DE1944078C3 - Optical transmitter (laser) - Google Patents

Description

The formation of a closed cooling system in FIG. 1 shown optical transmitter consists

such an optical transmitter can essentially consist of a hollow cylindrical excitation

. also use in portable devices. The mirror 1 and the interior

also the shock-insensitive storage of the fractured siab-shaped stimulable medium 2

endangered parts, namely the one made of crystalline material 5 with the parallel rod-shaped excitation

rial, for example made of ruby, the stimulating light source 3. The actual stimulating mirror

medium and the excitation light source is countered as a mirror support 1 "on a tubular metal

gen. metallic mirror carrier 1 'applied that the an

In a first preferred embodiment, the excitation mirror 1 accommodating housing 7 is with two

the hollow cylindrical excitation ^ mirror! with elliptical connecting piece 22 that is open towards the interior of the housing

Apparent cross-section executed, its large half-provided. An annularly arranged flow

aciise is insignificantly greater than the outer diameter resistance 23 on the inner wall of the housing

ser the excitation light source or the stimulable ensured that the coolant, for example

Medium is. Water, is severely obstructed, the direct route between

In a second preferred embodiment 15 see to take the two connecting pieces. the

is the hollow cylindrical excitation mirror as a circular excitation mirror 1 is verse with two openings 24

cylinder executed and the arrangement with respect to the hen through which the coolant enters and exits

Excitation light source and the stimulable medi- can. These two openings are for the better

dimensioned as an exfocal circular cylinder system. Flooding of the interior of the excitation mirror

To further increase dr cooling effect of the other 20 opposite and axially offset angeord coolant is designed as a net excitation mirror. The stimulable medium 2 and the excitation metallic hollow cylinder with openings for the transmitted light source 3 are provided in the coolant passages opposite one another. Mounted in the space of the housing wall parts of the housing 7. This inner surface of the tub and the outer surface of the hollow cylinder part are designed in three layers. They also consist of flow resistances in such a way arranged and designed from one of two rigid plates 5 and 6 that the coolant flows around the closed, middle, flexible end on all sides. plate 4. When assembling the optical transmitter

In a further development of the inventive op- the outer rigid plate 5 is against the housing The electrodes of the rod feeder are also screwed onto the table transmitter. The middle one becomes soft elastic migen excitation light source deformed by the coolant by 30 closing slits 4 and against the stimulation flow, in that the ends of the excitation light bare medium 2 and the excitation light source 3 ge source receiving wall parts of the housing presses. This way it becomes next to an elastic around the electrodes of the excitation light source storage of the stimulable medium and the excitation a tubular sheath are expanded. light source meet high requirements

In order to prevent the plastic parts from aging prematurely, the interior of the housing is sealed, namely the seals and the housing through which the cross-section of the openings in the rigid platintensive To use radiation from the excitation light source 5 and 6 is selected to be somewhat larger than it is the areas exposed to the radiation are the diameter of the excitation light source and the with a substantially opaque stimulable medium. This is covered Mistake. 40 ensures that the stimulable medium and the

Due to the inclination of the end faces of the rod-shaped source of excitation light only on the flexible ones

gene stimulable medium under the Brewster end plates 4 rest. The two inner star-

angle against the rod axis succeeds in simple ren plates 6 are to hold the excitation mirror

Way to direct the output beam so that it reaches gels I with a conical, annular elevation 6 '

the ends 45 reinforced by the connection caps.

the excitation light source and its power supply to prevent the material of the soft layers can be comfortably passed by. One of that kind of closing column4 in the immediate area tigc beam deflection is then in particular from in front of their openings for the passage of the excitation part, when the electrodes of the excitation light source are in the light source and possibly also of the stimulation module Cooling circuit included and with a 50 ren medium at an early stage due to the intense radiation tubular sheath are provided. the excitation light source is destroyed, the

On the basis of the exclusion plates shown in the drawing in the areas mentioned with a

Examples of management, the invention is not to be seen in the following from the figures, at least approximate-

will be explained in more detail. In the drawing, an opaque coating, for example

indicates 55 a metal layer, provided.

