DE10100242A1 - Device for gas analysis - Google Patents

Abstract

The invention relates to a device for analyzing gas, particularly flue gas, in which the gas is conducted through a gas channel to a gas sensor (20, 22). In order to prevent the formation of condensate, the gas-conducting component (18) of the gas channel is electrically heated. This gas-conducting component is thereby made of a material that can be electrically heated, in particular, of an electrically conductive plastic.

Description

The invention relates to a device for gas analysis, especially the flue gas analysis according to the preamble of the An saying 1.

For testing and monitoring processes, it is common to remove gases from the process and analyze them using a gas sensor. If the gases occur in the process at high temperature, as is the case, for example, in the flue gas analysis of combustion processes, condensate can form in the gas path leading to the gas sensor. This condensate can lead to a measurement falsification, for example in the case of sample gases which are partially absorbed by the condensate (for example SO ₂ , NO ₂ ). If the condensate contains aggressive substances, such as acids or lye, the condensate can attack and damage the gas-carrying components and possibly the gas sensor.

With high-quality devices, therefore, are completely tempered gated gas paths used. In particular, condensates tabscheider used (for example DE 41 01 194 C1 and DE 197 10 581 C1), the accumulation of condensate in the subsequent gas path prevent. The gases are preferably cooled dried. For heating or cooling the gas-carrying compo high energy consumption is necessary, d. H. the pre direction depends on or needs a mains connection powerful and therefore heavy batteries. Gas cooler or Ga dryers can only be used at temperatures above 0 ° C be, because the risk of freezing the radiator and the con there are parts in contact with the Simple network-independent drivable device therefore work with passive condensate fall. These condensate traps take up the condensate, wel ches when the gas cools down in the gas-bearing com components in front of the condensate separator. This principle is however not certain since the condensation of the respective ambient temperatures and the temperatures of the gas-carrying  Components depends. A condensate failure behind the con The trap cannot be reliably prevented.

The invention is based on the object of a device for gas analysis, especially flue gas analysis, for ver to provide, which with a low electrical Lei a condensate accumulation in the gas path with a high rate can prevent reliability.

This object is achieved by a Vorrich device with the features of claim 1.

Advantageous embodiments and developments of the invention are specified in the subclaims.

The main idea of the invention is little least a gas-carrying component of the gas path in the Vorrich device heated by means of an electrically heated material train. The electrically heatable material can be used immediately be arranged in a form-fitting manner on the gas path, so that there is good heat-conducting contact with the one in the gas guide flowing component results in flowing gas. An even more effective one Heating of the gas results when the gas-carrying compo nente itself is made of the heatable material. before preferably, an electrically conductive as the heatable material the plastic used. This makes it possible to Heating elements optimally adapted to the shape of the gas path To use plastic.

The use of electrically conductive plastic as a heatable Res material is particularly suitable for the production of gas-carrying components directly from the heatable Plastic, since plastics can be used that have a have high chemical resistance and through the gases passed through are generally not chemically attacked become.

The electrically heated material can be targeted to the gas guide components are form-fitting on the outside or the wall  educational where the heat is needed and condensate formation must be reliably prevented. The good heat transfer from the heatable material to the through flowing gas and the targeted arrangement of the heated mate rials cause that with a very low electrical Power consumption reliable condensate prevention can be enough. The device enables one device to operate independently of the mains with a light battery.

From a manufacturing point of view, it is advantageous that the gas-carrying compo made of an electrically conductive plastic as molded parts can be produced, these moldings simultaneously form the heating for the carried gas. The electrical Connections for the heating can be used as contacts in the Molded part to be injected. This makes it possible to be heatable gas-carrying components as plug-in modules form, so that easy assembly and possibly also upgradeability is guaranteed.

The invention is described below with reference to the drawing illustrated embodiments explained in more detail.

Show it

Fig. 1 shows schematically an axial section of an embodiment,

Fig. 2 shows schematically a cross section of this embodiment,

Fig. 3 shows schematically a section of a second Ausfüh tion

Fig. 4 schematically shows a section of a third embodiment and

Fig. 5 is a side view of this third embodiment.

In a device for gas analysis, in particular the Flue gas analysis, becomes a sample of the gas to be analyzed removed from the process and fed to a gas sensor. there  the gas taken for analysis flows through a gas path the device.

