DE1598612B2 - Measuring device - Google Patents

Description

The invention relates to a device for measuring a property, in particular the Moisture of a moving web of dielectric material to be measured, ζ. Β. Paper whose temperature is temporal Is subject to fluctuations.

The main application of such measuring devices is in the field of humidity of solids and the measurement of the composition of liquids. You can also measure it the mass per unit of length, per unit of area or per unit of space of materials used will. They depend in their mode of operation on the relationship between the applied to the electrodes Voltage and the electrical current flowing through the measuring device.

It is known in devices for measuring a dielectric material property, the temperature of the test material and to compensate for their influence on the measurement results. When measuring dielectric liquids, the electrodes are immersed in the liquid and a achieve relatively simple device for temperature compensation in that a thermometer in the Liquid is immersed and a temperature responsive signal is used to power the device to compensate for temperature changes that occur in the liquid itself.

In measuring devices for measuring solid materials, in which the electrodes are in the immediate Near or in contact with the material is usually an ambient temperature measuring device provided so that a temperature compensation can be made. With such devices, however, the measurement inaccurate in that the device for measuring the outside temperature does not necessarily measure the temperature that prevails within the measured material itself. This is especially true for the Cases where the material is at a temperature above or below ambient temperature is heated or cooled at which the measuring device is normally operated. Examples this arises in the manufacture of paper, textiles or tobacco products, where the particular useful function of a moisture measuring device is the operation of a To monitor or control the dryer that heats up the material so that the material present in the material Moisture is driven out. It was also found that the temperature difference between the material and the environment of the temperature measuring device for the outside temperature from different Reasons cannot be predicted. For example, it is desirable that the measuring device to operate with their measuring elements in frictional engagement with the material passing through, so that a corresponding temperature measuring device to a certain extent due to the friction occurring is heated.

The non-contact measurement of the temperature of moving material by means of a thermal radiation receiver is known, as is a compensation of a dielectric measuring device for temperature. The compensation has so far been made in such a way that a measuring device for the ambient temperature was provided.

In contrast, the aim of the invention is the quantitative determination of a changing property a running web which is a function of dielectric property by means of a Device that is non-contact and independent of any temperature difference between the running Railway and the surrounding area works.

This is achieved according to the invention by an apparatus as follows, which are known in detail Features:

a) A capacitance measuring device for measuring a dielectric property of the material to be measured;

b) a device for measuring the temperature of the material to be measured on the basis of the infrared radiation with a low time constant adapted to the speed of the running web, which is specified in The longitudinal direction of the web is arranged in the immediate vicinity of the device a);

c) a device for measuring the ambient temperature of the device b);

d) a computing circuit, which on the one hand the influence of the ambient temperature on the device compensated and on the other hand the dielectric measured values according to the temperature of the material to be measured corrected;

e) a mechanical device for moving a device containing the devices a), b) and c) Measuring head transversely to the running material path.

In the case of the present invention, the influence of the temperature of the material per se on the dielectric measuring device compensated by measuring the infrared radiation from the material. the Temperature measuring device for the environment is used to measure the effects of the ambient temperature To compensate for temperature measuring device. This results in a far better measurement accuracy than before achieved, as the actual web temperature due to the infrared radiation from the web for compensation is used.

Advantageous designs are the subject of the subclaims.

The invention is explained below in conjunction with the drawing on the basis of exemplary embodiments. It shows

F i g. 1 is a perspective view of part of a papermaking machine with one according to the invention Measuring device,

F i g. 2 is a sectional view through the infrared radiation measuring device according to FIG. 1,

Fig. 3 is a section along the line 3-3 of Fig. 2,

F i g. 4 is a block diagram showing the basic configuration of an embodiment of a device indicates according to the invention,

F i g. 5 is a more complete block diagram of the device according to FIG. 4 including a special one Arrangement of the computing circuit,

F i g. 6 is a block diagram showing an apparatus with a further embodiment of the computing circuit according to FIG. 4 shows, and

7 shows, partly schematically and partly as a block diagram, the view of a preferred exemplary embodiment of the device according to FIG. 6th

The invention is used in connection with a

3 4

direction for measuring and / or controlling the humidity is connected to the capacitance measuring device

activity of a running paper web, which at the exit with an adjustment of the balancing mechanism so

a papermaking machine- is obtained, described- arranged that it is floating on the web 10-

practice and illustrated. According to FIG. 1 occurs the current lies. In this way, the electrodes that are in

Web 10 from a dryer, in which a plurality of capacitance measuring devices are arranged, in

of rollers, e.g. B. 12 and 14 contains. The dryer-made electrical contact with the paper, whereby

rollers are heated with the help of live steam, but the contact is so light that it does not cause any

which is fed inside e.g. via lines 16, marking or damage to the paper can occur

the heated surfaces of the rollers can be the temperature.

