DE1573340A1 - Measuring device for temperature rays - Google Patents

Description

Measuring device for temperature rays.

As is known, radiation pyrometers are used to measure high temperatures These are based on the fact that the energy of the total radiation or that of the Basically, it measures and uses radiation from a certain spectral range Stef an-Boltzmann's law or the disadvantage of this method is that it only works is applicable if the distance from the measuring device to the radiating body and the Emission coefficient of the body are known. Another burned method is that Temperature color of the temperature radiator with the temperature color of a known one Body (e.g. filament of a light bulb). Disadvantage of this method: it is Cannot be used for the automatic control of a process.

The device for thermal radiation given by the inventor below works independently of the distance and the @@@@@ emission coefficient of the radiating Body and is suitable for the automatic control of processes.

The invention is based on the following idea by means of two @ on different Wavelength ranges of the radiation spectrum, appropriate indicators (photocells) the radiation energy of the radiator is determined. From these two measurement data, the quotient formed t. This t? t is then only a function of temperature and can be used directly to control processes.

It is again with this measuring method, as with the known methods, a prerequisite that the body whose temperature is to be measured is a gray body or that the dependence of the emission coefficient @ n on the wavelength is known is.

According to Planck's law of radiation. one finds e.g. the following spectral intensity distribution of the gray radiation: see Figure 1, if you filter e.g. the intensity I1µ at 14 wavelength for 800 ° C body temperature, one obtains 1.3 1o1 Units. So I2.5µ = 4.5 1o2 units. Then a measure @@@ 1,3 # 10 @@ is for T = 800 ° C the value @ 3 # 10-2 @@@@@ @@@@@@@ You can also find the value for T = 1000 ° C for = @@@ @@@@@ @@@@@@@ Neither the emission coefficient nor the distance plays a role, since these are in the numerator and denominator in the same way and stand out with it.

This basically results in the mlock circuit diagram: Figure 2.

The temperature radiation hits two indicators (photocells) Pi and P2, whose spectral sensitivity is well known. th area around # 1 or # 1 The resulting voltages U and U2 proportional to the intensity I # @ or go into the division circuit. The voltage comes from the division circuit Uw = U. U1 / U2, which only depends on the temperature. Since the division circuit is an essential It is part of the measuring device and must be described in more detail.

The invention of the division circuit is based on the fact that at non-linear resistances e.g. crystal diodes the differential resistance D = dU / dI depends on the voltage U. Figure 3 shows the characteristic of a voltage-dependent Resistance, which has the equation I = f (U).

Two voltages E1 and E2 are applied to the resistor, e.g. after of the circuit in Figure 4, of which E1 is a direct voltage, E2 an alternating voltage To simplify the explanation, it is assumed that @ 1 is zero for direct current, but for alternating current infinitely large (choke), # 2 should be infinitely large for direct current his-and for alternating current a short circuit (large capacitor). The alternating voltage E2 should be so small that the differential resistance D = dU / dI is constant can be viewed, i.e. that the characteristic curve in area E2 is viewed as a straight line (see Figure 3). By means of the G DC voltage E1 becomes by shifting The desired D is established from the working point. The measuring instrument should only use alternating current Calculate for the alternating current I2 = flowing through the instrument E2 / D with dU 1 1 1 1 D = dJ = dJ / dY = df (U) = f '(U) = f' (E1) dU is obtained for I2 = E2 f '(E1) Depending on the choice of the shape of the characteristic and the approach of the two voltages E1 and E2 on the voltage-dependent resistor can have a wide variety of functions I2 = I2 (E1, E2) achieve O If, for example, the characteristic curve in our example is the form I. = ln U, then dI / dU = f '(U) = 1 / U and one has the desired division for 12. = E2 / E achieved.

In the following, a division code (Figure 5) with an e-functional Characteristic curve I = I0 e # @ must be discussed, since crystal diodes have such a characteristic curve are in trade.

Choose R1 # U / I and R2 # D so that the following simplifications apply: 1. DC consideration E1 = R1. I1 + U it follows for R1 # U / I E1 = R1 # I1 (E2 and I2 should be much smaller than -E1 and I1) 2. Alternating current consideration E2 = (R2 + @ / @@@) @ 2 + D @ 2 With D = dU / dI = const for I2 sufficiently small. R1 was neglected. Selected one again (R2 + 1 / jwC) >> Dmax then ES = (R2 + ###) @ 2 (2) D & die Characteristic curve in the form of an exponential function, I = I0 e This results from the resolution after U 1. and by deriving dU = 1. 1 = D (3) dJ α J J = J1 ##### J2 << J1 Put (1) in (3) D = @ / @ R @ # @ / E1 D @ 2 = 1 / @ R @ @@ / E1 and with (2) R @ D @ 2 = @ / @ # E2 / E1 1 R2 + @@@ D 12 is exactly the alternating voltage that can be tapped after Cl Uw and you have achieved the division of 22 / E1.

