DE3047601A1 - Thermal conductivity detector in gas analyser - is preceded by heat exchanger to stabilise temp. of incoming gas to that of detector casing - Google Patents

Abstract

A measuring device for gas analysis equipment used in the determination of thermal conductivity of gases comprises a detector unit (11) containing a measuring sensor bore (12), measuring sensor (13) and gas inlet and outlet ducts (18,19). The entire casing of the detector block is thermostatically heated and externally insulated. Upstream of the detector block (11) the gas inlet duct (18) passes through a heat exchanger (22) which is maintained at the same temperature as the detector block casing itself. Pref. this heat exchanger is in good thermally conducting contact with the heated casing of the detector block. The heat exchanger may comprise a helical tube (23) in good thermal contact with a hollow cylindrical core (notshown). This core is in good thermal conduct with the detector casing. . Used as a measuring device in gas chromatography where the compsn. may be determined from the thermal conductivity. The result of the readings is affected not merely by the compsn. however, but also by the flow velocity of the gas and its inlet temperature. Previous devices have partly overcome this problem but suffer from fluctuation inlet temp. of the gas leading to unstable conditions. By incorporating a heat exchanger upstream of the detector, the inlet gas is already brought to the temperature of the detector casing. Consequently the stability of the device is improved and its sensitivity is increased while at the same time constants are reduced.

Description

"Measuring device for gas analysis devices for

Mood of the thermal conductivity of gases The invention relates to a measuring device for gas analyzers to determine the thermal conductivity of gases, with a detector block in which at least one measuring sensor bore with a sensor housed in it and with the necessary gas supply and discharge lines is arranged, and with a thermostatic surrounding the detector block on all sides heatable housing provided with external thermal insulation.

Measuring devices of the type described above are described in DE-OS 21 56 752 and DE-OS 24 36 366 known. With such measuring devices it is possible to determine the composition of gases in the field of gas chromatography as their thermal conductivity depends on the gas composition. It was observed that not only the composition of the gas but also whose flow rate has an influence on the measurement result, since the heat balance of the sensor is necessarily influenced by the flow of the gas to be measured will. The known solutions were therefore also based on the task of reducing the influence of the To reduce the flow rate of the gases to be measured. This is in one Case has been achieved by a tangential gas flow, which has a reduced flow velocity in the sensor bore. In the second case the circumstances were further improved by the fact that a thin-walled one around the probe Tube was arranged, which the direct flow influencing the sensor further reduced. Through the known solutions, the direct influence of the flow was admittedly turned off to a desirable extent; unfortunately it turned out that the Sensitivity of the measuring device decreased, while the time constant up to Production of a stable measured value increased undesirably.

In addition to the flow velocity, it also has the temperature of the incoming gas has a noticeable influence on the measurement result, as a deviating temperature a different gas composition is simulated. A reliable one Measurement namely the thermal conductivity of the gas to be analyzed on the prerequisite that the temperature T1 of the sensor, e.g. an NTC resistor can be, and the temperature of a reference element is as different as possible from each other, however, each should be stable in itself. Either the thermostated detector block or - if available - a tube or screen serve, which surrounds the sensor, as shown in DE-OS 24 36 366.

The temperatures mentioned can, however, be caused by inflowing gas, which has fluctuating temperatures, become unstable, which is unfavorable affects the measurement accuracy.

For example, if the reference element is the one already described, the Tube surrounding the sensor, which allows the gas to flow directly onto the sensor is to prevent, the following results: If this pipe is not on a stable temperature level T2 is, the thermal gradient of the measuring section changes between the sensor and the pipe and thus the measuring sensitivity of the arrangement. In addition, the removal of heat with the gas flow creates a measurement error, the size of which depends on the gas temperature and the gas velocity, which, however, can be kept constant via a gas flow regulator. The invention is therefore based on the object of a measuring device of the type described above Kind of improving that the stability and the sensitivity the measuring device can be increased with a simultaneous shortening of the time constants. With regard to the task, it must be taken into account that there are basically two requirements diametrically opposed: on the one hand, there should be a direct flow influence on the sensor should be avoided as far as possible, but on the other hand there is a rapid gas exchange indispensable in the sensor bore for a short time constant, so that a certain Flow rate, which is ultimately the rate of gas exchange determined, cannot be fallen below.

The problem is solved in the case of the one described at the beginning Measuring device according to the invention characterized in that in the flow direction upstream of the gas feed line of the detector block, a heat exchanger is arranged, which is at the same temperature can be heated, like the housing.