In order to prevent condensate from being deposited by cooling the gas in a gas-carrying component of the gas path, the gas-carrying component, for example a gas-carrying line 10 , can be made of a heatable material, in particular of a material, as shown in FIGS . 1 and 2 electrically conductive plastic. In the wall of the Lei device 10 electrical connection contacts 12 and 14 are injected, to which a battery 16 or a battery can be ruled out.

Since the wall of the gas-carrying line 10 itself is heated by the electrical heating, there is an optimal thermal contact with the gas which flows through the line 10 , as shown by an arrow in FIG. 1. Due to this favorable heat transfer from the electrically heated wall of the line 10 to the gas flowing through, only a small electrical power is required to heat the gas flowing through or to prevent the gas from cooling so that no condensation occurs. A small, light, rechargeable battery 16 or a battery is sufficient for this low power consumption, so that the device can be operated independently of the mains.

Heated lines 10 are arranged as gas-carrying components in particular or at least at the points or in the flow direction immediately in front of the points at which a condensation can be harmful.

Fig. 3 shows an embodiment in which the gas-conducting components made of the electrically heatable material is the measuring cell 18 , in which the gas is conducted past the sensor 20 as such. By forming the wall of the measuring cell 18 from an electrically heatable plastic, the gas in the area in which it comes into contact with the sensor 20 is heated up to a temperature such that no condensate on the sensor 20 and in particular on the sensor 20 can come into direct contact with the gas de contact surface 22 can precipitate.

Not only is the measuring cell 18 made of the heatable plastic, but also the receptacle 24 of the measuring cell head 28 in which the sensor 20 is arranged. This also allows the sensor 20 to be heated, so that it is avoided that the contact surface 22 of the sensor 20 coming into contact with the gas has a lower temperature than the surrounding wall of the measuring cell 18 . The measuring cell 18 and the receptacle 24 of the measuring cell head 28 are preferably made in one piece from the electrically conductive plastic, which on the one hand means inexpensive manufacture and assembly and on the other hand enables common heating via the injected connection contacts 12 and 14 .

FIGS. 4 and 5 show another embodiment, in particular, is characterized in that the made of the electrically heatable material heater for the gas-bearing component is a pluggable module.

In this embodiment, the measuring cell head 28 is a conventional component, which consists of the measuring cell 18 and the sensor 20 . The measuring cell 18 and the receptacle 24 of the measuring cell head 28 enclosing the sensor are made in a conventional manner from a material that cannot be heated electrically. The measuring cell head 28 is set on a support plate 26 up, the terminal contacts of the sensor carrier plate 20 used in the Trä 26 and preferably as a circuit board formed carrier board are contacted 26th

The measuring cell 18 and preferably the entire measuring cell head 28 with the receptacle 24 surrounding the sensor 20 are heated by a heating element 30 , which consists of the electrically heatable material. The heating element 30 positively encloses the measuring cell head 28 . For this purpose, the heating element 30 is designed in the form of a U-shaped yoke, the legs of which laterally lie over a large area on the measuring cell head 28 , the upper transverse part covering the surface of the measuring cell 18 and being in large area contact with it. The legs of the heating element 30 sit on the support plate 26 with laterally projecting tabs. In these laterally standing tabs, the contacts 12 and 14 are injected as contact pins, which are inserted into the carrier board 26 and are tattooed on the underside of the carrier board 26 and optionally soldered to the conductor tracks of the carrier board 26 .

Since the heating element 30 forms a separate construction part in this embodiment, the device can be carried out in the initial configuration with or without the heating element 30 and, if necessary, an existing device can be upgraded with the heating element 30 .

Claims (6)

1. Device for gas analysis, in particular the smoke gas analysis, in which the gas is passed through a gas path to a gas sensor and is heated in this gas path, characterized in that the gas in at least one gas-carrying component ( 10 , 18 ) of the gas path an electrically heatable material can be heated. 2. Device according to claim 1, characterized in that the heatable material is an electrically conductive plastic. 3. Device according to claim 1 or 2, characterized in that the electrically heatable material is arranged in heat-conducting contact with gas-carrying components ( 10 , 18 ) or with the gas-contacting components ( 20 , 22 ). 4. Apparatus according to claim 1 or 2, characterized in that the wall of the gas-carrying component ( 10 , 18 ) coming into contact with the gas consists of the electrically heatable material. 5. Device according to claims 2 or 4, characterized in that the electrical connection contacts ( 12 , 14 ) for the electrical heating in the electrically conductive plastic are injected. 6. Device according to one of the preceding claims, characterized in that the electrical connection contacts ( 12 , 14 ) for the electrical cal heating plug-in contact pins.