DE10318450B3 - Measurement cell for gas thermal conductivity analyzer has sample channel with parallel main bores and parallel adjacent bores penetrating casing - Google Patents

Abstract

The sample channel (8) has two parallel main bores (80, 81) and parallel adjacent bores (82, 83). All penetrate the casing (2), their ends opening on opposite sides into the common chamber (84, 85) formed in the casing, and sealed by a cover (16, 17) from the exterior. The inlet and outlet openings (21, 22) are arranged in one cover (16, 17). One main bore (80, 81) connects directly to the inlet opening (21). The other (80, 81) connects to the measurement chamber (5, 6) through a branched bore (25, 26). A counter-current heat exchanger is connected in series with the apparatus; it comprises two parallel tubes of thermally conducting material, connected together for heat transfer. One tube is connected to the inlet, the other to the outlet of the measurement cell. The compensation side of the measurement cell is mirror-symmetrical with the sample side. A further variant based on the foregoing principles is described.

Description

The invention relates to a measuring cell for an analyzer for the detection of gaseous or liquid Media by measuring the thermal conductivity with one through an adjustable heat source thermostatted housing, which contains a sample channel and a comparison channel separately from one another, wherein the sample channel has an inlet opening for Respectively a sample and an outlet for lead away the sample, the sample channel and the comparison channel each with at least one has a thermal sensor containing measuring chamber communicate and the measuring chambers arranged symmetrically with respect to a central plane of the housing are.

Analyzers based on the principle thermal conductivity measurement work, are used in many areas for the analysis of gases, because they are robust, versatile, sensitive and relative over a wide range are linear and do not destroy the sample. An application focus is the measurement of the hydrogen concentration in gas mixtures in the chemical and metallurgical industry. To capture the thermal conductivity With these analyzers, on the one hand, the cooling in the measuring cell located, electrically heated thermocouple through the sample and a Comparison medium as a change the electrical resistance of the thermocouples or on the other hand the performance that is needed the temperature of the sensors is constant to keep.

Measuring cells of the specified type are subject to numerous requirements. Sample page and comparison page the measuring cell have to largely symmetrical so that comparable values can be measured can be. The measuring cell must be made of thermally conductive material be producible so that a uniform thermostatting is possible. moreover must Material of the measuring cell resistant to one if possible wide field of test substances. In practice, this is a requirement can only be achieved with several different materials. The measuring cell must therefore have a shape that matches the different ones in question Materials are simple and economical to manufacture. Farther there is a need after a measuring cell design, the with little effort and without significant structural changes to different measuring tasks customized can be.

With one out DE 40 05 131 C2 Known measuring cell of the specified type, the measuring chambers and the channels from the comparison and sample side are arranged symmetrically to the heat source and the direction of flow in both channels is opposite, with partial areas of the channels lying in front of the connected measuring chamber having a small distance from one another and below the measuring chambers run. The measuring chambers are here one behind the other, as seen from the inlet opening of a channel, and the channels are each connected to the measuring chamber which is more distant from their inlet opening. This design of a measuring cell is not suitable for arrangements with four measuring chambers and is sensitive to temperature differences between the sample and the comparison medium.

Out DE 35 17 240 C2 A device for measuring the thermal conductivity of gas flows is known, in which the sensors are arranged in a flow channel which runs diametrically to an annular channel arranged in a housing and opens into the annular channel at both ends. The ring channel is provided on diametrically opposite sides with an inlet and an outlet channel each and the diametrical flow channel is arranged in a block rotatable relative to the housing, the surface of which forms a circular wall of the ring channel. By turning the block in relation to the housing, the ratio of measuring accuracy and response speed can be varied. However, asymmetry in the channel routing between the sample and comparison side can lead to a disturbing zero point shift. In addition, the construction effort is quite high.