Increase the temperature of the paper and reduce the humidity Drive out paper. The moisture is in the middle of the electrical coupling between form expelled by steam, which continuously see the capacitance measuring device and the paper from the area of the dryer, about a corresponding- in relation to the humidity of the paper under the Kades Ventilation system is discharged. The latter set capacitance measuring device. Because of the many can dry air nozzles, e.g. B. 18 and 20, have 15 variables in the stratification, drying from opposite sides of the dryer and calendering operations, the preferred through the wise uniform trajectory formed by adjacent rollers of a change in both Air pockets are directed, further by a (not processing direction as well as transversely shown below) Hood over the dryer, with the tossed. Such a change does not only occur in the moist air from the area of the dryer by 20 basis weight and in the moisture of the web, large fan blower is extracted. but also in their temperature.

After exiting the dryer, the paper web has a mean in the measuring range warm paper web 10 passed through a calender, or nominal temperature of about 38 to 82 ° C with the rollers of which are heated with steam at 22, which has a normal deviation of about ± 10 ° C from is fed through lines at 24, the 25 being the mean nominal temperature. The paper-paper A corresponding surface treatment manufacturer regards the control of the receives. The calendered paper is then moisture content to a value that is appropriate large rolls wound at 26, which is for the sen that when the paper is in an atmospheric onward transport can be stacked to the consumer - sphere of around 24 ° C and 45% relative humidity

The paper should be in a uniform state and in equilibrium with the moisture in the pain In relation to the basis weight as well as to the pier, it is about 5V2% of the weight of the paper. the Moisture coiled, such electrical admittance measurements, to which it is based Uniformity is supposed to be across the full width of the web. In order to achieve this, the bases are not directly one are present. To this crucial changeable function of moisture, but depend on the To measure quantities, a measuring device at 35 intermediate parameters of the complex dielectricity of its corresponding point, generally between the constant of the paper, which, as described above Output of the calender and the take-up roll, guided, a changing function of the paper arranged. The measuring device has a measuring temperature.

head 28, which is arranged above the web and an exact measurement thus requires that in the

mounted so that it engages a reciprocating 40 moisture measuring system a sensing device

on corresponding guide rods 30 over which is built, which depends on the temperature of the paper.

Width of the web can run. The leadership speech; since the paper is a massive material, it must

rods in turn are accommodated in a frame - the temperature sensing device outside the pa-

men, which has uprights 32 and 34, the piers are arranged. After the paper temperature

connected to one another by cross members 36 and 38 45 from point to point across the web as well

are. in the longitudinal direction of the web changes significantly, it is

The measuring head 28 has a beta radiation important that the temperature measurement on the part

Display device, the beta radiation remains limited by that of the paper, which through the capac-

Picks up the web. In this case a rate measuring device 46 is measured. So that should

beta radioactive source below web 50 the temperature sensing device across the width of the

in a housing (not shown) similar to the paper web in the longitudinal direction for the capacitance measuring

Measuring head 28 out and scan on a second pair of device 46.

Guide rods 40 and 42 below the track 10 The measuring head and other movable components,

moved back and forth. The housing for the radioactive which are assigned to the capacitance measuring device,

The source and the display device are in a vertical position 55 are exposed to ambient temperatures which can vary

Directional and can not only change from time to time over the width, but also

the web 10 scan in order to measure the basis weight substantially from the temperature to be measured

sen. The mechanical device can differ from paper itself. Particularly high

Transverse drive motor 44 driven. Temperature changes and temperature differences

The measuring head 28 also carries the sensing elements 60 are encountered after either the through the Moisture measuring device. The primary payoff web or measuring head in the normal sensing element is a capacitance measuring device 46 which has been missing area for a certain period of time. That above the track 10 on a corresponding, in the frame for the transverse displacement mechanism of Housing 48 accommodated compensation and lifting measuring device runs at some distance above mechanism is supported on two U-shaped 65 half the edge of the web at the far end, so Brackets 50 are attached, which are connected to the measuring head 28 with the measuring head and the capacitance measuring device are. Appropriate setting of the odisch for normalization purposes vertical position of the housing 48 on the bracket can be. In the case of moisture measuring

5 6

device, for example, it is desirable to expose occasionally from a disk 72 made of blackened silver foil a normalization setting on the electronic is arranged. The thermistor element is in a Carry out switching of the device, with the Pa-sealed glass capsule inserted, which in turn with pierce from the vicinity of the probe electrodes and remove the absorption disc using epoxy adhesive. By removing the measuring head assembly 5 is stuck.

