BE620659A - - Google Patents

Description

       

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    New optical elements and process for the manufacture of these elements.



   The present invention relates to novel optical elements, as well as to a process for the manufacture of these elements.



   Belgian patents 600,978 and 600,979, applied for March 6, 1961 in the name of the applicant, have described a process for manufacturing optical elements in magnesium fluoride and zinc sulphide. This process consists in molding a powder of zinc sulphide or of magnesium fluoride, in an inert atmosphere under a high molding pressure and at high temperature, which makes it possible to obtain homogeneous solid bodies, with a density of at least 99 / 100 of the theoretical density.

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   It has been found, according to the present invention, that it is possible, by an appropriate modification of the molding conditions, to apply the process to the molding of other mineral compounds in order to obtain new optical elements capable of numerous applications.



   The new optical elements according to the invention are eor.jtitués by a homogeneous and transparent polycrystalline solid body of a binary compound chosen from calcium fluorides, lanthanum and strontium, cadmium sulphide, magnesium oxide and binary zinc compounds, such as zinc selenide and zinc oxide.



   In the accompanying drawing, given only by way of example, FIG. 1 is a view of a polycrystalline solid obtained by molding according to the invention of a powder of calcium fluoride, of strontium or of lanthanum, of sodium sulphide. cadmium, magnesium oxide or a binary zinc compound, such as zinc selenide and zinc oxide; - Fig. 2 is an elevation, in partial section, of a molding device usable for carrying out the molding process according to the invention; - Fig. 3 is an elevational view, partially in section, of another device for molding optical parts from polycrystalline inorganic compounds, using high frequency heating; - Fig. 4 is an elevation in partial section of part of the molding device shown in FIG. 3;

   modified to be more particularly suitable for molding calcium fluoride; - Fig. 5 is a representative graph of the specular transmittance of a polycrystalline calcium fluoride according to the invention, for a thickness of 0.56 cm; - Fig. 6 is a representative graph of the trans-

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 Specular mittance of the polycrystalline calcium fluoride according to the invention, at 3, for various temperatures, the optical element having a thickness of 1 mm; - Fig. 7 is a representative graph of the values of the partial coefficient Pg-F as a function of the values V for various substances used in optics and for the fluoride of
 EMI3.1
 polycrystalline calcium according to the invention;

   - Fig. 9 is a representative graph of the specular infrared transmittance of a polycrystalline lanthanum fluoride element according to the invention, 0.5 mm thick; - Fig. 9 is a representative graph of the specular transmittance of a magnesium oxide element according to the invention 1.2 mm thick; - Fig. 10 is a representative graphic of trance
 EMI3.2
 Specular mittance in the infrared of a polycrystalline zinc light according to the invention. Fig. 11 is a representative graph of the specular mittance in the visible and in the infrared of a.
 EMI3.3
 another sample of polycrystalline zinc selenide according to the invention, 1 mm thick.
 EMI3.4
 



  The molding apparatus is generally; 1dent1 .. than that described in the aforementioned Belgian patents. As shown in Fig. 2, it comprises a base 16, a JÓint 23 in silicone resin, a block 9, a heat insulator 15, a block
 EMI3.5
 13, a molding cylinder i, a die-molding plunger II, the head 8 of which is connected to a driving member, not shown, such as the piston of a hydraulic press so that the plunger 17 is moved vertically in the cylinder of molding 12 to compress the powder and transform it into a sclid body 10.

   For the molding of certain powders such as calcium fluoride or zinc selenide, it is advantageous to have

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 ser, at the bottom of the cavity of the molding cylinder 12, a molding block which forms the base of the molding cylinder and completely closes this base and which is optionally rigidly fixed to this cylinder by screwing, the lower part of the wall internal cylinder then being tapped for this purpose.



   The head 8 is read back to a centering ring 18 by a metal bellows 20 which forms a vacuum-tight seal around the upper part of the plunger 17. A cylinder 21 surrounds the molding cylinder 12 and the plunger 17 and rests on a block. 7.



   A heating device 14 comprising a refractory wall is arranged around the cylinder 21 to also rest on the block 7 and contains electric heating coils 11, the terminals of which are shown at 27. A cylinder 29 is arranged concentrically with the cylinder 21, outside thereof, and delimits a vacuum chamber 30, the ends of which are closed by the joints 23 and 26, by the base 16 and by a plate 19. Cooling coils 25 are placed in contact with the wall cylinder 29 and plate 19.



