DE19511707B4 - Method for determining stresses in transparent materials - Google Patents

Abstract

wobei Δ die Summe der Phasenverschiebung auf Grund der Zirkularpolarisierung und der Phasenverschiebung δ_b durch das verspannte transparente Material ist:

Method for determining stresses in transparent materials, in particular in glass, wherein polarized light is passed through the material and the exiting light beam is analyzed such that a change in the polarization state of the light beam due to birefringence due to stresses in the material is measured, characterized
That circularly polarized light is transmitted through the material,
- That simultaneously and independently of each other, the intensity of the light passed through the material light in two mutually perpendicular polarization components Ip, I _{s is} measured and
- That from the polarization components I _p , I _s, the quotient K is calculated from

where Δ is the sum of the phase shift due to the circular polarization and the phase shift δ _b through the strained transparent material:

Description

The The invention relates to a method for determining stresses in transparent materials according to the preamble of claim 1.

From the DE 35 12 851 A1 is a method for measuring permanent longitudinal stresses of a strip of float glass in the production line known. For this purpose, a bundle of linearly polarized light is sent into the glass ribbon, wherein stresses in the glass cause a birefringence. The outgoing light beam is analyzed to determine the changes in polarization state caused by birefringence and, consequently, the stress in the glass. Here, on the same optical axis, a light source, a linearly polarizing polarizer and a device which converts the linearly polarized light beam into a circularly polarized light beam are used. On the other side of the glass ribbon, a second linear polarizer and a photosensitive receiver for converting the intensity of the light beam into an electrical signal are arranged on the same optical axis. One of the two polarizers is driven by a continuous rotation. In addition, the temperature of the glass ribbon at the measuring point for the voltages is still determined.

adversely at this measuring method is, inter alia, that permanent rotating polarizers are used, which are just measurements in a production line of glass ribbons with their high temperatures and high degree of contamination easily to disturbances to lead can.

Of the Invention is based on the object, a method for determining of stresses in transparent materials, especially in glass, specify with no rotating elements and with a sensitivity independently from disturbing external influences, such as changes in brightness the light source and the transmittance of the transparent material, can be measured.

Under transparent materials is glass, plastic wrap or plastic as plexiglass, etc., i. not passing light diffusing transparent materials.

According to the invention this object is achieved in that circularly polarized light is passed through the material and that simultaneously and independently of each other, the intensity of the light transmitted through the material in two mutually perpendicular polarization components Ip, I _{s is} measured.

The quotient K is calculated from the polarization components I _p , I _s :

wobei λ = Wellenlänge der Lichtquelle,
dass die Materialdicke d des transparenten Materials mittels an sich bekannter Meßverfahren ermittelt wird und
dass die Materialspannung A a berechnet wird aus der Beziehung Δσ = δ/(S·d)wobei S die spannungsoptische Konstante des zu untersuchenden Materials ist.An advantageous embodiment is characterized in that it calculates the path difference δ from the birefringence

where λ = wavelength of the light source,
that the material thickness d of the transparent material is determined by means of measuring methods known per se, and
that the material tension A a is calculated from the relationship Δσ = δ / (S · d) where S is the stress-optical constant of the material to be examined.

One The essence of the invention is that circularly polarized Light is sent through the material and simultaneously and independently the intensity of the light which has passed through the material into two mutually vertical polarization components is measured. strained Glass changed by its birefringence the degree of polarization of the glass urgent circular-polarized light. This occurs either an enlargement or a reduction of the path difference δ between the two vertically mutually oscillating polarization components of the light, depending on size and sign the glass tension. It is therefore an elliptically polarized light leave the glass. It is often referred to below for the term "transparent material" Glass used. As mentioned above, can but except Glass also other materials are used.

The Light intensity The polarization component is a direct function of the path difference and the brightness of the light source. The light intensity will however through the glass color, glass thickness, contamination of optical components in the light path and the aging of the light source affected. To this To eliminate the effect, therefore, the above-mentioned quotient K is calculated, the one of the light intensity independent Size represents. This means that above mentioned Effects have no effect on the Have measurement. The range of values of the quotient K lies between -1 and +1.

The calculation of the path difference δ is made after the determination of the quotient K simply by the above equation. The only requirement is the knowledge of the wavelength λ of the light source. Advantageously, a laser is used.

With the knowledge of the material thickness d at the measuring point of the voltage measurement, the voltage simply results from the relationship Δσ = δ / (S × d), where S is the stress-optical constant of the glass to be examined. δ is the gait difference. The material thickness or glass thickness is determined by methods known per se (see, eg DE 35 12 851 A1 ).

In the case of glass bands, the principal stress directions σ ₂ and σ _1, which are of interest for the measurement, are in the direction of glass run and transverse to the direction of glass run (= transverse direction). The mutually perpendicular polarization components I _p and I _s are now in turn with respect to the glass ribbon oriented so that their bisector coincides with the glass direction.

Conveniently, the transmitter consists of a laser as a light source, a diaphragm and a polarizer with a downstream lambda / 4 plate. The transmitter thus generates circularly polarized light which then sent through the glass.

The receiver consists inter alia of two polarizers, preferably two Brewster plates, which are each crossed to each other and are arranged at an angle of 45 ° to the glass direction. With these Brewster plates thus the two mutually perpendicular polarization components I _p , I _{s are} cleanly separated.

The intensity the two mutually perpendicular polarization components are inventively means PIN diodes with downstream lock-in amplifier measured.

