DE1814581C3 - Optical transmitter with a gaseous stimulable medium - Google Patents

Description

dhn body in ^ ⁿ f ™ ^ht ™ f X ^{orestandn and}

SWEET. ώΰαΑ «, V

their firm support on three each perpendicular to the thin ^ f

optical axis ground cams (B, C, D) symmetrically over ^de ° ^^. ^^^ "ij _cemäß secured, which at each end of the discharge starting from a S and the Tecnn.K according to Fohres (21) in the longitudinal direction protrude and of the type mentioned, the invention is de symmetrically distributed over the edge that the i _S task is based on a ⁰ P ^ n transmitter to cha two hollow cylindrical electrodes (25) in fen, its production and first adjustment of the Pa symmetrical arrangement the inner wall of the allelicity of the ^ reflector surfaces_ simplified ^ st and be, discharge tube (21) rest and a longitudinal which have this parallelism even when heated in the protector and that a water cooling jacket ensures that st. With the simplicity of the crfin- (23) is symmetrical around the discharge tube ». The transmitter according to the invention should also extend a small distance (21) to the electrode area. weight can be achieved

2. Optical transmitter according to claim 1, characterized in that the object is characterized according to the invention dadu d that the discharge tube (41) solves that the parallelism of the resonator mirror by Airy points (al, al) is attached or rests. their firm support on each of three ^{cams ground perpendicular to the opt, - 3 b} a ₅ see axis is secured, the

at each end of the discharge tube in the longitudinal direction

tion protrude and symmetrically over the edge

are distributed so that the two hollow cylindrical electrodes in a symmetrical arrangement on the inner

The invention relates to an optical so that the wall of the discharge tube rest and a transmitter with a gaseous, stimulable medium, in a longitudinal slot and that a water-filled discharge tube, both the concentric / ur jacket symmetrically around the discharge tube up to the optical axis, arranged hollow cylindrical to the electrode area extends the parallelism Electrodes as well as the plane-parallel resonator are set once and for all, namely by built-in mirrors. 35 the known length adjustment in the form, there are such optical transmitters or lasers that the height of the three cams of each pipe end knows (British patent specification 1013 725), in which by grinding to exactly the same amount work on the parallel resonator mirror has been joined. This avoids the difficult turning of the ends of the discharge tube by means of an angle adjustment. The netallenen in vcrnaltnis- (bellows are connected. In order to maintain the standard mirror * ° simple manner and with few and cinfla'chen with the greatest possible precision parallel, multiple components performed Parallclitatseinstcl- (nuts this necessary additional measures, requires no development spateren readjustment The frame parts attacking from the outside, provided allelity is in the optical line according to the invention, which hold the reflector mirror. Transmitter (laser) of course not according to ju the discharge tube, a readjustment might be desirable, as is known from a device (German Palentschrift it for instance when higher or uneven dimensions occur) However, there is no coaxial cone . Avoidance By twisting the different cones with the help of such a parallelism distortion through Ί enipe-Von flanges, the end face of the innermost temperature can serve the well-known (FR-Pi! Cone, which is covered with the reflector, within 14 87 672) water cooling of the pipe with certain limits, any solid angle gives symmetrical water cooling jackets and which are per se. The construction with several intertwined (Proc. IFEE, 54 [1966], 4, pp. 547 to 5.Si; matching, mutually rotatable, but gas-tight 55 symmetrical arrangement of the electrodes. Since the cones or electrodes held in the longitudinal direction have a longitudinal slot and on the hollow cones, however, a complex and expensive inner wall of the discharge tube rests, whereby they represent construction, which are also stretchable due to their in the circumferential direction, there is a good increased weight for various applications B. Space research, less heat-generating electrodes are in this case. The well-known parallel adjustment allows the water cooling jacket to be arranged, and it also requires constant readjustment, since temperature distortion of the pipe dimensions is not to be expected at first. that a change has been set. To maintain the Parallclita Parall Elity of the reflector surfaces unchanged bc- the resonator mirror even in the event that the Ent remains. 85 charge tube due to its weight, as it is generally also known (F. Kohl rau sch, very long tubes, sagging "Practical Physics", Vol. 1, 1960, p. 324), is a plane expediently a support of the discharge surface, to be fixed by three Aufstützpunktc md tube at Airy point: n provided. Here handcl

it is from Sir George Biddel Airy (1801 to 1892) determined support points for a rod at points that would allow the parallelism of the end surfaces drown the bar despite its sagging, as is known in physics.

The invention thus creates an optical transmitter (laser) of the non-adjustable type, which however, for special operating conditions or training, it is designed so that readjustment is possible

Further details, advantages and features of the invention will become apparent from the following description. In the drawing, the invention is illustrated by way of example, namely shows

F i g. 1 is a schematic representation of the entire car an optical transmitter according to the invention,

2a shows a perspective view of an end part of a discharge tube according to the invention, tube 1 is placed on the resonator mirror 2, as shown in FIG. 3 a shown, and on its scope connected to it by means of an adhesive 4, such as Fit. 3b shows.

Each of the cams B, C and D is ground so that when the resonator mirror unit according to FIG. 3b is attached to the discharge tube 1, the mirror Z _{1 is} perpendicular to the optical axis of an autocolli-

. . _a mators 5 is arranged, which with the axis of the Ent-

also is not required. For that are. Manufacture of the charge tube 1 is aligned with the mirror 2 and using this laser very easily. an adhesive 6 attached to the discharge tube 1.

