DE1869477U - SOLID IMAGE ENHANCER. - Google Patents

Description

Known according to 2 March 8th ISo3

2Ie, 29-WI% 9477. NV Philips' Clocil Lamp Factory. Eindhoven (NIE "...! Lerwndc ,: reps .: Dr. P. Patterson Rossbach> \ nw, Hamburg J FCST * io M $ iM * e" ^tär-: IÖ kcr 5. 61. N 12,564th. Japan 14 5 6 P.

564/21 g Gm Q ft Π 7, if, g ^{/ 2} ** ^2u - ³⁰ ^ o. »Ö9 4τ. (τ. τό _: ζ. 2)

Ε * - "Un IiJ ^ T? —Nr» »- ~~ -

S.V.Philips »Gloeilampenfabrieken, Eindhoven / Holland

Pestatoff image intensifier.

The innovation relates to a Peststoff image intensifier to be connected to a supply voltage source Electrodes and a luminescent layer whose luminance depends on the electric field strength in them is dependent, with a first electrode on one side and a photoconductive layer on the other Side of this luminous layer and neutral impedance elements permeable to radiation on that of the luminous layer applied side of the photoconductive layer are provided, which impedance elements on the from the side facing away from the photoconductive layer are provided with a second electrode.

Two fundamentally different types of pesticide image intensifiers are known; one at a time controls a luminescent element by a photoconductive element electrically connected in series therewith; in the second type, a luminescent element and a photoconductive element are each placed electrically in parallel and connected together in series with a neutral impedance element. When the luminescent elements of the amplifier are electro-luminescent elements and thus an increasing luminance

El / P-10 328 - 2 -

ffi / 7.

Known Sem. 28. fcarz

"* ·» '«.. 1» «7. N.V. Philip, -CIoctbmpcnfabricken. Eindhoven (Netherlands): Represent .; Dr. P. Roßbid». Pat- "\ Nw Hamburg I Fttffßild

derlande): Sales; Dr. P. Rossbid ». Pat- »\ nw .. Hamburg. I Fxststoff.ildventär · kcr. May 10, 61, N 12564. laoan, May 14, 60 ' W24 542 and June 30,'). 55/29 9S7. (T. V; line 2) "

be_ increasing electric field strength , a positive and a negative reproduction of a primary radiation image projected onto the photoconductive elements is obtained in the first type of image intensifier and in the second type. The light-emitting elements of the amplifier on the other hand be ei nes type having Peldtöschung, ie that an electric field deletes a fact brought about by suitable radiation, for example ultraviolet radiation luminescence to a greater or lesser extent in these elements, namely the more the stronger the PEiD more. If the mentioned types of solid-state image intensifiers are equipped with luminous elements of the last type, then image inversion occurs with an image intensifier of the first type, while with the second type a positive image is generated.

The innovation relates to a solid image intensifier of the second type, which does not, however, anticipate that the amplifier will be replaced by a certain connection of the electrodes to the supply voltage source also as an amplifier of the first type is applicable.

According to the innovation, the photoconductive layer is provided with a third electrode which is lattice-shaped is designed, wherein the second electrode is attached at least above the openings of this third electrode is, and the openings of the third electrode are dimensioned such that when connecting the first and the second electrode to the terminals of the supply voltage source, while the third electrode with the

21c. 29. '"IS69 477. N.V. Philipp GlociUmpenbbrickcn. Eindhoven (Niederiomk): Representative: Dr. P. Rosswch. Ρλ- »\ Nw .. Hamburg. | F «btoff-BiMver» ar · '

«Τ; ¹ P, ⁵ - ^6I - ^{N I25M} · J'p »· ♦ · 5-». '

W / 24 542 and ViAJSO. 35/29% ?. (T. »; Z 2)

ers ⁺ en electrode or is coupled to a tap of the mentioned voltage source, the potential of this tap being between that of the first and that of the second electrode, in the state of minimal conductivity of the photoconductive layer a luminance passing through the openings of the third electrode the luminescent layer bedingendes, electric PEiD in the luminescent layer occurs, which decreases with increasing PEiD conductivity of the photoconductive layer in thickness. The way the third electrode in the pesticide image amplifier after the innovation can be compared to a certain extent with that of a control grid in an electron tube, under the understanding that the expansion of this control grid can be changed in the image intensifier by irradiating the photoconductive layer .

According to a further elaboration of the innovation there is the third electrode is preferably made of interconnected, linear, equidistant, highly conductive Elements, in particular made of conductive wires running parallel to one another. In the latter Palle is It is advantageous to let the conductive wires consist of metal ". According to the innovation, it is such possible to let the third electrode consist of a metal, reticulated grid that has more or has fewer rectangular meshes whose length and width dimensions are approximately the same.