A measuring cell for measuring the thermal conductivity of gases with four symmetrically arranged measuring chambers, each containing a thermal sensor, is off US 4,215,564 known. The measuring cell is in the form of a hexagonal prism, which has two inlet prisms and one outlet opening on two opposite prism surfaces, which are connected via connecting channels to two adjacent measuring cells in such a way that the gas supplied passes from the inlet opening through the measuring cells to the outlet opening. The resulting direct flow to the sensors and the short flow paths between the inlet opening and the measuring chamber lead to a strong dependence on the temperature and the flow rate of the sample gas.

The invention has for its object a measuring cell to create the kind mentioned above, which is characterized by a favorable relationship of measurement accuracy at response time, for a big Measuring range is suitable and inexpensive different materials can be made.

The task is defined in the claim 1 specified invention solved. Advantageous embodiments of the invention are specified in the subclaims.

In the measuring cell according to the invention, the sample channel has two parallel main bores and at least one parallel to this secondary bore, wherein the main bores and the secondary bore penetrate the housing and each end with their ends on opposite sides of the housing in a common chamber which is formed in the housing and closed to the outside by a cover, in one the cover, the inlet opening and the outlet opening are arranged and wherein one main bore is connected directly to the inlet opening and the other main bore is connected to the at least one measuring chamber by a branch bore branching from the latter.

The design of the measuring cell according to the invention forms a cheap one Compromise on Fulfillment of the mentioned requirements. The bypass formed by the secondary bore allows a sufficiently large one Flow area inside the measuring cell and ensures short response times with low flow sensitivity. The sample must on her Way to the measuring chamber the measuring cell once completely cross, which achieves an effective thermostat and the Influence of Sample temperature on the measurement is kept low. By the arrangement from inlet and outlet opening the same side of the measuring chamber it is also possible with simple means the measuring cell a counterflow heat exchanger upstream. As a result, the temperature load during large temperature changes the supplied Sample without additional Energy requirements can be reduced.

The upstream counterflow heat exchanger can be in a simple design from two guided in parallel Pipelines made of thermally conductive Made of material that is thermally conductive are connected to each other, the one tube with the inlet opening and the other pipe with the outlet opening of the measuring cell connected is.

The comparison side of the measuring cell is preferably a mirror image of the sample side and the Accordingly, the comparison channel also has two parallel main bores and at least one parallel to this secondary bore that the casing penetrate and their ends on opposite sides of the housing each in a common, in the housing trained chamber open, which is closed by a lid, in one Cover an inlet opening and an outlet opening is arranged are and a main bore is connected to the inlet opening and from the other main bore at least one branch bore to one Measurement chamber leads. By this symmetrical structure of the measuring cell is a uniform temperature distribution between Sample side and comparison side reached and the detuning one to the thermocouples connected measuring bridge minimized.

After another suggestion from the Invention, the comparison channel can also be sealed and sealed one for the measurement task suitable gas filled his.

After another advantageous one Embodiment of the invention can in the inlet end of the main bore, from which the measuring chamber branches off, a diffuser nozzle be arranged. As a result, the flow rate in the Main bore additionally reduced and produces a predominantly laminar flow behavior, which to a homogenization of the flow field in the area of the measuring chambers leads.

Preferably in both ends the main bore arranged in the direction of the main bore widening diffuser nozzles. To generate a flow largely within the measuring chamber to avoid, can be provided according to a further proposal of the invention be that the diffuser nozzle the opening of the to the measuring chamber leading Branch hole completely or partially covered. This will make the flow essentially at the branch opening steered past so that the filling the measuring chambers mainly is based on diffusion effects. The flow dependence of the thermal conductivity measurement is reduced to a minimum.

The lid to close the Chambers can by welding, for example tungsten inert gas (TIG) welding, gas-tightly connected to the housing his. Is welding based on the chosen Materials not possible, mechanical attachment of the cover can be provided, with the lid facing the housing are sealed with the help of a sealing ring.