   A pipe 24 places the vacuum chamber 30 in communication with a vacuum pump system, not shown. The base 16, the plate
19 and the threaded rod 22 hold the assembly.



   The temperature is measured by one or two thermocouples 28 and 31 which are arranged in suitable wells, in the vicinity of the molding site. Blocks 9 and 13 and cylinder 12 are for molding calcium fluoride and l. Molybdenum magnesium oxide, molybene alloy or any other suitable material having high resistance to high temperatures.

   In the case of strontium fluoride casting, these parts are made of an alloy of molybdenum and titanium; in the case of the casting of lanthanum fluoride or cadmium sulphide, these parts, as well as the plunger 17, are

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 in molybdenum, in a molybdenum alloy, in nichrome or in stainless steel; in the case of the molding of zine selenide, the block 13 and the cylinder 12 are advantageously made of molybdenum or of a molybdenum alloy, as well as the screw block which forms the base of the molding cylinder, while the block 9 is in ni; . chrome or stainless steel;

   in the case of zinc oxide casting block 9 and cylinder 12 are made of molybdenum or molybdenum alloy, steel and chromium alloy, or stainless steel, while block 13 and plunger 17 are of a molybdenum alloy or a superalloy. In the case of the rolling of the magnesium oxide, the substances which can be used to constitute the plunger 17 can be the same as for the blocks 9 and 13 and the cylinder 12. In all cases, these parts must, of course, be be inert with respect to the compound to be molded.

   In addition, for the molding of calcium fluoride, as already indicated, the base of the molding cylinder is closed with a block and this block is advantageously made of molybdenum, an alloy of molybdenum, graphite, d high density alumina, stainless steel or high strength nickel alloy.



   Another embodiment of the molding apparatus which can be used for the manufacture of the new optical elements according to the invention is shown in FIG. 3. In this apparatus, high frequency heating is used.



   The molding compound powder is shown at 41.



  The apparatus comprises a molding cylinder 42, optionally closed at its base by a molding block 70 which rests on the block 43 (this molding block being advantageously used for molding calcium fluoride or zinc selenide), a insulator 44 and support blocks 45 and 46. Block 46 rests on a base 47. A graphite sleeve 60 is disposed between the induction heating coils 63 and the

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 parts 42 and 43. Also placed on the base 47 ze finds a cylindrical water chamber 62 through which a vacuum pipe 64, a vacuum breaker pipe 65 and a thermocouple shell 69 passes.

   Lines 68 communicate pulpit 62 and cooling grooves 56 with a source of water supply not shown. The thermocouple is represented at 66. A quartz cylinder 61 is mounted between the chamber 62 and the plate 57 from which it is isolated by seals 67. The cylinder 61 and the chamber 62 thus define a vacuum chamber 69 closed to the upper part by the plate 57 in which the cooling grooves 56 are formed. A seal 55 closes the upper part of the grooves 56 and is held in clamping position 59. Rods 58 associated with wing nuts make it possible to hold the assembly. in assembly position.



   The plunger 48 passes through an opening in the plate 57.



  A metal bellows 53 provides the necessary freedom of movement for the diver, while maintaining the vacuum seal. The ends of the bellows are fixed respectively on the head 54 of the plunger 48 and on the plate 57.



   The plunger 48 comprises a section 49 made, preferably in nichrome or stainless steel, a section 50 in nichrome and a section 52 in molybdenum or a molybdenum alloy * A heat insulating disc 51 is disposed between the sections 49 and 50 and between sections 50 and 52. The various sections of the plunger are secured by threaded rods.



   The plate 57, the clamping plate 59 and the base 47 can be made of aluminum. The molding cylinder 42 and the block 43 are preferably made of molybdenum or a molybdenum alloy, the support block 45 of nichrome and the support block 46 of nichrome or stainless steel. Insulators 44 and 51 must withstand the high temperatures and pressure of the molding.

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   Since molybdenum couples poorly in the high frequency field, the graphite sleeve 60 is fitted on the molding cylinder. The high frequency field heats up the graphite which in turn raises the temperature of said molding cylinder by heat conduction. In the event that it is desirable not to use a graphite sleeve such as sleeve 60, the plunger section 52, cylinder 42 and block 43 should be made up of substances which effectively couple in the field to. high frequency, for example by nickel alloys for high temperatures.



