DE4429582C2 - Radiation source for a measuring system - Google Patents

Description

The invention relates to a radiation source for a Measuring system for the spectroscopic determination of the proportion of a substance in a gas sample with at least one Temperature control device for setting a Temperature operating point of the radiation source.

A device for the spectroscopic determination of the The proportion of a substance in a gas sample is from the DE 41 22 572 A1 has become known. With the known Device will use oxygen concentrations Radiation absorption in the wavelength range Measured 760 nanometers. A radiation source is used So-called edge-emitting laser diode with one Monitor diode used, with a wavelength range from 759 to 764 nanometers. The one on the front of the Radiation emitted by laser diode is called measuring radiation used, the back radiation hits the Monitor diode. The laser diode is powered by a control current fed from a DC component and a AC component with a frequency of 5 KHz is composed. With the DC component of the Control current is the working current I of the laser diode set while the AC component is a periodic upset in the area of Absorption lines causes. To one if possible harmonic-free control of the laser diode reach is a sinusoidal as an alternating current Curve chosen. The laser diode and the  Monitor diode are as a block on one Temperature control device mounted, with the Temperature T is the temperature operating point of the laser diode adjusted and this thereby to one of the known Absorption lines of oxygen is brought. Since the Absorption lines, especially with oxygen, weak are pronounced, the second derivative of the Absorption line for concentration measurement used. The lies within the absorption line Working point usually on the middle extremum the second derivative of the absorption line. The radiation emitted by the laser diode strikes after going through the gas to be examined, on a detector device connected to a Evaluation circuit is connected. The Evaluation circuit essentially consists of a Lock-in amplifier connected to the signal input Measuring signal of the detector device and at his Reference input with a signal voltage from the double frequency of driving the laser diode is applied. The output signal of the lock-in Amplifier corresponds to the second derivative of the Absorption signal.

A disadvantage of the known device is that edge emitting laser diodes when changing the Temperature T of the temperature control device, the Working current I and also due to aging processes can change the longitudinal mode, whereby a sudden frequency jump or mode jump occurs. Another disadvantage is that the monitor diode with the the backward radiation emerging from the laser diode is applied and not with that too Examining gas passing through measuring radiation. This can cause inaccuracies in the measurement  the radiation power of the laser diode by means of Set the monitor diode.

A measuring system for the spectroscopic determination of the Proportion of oxygen in a gas sample with a Peltier element as temperature control device, is from the US 4,730,112. The Peltier element is sandwiched between two metallic ones Carrier plates, one of which is warm and the other represents the cold side of the Peltier element. As Radiation source becomes an edge emitting Laser diode used, which has a heat sink on the "cold" support plate of the Peltier element attached is. The back radiation of the laser diode is with one on the "cold" carrier plate Monitor diode registered while that from the Laser radiation emerging from a measuring beam Optical fiber guided to the gas sample to be analyzed becomes.

The disadvantage of the known measuring system is complicated structure of the radiation transmitter with the Heat sink.

A display system for projecting data into the The field of vision of a helmet wearer is from US 5,325,386 known. Essential part of the Display system is an array of vertical emitting laser diodes on a substrate are arranged as a carrier and via an electronic Circuit can be controlled. With the laser diode array can be both colored and monochromatic Representations can be realized with high resolution.  

From the US Z .: Appl. Phys. Lett., Vol. 59, No. 1, 1991, pp. 117-119 is one Infrared radiation source known from an on a Peltier element attached, vertically emitting laser diode. The well-known Radiation source can also be used for applications in IR spectroscopy.

To stabilize the radiation power of laser diodes, it is known to use so-called monitor diodes with which the emitted Radiation power detected and then the laser diode current accordingly is adjusted. Such stabilization circuits go from the JP 4-57 382 A and JP 2-112 295 A.

From the US Z .: Appl. Phys. Lett., Vol. 58, No. 1, 1991, pp. 31-33 and U.S. Z .: Journal of Lightwave Technology, Vol. 9, No. 12, 1991, pp. 1665-1673 Arrays of vertically emitting laser diodes are known, which at emit different wavelengths and in the range of optical communication technology can be used.

The invention has for its object a radiation source for a Measuring system for the spectroscopic determination of the proportion of a substance in a Improve gas sample so that the occurrence of mode jumps is reduced is.

The problem is solved with the features of claim 1.

Vertically emitting laser diodes are because of their small beam angle and their good tunability in that used for gas analysis Waveband can also be used particularly advantageously in IR spectroscopy. she have namely the advantage over edge emitting laser diodes that they due to their small resonator, large distances between the individual modes have so that within a mode a wavelength range of about one Nanometer can be tuned.

The laser diode is a chip-shaped array of individual, vertically emitting Laser diodes designed, which are tuned to different wavelengths are to absorb the measuring radiation at different wavelengths to be able to measure.

Advantageous embodiments of the invention are in the subclaims given.  

A particularly simple and compact construction in Connection with a temperature control device with a Peltier element arises when the laser diode bearing substrate flat on a carrier plate of the Peltier element is attached, being as Carrier plate usually the cold side of the Peltier element is used. The Temperature control device exists next to the Peltier element essentially from a control unit, which for Energy supply of the Peltier element is used.