Due to the influence of the heat exchanger, the incoming gas is on a Temperature heated (or cooled down) as closely as possible to the case temperature and thus corresponds to the temperature of the detector block, which in turn is heated by the housing. The closest possible approximation of the gas temperature to the housing temperature is essentially a question of heat transfer due to the flow conditions as well as the surface area of the heat exchanger. Because the flow conditions largely are given, the main influencing factor is the size of the surface of the Heat exchanger. Under "heat exchanger" every facility is to be understood, which changes the temperature of the incoming gas through heat transfer in such a way that that the gas passes through the walls of the probe bore and, if necessary, with the probe bore in thermally conductive connection parts, such as the one below pipe, described in more detail, no longer withdraws any significant amounts of heat.

As a result, the heat exchanger can have a i.e. independent of this, a device which is thermostated for itself, i.e. is provided with a regulated heating device. However, it is according to the further Invention particularly advantageous when the heat exchanger with the heatable housing of the detector block is in a good heat-conducting connection, so that on a separate Heating device and an additional temperature controller for the heat exchanger can be dispensed with.

The use of the heat exchanger has the advantage that the gas flowing in the detector cell is the temperature described above Reference elements cannot change, so that the resulting thermal gradient the measuring distance between the temperature sensor and the environment is preserved. This results in a significantly better stability of the measuring device and thus the measuring sensitivity. This enables a higher flow rate in the entire system, which means the gas exchange is favored and thus the time constant is reduced. In particular is it possible to measure the volume reduce sensor bore, whereby this gas exchange is accelerated.

A particularly advantageous embodiment of the subject matter of the invention, in which the sensor is surrounded by a tube, which the measuring part of the Sensor surrounds and protrudes in both axial directions, is according to the further Invention characterized in that the tube conducts heat well with the detector block connected is. In the subject of DE-OS 24 36 366, the pipe in question is on attached to a contact pin of the probe. This contact pin puts together with the insulator in which it is attached, a significant thermal resistance to the detector block. It can therefore assume a temperature that is not the temperature of the detector block, but - after the dependence on the gas temperature has been eliminated by the heat exchanger - still of the thermal conductivity, depends on the amount of gas and the gas velocity. This dependency leads to Changes in the measurement sensitivity in-which the pipe after disturbances of its temperature carries out a temperature drift with time constants of minutes length until equilibrium. At least that is the measurement sensitivity due to the unstable temperature gradient also unstable. Due to the good heat-conducting connection between the pipe and the Detector block ensures that the pipe is largely at the temperature of the detector block is held, so that the described influences are practically completely eliminated will.

Further advantageous configurations of the subject matter of the invention result from the other subclaims.

The prior art, an embodiment of the subject matter of the invention as. essential individual parts are explained in more detail below with reference to FIGS. 1 to 5 explained.

The figures show: FIG. 1 a section through a detector block of a conventional one Measuring device (schematic), Figure 2 shows a section through a detector block of a Measuring device according to the invention (schematic), Figure 3 is a section through a practical embodiment of the subject matter of the invention, Figure 4 is a side view of the heat exchanger according to Figure 3 and Figure 5 is a plan view of the object according to Figure 4 in the direction of arrow V.

In Figure 1, a detector block 1 is shown, which is made of thick-walled Metal parts is formed and as a result has a noticeable thermal inertia. In the detector block, a sensor bore 2 is arranged, which is used to receive a Sensor 3 is used. The measuring sensor 3 is via unspecified connecting wires connected to pins 4 and 5, which are in a Isolator 6 are embedded, which in turn closes the sensor bore 2 in a gas-tight manner. At the Contact pin 4 is attached to a tube 7 which surrounds the probe 3 and in both protrudes in axial directions. The entire sensor array is approximately concentric housed in the sensor bore 2.

In the detector block 1 are a gas supply line 8 and a gas discharge line 9 arranged, which are in communication with the sensor bore 2 and for example open tangentially into this, as shown in principle in DE-OS 24 36 366 is. The housing surrounding the detector block, its heating device and thermal insulation are omitted in Figure 1 for the sake of simplicity.

In Figure 2, the detector block 11 is in an analogous manner with a sensor bore 12, a probe 13, contact pins 14 and 15, an insulator 16, a pipe 17, a gas supply line 18 and a gas discharge line 19 are provided. The pipe 17 is, however formed longer and at its lower end with one or more slits Understand 20, through which the slotted end is elastic in the radial direction. The tube 17 is inserted into a wall of the probe bore 12, which for this purpose has a bore 21. In the manner indicated, the tube 17 is a good heat conductor Connection to the detector block 11.

Bores 20a are provided for better gas exchange.