   The use of induction heating has, among other things, the advantage of allowing more conveniently than resistance heating the use of inert atmospheres.



   The operation of these devices will be described with first reference to the implementation of the molding process according to the invention for the transformation of a beam of calcium fluoride into an optical element consisting of a homogeneous solid and transparent polycrystalline.



   When using the apparatus shown in FIG. 2, calcium fluoride powder is introduced into the molding cylinder 12, under the plunger 17, so that this powder is carried by the block, not shown, which ends at the base of this cylinder, and the the apparatus is mounted as shown in Fig. 2. The calcium fluoride is first cold compressed.



  The plunger 17 - maintains for a few minutes, on the calcium fluoride powder, a pressure of 1380 to 2070 tara to transform the powder into a firm agglomerate. The plunger is then removed and any excess powder or powder which is not integral with the agglomerate is removed. This cold compression operation serves to force a united load and also allows the mass which has undergone this prior compression to heat up more easily because the heat is thus transmitted more easily.

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 effectively.



   However, satisfactory calcium fluoride moldings can be manufactured without performing the preliminary cold pressing operation described above and using only hot molding as shown below.



   The molding apparatus is mounted again as shown in FIG. 2 and placed in communication with a suitable vacuum source not shown through the conduit, 24. A vacuum is created in the chamber 30 so that the pressure is reduced to a value between 0.4 mm and
1 x 10-5 mm of mercury. Cooling water is passed through coils 25 and resistors 11 are heated.



   The temperature of the mold is monitored by the platinum-rhodium thermocouples 28 and 31. When the temperature reaches about
815 ° C (thermocouple 31), the plunger 17 is lowered by a hydraulic press, not shown, so that the pressure on the powder reaches, in about one minute, a pressure of 276p bars. The pressure on the calcium fluoride is maintained at this value for 15 minutes to 20 minutes at the same time as the temperature is maintained at about 815 C.



   Because the temperature is measured by a thermocouple, the temperature indicated as giving the best results in this example, as well as in the other examples given below, is only accurate to # 10%. near. During the heating period, the gases contained in the device escape and the pressure increases to about 0.5 mm, but this pressure drops to a level down to 0.2 mm because the gases released are trained outside.



   At the end of the compression period, the electric heating is stopped, the pressure is gradually removed over a period varying from a few seconds to several minutes and the device is allowed to return to room temperature, that is to say. say about 21 C.

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   It is then possible to remove from the molding device the piece of calcium fluoride which consists of a transparent polycrystalline solid, the density of which reaches 99/100 of the theoretical density.



   The apparatus of FIG. 3 operates substantially under the conditions of temperature, molding pressure and pressure which have been described in connection with the apparatus of FIG. 2, but the molding temperature heating time is reduced due to the use of a high frequency field for heating.



   The molding conditions indicated above make it possible to obtain calcium fluoride optical elements which exhibit the optimum characteristics. However, satisfactory optical elements can be obtained by using for molding calcium fluoride a temperature of from about 760 C to 925 C. If one is used, within the molding time and pressure applications given above. above, a temperature below 760 C, the transmission of calcium fluoride for short wavelengths may be lowered. By increasing the time of compression and the molding pressure, or just one of these factors, satisfactory optical elements can still be obtained at a temperature below 760 C.

   It does not appear that using a temperature above about 815 * C will help to improve the quality of the molded element.



   The pressures used for calcium fluoride are between 2070 bars and 3450 bars. In the conditions! for the duration and temperature indicated above, if an internal pressure of 2070 bars is used, it may happen that the optical element is not completely compressed to the state of a homogeneous mass. The use of a pressure greater than 2760 bars does not significantly contribute to improving the quality of the optical element. The residence time at the temperature can be varied.

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 compression swears between 5 minutes and 45 minutes. For a period of less than 5 minutes, it may happen that the optical element is not completely compressed.

   On the other hand, the use of a compression time greater than 15 minutes does not appear to contribute to improving the quality of the optical element. However, as already indicated, if the compression is prolonged, the hot molding can be carried out at a lower temperature and at a lower pressure.



   In the case of the molding of calcium fluoride according to the process of the invention, the molded element may flake off at the edges or show cracks. These defects may be due to the fact that a thin layer of calcium fluoride builds up, during hot molding, in the small space between the plunger 52 and the inner wall of the molding cylinder 42, as well as between the block which closes the base of the molding cylinder and the inner wall of the latter.