It should be noted that a pesticide image intensifier of the afore-mentioned, second type is known in which similar

- ,, 29/40. 1569477. NV Philip '' j

Glocilamprnfabricken. Eindhoven (Nie- ί

derUndc); Represent. _: Dr. P. Koßbadi. Pat.- j

l \ nw .. IIamburR. | FcMstcfi-Rüdvenar- * |

kcr. May 10, 61, N 12564. Japan, May 14, 60 / i

35/24 542 and 6 € 0. 55Ώ9 VS ". (T. 3C: Z. 2) i

As "in the amplifier according to the innovation, three electrodes are provided, but the third electrode is" in this known amplifier interlining with the second electrode on the outside of the neutral impedance elements. The Peststoff image intensifier according to the innovation has the advantage of greater sensitivity compared to this known image intensifier and is suitable, with otherwise the same execution, for feeding with a higher voltage, which results in a more clearly visible image. In addition, according to the innovation, the third electrode in the Peststoff image intensifier, which is in contact with the photoconductive layer, can consist of two electrically separated groups of alternating, linear electrodes, which groups are connected to one another and to the supply voltage source via oppositely directed DC voltage sources If the photoconductive layer consists of a photoconductive powder and a binder, it gives higher sensitivity.

The innovation is explained in more detail at the end of the drawing, which shows a number of exemplary embodiments. Show it in this drawing

Pig. 1 schematically shows a cross section through a first exemplary embodiment and

Pig. 2 shows an electrical diagram of a group of elements of the amplifier according to Pig. 1, which elements together define a pixel of the reproduced image.

Known according to 2 8- March 1S53 ,

21s, 29 / 40.1869 477. NV Philips' Olocilampcnfabrickca. Eindhoven (Nicdcrlandc); Rep .: Dr. P. Roßbadi Pat- »» »·. Hamburg. | Plastic picture strong 5/10/61 N 12 564. Japan 5/14/35/2 + 542 and 6/50/60. 35/29 9S7. (T. 30- Z 2)

Pig. 3 shows the same electrical schematic except in FIG a clearer presentation

4 shows a second in an isometric projection Embodiment of the pesticide image intensifier after the innovation, with some of the different layers removed.

Pig. 5 shows a cross section through another example of the image intensifier according to the invention, wherein also the possibility of switching the electrodes ve "is illustrative, so that at choice the amplifier can be of the first type or of the second type.

Pig. 6 shows schematically a cross section through a further exemplary embodiment in which the third Electrode is formed by parallel metal wires.

Pig. 7 finally shows in an isometric projection an embodiment in which the third electrode consists of a reticulated metal grid that rests on the first electrode. Here, too, some of the different layers are anticipated

Several parts are available in practically the same design in the various embodiments, these parts are therefore denoted by the same reference numerals in the different pigures. Let it go on noticed that many dimensions e.g. different thickness dimensions in the figures not in the opposite

Beicgem. 2 March 8, 1S63

21 ?, 29/40. J 869 477. NV Philips' Giocilampcnfabrickci ». Eindhoven (Lower Saxony); Verfr. _: Dr. P. Rossbadi. Pat.- 'An' ·., Hamburg. | Plastic image intensifier. May 10, 61, N 12 564. Japan, May 14, 60. "35/24 542 and June 50, 1960. 35/29 VS7. (T. 30 · 7 2)

- ff-

correct proportions are indicated on both sides, if necessary suitable dimensions are given numerically below.

With the solid image intensifier according to I ¹ Xg. 1, a transparent carrier plate 1 made of glass is provided with a flat, transparent electrode 2 (first electrode), which consists, for example, of conductive tin oxide. A luminescent layer 3 extends over the electrode 2 and consists of an electro-luminescent material such as zinc oxide activated with copper and aluminum and a synthetic resin such as an epoxy, polystyrene or urethane resin as a binding agent. The thickness of the layer 3 is about 70 / u. Over the layer 3 extends a thin, light-shielding layer 4, which can consist of finely divided carbon and a binder, for example one of the aforementioned synthetic resins. The thickness of the layer 4, which is, for example, about 10 / U, and the composition of the layer 4 should be such that the electrical resistance of this layer is not too low in its area, otherwise the image sharpness could be impaired. Instead of a single layer 4 of carbon and a binding agent, a shielding layer consisting of two different parts can be used, with a thin reflective layer, for example titanium dioxide and a binding agent, lying directly on the luminous layer 3, on which a thin layer of carbon with binding agent extends. The purpose of the light-shielding layer 4 is to prevent light from the luminous layer 3 from influencing the photoconductive layer 5 extending over the layer 4 in an undesired manner. This photoconductive layer consists of a photoconductive powder, for example cadmium sulfide

7 -

Noted according to March 3, 1353:

2? F. 29/43 1369477. N.V. Philipp

; Glocilampfabrickcn. Eindhoven (Never-5

dcrlnndc): Verir. _: Dr. P. Rossbach Pat- '

\ nu Hamburg. | Plastic Image Strength

£ «· May 10, 61. N J2 564. Japan 14.560 '

^{/ 24 5} I ^ "^ f ⁶⁰ - ^55/29 &>'· (T. 30; line 2)»

(activated with copper and chlorine), cadmium selenide or the like. and a binder such as one of the aforementioned synthetic resins; it has a strength of about 50 yes.