Figure 5 shows only a basic arrangement to achieve a division. In practice, it is not very favorable because of the high resistances R1 and R2 and the high voltages E1 and E2 required , for which the required proportionalities (between E1, I1 and E2,12) still apply, but the resistances can be selected to be lower. Figure 6 shows such a circuit. V is a constant DC voltage source. Figure 7 is the equivalent circuit diagram for Figure 6 for calculating the effect of the DC voltage E1. The following applies: 1 = R @ I1 + U - V As you can see from Figure 3, U fluctuates only in small limits if I changes significantly ¢ One chooses hence the mean value of U for V. This makes the difference U - V much smaller than U (especially when the exponential function is very steep) and one can use the approximation E1 = R I1 for much smaller R than in the Circuit Figure 5. For the alternating current E2, Figure 6 can be replaced by the equivalent circuit diagram 8. The capacitor 0o should be so large that it represents a short circuit at the frequency of the alternating current E2 used. It then applies to the alternating voltage Uw taken from the diode If one tunes the circle L, C exactly to its natural frequency @ = @ / @@, then applies to Uw @ 2L CDU w L The last law again has the desired form, like (2). With this circuit, tan can achieve the desired division with much smaller E1 and E2 and then with less effort. The frequency dependency of the circuit is not a disadvantage.

The e-function-shaped characteristic is generally valid for a specific one Area with which E1 is restricted. E2 is limited upwards by the fact that the characteristic can no longer be replaced by a straight line, i.e. that D is no longer independent from E2ist and after. below by the residues of alternating voltage penetrating via E1 and by the sensitivity of the subsequent amplifier.

Figure 9 shows the block diagram of the entire measuring device.

The thermal radiation passes through an optical device (not drawn), a perforated disc t, which is driven by a (synchronous) motor S. and the filter Pi 1 or the filter Fi 2 and hits the indicators (photo cells) Pl or P2.

The combination Fi @, P1 and Fi 2, P2 take effect from the temperature radiation spectrum two different areas around @@ and r, out, those created by the two photocells AC voltages are amplified by the amplifiers V1, V2 and V3 Amplifier v3 and subsequent rectification received control voltages U51 and US2 the amplification factors of amplifiers V1 and V2 can be changed, Just make sure that this happens in the same way in both amplifiers.

In this way, the ratio of E1 or 22, given a high incident intensity Imax and a low intensity Imin, can be made smaller than the ratio of the two intensities themselves.

This means that the working area of the device is superimposed on the working area The division circuit is enlarged. By means of U51 and U52 it is also possible to switch to mechanical Ways to control the radiation falling on the indicators (photocells), e.g. if If the radiation becomes too strong, an additional, gray filter is placed in the beam path You can also measure the control voltage US1 or U52 (instrument U) and thus recognizes whether the device is working in the permissible range rs2 goes directly into the division circuit (possibly according to Fig. 6) the AC voltage must from amplifier V2 rectified (in Eq. 2) and well filtered to then be used as E1 into the division chat to kick. The one from the division circuit occurring alternating voltage Uw depends on the temperature and can after amplification can be used to control a process.

Claims (4)

Claims 1. A measuring device for temperature rays, characterized in that that the intensities from two different wavelength ranges of the temperature radiation spectrum of the radiating body can be measured and its quotient as a measure of the temperature is formed. 2. Method for calculating a third variable from two variables electrical path, characterized by the simultaneous use of the following features: a. Use of a voltage-dependent resistor (in the following only as a resistor b. One variable is applied to the resistor as an alternating voltage. It is so small that the resistance in this area can be regarded as constant can. The second quantity is applied to the resistor as a sliding voltage, along with it the operating point on the resistance curve is changed. The third variable is the amount of alternating current flowing through the resistor or through the Voltage drop of the alternating current across the resistor is determined. 3. The method for division according to claim 2, characterized in that the characteristic curve of the resistance is e-functional and the two currents are theirs Generator voltages are proportional to @@. (ohmic) 4. Procedure for division by Claim 3, characterized in that the variable resistance is alternating current is connected as I) damping resistance of an oscillating circuit, e.g. according to Fig. 6) 5 ... measuring device for thermal radiation according to claim 1, characterized by simultaneous application the following features: a. claim 4 @@@ 3 b. the mediated to the division circuit Voltages can be proportionally regulated by two amplifiers, this is done automatically. Your process can be monitored. L e r s e i t e