   There is shown in FIG. 4 a device which avoids these defects when molding calcium fluoride. It has, in fact, been observed that, if the plunger and the part which close the base of the molding chamber 42 are made of a substance whose coefficient of expansion is smaller than that of calcium fluoride, the fluoride layer Calcium responsible for the indicated defects is detached from the molded element during the cooling following molding, thus forming fragments at the periphery of the optical element. These chips can then determine the appearance of cracks which penetrate inside the element.

   According to the invention, these defects are avoided by introducing into the molding chamber two blocks 74 and 75 (Fig. 4), the nature and dimensions of which are chosen such that, under the temperature and pressure conditions used for the molding. molding, the diameter of these blocks is strictly equal to the internal diameter of the molding cylinder 42.

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   Under these conditions, the flow of calcium fluoride between these blocks and the molding cylinder is extremely reduced so that the splinters and cracks are considerably reduced. To obtain this result, two means are possible. One of these means is to use as the blocks 74 and 75 a substance which undergoes a small deformation under the conditions of the hot molding. These blocks are given a diameter slightly less than the internal diameter of the molding cylinder to facilitate their introduction into the latter.

   When the mold reaches the temperature of the hot molding and under the conditions of mechanical pressure indicated the vertical force exerted by the plunger on the blocks 74 and
75 determines an increase in the diameter thereof until the diameter is equal to the internal diameter of the cylinder of the molding. The second means consists in constituting the blocks of a substance whose coefficient of expansion is greater than that of the molding cylinder.

   Since the diameter of. blocks then grow faster than the cavity of the molding cylinder, these blocks can be given an initial diameter allowing them to be easily introduced into the cylinder at ambient temperature while at the temperature used for hot molding these blocks blocks completely fill the space entered themselves and the walls of the cylinder. Whichever of these two means is used, the graphiting of the internal wall of the molding cylinder facilitates the translation of the upper block
75. Certain substances used to constitute these blocks can weld to calcium fluoride or to neighboring parts of the mold; it suffices then to graahiter the entire block to avoid this drawback.

   Examples of a substance which can be satisfactorily used to form the blocks 74 and 75 are high density graphite and alumina, stainless steel and several high strength nickel-chromium alloys.

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   The type of calcium fluoride used imposes certain limitations on the hot molding operation. Satisfactory windows are obtained% from crystalline fragments whose average size is between a value less than 10 microns and several millimeters. Windows of acceptable quality are also obtained when using a calcium fluoride powder prepared in the laboratory from chemicals having the purity of reagents for analysis. Satisfactory windows can also be molded from commercial calcium fluoride having reagent grade for analysis after appropriate processing.

   Although fragments of synthetic calcium fluoride crystals can be hot cast directly to form a polycrystalline solid, chunks of natural crystalline calcium fluoride containing substantial amounts can also be used for virtually any application. of impurities. These crystals are reduced to powder to allow the removal of impurities constituting a separate phase, for example by washing with an acid, and the powder obtained is hot molded. The opti * conditions. The males of the molding depend somewhat on the quality of the starting material.



   Plano-convex moldings can be obtained by hot pressing calcium fluoride powder in a concave mold using a planar plunger, in the apparatus and according to the method described. Regarding Fig. 2, under the same temperature and pressure conditions. The calcium fluoride part which is thus obtained is resistant and has all the properties described above. It can be smoothed and polished to form a lens, cap, or other similar optical element.

   From marl, we can form concave menisci. convex that can be used as windows for remote-controlled projectiles or other special devices. If we use

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 molds with aspherical polished surfaces, aspherical optical elements can be obtained economically.



     The calcium fluoride elements obtained can be shaped by hot molding For example, at the base of said cylinder of the molding apparatus, the cylinder having a diameter of 5 mm, a cylindrical disc of calcium fluoride obtained by hot molding according to 'invention and have a diameter of 28.40 mm + 0.25 mm and a thickness of 7.62 mm after training.



   On both sides of the sample, a sheet of molybdenum 6.125-0.250 mm thick covered with graphite is placed.



   Under a pressure of approximately 1.035 bar, the disc is heated to a temperature of approximately 900 C, a temperature which is maintained for 10 min - 15 min. At the end of this period, the pressure is applied very carefully and slowly by adjusting needle valves until the height of the pressure gauge has a calculated change in advancing when this change is obtained the pressure on the sample is about 345 bar. These conditions are maintained for 15 minutes to 20 minutes.



