DE10018991A1 - Analysis of multiple gas flows at several measuring points, e.g. for varnish drying process, by supplying only gas to be analysed from distributor to analyser - Google Patents

Abstract

The gas flows to be analysed are supplied from the measuring points (2a,b,c,d) to an analyser (11). The gas flows from each measuring point are fed to a distributor (4). Only the gas to be analysed is supplied from the distributor to the analyser (11). The remaining gas flows are drawn off from the distributor. The analyser may measure the oxygen content of the gas flow for the process atmosphere when hardening lacquers. An Independent claim is included for an apparatus for analysing gas flows.

Description

The invention relates to a method for analyzing one of several gas streams at several measuring points, the gas stream to be analyzed being determined by the Measuring point is passed to an analyzer and a device for analyzing a of several gas streams with several measuring points for recording one each Gas flow, one measuring line from each of the measuring points to an analyzer and a primary pump for conveying gas from the measuring points on the Test leads to the analyzer.

Tighter environmental regulations have led to industrial paint shops increasingly switch to the use of radiation-curable coatings. By Irradiation with fast electrons or UV rays can be specially designed Varnishes are cured without the need for volatile solvents or other environmentally harmful emissions occur.

In the radiation curing of paints, however, atmospheric oxygen affects quality the paint layer negative, because the oxygen reacts with the paint surface and the Hardening process slows down or even prevents it. Radiation curing therefore takes place in usually in an inert gas atmosphere, usually in an atmosphere of pure Nitrogen. The concentration of oxygen in the curing zone should be in in a range of about 200 to 1000 ppm.

To monitor the oxygen content in the often meter-long paint shops several measuring points at a distance from each other, at which gas is drawn off and pumped to an analyzer in which the oxygen concentration at the respective measuring point is determined. If the oxygen concentration is too high it can then intervene regulatingly in the process flow.

Usually, for cost reasons, a single analyzer is used for several measuring points used, the individual measuring points over meter-long measuring lines are connected to the analyzer. Here are the dead times when switching between two measuring points is a big problem  Oxygen concentration are determined at different measuring points, then after analyzing the gas atmosphere at the first measuring point, the Line between the first measuring point and the analyzer closed and the The line between the new measuring point and the analyzer is open. Due to the long lines between the measuring point and the analyzer are relatively long Pumping times required until there is one for the new measuring point on the analyzer representative gas concentration. A quick switch between Different measuring points are therefore at the expense of the quality of the measurement result.

Are short measuring intervals required to monitor the process and if the measured values also have to be of high quality, several have so far been required Analyzers are used. In extreme cases there is even one for each measuring point separate analyzer required.

The object of the present invention is to provide a method and an apparatus develop that allow to analyze several gas flows in succession, whereby can be switched quickly between the analyzes of the individual gas flows.

This object is achieved by a method of the type mentioned solved, in which the gas flows from each of the measuring points to a distributor only the gas stream to be analyzed from the distributor to the analyzer is passed and the remaining gas flows are withdrawn from the distributor.

The device according to the invention is characterized in that several Measuring points for detecting a gas flow, one measuring line from each the measuring points to an analyzer and a primary pump for pumping gas are provided from the measuring points via the measuring lines to the analyzer, where a suction line branches off from each measuring line, with all suction lines in one Manifold open, in which a secondary pump is provided, and that in each Intake line and in each measuring line downstream of the branch to the respective Intake line a valve is arranged.

According to the invention, all gas streams are first routed to a distributor. Under In the following, a distributor is understood to be a device which allows everyone the gas streams either to the analyzer or through another line  dissipate. The distributor therefore has at least one branch for each measuring line on. By interposing the distributor, which always with all gas flows is supplied, the dead time problem explained above is solved.

For this purpose, the device according to the invention has a secondary pump with which constantly simultaneously from all measuring points, which are examined with the help of the analyzer, Sample gas is pumped to the distributor. The sample gas from the various measuring points is merged into a manifold after the distributor and withdrawn, in usually conveyed into the open as exhaust gas. Should the gas atmosphere on one of the Measuring points are analyzed, so is the gas flow coming from this measuring point not forwarded to the manifold, but from the distributor directly to Led analyzer. To switch to another measuring point, the previous one Gas flow to the analyzer is interrupted and instead led into the manifold and the gas stream now to be analyzed is diverted from the distributor to the analyzer.

The analyzer is preferably arranged in close proximity to the distributor, d. H. that the line lengths between the distributor and the analyzer are minimized are and particularly preferably so that the flow paths between the manifold and the analyzer for the gas flows obtained at the individual measuring points are the same.

Since the distributor is constantly supplied with gas from all measuring points, this must be done Analyzing gas only from the distributor to the analyzer and not from the respective one Measuring point to be promoted to the analyzer. Even with several far apart spaced measuring points, whereby the analyzer inevitably not in immediate Near all measuring points can be arranged, it is possible to the dead times at Keep switching between different measuring points small.

According to the invention, the gas stream to be analyzed is transferred from the distributor to the Analyzer. A part of this gas flow can also with the rest Gas flows are withdrawn. However, preferably the whole is closed Analyzing gas stream fed to the analyzer, as this will affect the quality of the Analysis is improved.  

To convey the gas to be analyzed from the distributor to the analyzer preferably a primary pump is provided downstream or upstream the analyzer is arranged. The primary pump is particularly preferably located downstream of the analyzer, as this may Analyzed gas from the primary pump entrained impurities Do not negatively influence the analyzer.

The invention and further details of the invention are described below explained in more detail by the embodiment shown in the drawing.

Here, the single figure shows schematically a device for analyzing the Gas atmosphere in a spray hardening system of a paint shop.