Fig. 1 is a section through a first embodiment in the second shown in Figs

example of the optical transmitter with air-cooled embodiment of the optical transmitter are also

Electrodes of the excitation light source, the electrodes 3 'of the excitation light source 3 in one

2 shows a section through a second embodiment, including a second cooling circuit. As in the in

rungsbeispid of the optical transmitter, in which also 60 F i g. 1 described embodiment are also

the electrodes of the excitation light source in a here the stimulable medium 2 and the excitation

Cooling circuit are included, light source 3 in flexible end plates 4

3 shows the side view of the second embodiment. These, in turn, are rigid between two

for example according to FIG. 2, plates 5 and 6 embedded. The outer rigid plates

Fig. 4 the cross-sectional view of the second 65 th 5 are in the area of the excitation light source 3 in

Embodiment according to FIG. 2, its extension to a tubular sheathing

F i g. 5 an arrangement of the optical transmitter with treatment 25 expanded. The end of the tubular umoptical Resonator cladding 25 is provided with a sealing ring 26

containing cuff 27 completed. The coolant in this circuit passes through the connecting piece 28 in the cavity 29 of the tubular casing 25 at the end of the electrode Excitation light source. In order not to obstruct the radiation from the stimulable medium 2, the Sheathing 25 partially brought up close to the excitation light source 3. The housing 7 Adjacent section of the casing 25 is therefore also designed to be rectangular. At this point is between the casing 25 and the excitation source 3 placed a piece of sheet metal 30 with good thermal conductivity, the ends of which are immersed in the coolant not to heat the plastic casing too much. The coolant then exits, as in F i g. 4 can be seen through two openings in the flexible end plate 4 and the inner rigid plate 6 in the interior of the housing 7 one. The position of these openings is shown in FIG. 4 in interrupted Line drawn. The coolant flows through openings in the end plates on the opposite side of the housing 7 further to the other electrode 3 'of the Excitation light source and occurs after it has passed the interior of the casing 25 from the other connecting piece 28 from. For cooling the stimulable medium 2 and that part of the excitation light source arranged in the excitation mirror 1 3 a second cooling circuit is provided. The excitation mirror 1 is for better cooling of the excitation light source 3 and the stimulable medium 2 with two opposite slit-shaped openings 31 provided, which extend over almost its entire length. So the whole Width of the slot-shaped openings 31 are uniformly flowed through by the coolant, are the two connecting pieces 28 for the second cooling circuit bearing housing walls across the width the openings 31 are provided with rows of holes 32 acting as flow resistances. The connecting pieces 28 are expanded in their part facing the housing to form a chamber 33 in such a way that that a whole row of holes is detected in each case. The in the F i g. 4 visible flow resistances 34 the tubular inner surface of the housing 7 serve to separate the two cooling circuits in the area of the housing.

F i g. 5 illustrates how the optical transmitter of FIG. 1 as an assembly on an optical Resonator containing further assembly is arranged in modular design. The slimable one

ίο Assembly containing medium 2 is in view of an easy exchange easily detachably attached to the base plate 12. The attachment can, for. B. can be achieved by screws or a simple plug-in connector. The one with the base plate Connected optical resonator consists of two mirrors, one of which is a multi-plate resonance reflector 8 and the other is designed as a 90 ° prism 9. The 90 'prism is for generation a pulsed output radiation around the

so axis 10 rotatably arranged. In the arrangement shown, the end faces of the stimulable medium 2 are inclined at the Brewster angle with respect to the rod axis. The multi-plate resonance reflector 8 and the <) 0 ^o prism 9 are therefore not directly in

as the rod axis of the stimulable medium, but arranged somewhat offset. The multi-plate resonance reflector 8 is partially transparent, so that a at the resonance position of the 90 ° prism 9 triggered light pulse by the multi-plate resonance reflector 8 is radiated through.

This constructive solution of an optical resonator provided with a quality-modulated optical resonator The transmitter can be used for many measurement purposes. It is precisely with such arrangements

It is extremely advantageous that all components that can be expected to have a short service life in one assembly are summarized. This inexpensive assembly, which is a replacement unit, is included in Failure of the excitation light source, for example

easily removed and replaced by another, which makes maintenance of the optical extremely easy Sender means in practice.