The radiation absorbing disk 72 is in turn subject to temperature conditions

are different from those placed on two parallel copper wires 74 and 76 above the heated

Paper webs are encountered, which causes hanged, which are relatively thin, so they

the parts of the arrangement are relatively strong as little as possible thermally conductive. At the left end

Heat transfers are exposed when the anio is each wire with a metal eyelet 78 in one

Order is shifted back on the track so that terminal board 80 is soldered out of phenol, which is in a

the measurement can be resumed. groove-shaped recess 82 in the outer part of the

F i g. 1 shows a section 52 from a part of the housing 60 which is fastened by means of screws 84. Of the

of the measuring head 28 and its holding device. The bottom of the recess 82 has two openings 86

at is an infrared radiation sensing device 54 15 through which the wires through the metal wall

visible, which are passed through an arm 56 on the measuring head 28 of the housing, without the

is appropriate. The infrared radiation sensing device housing is touched. Everyone is at the right end

device is above the paper web at a distance of wire 74 and 76 through an axial hole in the middle

led to offset so that the part of the current head of a bushing insulator, for. B. at 88,

Track is observed, which leads directly down the track to 20. When reassembling, the slack becomes a

Capacitance measuring device 46 and with it aligned each wire eliminated without the wire being taut

tet lies. The sensing device 54 is part of the tension and the wire is then in its

Moisture measuring device. Position soldered.

In the device shown, the capacitance is The suspension wires 74 and 76 connect the rate measuring device 46, a stray field capacitor, 25 thermistor 70 to a feed line 90, and which is coupled to the web on only one side. accordingly, the thermistor leads 92 and In such a device, it is advantageous to solder the 94 to the hanging wires in the vicinity of the display infrared radiation sensing device on the same device. To attach the radiation absorbing side of the web as there is generally a disc 72 on its opposite sides with a temperature differential of up to about 2 ° C between the respective suspension wires 74 and 76 with the two sides of the web. Satisfied with an epoxy adhesive, e.g. B. at 96, with positional results can usually be taken care of, however, that the suspension wires in the Abder capacitance measuring device and the infrared level from the absorption disk by the radiation sensing device are held on opposite epoxy adhesive so that the lines reached sides of the web the capacitors are electrically isolated from the disk,
At the top of the housing 60 the internal absorption device is either above or enlarged in diameter so that a metal-coated glass mirror 98, e.g. B. can be used in the form of a spherical segment, downstream or in the immediate vicinity of each other, which comes close to an ideal paraboloid corresponding to the available free 40. The space in the machining system is arranged around the outer circumference. The mirror is connected to the housing 60 by means of adhesive (in the case of capacitance measuring devices, separate electrodes 100 can be used) and furthermore also with its apex 102 on the or groups of electrodes on both sides of the upper cover 66. The mirror 98 use web, with the web between the electrodes passing through infrared radiation emanating from web 10 (Fig. 1). While the measuring head exiting the 45 and entering through the window 68 picks up on the capacitance measuring device as the radiation absorbing disk 72 focus. The housing of a display device for the beta ray disk is written and shown in the immediate vicinity and in the thermal conduction measurement or radiation source housing exchange relationship with the thermistor 70, the measuring head can be brought.