The substrate is expediently on the receiving carrier plate a temperature sensor provided which to the temperature control device connected. The temperature sensor measures that Temperature around the laser diode and can either on the substrate or directly on the Carrier plate may be attached. Within the Control unit of the temperature control device with the Temperature sensor measured temperature with a Setpoint value of a temperature operating point T compared and then the supply voltage of the Peltier element changed in such a way until specified and measured Temperature match.

The emission range is expediently the Laser diode at least the emitted radiation partially reflective, transmission radiation transmitting disc is provided and on which the Laser diode receiving carrier plate or the substrate a monitor diode is attached, which in Reception area of the reflected on the disc Partial radiation is. As part of the monitor diode the radiation emitted is measured on this Way a particularly good regulation of the  Radiation power of the laser diode possible. At the out edge emitting known in IR spectroscopy Laser diodes are usually the rear emerging radiation used for power control, which is generally not the same Like the measuring radiation, radiation intensity has with which is irradiated through the gas sample.

An expedient structure of the invention Radiation source is that the Peltier element in the area of the bottom one with contact pins provided, pot-shaped housing is attached, and that the side of the housing opposite the floor is completed by the disc.

An embodiment of the invention is in the Drawing shown and explained in more detail below.

The single figure shows schematically a radiation source ( 1 ) according to the invention in longitudinal section. The radiation source ( 1 ) consists of a laser diode ( 2 ) on a flat substrate ( 8 ), which emits a measuring beam ( 12 ) vertically to the substrate ( 8 ) and is glued flat onto a first carrier plate ( 3 ) of a Peltier element ( 4 ) is. The first carrier plate ( 3 ) corresponds to the cold side of the Peltier element ( 4 ). A second carrier plate ( 5 ), which represents the warm side of the Peltier element ( 4 ) and is arranged like a sandwich to the first carrier plate ( 3 ), is fastened to the bottom ( 6 ) of a pot-shaped housing ( 7 ). A monitor diode ( 9 ) and a temperature sensor ( 10 ) are also attached to the substrate ( 8 ). The temperature sensor ( 10 ), the Peltier element ( 4 ), and a control unit ( 15 ) with a set point adjuster ( 16 ) for a temperature T, together form a temperature control device ( 17 ) for setting the temperature operating point T of the laser diode ( 2 ) . The contacting of the Peltier element ( 4 ), the laser diode ( 2 ), the monitor diode ( 9 ) and the temperature sensor ( 10 ) takes place via contact pins ( 11 ) on the bottom ( 6 ) of the housing ( 7 ). The right contact pin ( 11 ) is connected to the temperature sensor ( 10 ); the two contact pins ( 11 ) in front of it are used to contact the Peltier element ( 4 ). The control unit ( 15 ) consists essentially of a voltage supply unit for the Peltier element ( 4 ), not shown in the figure, and a controller, also not shown in the figure, which uses the measured value of the temperature sensor ( 10 ) as the actual value and that on the setpoint adjuster ( 16 ) preset size for the temperature operating point T is applied. The housing ( 7 ) is closed on the side opposite the bottom ( 6 ) with a disc ( 13 ), on which partial beams ( 14 ) of the measuring beam ( 12 ) emitted by the laser diode ( 2 ) are reflected in the direction of the monitor diode ( 9 ) . The beam ( 12 ) is only shown schematically in the figure, since the radiation emission from the laser diode ( 2 ) takes place at a certain radiation angle. The measuring system for spectroscopic analysis of the proportion of a substance to be detected in a gas sample can be constructed, for example, according to DE 41 22 572 A1.

Claims (5)

1. radiation source ( 1 ) for a measuring system for the spectroscopic determination of the proportion of a substance in a gas sample with at least one temperature control device ( 17 ) for setting a temperature operating point (T) of the radiation source ( 1 ), characterized in that the radiation source ( 1 ) is a chip-shaped array of individual, vertically emitting laser diodes ( 2 ) located on a planar substrate ( 8 ) and emitting vertically to the substrate ( 8 ), which are set to different wavelengths. 2. Radiation source according to claim 1, characterized in that the substrate ( 8 ) with the array of laser diodes ( 2 ) lying flat on a first carrier plate ( 3 ) of a Peltier element ( 4 ), which is part of the temperature control device ( 17 ), is attached. 3. Radiation source according to claim 2, characterized in that in the region of the substrate ( 8 ) or the substrate ( 8 ) receiving the first carrier plate ( 3 ), a temperature sensor ( 10 ) is provided which is connected to the temperature control device ( 17 ). 4. Radiation source according to one of claims 1 to 3, characterized in that in the emission region of the laser diodes ( 2 ) a partially reflecting the emitted radiation and the transmission radiation ( 12 ) transmitting disk ( 13 ) is provided and that a monitor diode ( 9 ) is present which receives the partial beams ( 14 ) reflected by the disc ( 13 ). 5. Radiation source according to claim 4, characterized in that the first carrier plate ( 3 ) opposite side of the Peltier element ( 4 ) on the bottom ( 6 ) of a contact pin ( 11 ) provided, pot-shaped housing ( 7 ) which is fixed by the disc ( 13 ) is completed.