The sensors are on at the measuring cell one side of the case into the measuring chambers used as a step hole that widens outwards are trained. The sensors are preferably completely encapsulated in glass and connected to a metal membrane by means of a gas-tight glass-metal connection, the gas-tight in the housing is attached. The gas-tight fastening of the metal membrane can according to the invention Welding, especially TIG welding, or by mechanical clamping, with the help of preloaded Springs a defined clamping force is generated.

The invention is described below of embodiments explained in more detail the are shown in the drawing. Show it

1 the view of a measuring cell from above,

2 a section in the plane II-II of the measuring cell according 1 .

3 a section in the plane III-III of the measuring cell according 1 .

4 a section in the plane IV-IV of the measuring cell according 3 .

5 a longitudinal section of the comparison side of another embodiment of a measuring cell according to the invention.

The in the 1 to 7 shown measuring cell 1 has a cuboid housing 2 , which consists of a material with good thermal conductivity, such as aluminum. The measuring cell 1 is divided into two symmetrical sections with respect to the median longitudinal plane, one section of which 3 the sample page and the other section 4 forms the comparison side of the measuring cell. Both sections 3 . 4 have two measuring chambers 5 respectively. 6 each with a thermal sensor 7 on. The measuring chambers 5 of the section 3 stand with a sample channel 8th and the measuring chambers 6 of the section 4 with a comparison channel 9 in connection.

To form the sample channel 8th and the comparison channel 9 points the case 2 in each of the sections 3 . 4 two main holes 80 . 81 respectively. 90 . 91 and two secondary holes 82 . 83 respectively. 92 . 93 on, which are aligned parallel to the plane of symmetry and to each other and the housing 2 penetrate completely in the longitudinal direction. The ends of the main holes 80 . 81 respectively. 90 . 91 and the secondary holes 82 . 83 respectively. 92 . 93 are each through a chamber 84 . 85 respectively. 94 . 95 connected with each other. The chambers 84 . 85 respectively. 94 . 95 are due to stepped depressions in the housing 2 formed and outwards by a cover 16 respectively. 17 tightly closed. Every lid 16 . 17 is here with the help of a sealing ring 18 towards the housing 2 sealed and is held by a pressure plate 19 held by means of cheese head screws 20 on the housing 2 is attached.

The one on the same side of the case 2 arranged lid 17 each have two through holes that have an inlet opening 21 . 21 ' and an outlet opening 22 . 22 ' form. In the through holes are connecting pipes 23 . 24 , respectively. 23 ' . 24 ' used and gas-tight by welding with the lids 17 connected. That of the respective outlet opening 22 . 22 ' assigned connection pipe 24 . 24 ' the lid ends within the through hole 17 , The inlet openings 21 . 21 ' are made by extending the connecting pipes assigned to them 23 . 23 ' formed by the through holes in the covers 17 extend through and with their ends in the main holes 80 . 90 protrude into it, with their tube wall resting essentially free of play on the bore wall.

From the main holes 81 . 91 branch branch holes at the same distance from the ends of the same at right angles 25 . 26 from, each in a measuring chamber 5 respectively. 6 lead. The measuring chambers 5 . 6 are above the main holes 81 . 91 arranged and each consist of a step bore widening outwards in several steps. In the ends of the main holes 81 . 91 are diffuser nozzles 27 used that expand towards the center of the hole. The diffuser nozzles 27 have a section whose outside diameter is smaller than the inside diameter of the main bores 81 . 91 and the mouths of the branch holes 25 respectively. 26 covered. As a result, there is a direct flow against the branch bores 25 . 26 and the measuring chambers connected to them 5 . 6 through which the main holes 81 . 91 flowing gas avoided.