The photoconductive layer 5 has an electrode on the side facing away from the shielding layer 4 6 provided (third electrode), which consists of a number of equidistant, linear elements, that are electrically connected to each other. These lenticular elements can be made of metal and e.g. vapor-deposited. You can also use a conductive lacquer e.g. silver powder with resin e.g. consist of a thermosetting resin.

On the photoconductive layer 5 with the electrode 6 extends a radiation-permeable layer 7 made of a material with low dielectric losses. The layer 7 may, for example, be made of a transparent synthetic resin, for example one of the aforementioned synthetic resins consist or it can be formed by a glass plate. The thickness of the layer 7 depends on the dielectric Constant of the material of the layer of the impedances in the direction of the thickness of the underlying Layers and on the mutual spacing of the parallel elements of the electrode 6, what further is discussed in more detail below. The top of the layer is covered with a clear, flat electrode 12 (two te electrode) provided by vapor deposition of a thin layer of aluminum, gold or a layer of other suitable metal or can be obtained in that this side of the layer 7 with a thin Layer of conductive lacquer is coated by mixing silver powder with a binder

Noted according to March 8, 1953

2Ie, 29/40. 1869477. NV Philips' Glocilampfabrickcn. Eindhoven (Nie- <2crLir.dc) _: Verir. _: Dr. P. Koßbadi Pat-> \ nw .. JJambiirj ;. | Fabric image strength 1 kcr. May 10, 61, N 12564. Japan, May 14, 60Λ 35/24 542 and 6/30/60. 55/29 9S7. (T. 30 · Z 2) f

for example a thermosetting resin is obtained. If the layer 7 consists of glass, the electrode 12 can consist of conductive tin oxide or of another conductive oxide in a known manner. If the layer 7 is formed by a self-supporting plate or film, the connection with the photoconductive layer 5 and the electrode 6 can be made by means of an adhesive layer, for example made of synthetic resin; a thin layer of an insulating liquid with low dielectric losses, for example silicon oil, can also be interposed and the layer 7 can be held on the layer 5 by pressure.

To use the described solid-state image intensifier as an amplifier of the aforementioned second type, the electrodes 2 and 12 are connected to the various terminals a_ and b_ of a voltage source 10 via the conductors 11 and 13, respectively. The electrode 6 is connected via the line 9 to the same terminal, in this case the terminal a_ of the source 10 to which the electrode 2 is connected. A primary radiation image is projected onto the photoconductive layer 5 through the electrode and the transparent layer 7 (This image is symbolically _{indicated in the figures by L 1} ), which image makes the photoconductive layer locally conductive to a higher or lower degree according to the local intensity of the primary radiation image, so shows the electro-luminescent layer 3 through the electrode 2 and the Carrier plate 1 passes through an image that corresponds to the primary image but is reversed, ie an image reversed in terms of brightness (in the figures this is indicated by the

- 9

Bek-acc. 2 March 8, 1S63

21g, 29/40. 1869477. NV. Philips * Glpcilampcnfabrickcn. Eindhoven (Netherlands); Sales ·. Dr. P. Koßbach. Pat- ι Λη »·., Hamburg, j Fcststoff-Biidvcrstark-I kcr. May 10, 61, N 12 504. Japan, May 14, 55/24 542 and 6/50/60. 55/29 V) S7. (T. 50; line 2)

Image reproduced image intensifier symbolically _{indicated by L 2} ); It is assumed that the voltage supplied by the voltage source 10 at the electrodes is sufficiently high to allow the electro-luminescent layer 3 to light up more or less uniformly in the non-irradiated state of the photoconductive layer 5. This mode of operation of the image intensifier according to I ¹ Ig. 1 is explained with reference to FIGS. 2 and 3, which represent the electrical equivalent circuit diagram of a group of elements of the various layers of the image intensifier lying one above the other between two adjacent, parallel, linear parts of the electrode 6. Such a group of elements, denoted by 20 in FIG. 1, determines the size of an image point of the luminous image reproduced by the layer 3. The dimension of this group in a direction transverse to the plane of the drawing is approximately the same as the dimension in the plane of the drawing parallel to the luminescent layer 3 »that is, the distance between the center lines of the parallel parts of the electrode 6. In the electrical equivalent circuit diagram of group 20 according to FIG the circuit elements are illustrated in the form of separate impedances; in fact, these are distributed impedances. In addition, the electrical shielding effect of the parallel parts of the electrode 6 is not included in this circuit diagram. In Fig. 2, the capacitors C represent the capacitance between the electrode 12 and a segment of the electrode 6. The resistor R. .., omitting any parallel capacitance, represents the part of the photoconductive layer

according to 2.8. March 1S63

21g, 29/40. 1869477. N.V. Philips'