1 sheet of drawings

Claims (7)

ι 2 ^ medium under the Brewster angle against the claims: rod axis are arranged inclined. 1. Optical transmitter (laser) with a rod conveyor 5 migen stimulable medium and a parallel The invention relates to an optical rod-shaped excitation transmitter (laser) arranged next to it with a rod-shaped circulating light source, both of a medium parallel to them and a parallel next to them hollow cylindrical excitation mirror th rod-shaped excitation light source, both of are encompassed over its longitudinal extent, the io a hollow cylinder running parallel to them on the one hand is encompassed by a housing that see the excitation mirror over its longitudinal extent to the housing interior open connection pieces are included, which in turn by a housing Umür the connection to an external cooling circuit, which is open to the interior of the housing, whose coolant the remaining connection piece for connection to an external one The interior of the excitation mirror has completely 15 cooling circuit, the coolant of which fills the, characterized in that the remaining interior space of the excitation mirror is fully facing end walls (4 constantly fills to 6) of the housing (7) for / receiving the ends In this context, optical transmitters should also be understood to include the excitation light source (3) and the stimulation beam, the medium (2) of which, as flexible mounts, has an output radiation in the infrared or ultraviolet - (4) designed openings are provided which are in the lathe spectral range, i.e. not directly in relation to the sealing of the interior of the housing from the visible radiation,
mes serve to the outside, and that the excitation laser arrangements of this type are, for example, mirror (1) made of an internally mirrored metallic hollow cylinder with a hollow cylinder with a counter-light as seen through French patent specification 1 570 455. Depending on the width of the housing, its structural design complies with the smaller outer diameter, but certain applications, in particular for water, which are also not suitable for mobile use on its outer surface. That hits a coolant is flowing around it. on the one hand in terms of the most compact possible 2. Optical transmitter according to claim 1, characterized approximately shape and on the other hand in terms of a large characterized in that the hollow cylindrical stimulus is shock-resistant and easy to maintain transmission mirror (1) has an elliptical cross-section, therefore. In a compact embodiment, in particular large semiaxis insignificantly larger than those for high output powers, must be special outer diameter of the excitation light source (3) requirements are placed on the cooling system, or the stimulable medium (2). However, this cooling system should be as simple as possible 3. Optical transmitter according to claim 1, characterized in that it can be used in portable devices, that the hollow-cylidrian approach will come. transmission mirror (1) designed as a circular cylinder and the object of the invention is for with regard to the excitation light source (3) and the one optical transmitter another constructive 1.ö- stimulable medium (2) to be addressed as an exfocal circling, which at high energy of its general cylinder system is dimensioned. 40 common pulse-shaped output radiation with 4. Optical transmitter manages according to one of the previously smallest possible dimensions, and pending claims, characterized in that while ensuring the to such a Strahder Otherwise designed as an excitation mirror (1) in mobile use to provide a metallization source Hollow cylinder openings (24) for the properties to pass through. of the coolant and that in the space 45 This object is achieved according to the invention between the housing inner surface and the solved that in opposing front wall outer surface of the hollow cylinder flow resistances of the housing for receiving the ends of the spacings (23) arranged and designed in such a way for the return light source and the simulatable medium are that the excitation mirror (1) on all sides of the öff-Kuhlmittel designed as flexible mounts is flowed around. 50 openings are provided, which are also used for sealing 5. Optical transmitter serve one of the previous of the housing interior to the outside, and pending claims, characterized in that the excitation mirror consists of an internally verspiedie Electrodes (3 ') of the rod-shaped excitation apply metallic Hohlzvlinder with one against the light source (3) are flowed around by the coolant, in the clear width of the housing smaller outside through the which consists of the ends of the excitation light source, which is also on its outer surface from the taking wall parts of the housing (7) flows around coolant. the electrodes of the excitation light source around an optical transmitter with a hollow cylindrical to a tubular casing (25) widening the excitation mirror, in the interior of which the rod-conveying tert are. Medium stimulable medium and the rod-shaped 6. Optical transmitter after one of the previous 60 excitation light sources parallel to one another and in parallel pending claims, characterized in that it is arranged on the wall of the excitation mirror which are the radiation of the excitation light source (3) can be with very small dimensions, in the exposed surfaces of the plastic parts are only a few centimeters in size Apply an opaque coating. The evidence surrounding the excitation mirror. 65 at home can be easily 7. Manufacture the optical transmitter according to one of the above, for example from plastic. Through pending claims, characterized in that this constructive solution is a possibility End faces of the rod-shaped stimulable ben, an optical transmitter to manufacture very cheap.