The in the measuring chambers 5 . 6 thermal sensor used 7 are fully glazed and have an annular mounting flange 28 from a suitable metal. In the embodiment shown in the drawing, the mounting flange 28 from a temperature-related expansion difference compensating gold membrane using a metallic sealing ring 29 is pressed gas-tight on an annular surface formed by the stepped bore of the measuring chamber. For pressing the sealing ring 29 are disc springs 30 provided at one with the housing 2 firmly screwed pressure plate 31 are supported. The design described for attaching the thermal sensor 7 is intended for housings made of materials that cannot be welded. The thermocouples are provided for housings made of weldable materials 7 a flange made of the same material, which is then welded gas-tight to the housing 2 is connected. The electrical connections 32 the thermocouple 7 protrude from the top of the housing 2 out and are at an electrical measuring bridge 33 connected on one with the housing 2 connected circuit board 34 is arranged.

For thermostatting the measuring cell 1 are on both long sides of the housing 2 heating elements 35 appropriate. It is also located on the underside of the housing 2 a temperature limiter 36 the heating elements when a maximum temperature is exceeded 35 switched off. In a housing bore lying in the plane of symmetry 37 is still a sensor 38 for measuring the temperature of the housing 2 arranged. The electrical connections 39 of the heating elements 35 and the connectors 40 of the sensor 38 are on one at the bottom of the case 2 attached circuit board 41 connected to circuit elements, not shown.

With the measuring cell described 1 the gas mixture, which contains a gas component to be determined quantitatively by measuring the thermal conductivity, for example hydrogen, is passed through the connecting pipe 23 in the main hole 80 of the sample channel 8th directed. At the same time, the other connecting pipe 23 ' a reference gas in the main bore 90 of the comparison channel 9 directed. The supplied gases flow through the main bore 80 respectively. 90 , their temperature to the temperature of the housing 2 is adjusted. The gases then enter the chambers 84 . 94 , The respective gas flow divides there. A partial flow leaves the chamber 84 respectively. 94 through the secondary holes 82 . 83 respectively. 92 . 93 passes through this to the chamber 85 respectively. 95 and from there to the outlet 22 respectively. 22 ' connected pipe 24 respectively. 24 ' , The other partial flow passes through the diffuser nozzle 27 in the main hole 81 respectively. 91 , whereby its flow velocity is reduced, flows through it and passes through the other diffuser nozzle 27 again accelerated into the chamber 85 respectively. 95 and the pipe 24 respectively. 24 ' , This division of the gas flows into the sample and comparison channel results in an advantageously low flow velocity in the main bores 81 . 91 reached to which the measuring chambers 5 . 6 are connected. The gases can therefore with a relatively high flow rate of the measuring cell 1 are supplied without a significant flow in the measuring chambers 5 . 6 to cause, which could affect the thermal conductivity measurement. The measuring cell thus advantageously enables short response times with minimal flow sensitivity. Furthermore, a good temperature equalization is achieved by the comparatively long flow path of the gas until the measuring chambers are reached, and the impairment of the measurement by temperature fluctuations in the gas supply is effectively reduced. Since the connecting pipes are arranged on the same side of the housing, they can also be connected to one another in a simple manner to form a heat exchanger, as a result of which the influence of temperature fluctuations can be reduced even more. Other designs of heat exchangers can easily be connected upstream of the measuring cell.

The measuring cell described is also suitable for applications in which the reference gas is not continuously supplied to the comparison side of the measuring cell during the measurement process, but instead the comparison side is sealed after filling with a reference gas suitable for the intended application. In such a case, however, it is not necessary to make the comparison channel completely symmetrical to the sample channel, since there is no need to suppress flow influences. The comparison page of such in 5 The measuring cell shown therefore requires no secondary bores and only one main bore 91 , from which the branch holes 26 and the two measuring chambers 6 branch. The hole 91 is designed as a blind hole and has a short pipe socket at its open end 42 provided, which is tightly sealed after introduction of the gas filling and with a cap 43 is covered.

The closed version of the comparison channel 9 deviates slightly in its measuring behavior from the measuring behavior of the continuously flowing sample channel. The size of the deviation can, however, be determined with the required accuracy and compensated for by a suitable detuning of the measuring bridge connected to the thermocouples. Measuring cells with a closed comparison side are limited in their range of use, since the reference gas must correspond to the one component of the sample gas with regard to the thermal conductivity under measurement conditions. Such measuring cells, however, significantly reduce the measuring outlay, since no preparation and supply of reference gas is required. Such measuring cells therefore enable a significant reduction in costs for numerous applications.

