub.2 remover, a UV digester, a second gas-water separator membrane, a buffer solution injection valve, a helical tube for a buffer solution reaction, a cadmium column, a chromogenic agent injection valve, a helical tube for a chromogenic agent reaction, and a UV detector, sequentially connected via a pipeline. The tail-end injection valve is for receiving a fluid phase and a sample. The second gas-water separator membrane is connected to an electrical conductivity-based CO2 detector. The UV detector and the electrical conductivity-based CO.sub.2 detector are connected to a data processing computer.

An abnormality of a state in a system between a combustion tube and a detector can be detected without increasing device cost. An instrument for elemental analysis includes a combustion tube (2) that has a sample injection port (3) with an open top and is for combusting a liquid sample in the inside, a sample injection mechanism (6) having a nozzle (10) and a slider (8), the nozzle (10) being for injecting a sample into the combustion tube, and the slider (8) being configured to slide between a first position and a second position above the combustion tube (2), the sample injection mechanism (6) being configured so that the sample injection port (3) of the combustion tube (2) is sealed in a state where the slider (8) is positioned at the first position, and the sample injection port (3) is unsealed and the nozzle (10) is positioned above the sample injection port (3) in a state where the slider (8) is positioned at the second position, a carrier gas supply flow path (26) communicating with the inside of the combustion tube (2) to supply carrier gas into the combustion tube (2), a pressure sensor (30) for detecting pressure in the carrier gas supply flow path (26), a detector (22) that detects a component in sample gas flowing out of the combustion tube (2), and an arithmetic part (44) configured to determine an abnormality degree of a state in a system between the combustion tube and the detector based on a change in pressure, which is detected by the pressure sensor (30), at the time when the slider (8) of the sample injection mechanism (6) slides from the first position to the second position.

An inspection apparatus includes a measurement unit, a flow-in tube for flow of sample water into the measurement unit, a connection portion that connects a sample tube and the measurement unit to each other, a liquid sending portion that sends sample water to the measurement unit, a pressurization pump that increases a pressure in the inside of the sample tube, and a controller. The controller controls operations of the liquid sending portion and the pressurization pump to suppress within a prescribed range, variation in pressure applied to sample water until sample water reaches the measurement unit from the inside of the sample tube.

A method and system are disclosed for determining surfactant concentration levels in aqueous solutions. In accordance with the method of the present disclosure, a related carbon parameter, such as COD or TOC, is measured in an aqueous solution. This measurement is then converted to surfactant concentration using a mathematical correlation or reference data. Through the method and system of the present disclosure, surfactant concentrations in process streams can be monitored and adjusted on the fly.

In an embodiment, a TOC analyzer is provided. The TOC analyzer includes one or more processors and a memory communicably coupled to the one or more processors. The memory stores instructions that when executed by the one or more processors cause the one or more processors to: receive a sample having a known TOC and conductivity, wherein the sample comprises an organic acid; measure a TOC of the sample; and measure a conductivity of the sample. The TOC and conductivity are measured at approximately the same time using the same sample resulting in an improvement over existing systems for TOC and conductivity verification.

Methods and systems are described for evaluating the level of organic contaminants in water, and in particular water that is used as boiler feedwater in food processing facilities such as sugar factories. The method includes measuring at least one parameter of the water including pH, conductivity, and/or total organic carbon, and, based on the measured values, determining whether corrective action needs to be taken to reduce the levels of organic contaminants.

The present invention relates to a sensor (1) for sensing organic carbon in a liquid (L), comprising: a container (2) having an interior space (20) for receiving the liquid (L), a photodetector (3), and a light source (4) configured to emit ultraviolet light (5) so that the ultraviolet light (5) travels along an optical path (P) through liquid (L) residing in the interior space (20) and is absorbable by carbon bonds of organic molecules in the liquid (L). According to the present invention, the photodetector (3) is configured to detect light in the visible or infrared spectrum, and the sensor (1) comprises a down conversion material portion (22; 22a) arranged in the optical path, wherein the down conversion material portion (22; 22a) is configured to receive incoming ultraviolet light (5) emitted by the light source (4) and to down convert received ultraviolet light (5) and to emit said down converted light (50) in the visible or infrared spectrum so that emitted down converted light (50) impinges on the photodetector (3).

An abnormality of a state in a system between a combustion tube and a detector can be detected without increasing device cost.

An instrument for elemental analysis includes a combustion tube (2) that has a sample injection port (3) with an open top and is for combusting a liquid sample in the inside, a sample injection mechanism (6) having a nozzle (10) and a slider (8), the nozzle (10) being for injecting a sample into the combustion tube, and the slider (8) being configured to slide between a first position and a second position above the combustion tube (2), the sample injection mechanism (6) being configured so that the sample injection port (3) of the combustion tube (2) is sealed in a state where the slider (8) is positioned at the first position, and the sample injection port (3) is unsealed and the nozzle (10) is positioned above the sample injection port (3) in a state where the slider (8) is positioned at the second position, a carrier gas supply flow path (26) communicating with the inside of the combustion tube (2) to supply carrier gas into the combustion tube (2), a pressure sensor (30) for detecting pressure in the carrier gas supply flow path (26), a detector (22) that detects a component in sample gas flowing out of the combustion tube (2), and an arithmetic part (44) configured to determine an abnormality degree of a state in a system between the combustion tube and the detector based on a change in pressure, which is detected by the pressure sensor (30), at the time when the slider (8) of the sample injection mechanism (6) slides from the first position to the second position.