   The sample is then allowed to cool slowly to about 732 C, then the heating is turned off. Argon is introduced and the apparatus is allowed to cool to about 205 ° C. before extraction. The samples then have a diameter of approximately 31.75 mm and a thickness of approximately 5.72 mm. The diameter of the sample therefore varied by 3.35 mm. These samples show normal stress patterns which can be removed by annealing.



   Hot-cast calcium fluoride is capable of good optical polish. It has the clarity of water and exhibits a high transmittance between 0.25 and 9, as shown by the graph in Fig. 5, where the abscissas represent the wavelength in microns and the ordinates the specific transmittance for a sample of 5.6 mm thickness * Interferometric tests show that the elements are optically homogeneous. Refractive index measurements indicate a

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 very good agreement between the values thus measured and those published for a crystal of calcium fluoride.

   Because the molded elements according to the invention exhibit improved mechanical stability during grinding and polishing, it is assumed that the mechanical strength of hot-molded calcium fluoride is significantly greater than that of hot-molded calcium fluoride. a single crystal of calcium fluoride.



   When removed from the mold, after the molding cycle described above, the molded parts show significant stress figures when viewed with a conventional type polariscope. These stresses can be removed by annealing in the oven. It is also possible to eliminate it by modifying the cooling phase of the molding cycle so that this phase reproduces the conditions of an annealing in the oven. A suitable annealing cycle is given below for a specific example. The sample obtained by molding according to the invention and which has a thickness of 7.62 mm and a diameter of 28.58 mm is introduced into an oven, heated to approximately 815 ° C., maintained at this temperature for approximately 20 minutes, then cooled to at about 52 C per hour.

   The samples thus annealed no longer show any stress detectable with a conventional polariscope.



   Corrections to the annealing can be made to the degree of annealing desired. For example, if cooling at a rate of about 205 ° C per hour, the level of stress after annealing is barely detectable with a polariscope. The best annealing cycle also depends on the size of the sample. To avoid surface oxidation, annealing is often necessary in an inert atmosphere or in a vacuum.



   The specular transmittance of polycrystalline calcium fluoride is shown in Fig. 5. FIG. 6 indicates the variation of the specular transmittance at 3 for polycrystalline calcium fluoride as a function of the hold time at

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 various temperatures. The abscissas represent the time in minutes.



   The exceptionally small coefficient of dispersion (V = 95) of polycrystalline calcium fluoride makes this substance particularly valuable for the construction of lenses. Another interesting characteristic of the calcium fluoride elements according to the invention is the relation between the partial dispersion coefficient Pg-F and the dispersion coefficient V The partial dispersion coefficient Pg-F is defined by the / relation
 EMI15.1
 n9 - ny Pg-F = ###### nu - ni and the coefficient V is defined by the relation
 EMI15.2
 nD - 1 1) = #### np-np In these relations, ng is the refractive index for 4359 A, nF is the refractive index for 4861 A. nC is 1-'refractive index for 6563 A and nD is the refractive index for 5893 A.

   As shown by the variation curve of the partial dispersion coefficient Pg-F as a function of the dispersion coefficient @ reproduced in FIG. 7, most of the known optical glasses are located very close to the drawn line. Opticians are looking for substances that can be used in optics - which deviate from this straight line, but which nevertheless have the same partial dispersion coefficient Pg-F as known optical glasses.

   Fig. 7 shows that the hot-molded polycrystalline calcium fluoride according to the invention, the representative point of which is located! in the vicinity of the horizontal line of ordinate 0.540 (540 below this line and to see the sinage of the axis of the ordinate has approximately the same coefficient

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 of partial dispersion Pg-F than ordinary glasses designated by the symbols BSC 1, BSC 2, C-11, DBC-6, DBC-16, but a coefficient of dispersion @ significantly greater.

   It has long been known that calcium fluoride exhibits exceptional optical qualities, but until now the mediocrity of its mechanical properties have prohibited its use in optics.



  Calcium fluoride crystals easily cleave and are therefore very prone to shattering. Although no quantitative measurements have been made on hot-cast calcium fluoride, the ocean resistance of this product appears to be greater than that of monocrystalline calcium fluoride. For example, it easily undergoes grinding and polishing operations without damage.