obviously any independent assembly 50 that will accommodate the radiation indicator

or an addition to another type of measuring-sealed chamber is outwardly through a

be device. Heat-insulated dead air space, which is covered by the window 68

The details for a preferred embodiment and a second similar window 104 enclosing the sensing device 54 are shown in FIGS. 2 sen, which is shown on an extension 106 of the Ge and FIG. This arrangement has a cylindrical housing 60 attached and connected via screws at 108 to the metal housing 60 with a one-piece fitting. The window 68 is provided with an annular mounting flange 62; the housing is connected by a shaped spacer 110, which surrounds the housing 60 and its extension 106 foam between a heat-insulating jacket 64 made of plastic. Inside the housing 60 is clamped with appropriate seals a sealed chamber provided at the top 60 of synthetic rubber, as at 112, on both ends by a metal lid 66 and on the lower side of the spacer. In a similar-end by a transparent way for infrared radiation, the outer window 104 is closed with a window 68, which is connected to a thin annular cover plate 114, which plastic layer, for. B. made of polyester film. In with the housing extension via screws, as the sealed chamber is attached in the axial direction 65 at 116. A seal 118 made of a synthetic infrared radiation rubber above the window 69 is inserted between the window and the housing display device with a thermistor 70 and extension,
an infrared radiation absorber which, in addition to the infrared radiation from the web

7 8

10, which is indicated by the dashed line 1386 on the radiation display device

seems, the latter takes an infrared radiation from being. This mechanical output signal changes

the housing and associated parts due to changes in the property

the ambient temperatures. Heat is also of the material to be measured, but it is also one

via the suspension wires 74 and 76 in the display 5 change due to temperature changes

device in and out of this. To be subjected in the material.

The effect of this changing environment is accordingly to display the output signal of temperature conditions on the infrared radiation of a compensation arrangement 154 with two sensing thermistors 70, a temperature section 154 a and 154 b is processed. The compensation sensing device, which includes a thermistor 120, iosation sectionl54a picks up the signal on the line on the surface of the glass reflector 98 at a slight distance 142 from the infrared radiation sensing device spaced from the edge thereof. The distance 140 on and uses this signal to influence the influence is selected so that it defines a point of attachment with temperature changes in the running web of a heat transfer characteristic which counteract that on the output signal 138 b. The mean influence of the housing temperature changes 15 compensation section 154 b receives the signal on the display thermistor 70 is adapted. Thermostatic line 146 from ambient temperature transistor 120 is connected to the surface of the reflector sensing device and uses this signal to connect by means of an epoxy adhesive. One of the line influences of the ambient temperature changes in 122 of the temperature sensing thermistor is with that on the output signal 138 b, as soldered from the Kom suspension wire 74. The other line is compensation section 154 α has been changed, separated by a bushing insulator 124 to act. The entire feedback circuit is routed outside and connected to the feeder cable 90 by using the double-changed output. The cable 90 also receives a ground wire input signal closed, which is determined by the position of a 126, which is connected to the housing 60 via a grounding mechanical component, which screw 128 is connected. 35 is represented by the dashed line 138 c ,

A schematic embodiment according to which the output from a variable energy invention is thus shown in FIG. 4, in which the capacitance source 134 a is set, which the excitation measuring device 46 feeds two spaced apart voltage into the electrodes 130 and 132, accommodates electrodes 130 and 132, which the reading display is preferably in contact with the Measuring material web 10 30 position 138 d of a pointer 156 are on a measuring scale. These electrodes electrically couple a stripe recorder 158 (not shown) power source 134 and a display device 136.

with the material. The display device has a device corresponding to a further embodiment of the arrangement, which is based on an electronic device according to FIG. 4 is in FIG. 6 shown. Here, the tric admittance characteristic of the coupling between the output signal on the line 142 from the infrared material and capacitance measuring device radiation sensor 140 corresponds to the environment, so that an output signal on the line temperature sensor 144 is connected. The 138 is generated, which specifies the value of the desired Ma temperature sensing device is in a circuit material property. An infrared radiation switched on, the influences of the ambient sensing device 140 is fixed at a distance from the measurement 40 temperature changes on the output signal 142 good web 10, so that the infrared radiation from the radiation sensing device counteracts so that the web is displayed. The radiation indicator - that a signal is generated on the line 142 a, the device contains the thermistor 70 (FIG. 2) and indicates the material temperature and independently of an associated circuit for generating a signal on the influences of the ambient temperature on the signal line 142, which is the temperature of radiation sensing device 140. The display path indicates how it is determined by the amount of infrared signal for the material temperature in a de-radiation which impinges on the radiation-speaking compensation circuit 160 with the sensing device 140. A temperature-indicating material property of not kompenabfühlvorrichtung 144, the thermistor 120 overbased signal b combined on line 138, the (F i g. 2), and contains its associated circuit 50 of the dielectric display device 136 b beer demonstrates a signal on the Line 146, which is to be rerouted. The quantitative value of the measured ambient temperature influences on the radiation property is displayed by an analog output display device 140. An arithmetic logic signal is displayed on the line 150, the output 148 takes the signals from the capacitance signal and is independent of changes in the display device coupled to the measuring device, 55 temperature of the material.

the radiation sensing device and the tempe- Another embodiment is shown in FIG

temperature sensing device and generates an output shown, which in detail an arrangement

signal on line 150 which corresponds to the quantitative speaking of the arrangement according to FIG. 6 reproduces.