Claims (10)

Measuring cell for an analyzer for the detection of gaseous or liquid media by measuring the thermal conductivity with a housing which can be thermostatted by a controllable heat source and which contains a sample channel and a comparison channel separately from one another, the sample channel having an inlet opening for supplying a sample and an outlet opening for removing the sample , the sample channel and the comparison channel are each connected to at least one measuring chamber containing a thermal sensor and the measuring chambers are arranged symmetrically with respect to a central plane of the housing, characterized in that the sample channel ( 8th ) two parallel main bores ( 80 . 81 ) and at least one secondary bore parallel to these ( 82 . 83 ), the main bores ( 80 . 81 ) and the secondary bore ( 82 . 83 ) the housing ( 2 ) penetrate and with their ends on opposite sides of the housing ( 2 ) each in a common chamber ( 84 . 85 ) open into the housing ( 2 ) and a lid ( 16 . 17 ) is closed to the outside, with a cover ( 16 . 17 ) the inlet opening ( 21 ) and the outlet opening ( 22 ) are arranged and wherein a main bore ( 80 . 81 ) directly to the inlet opening ( 21 ) is connected and the other main bore ( 80 . 81 ) through a branch hole branching off from this ( 25 . 26 ) with the at least one measuring chamber ( 5 . 6 ) connected is. measuring cell according to claim 1, characterized by an upstream countercurrent heat exchanger. measuring cell according to claim 2, characterized in that the upstream countercurrent heat exchanger from two guided in parallel Pipelines made of thermally conductive Material is made of heat conductive are connected to each other, the one tube with the inlet opening and the other pipe with the outlet opening of the measuring cell connected is. Measuring cell according to one of the preceding claims, characterized in that the comparison side of the measuring cell ( 1 ) is mirrored to the sample side and the comparison channel ( 9 ) two parallel main bores ( 90 . 91 ) and at least one secondary bore parallel to these ( 92 ) on points the housing ( 2 ) penetrate and their ends on opposite sides of the housing ( 2 ) each in a common chamber formed in the housing ( 94 . 95 ), each with a cover ( 16 . 17 ) is closed, with a cover ( 17 ) an inlet opening and an outlet opening are arranged and a main bore ( 90 ) is connected to the inlet opening and from the other main bore ( 91 ) at least one branch hole ( 26 ) to a measuring chamber ( 6 ) leads. Measuring cell according to one of the preceding claims, characterized in that the comparison channel ( 9 ) is tightly sealed and filled with a reference gas suitable for the measuring task. Measuring cell according to one of the preceding claims, characterized in that in the inlet end of the main bore ( 81 respectively. 91 ) from which the measuring chamber ( 5 respectively 6 ) branches off, a diffuser nozzle widening in the direction of the same ( 27 ) is arranged. Measuring cell according to claim 6, characterized in that in both ends of the main bore ( 81 respectively. 91 ) Diffuser nozzles widening in the direction of the same ( 27 ) are arranged. Measuring cell according to claim 6 or 7, characterized in that the diffuser nozzle ( 27 ) the opening of the to the measuring chamber ( 5 respectively. 6 ) leading branch hole ( 25 respectively. 26 ) completely or partially covered at a short distance. Measuring cell according to one of the preceding claims, characterized in that the thermal sensors ( 7 ) from one side of the housing into the measuring chambers ( 5 . 6 ) are used, the measuring chambers ( 5 . 6 ) are designed as step holes that widen outwards. Measuring cell according to one of the preceding claims, characterized in that the thermal sensors ( 7 ) completely encapsulated in glass and gas-tightly connected by a glass-metal connection to a metal membrane which is gas-tightly fastened in the housing.