   It is not yet clear why the hot molded polycrystalline calcium fluoride exhibits better mechanical properties, but it may be that this improvement is due to the fine polycrystalline structure and the resistance to deformation and stress that it has. small crystallites acquire during hot molding.



   Hot-cast polyucrystalline calcium fluoride exhibits good stability and resistance to oxidation at elevated temperatures. After exposure of samples to air at temperatures up to about 815 ° C for prolonged periods of time, it is found that the infrared transmission has not changed or has suffered only a very small decrease.



   Polycrystalline calcium fluoride is quite insoluble in water and therefore performs satisfactorily in moisture resistance tests. The sample exhibiting the greatest heat resistance which has hitherto been produced according to the invention is resistant to the thermal shock resulting from the sudden immersion in water at 25 ° C. of a sample brought to temperature. temperature of 200 C.

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   The density of calcium fluoride and of * other elements according to the invention described below is measured by the hydrostatic weighing method indicated on page 104 of chapter III of the work de'A. Weissberger, Physical Methods of Organic Chemistry, Vol. 1, published by Interscience Publishers Inc., New York, N.Y. United States of America (1945). Deviations from the theoretical density indicate the presence of second phase inclusions in the molded part, due to impurities or porosity.



   The manufacture of new homogeneous polycrystalline optical elements in lanthanum or strontium fluoride, in cadmium sulphide, in magnesium oxide, in zine selenide, or in zinc oxide, is generally carried out in the manner which has been described. described for calcium fluoride. However, the hot molding is carried out directly, without going through the cold molding phase which has been described in the case of calcium fluoride.



   In all cases, it is also possible to use the apparatus of FIG. 2 that the apparatus of FIG. 3.



   Table 1 indicates the specific conditions to be used for each of the aforementioned compounds. Column A indicates the optimum temperature in degrees Celsius read with thermocouple 28 or 31 (according to the indication in brackets) at which the temperature of the mold is raised after establishing a vacuum, column? the optimum molding pressure in bars, column C the duration in minutes of maintaining these molding temperature and pressure conditions, column D the temperature at which the mold is allowed to cool before removing the plunger, column E the range of temperatures that can be used for molding, column F the range of pressures that can be used for molding.

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  TABLE 1
 EMI18.1
 
<tb> Powder <SEP> A <SEP> B <SEP> C <SEP> D <SEP> E <SEP> F
<tb>
<tb> Fluoride <SEP> da <SEP> lanthanum <SEP> 8500 <SEP> (28) <SEP> 2760 <SEP> 20-30 <SEP> 2000 <SEP> 825 -875 <SEP> 2480-3100
<tb>
<tb> <SEP> strontium <SEP> fluoride <SEP> 8600 <SEP> (28) <SEP> 2760 <SEP> # <SEP> 20 <SEP> 3000 <SEP> 800 -900 <SEP> 1725-3450
<tb>
<tb> Cadmium <SEP> <SEP> <SEP> 530 <SEP> (28) <SEP> 2760 <SEP> 10-40 <SEP> 200 <SEP> 510 -800 <SEP> 690-3800
<tb>
<tb> Magnesium <SEP> <SEP> <SEP> 8600 <SEP> (28) <SEP> 4140 <SEP> 20 <SEP> 2000 <SEP> 800 -860 <SEP> 2760-4485
<tb>
<tb> Selenide <SEP> of <SEP> zinc <SEP> 980 <SEP> (31) <SEP> 2070 <SEP> 15-30 <SEP> 200 <SEP> 845 -1095 <SEP> 690-3450
<tb>
<tb> Zinc <SEP> <SEP> <SEP> <SEP> 700 <SEP> (28)

   <SEP> 3100 <SEP> 10-40 <SEP> 3000 <SEP> 600 -750 <SEP> 2070-3100
<tb>
 
If a pressure lower than the lower limit indicated in column F is used, it may happen that the optical eludent is not completely compressed to a state of homogeneous mass, while a pressure higher than the optimum pressure (column B). or the upper limit indicated in column F does not appear to contribute significantly to improving the quality of the optical element or window according to the invention.



   Of course, the materials constituting the apparatus must be chosen as indicated and taking into account, moreover, that the plunger, the molding cylinder and the block 13 must not only be resistant to high temperatures. , but also be inert with respect to the molding powder. In the case of lanthanum fluoride, strontium fluoride, magnesium oxide and zinc oxide, the plunger, the molding cylinder and the block 13 can be made from an alloy of molybdenum and titanium. . In the case of cadmium sulphide, an alloy of molybdenum and titanium, an appropriate superalloy or certain steels or nickel alloys for high temperatures can be used for these same parts.