Value of the measured material property independent In this example the energy source supplies a

of temperature changes in the test material web tension, with two discrete and largely

shows. oscillates at different frequencies. The high fre-

The computing frequency designated by 148 in FIG. 4 is generated by an RF oscillator 162 which

device can be designed in many ways. low frequency from a low frequency oscillator 164, the

F i g. 5 shows a switching arrangement in which a potentiometer 166 is connected.

Pointing device 136 a an electrical output 65 The voltage from the RF oscillator and part

signal on line 138 a generated by one of the voltage from the LF oscillator, which is from the

Servo system 152 is recorded and processed, movable tap 166 a of the potentiometer 166

so that a mechanical output signal, as it is picked up by, are in appropriate combination

9 10

circuitry 167 fed. An output of this temperature of the paper on a fixed nominal

Combination circuits will thus remain above a phase temperature value.

transducer 168 placed on the electrode 130 that a so that the millivolt output signal exactly the

Double frequency alternating current to the connec- tion can indicate humidity when the temperature

application office 170, the. with the other electrode 132 5 of the paper deviates from the nominal temperature

connected is given. The combination circuit tap 190 a to the other output terminal

gen 167 also excite the line 172, with a 196 in series with a

equally large and oppositely directed current chung-related millivolt voltage switched, the

to the junction. 170 is obtained via a balancing from a bridge circuit 198, which

capacitor 174 with missing web 10 to the Kapa- io the infrared radiation sensing thermistor 70 and the

is given, for example, when the temperature sensing thermistor 120 of Figs

And 3 contains capacitance measuring device for normalization purposes.

in connection with Fig. 1 described manner of <. The bridge circuit 198 is controlled by a corresponding

the web is removed; corresponding constant voltage source, e.g. B. the battery

The connection 170 of the capacitance measuring device 15 200 is fed. The thermistor 70 is connected to the

and the adjustment capacitor is connected to the input voltage source in series with a resistor 201

a display amplifier 176 placed. When the capa; the thermistor 120 is with the voltage source

ity measuring device. connected in series with a resistor 202 in the vicinity of the track 10. Two

is brought, they are. Currents through capacitance resistors 204 and 206 are also in series

measuring device and placed through the capacitor 174 20 the battery. The connection 208 of the cons

no longer in equilibrium, and the potential at stands 204 and 206 results in a reference potential point

junction 170 is trying to change. in the bridge circuit.

This tendency is determined by the display amplifier. The value of resistor 201 is set so that counteracted, the output of which a current flow in that the connection 210 of the resistor 201 and the junction 170 via the feedback 25 of the thermistor 70 is at the reference temperature, the capacitor 178 caused. The current due to approximately the average temperature of the material or Negative feedback is the same size and counteracts when the machine is in normal operation set the unbalance current that works in the upstream. The value of the resistor 202 becomes so called one Connection flows so that the connection is made that connection 212 to the thermistor is always kept at zero potential. 30 120 is at reference potential when the housing 60 , The output 180 of the display amplifier gives (Fig. 2) and adjacent parts on a middle a voltage, which is made up of two voltages with operating temperature, the arrangement from the corresponding low and high frequencies display head and capacitance measuring device above the composed, which by the oscillators 162 path in the measuring position according to F i g. 1 is arranged. and 164 are generated. The RF voltage will be 35 when the web temperature is selected from the by an HF modulator 182 and the nominal LF span temperature deviates, results in the potential difference demodulated by an LF demodulator 184. rence between the junction 208 and the The outputs from the two demodulators are junction 210 a millivolt signal that the fed to a servo amplifier circuit 186, temperature deviation as indicated by the infrared die receives a zero voltage input when the radiation sensing thermistor 70 is detected at ratio of the voltages from the two demo shows, although the signal from the ambient tempedulators is equal to one. A change in this default condition is influenced. When the circumstances causes the servo amplifier to have an ambient temperature of the nominal or mean value Servomotor 188 energized, which deviates the movable tap, gives the potential difference between the fung 166α of the potentiometer 166 drives. A millivolt signal on these 45 connection points 208 and 212, Way, the LF excitation voltage, which is proportional to the deviation in the in The capacitance measuring device is fed in, voltage divider resistors 214 connected in series Necessarily adjusted so that the constant ratio and 216 occurs.