During the radiation curing of paints, the paints are irradiated with UV lamps 1 a, 1 b, 1 c, 1 d, which initiates radical chain polymerization, which leads to curing of the paint. The quality of lacquers cured in this way is greatly affected by the presence of oxygen during the curing process. The hardening zone is therefore rendered inert with nitrogen gas and the oxygen concentration in the hardening zone is monitored.

For this purpose, 1 a, 1 b, 1 c, 1 d measuring points 2 a, 2 b, 2 c, 2 d are arranged in the immediate vicinity of each UV lamp. At each measuring point 2 a, 2 b, 2 c, 2 d, gas is drawn off from the surroundings of the respective UV lamp 1 a, 1 b, 1 c, 1 d and via measuring lines 3 a, 3 b, 3 c, 3 d fed to a distributor 4 . In the area 13 , the measuring lines 3 a, 3 b, 3 c, 3 d have different and sometimes considerable lengths, depending on the arrangement of the measuring points 2 a, 2 b, 2 c, 2 d.

In the distributor 4 branch off from the measuring lines 3 a, 3 b, 3 c, 3 d suction lines 5 a, 5 b, 5 c, 5 d, which lead to a common manifold 6 in which there is a secondary pump 7 . The manifold 6 leads downstream of the secondary pump 7 to the outside. The flow connections between the measuring lines 3 and the manifold 6 can be interrupted by valves 8 a, 8 b, 8 c, 8 d, which are provided in each of the suction lines 5 .

The measuring lines 3 are merged downstream of the branches of the suction lines 5 into a collecting line 9 , in which a primary pump 10 and an oxygen analyzer 11 are arranged. The primary pump 10 can be arranged both downstream and upstream of the analyzer 11 , and in the case of sensitive measurements, the primary pump is preferably provided downstream of the analyzer 11 in order to keep contaminants, such as traces of oil, emerging from the pump 10 away from the analyzer.

The measuring lines 3 can be closed between the respective branches in the suction lines 5 and the connection to the collecting line 9 by means of the valves 12 a, 12 b, 12 c, 12 d. The line lengths between the distributor 4 and the analyzer 11 are kept as short as possible.

In operation, the valves 8 are first opened and the valves 12 are closed. The secondary pump 7 sucks gas permanently from the measuring points 2 via the measuring lines 3 , the suction lines 5 and the collecting line 6 and conveys the gas mixture forming in the collecting line 6 to the outside. In this way, the distributor 4 located in the immediate vicinity of the analyzer 11 is constantly provided with measuring gas from all measuring points 2 .

If the oxygen concentration in the vicinity of the radiator 1 a is to be measured, the valve 8 a is closed and the connection to the secondary pump 7 is interrupted. At the same time or with a slight time delay, the valve 12 a is opened. By means of the primary pump 10 as the analyzer is fed to a short path, the gas to be analyzed from the measuring site 1 a. 11

When switching to another measuring point, for example measuring point 1 c, valve 12 a is first closed and valve 8 a is opened. Due to the short line lengths between the distributor 4 and the analyzer 11 , the gas in the line between the valve 12 a and the analyzer 11 is drawn off in a very short time by the primary pump 10 . The subsequent analysis is therefore not affected by the previous measurement. By closing the valve 8 a, the gas supply from the measuring point 1 a to the distributor 4 is maintained again by the secondary pump 7 . The valves 8 c are then closed and 12 c opened, so that the analyzer 11 is now supplied with gas from the measuring point 2 c for analysis.

Due to the short flow paths between the distributor 4 , in which gas is constantly kept ready by each of the measuring points 2 , and the analyzer 11 , a very quick switching between different measuring points 2 a, b, c, d is possible without an analysis by the previous analysis is affected. The control of the sample gas switchover is preferably carried out by the usually existing data processing system, for example a PLC control.

Claims (9)

1. A method for analyzing one of several gas flows, which are detected at several measuring points, the gas stream to be analyzed being passed from the measuring point to an analyzer, characterized in that the gas flows from each of the measuring points ( 2 a, b, c, d ) are conveyed to a distributor ( 4 ), only the gas stream to be analyzed is conducted from the distributor ( 4 ) to the analyzer ( 11 ) and the remaining gas streams are withdrawn from the distributor ( 4 ). 2. The method according to claim 1, characterized in that the analyzer ( 11 ) is arranged in close proximity to the distributor ( 4 ). 3. The method according to any one of claims 1 or 2, characterized in that the gas stream to be analyzed is passed only to the analyzer ( 11 ). 4. The method according to any one of claims 1 to 3, characterized in that the oxygen content of the gas stream to be analyzed is measured with the analyzer ( 11 ). 5. The method according to claim 4, characterized in that the oxygen content in the process atmosphere during the jet hardening of paints is measured. 6. Device for analyzing one of several gas flows with several measuring points for detecting a gas flow, one measuring line from each of the measuring points to an analyzer and a primary pump for conveying gas from the measuring points via the measuring lines to the analyzer, characterized in that each measuring tube (3 a, b, c, d) a suction duct (5 a, b, c, d) branches off, in which all suction ducts (5 a, b, c, d) in a manifold (6) open, in which a Secondary pump ( 7 ) is provided, and that in each suction line ( 5 a, b, c, d) and in each measuring line ( 3 a, b, c, d) downstream of the branch to the respective suction line ( 5 a, b, c, d) a valve ( 8 a, b, c, d, 12 a, b, c, d) is arranged. 7. The device according to claim 6, characterized in that the primary pump ( 10 ) is arranged downstream of the analyzer ( 11 ). 8. Device according to one of claims 6 or 7, characterized in that the primary pump ( 10 ) is arranged upstream of the analyzer ( 11 ). 9. Device according to one of claims 6 to 8, characterized in that an analyzer ( 11 ) for determining the concentration of a component of the gas, in particular an oxygen analyzer, is provided.