Further Features of the invention will become apparent from the figures below be described in detail. It shows:

1 schematically a measuring arrangement according to the invention for determining the voltage in a glass ribbon and

2 schematically the associated peripherals.

1 schematically shows a measuring arrangement for determining the voltage in a glass ribbon 1 , Below the glass band 1 is a transmitter 2 arranged, consisting of a laser as a light source 3 , a panel 4 and a polarizing filter 5 oriented at 45 ° to the glass direction with downstream lambda / 4 plate 6 consists. The transmitter 2 generates circularly polarized light, which passes through the glass ribbon 1 is sent through. The light beam is denoted by the reference numeral 11 indicated. The laser is, for example, a diode laser with a wavelength of, for example, 688 nm. In order to suppress interference by extraneous light, the laser is modulated.

Above the glass band 1 is a receiver 7 arranged behind an optical filter 12 two Brewster plates 8a . 8b contains, which are each arranged at an angle of 45 ° to the glass direction and crossed relative to each other. These two Brewster plates 8a . 8b split the incoming light into two polarization components I _p , I _s , their intensities with high sensitivity PIN diodes 9a . 9b be measured. The evaluation of the output signals of the two PIN diodes 9a . 9b takes place via a high-precision linear measuring amplifier with a downstream lock-in amplifier 10 , The output signal of the lock-in amplifier 10 is passed directly to an analog-to-digital converter and to a microcontroller 13 (please refer 2 ).

As for the determination of the voltage and the measurement of the thickness of the glass sheet 1 is required is a thickness gauge 14 above the glass railway 1 arranged. To determine the permanent tension, also called "cold tension" Δσ _cold , the knowledge of the temperature of the glass web at the measuring location is required. For this reason, a radiation pyrometer 15 built-in.

2 shows the associated periphery. Both the transmitter 2 as well as the receiver 7 are with a microcontroller 13 connected. The lock-in amplifier or the measuring amplifier 10 converts the intensity of the two polarization components into a 12-bit digital value. The lock-in amplifier suppresses this in the receiver 7 falling extraneous light. The digital measured values are then sent to the microcontroller for further processing 13 transfer. This connects the values with the current measuring position, the local glass temperature and the local glass thickness from the thickness gauge 14 , After the path difference δ of the two polarization components has been calculated, the results are sent to a personal computer 16 with monitor 17 , Keyboard 18 and printers 19 transmitted for display and for statistical evaluation. With the reference number 20 is a power switch designated, also with the reference numeral 21 the power supply for the personal computer 16 with periphery. The personal computer 16 can also be advantageously in a network 22 integrate.

The determination of the instantaneous glass tension, also called "thermal stress" Δσ _warm , then takes place according to the method described above. This value of glass tension is ever but only for the measuring location and for the current temperature of the glass sheet at the time of measurement. The following known equation is used for the calculation of the permanent voltage: Δσ cold = Δσ warm - F · ΔT = Δσ warm - F · (T (x) - T m ).

Here, Δσ _{k is} the permanent glass tension and Δσ _W , the warm voltage from the measurement, T (x) the temperature at the measurement location. T _m the mean glass transition temperature is averaged over the glass width at the measurement site and F is a constant that describes the elastic properties for the particular type of glass. For this constant, the value F = 0.63 N / mm ² K is preferably used for float glass.

Since the range of values for the quotient K is between -1 and +1, the maximum measuring range for the path difference δ results -Λ / 4 ≤ δ ≤ + λ / 4.

The diode laser used has a wavelength of 688 mm, whereby the range for the path difference between -172 nm and +172 nm. With a mean glass thickness of 5 mm, this corresponds to a glass tension Δσ between -12.08 N / mm ² and + 12.08 N / mm ² . The measurement results are not dependent on the absolute intensity values of the polarization components.

Claims (6)

Method for determining stresses in transparent materials, in particular in glass, wherein polarized light is passed through the material and the exiting light beam is analyzed such that a change in the polarization state of the light beam due to birefringence due to stresses in the material is measured, characterized - That circularly polarized light is sent through the material, - that simultaneously and independently of each other, the intensity of the light passed through the material light in two mutually perpendicular polarization components Ip, I _{s is} measured and - that of the polarization components I _p , I _s, the quotient K is calculated

where Δ is the sum of the phase shift due to the circular polarization and the phase shift δ _b through the strained transparent material:

Method according to Claim 1, characterized in that the path difference δ of the birefringence is calculated from the quotient K

where λ = wavelength of the light source ( 3 ), and

that the material thickness d of the transparent material is determined by means of measuring methods known per se and that the material tension Δσ is calculated from the relationship Δσ = δ / (S · d) where S is the stress-optical constant of the material to be examined. Method according to claim 1 or 2, characterized in that the transparent material is a glass ribbon ( 1 ) and the polarization component Ip is the intensity in the direction of travel and the polarization component I _{s is} the intensity in the transverse direction. Method according to one of Claims 1 to 3, characterized in that the transmitter ( 2 ) from a laser as a light source ( 3 ), an aperture ( 4 ) and a polarizing filter ( 5 ) with a downstream lambda / 4 plate ( 6 ) consists. Method according to one of Claims 1 to 4, characterized in that the receiver ( 7 ) of two separate polarizers, preferably of two crossed Brewster plates ( 8a . 8b ), which are each arranged at an angle of 45 ° to the glass direction. Method according to one of claims 1 to 5, characterized in that the intensity of the two mutually perpendicular polarization components Ip, I _s by means of PIN diodes ( 9a . 9b ) with a downstream lock-in amplifier ( 10 ) are measured.