   In the

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 case of zinc selenide, an alloy of molybdenum and titanium or an alloy of molybdenum, titanium and zirconium is suitable for these same organs.



   As in the case of calcium fluoride, it can be useful to graphite the parts of the mold which come into contact with the powder, to avoid adhesions and the appearance of cracks. It may further be useful to line the mold cavity with a thin sheet of a substance such as tungsten.



   The quality of the molding powder is advantageously chosen according to the following indications. High purity lanthan fluoride and strontium fluoride perform better than less pure fluorides; it is the same for the wave of magnesium and zinc oxide. It is advantageous that the powders of these compounds are as fine as possible; the grains of lanthanum fluoride, cadmium sulphide, magnesium oxide and zinc oxide must be less than one micron in diameter. In the case of hot casting of zinc selenium, the compound must be purified to remove foreign substances and establish the stoichiometric conditions in the compound.

   The powder can be prepared for hot molding by heating it under vacuum in the molding chamber at about 1120 C for 15 minutes to 30 minutes. Partial purification can be achieved before introducing the powder into the apparatus by heating under a slow stream of hydrogen at 950 ° C for 6 h. When this partial purification is carried out by treatment with hydrogen, the temperature of the vacuum cooking before molding can be lowered to about 1080 C. These purification conditions apply to a partial starting material. and it may be necessary to modify them somewhat when using a starting material from another source.



  Likewise, when cadmium sulfide is used, it should be purified in the molding cylinder by vacuum cooking before application of mechanical pressure; in addition, we can

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 EMI20.1
 partially purify the powder before introducing it into the molding cylinder.



  The properties of the new optical elements according to the invention are indicated in Table II.



  TABLE II
 EMI20.2
 Compound Ca F3 Sr F2 Gd S Mg 0 Zn Se rr0 orsno -
 EMI20.3
 
<tb> pain <SEP> water <SEP> water <SEP> red <SEP> water <SEP> water
<tb> dark
<tb>
 
 EMI20.4
 Ïri nri "i5slon in t'ranspa-
 EMI20.5
 
<tb> visible <SEP> rent
<tb>
 
 EMI20.6
 Density transmission ...



  IR -13-14 / # 10 / J -> 16, p. ,,, 8, 5 u +.,. 2I ++ 4 t Index of r (frac- 1.55 to 1.43 2.33 to 1.711 to 2.89 2, D tion 7u 1/3. l, 8yu Loss ppr rflex- No / loo sl, oo N / oo .al.oo zo / 1o ion 10/100 6/100 ri2e / 100 13/100 h 20/100 ¯¯¯¯¯¯¯¯¯¯¯¯¯ ¯¯¯¯¯¯¯¯¯¯¯¯¯: ¯¯¯¯¯¯¯¯¯¯ ## ¯¯¯¯ Hard scale unknown - 3- 35 5-6 4-: 4.5!? Enait'f - 43.24 4.82 3.58 gIt.1 - 5.7 yil # l # MW. '"In' #" # "li '#" wall # ¯¯¯ '; l ¯¯¯¯¯¯¯¯¯¯, .- ¯¯¯, -! Bsit: tMce yyyy * 9U'chpc therrique good good good la: ftB: Tllâ' & U'9 good good good .4 \ * ivteit '' good - good hold # .. ###, ################# <####. ### '** - * "
 EMI20.7
 
<tb> Coefficient <SEP> of
<tb>
 
 EMI20.8
 Coefficient - 4:; 10- '13.9xlo-6 gsa-quartz C, rie ivitc thé'- 3p8xlO 0.048 0.011 njlaue X * (14 "C) f3oo c - <1000 C), ins.HpO}, 011g / 100ml ground.



  Solubility 2Q to OOC ins. ins, H20 ina.H2o acids Cpucis *! weight and like cqni-Ke the co! lme as the coait the pplispagë glass glass glass glass glass
 EMI20.9
 * IR: lnJrf'rOur: e p + to 1 * red extract #t expr1: "" "" E.n CF] .. ci. S C.cn # <# ++ # stuck indicated in Figs. 10 and 11 + q'r, eni e purity

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Moldings of lanthanum or strontium fluoride and of magnesium oxide can be obtained according to the invention. or zinc of very different shapes and sizes, for example cylinders of various diameters, lenses by casting in carefully polished molds to a precise radius of curvature or by optical polishing.