of the demodulated signals maintained at one. The ratio of the two resistors 214 and

remain. 50 216 will depend on the ratio of the

The potentiometer 166 is used in the manner of the sensitivity of the thermistor 70 to the It detects that a plurality of shunts resist infrared radiation from the web and the housings the taps of the potentiometer connected temperature as indicated by the thermistor 120 sen be set, whereby the one from the tap 166 a is set, with any difference in the holding voltage is a non-linear function of the 55 characteristic properties of the two thermi positions the tap along the potentiometer. disturb is taken into account. The exit of the Briik-Durch Setting the values of the shunt resistor 198 is made between the connection levels, this function is shaped so that the adjusters 210 and 218 are removed, and the absolute one Shifting the potentiometer tap 166 a millivolt voltage of this output is applied to the linear function of the moisture in the material at the 60 millivolt output of the reading potentiometer 190 predetermined nominal temperature. fits, in that the output of the constant voltage

The servo motor 188 also drives the slide 190 a source 200 is set, the energy in the tem-

of a potentiometer 190, which feeds into a constant temperature bridge circuit.

Voltage source is connected. If desired, the accuracy of the

series 192 is shown. Thus, the tapping 65 radiation sensing device results in increased

function 190 α a millivolt signal in relation to an output that the arithmetic circuit is more complicated and expensive

output terminal 194, which is built as a linear function of the diger, e.g. B. as an arrangement that the

There is moisture in the paper, provided that the output of the temperature sensing device to the control

An automatic heating device is used to keep the body temperature of the radiation sensing device is kept at a constant value. It is also not necessary that the radiation sensing device and the temperature sensing device are separate elements. For example, it is possible to use a chopper arrangement, which alternately blocks infrared radiation against a single discharge device or blocks this radiation passes, then alternately a material temperature output is obtained when the device is in its illuminated position and an ambient temperature output occurs when the device is darkened.

15th

Claims (8)

Patent claims: 1. Device for measuring a property, in particular the humidity of a running Web of dielectric material to be measured, e.g. B. Paper, the temperature of which is subject to fluctuations over time is characterized by the combination of the following individually known measures: a) a capacitance measuring device (46; 130, 132) for measuring a dielectric property of the material to be measured (10); b) a device (54, 70; 140) for measuring the temperature of the material to be measured on the basis of the Infrared radiation with a speed of the running web (10) adapted low time constant running in the longitudinal direction of the web in the immediate vicinity of the device a) is arranged; c) a device (120, 144) for measuring the ambient temperature of the device b); d) a computing circuit (148) which on the one hand the influence of the ambient temperature on the device b) compensates and other 40 on the one hand, the dielectric measured values are corrected according to the temperature of the material to be measured;
e) a mechanical device (30, 44) for moving a measuring head (28) containing the devices a), b) and c) transversely to the running web of material to be measured (10). 2. Apparatus according to claim 1, characterized in that the temperature measuring device (70) is arranged in a housing (60, 64, 66) which has a window (68) which is transparent to infrared radiation. 3. Apparatus according to claim 1 or 2, characterized in that one of the temperature measuring device (70) associated infrared radiation absorption device (72) is arranged within the housing (60). 4. Apparatus according to claim 3, characterized in that the infrared radiation absorption device (72) is a blackened disk suspended from wires (74, 76) insulated in the housing (60). 5. Apparatus according to claim 2, characterized in that the temperature measuring device (70) is designed as a thermistor and is connected to the suspension wires (74, 76) is in connection. 6. Apparatus according to claim 1 or one of the following, characterized in that the housing (60, 64, 66) has a reflector (98) at the end facing away from the radiation inlet side, which focuses incident infrared radiation on the absorption device (72). 7. Apparatus according to claim 6, characterized in that facing the measuring space Side of the reflector (98) a temperature measuring device (120) is arranged, which with the suspension wire (74) is connected. 8. Apparatus according to claim 1 or one of the following, characterized in that the Window (68) of the housing (60, 64, 66) closed off by a further window (104) thermally insulating Space is pre-built. 1 sheet of drawings