A mirror 2 _O is attached to the discharge tube 1 in the same way. It is better to align mirror L ₁ with respect to mirror I ₁ than with respect to the autocollimator, since a higher degree of accuracy is achieved in this way. This way of fixing the mirrors is related to the fact that while the fine angle adjustment is extremely difficult, the length adjustment is to the same degree

2b shows a view of the end face which can be carried out relatively easily in terms of accuracy. F i g. 2 a tube shown, thus the parallelism of the reflectors is through

F i g. 3 a is a perspective view of one in the arrangement of the three adjustment projection cams Tube according to FIGS. 2a and 2b to be installed Reso- slightly improved.

natorpiegel, bei f _{est m} j _t ^ _em R ₀ J ₁₁ . connected resonator

Fig. 3b is a side view of the mirror with an adhesive 25 can result in the difficulty that means provided resonator mirror according to Fig. 3a, if the temperature of the ^ tube wall is unequal 4 shows a schematic representation of the optical setting of the resonator mirrors see adjustment of the parallelism of the resonator- bending of the pipe changed. For example mirror, carries the deviation from parallelism with one

5 shows a view of the quartz tube with a diameter of 20 mm and a length of 20 mm attached to the discharge tube 30 according to Fig. 2a and 2b attached resonator picgcls 52 seconds at a temperature difference of

10 ⁰ C on both sides. The deviation for a tube made of tempered glass of the same size is as much as 6 minutes. As a result, it is desirable that a discharge tube be constructed so that the temperature increases axially uniformly.

6 shows a discharge tube 21 in which CO ₂ gas is enclosed and which is provided at its end with a Rcsonalorspicgel 22, further with a discharge electrode 25 and a cooling jacket 23. The discharge electrode 25 consists of a thin metal tube which is bent to form a slotted cylinder and which clings to the inner surface of the discharge tube. The gap of the

appropriate optical transmitter or a laser tube. 45 electrode is used to absorb the thermal expansion Discharge tube is a double tube made of quartz to protect the electrode from damage to protect.

With known gas laser tubes it is not necessary

_t agile, especially when it comes to cooling the resonator

created for attaching the resonator picgel. 5 ° mirror to watch out for, as these mostly come from the discharge tube The optical transmitter of Fig. 1 has reflectors which are separate. With an optical transmitter where

the discharge tube and the resonator mirror form a unitary whole, but the temperature can the mirror can be very high, which may lead to impermissible stresses in the mirror or in the Pipe leads and the adhesive can decompose. Therefore, the resonator picgel is directly mixed with water chilled.

The F i g. 7 and 8 show one type of cooling

Charge tube 1 are ground so that they protrude 60 the mirror. A Kühlgcfüßmantcl 33 around a detent cams B, ('and D , as Fig. 2a shows a Kulungsrolir 31 shows at its two ends. It is sufficient if the cams / ?, C and /) about
1 mm high.

3a and 3b show the training a

according to Fig. 3b,

6 is a sectional view showing the cooling means and the arrangement of an electrode an optical transmitter,

F i g. 7 shows a longitudinal section through an optical transmitter with cooled resonator tubes,

F1 g. 8 partially torn open and "in section a View of the front face of the transmitter according to FIG. 7 and

9 shows a schematic representation of a type of holder for the discharge tube of an optical transmitter.

Fig. 1 shows the overall structure of an invention

or glass with a cooling jacket. By sanding the two faces at the ends of the inner one Pipe perpendicular to the pipe axis is the support

Ai ₁ and M. “furthermore cams S for adjusting the parallelism of the reflectors, an adhesive / 1, a fusible link / · ', electrodes E, an outlet end V and cooling water W.

Dit I ⁷ Ig. 2a to 5 show details of the structure of a resonator mirror attached to the discharge tube.

The two faces at the ends of a de-face many holes 33 ″ through which water can flow. Each end face of the jacket 33 is furthermore with a tubular cooling cap 33 'over-

Resonator mirror. A Fülmmgsrahmcn 3. the something 65 catch. The cap on the exit side shows a

is higher than the cams H, C and /) and its diameter is elw i ¹ . is smaller; ils that of a resonator mirror? .. but larger than that of the discharge microhole 34. The cooling caps 33 'are designed to cool the mirrors 32 tin. Cooling water is, for example, from below into the cooling cap

33 'initiated on the exit side. The water flows from there through the holes 33 ″ in the jacket 33 into, out of this through the holes 33 ″ on the opposite side into the other cooling cap 33 'and is finally pulled from above from this cap 33'. This is how the resonator mirrors are 32 immediately cooled with water.

Even if the optical transmitter has been precisely adjusted during its manufacture, the setting can change due to the weight of the tubes, especially in the case of a long discharge tube. For this reason it is particularly expedient, for example in a device to be built into a VVeI trustworthy body, to minimize the changes that occur due to the weight of the laser tube and its inertia during the high acceleration. A discharge pipe 41 is therefore held by supports 44 and 45 on the Airy Punktcn ", and a", as shown in FIG. 9 shows. In this case, reflectors 42 and 43 attached to the opposite ends of the discharge tube 41 retain their parallelism despite the deformation of the tube.

For this purpose 3 sheets of drawings

Claims (1)

also the mutual position of two planes through ... a body that has a three-point support on both sides: a ^ ^ application of this 1. Optical transmitter with gas ormigem stimulating ^ Ρ ^^ _ΜΓ known (»Fine device technology, medium in its discharge tube both 5 PerotJnte rterome ^ i _the ^ the concentric to the optical axis arranged-} * "O ^ iz, ay _one Neten hollow cylindrical electrodes as well as the lall eoenen sf _b f _Au fl _aEe a ' iHl Ri> ibt smd ^ S Γ Ä i ^ Neten hollow cylindrical electrodes and the LALLS eoenen sf _b f _Au fl _AEE on ieweils'drei pi.nparaHel.n R _e so »a,„, spi _eg e> built in smd, ^ S. ζΓ »pÄ ih ^ Spo! ^