   The variety of shapes and sizes that can be accommodated by the hot molded lanthanum fluoride elements is limited only by the equipment available and parts of very complicated shapes and large diameter can be fabricated. Lanthanum fluoride lens clusters can also be molded.



   Since cadmium sulphide and zinc selenide have a high refractive index, respectively (about 2.4 and 2.89 at extreme red), the optical elements thus manufactured are very refractive and can be used to constitute lenses of. 'a great power of concentration of light. It is thus possible to apply a layer of lead sulphide or of another infrared sensitive substance on a lens of cadmium sulphide or of zinc selenide according to the invention in order to constitute a detector. Infrared, cadmium sulphide or zinc selenide increasing the density of the radiation on the photodetector.



   The hot cast elements of cadmium sulfide and zinc selenide take a good optical polish. Due to their high refractive index, there is a noticeable loss of light by reflection (about 26% for CdS), which can be effectively avoided by applying an anti-reflective coating. which must transmit infrared very well.



   By operating as indicated in the aforementioned Belgian patents, the new optical elements according to the invention can be mounted in metal rings to constitute infrared transmitting windows hermetically crimped in metal.

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   Of course, the invention is not limited to the embodiments described and shown which have not been chosen.
 EMI22.1
 that as an example,


    

Claims (1)

ABSTRACT The present invention has for objects: 1 / new optical elements, remarkable in particular for the following characteristics considered separately or in combinations: a) they consist of a homogeneous and transparent, polycrystalline solid body, formed of a binary compound chosen from calcium fluorides, lanthanum and strontium, cadmium sulphide, magnesium oxide and binary zinc compounds such as zinc selenide and zinc oxide; b) they have a density, related to the theoretical density, between 99/100 and 1; c) they transmit electromagnetic radiation in the visible and infrared ranges; d) according to one embodiment, it is a homogeneous solid consisting of transparent polycrystalline calcium fluoride transmitting in the visible, infrared and micrometric wave regions of the electromagnetic spectrum; e) it is a homogeneous transparent polycrystalline calcium fluoride solid which has undergone annealing and is substantially free from stress patterns; 2 * / a process for the manufacture of optical elements as defined under /, this process being remarkable in particular by the following characteristics considered separately or in combinations: a) a powder of the compound to constitute EMI22.2 the optical element under v1deouenabnosphere inert, at a pressure <Desc / Clms Page number 23> molding pressure between 2070 bars and 3450 bars and a temperature of 7600 and 925 C for calcium fluoride, at a molding pressure between 2480 bars and 3100 bars and a temperature between 825 and 875 "C for fluoride of lanthanum, at a molding pressure of between 1725 bars and 3450 bars and a temperature of 800 to 900 C for strontium fluoride, at a molding pressure of between 690 bars and 3800 bars and a temperature of 510 to 800 C for cadmium sulphide, at a molding pressure of between 2760 bars and 4485 bars and a temperature of 800 to 860 C for the magnesium oxide, at a molding pressure of 690 bars to 3450 bars and a temperature of 845 to 10950C for the selenide zinc and at a molding pressure of 2070 bar to 3100 bar and a temperature of 6000 to 750 C for zinc oxide; b) according to one embodiment applied to molding 1 of calcium fluoride, the hot molding is preceded by a cold molding operation at a pressure of between 1380 bars and 2070 bars; j c) according to one embodiment applied to the molding of lanthanum fluoride, the operation is carried out at a casting pressure of 2760 bars, the temperature being 850 C; d) according to another embodiment applied to strontium fluoride, the operation is carried out at a molding pressure of 2760 tars and at a temperature of 860 C, e) the molding of the cadmium sulphide powder is carried out, according to a method of particular embodiment, at a pressure of 2760 bars and at a temperature of 530 C; f) the magnesium oxide powder is, according to a particular embodiment, ground under a pressure of 4140 bars, at a temperature of 860 C; g) according to another embodiment, the zinc selenide powder 4 is molded at a pressure of 2070 bar and at a temperature of 980 ° C; <Desc / Clms Page number 24> h) the hot molding of the zinc oxide powder is carried out, according to a particular embodiment, at a temperature of 700 ° C., under a pressure of 3100 bars.