A heat exchanger is located upstream of the gas feed line 18 in the direction of flow 22 arranged, of which only the outline is shown in dashed lines. The heat exchanger 22 can, for example, consist of a helically coiled pipe coil 23 exist, as is explained in more detail with reference to FIG. By accordingly Long Formation of the coil 23 can provide the necessary heat exchange Surface are formed.

In FIG. 3, the same parts as in FIG. 2 are given the same reference numerals Mistake. In the present case, the detector block 11 has two sensor bores 12 and 12a, only one of which is shown partially cut away. The other Sensor bore 12a is only indicated by dashed lines.

In addition, the following can be seen: The detector block 11 exists from a middle part 24 with corresponding bores and two closure plates 25 and 26, which are screwed to the central part 24 by screws 27. In the gas supply line 18 opens the heat exchanger 22, which consists of the coil 23, the screw is soldered coiled in a line on a hollow cylindrical support body, so that there is a good heat-conducting connection. The heat exchanger 22 has a Feed line end 29 which is passed concentrically through the support body 28. The gas to be analyzed is passed through the feed line end 29, in the Coiled pipe 23 brought to the desired temperature and then arrives from there through a connection nipple 30 into the gas supply line 18 of the detector block 11. Above the gas discharge line 18, whose course in the interior of the detector block is not detailed is shown, it then exits again.

The detector block 11 is arranged in the cavity 31 of a housing 32, which consists of metallic wall panels 33, 34, 35 and 36 by means of Screws 37 is composed. The detector block has a three-point bearing attached by means of set screws, of which only one set screw 38 is shown is.

As a result, a temperature distribution that is as uniform as possible is achieved. In the wall plate 35, a heating element 39 is arranged, which on a bracket 40, which is screwed into the wall plate 35. By means of the heating element 39 it is possible to heat the entire housing 32 to a uniform temperature. To avoid radiation and convection losses, the housing 32 is with a thermal insulation 41, which is only shown in phantom.

The temperature is controlled by means of a thermostat, not shown, as is known per se.

The wall plate 36 has a recess 42 in which the heat exchanger 22 is arranged in such a way that its lead end 29 through the wall plate 36 is passed through.

The carrier body 28 has a flange 43 with which it conducts heat well is attached to the wall plate 36, so that the coil 23 the temperature of the Housing assumes.

The wall plate 34 has a recess 44 in which a connection element 45 is arranged for the required electrical leads. It is still closed recognize that the contact pins 14 and 15 by means of a screw nipple 46 under Interposition of a seal 47 mounted in the middle part 24 of the sensor block 11 are. The electrical leads are omitted for the sake of simplicity.

In Figures 4 and 5 details of the heat exchanger 2; more clear visible. Due to the retention of the same reference symbols, however, a repetition can be made the description can be omitted. The coil 23 is a Copper pipe about 300 mm long, 4 mm outside and 2 mm inside diameter, which is wound on the carrier body 28 and soldered. Since the pipe coil 23 by the thermally conductive connection with the housing 32 assumes its temperature, corresponds the gas temperature at the exit from the heat exchanger 22 is also the housing temperature, so that the desired effect is achieved.

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Claims (7)

A N S P R Ü C H E: 1. Measuring device for gas analyzers for determination the thermal conductivity of gases, with a detector block in which at least one Sensor bore with a sensor housed in it and with the required Gas supply and discharge lines are arranged, as well as with a detector block on all sides surrounding thermostatically heatable, provided with an external thermal insulation Housing, characterized in that in the direction of flow in front of the gas supply line (18) of the detector block (11), a heat exchanger (22) is arranged on the same Temperature can be heated, like the housing (32). 2. Measuring device according to claim 1, characterized in that the Heat exchanger (22) with the heatable housing (32) in good heat-conducting connection stands. 3. Measuring device according to claim 2, characterized in that the Heat exchanger (22) made of a helically coiled pipe coil (23) consists, which is attached to a hollow cylindrical support body (28) in a thermally conductive manner is, and that the carrier body is in turn connected to the housing (32) in a thermally conductive manner is. 4. Measuring device according to claim 3, characterized in that the Feed end (29) of the heat exchanger (22) concentrically through the support body (28) and through a wall plate (36) of the housing (32) to the outside. 5. Measuring device according to claim 3, characterized in that the Carrier body (28) has a flange edge (43) with which it is attached to a wall plate (36) of the housing is attached in a thermally conductive manner. 6. Measuring device according to claim 1, wherein the sensor of a Tube is surrounded which surrounds the measuring part of the probe and in both protrudes beyond axial directions, characterized in that the tube (17) conducts heat well is connected to the detector block (11). 7. Measuring device according to claim 6, characterized in that the Tube (17) formed elastically by slotting (20) and preloaded into a corresponding hole (21) of the detector block (11) is inserted.