Glocilampfabrickcn. Eindhoven (Nie-;

derl.indc); Representative to Dr. P. Rossbach. PaI.-

»\ Nw.

kcr.

35/24 542 <.

"τ

derlandc); Representative to Dr. P. Rossbach. PaI.-; ftnw. Hamburs. I Plastic image intensifier. May 10, 61, N 12 564. Japan, May 14, 60, Yl 35/24 542 a. 50.6 * 0. 35/29 VS7. (T..30: line 2). '

- 10 -

between the adjacent parts of the electrode 6. Oj. and R. denote the impedance of this part of the photoconductive layer in the transverse direction thereof; 0. is the capacity, R. is the resistance. The impedance

pe -

in the transverse direction of the electro-luminescent layer 3 is indicated by 0, omitting the resistance. The impedance of the light shielding layer 4 becomes neglected in the process; it can of course be used as a included in capacity C. The impedance between the parts of the electrode 6 and the electrode 2 is omitted because these electrodes are outside the Image intensifier are electrically connected to each other.

Pig. 3 basically shows the same circuit diagram, but in a clearer form. The two circuit diagrams clearly show that in each elementary group of the An element of the luminous layer 3 with the image intensifier Capacitance C in series with the capacitance C caused by the parallel connection. and the resistance R. educated Impedance in the transverse direction of an element of the photoconductive Layer 5 is switched on. With this series connection, half the resistance is in the plane direction of the photoconductive element i.e. R, / 2 in parallel. This parallel connection of elements of the photoconductive Layer 5 and an element of the luminous layer 3 is in itself electrically in series with that in the form of the capacitance C, indicated impedance of an element of the layer 7 connected between the electrode 12 and the relevant element of the photoconductive layer 5 is located. The alternating voltage is connected to this series connection connected voltage source 10, via which voltage source the capacitors C are connected. It it will be evident that this is a picture

Bek.gem .. 2 8th March Ώ63;

21g, 29/40. 1869477. N.V. Philips'! GIocilampcnfabrickcn. Eindhoven (Nie-: derlnnde): Veiir .; Dr. P. Koßbadi. Pal.-;

- 11 -

is is strong the aforementioned, the second type and that an amplifier, in which the reproduced image L ₂ is the reverse of the primary radiation image L-, since the voltage of the supply voltage source 10 Nominal sufficiently high, in order in the non-irradiating state of the photoconductive Layer 5 dH with a high value of ^R _O i / ² > to light up the element with the capacitance C, the primary radiation pattern L _{1 will make} the photoconductive layer more or less conductive, with & -j_ / 2 depending on the local radiation intensity decreases and as a result the distribution of the supply voltage across the capacitance C-, and c.ie parallel connection of R -./2 and C is changed in such a way that the voltage across the capacitance C decreases accordingly.

The influence of the parallel connection of C. and R. Impedgnz shown in the transverse direction of the photoconductive layer 5 is low or negligible if this impedance compared to that formed by C. Impedance is small. This can be achieved by properly dimensioning layers 3, 4 and 5.

From Pig. 2 it can be seen most clearly that the photoconductive layer 5 as a function of the conductivity more or less strong shielding against that of the electrode 12 via the capacitor C after the electric field running through the electrode 2 is effective that the luminance of the element represented by C. The distance between the parallel parts of the electrode 6 should be such be that when the image intensifier is fed by a voltage that is not too low, which goes without saying

- 12 -

- i

Known according to March 28, 1S63

21s, 29/40. 1869477. NV Philips' Glocilampfabrickcn. Eindhoven (Netherlands); Vcrir .: Dr. P. Rossbach. Pat .-) \ n \ v. Hamburg. | Plastic image intensifier. May 10, 61. N 12 56i. Japan May 14, 60, 35/2 + 542 and 6/30/60. 55/29 V> S7. (T. 30; line 2) ■ ■ - - ■ '"·' ·.-..- _r .

- 12 -

must be below the breakdown voltage, this electrical PeId in the non-irradiated state of photoconductive layer 5 can sufficiently pass through the parts of the electrode 6 «On the other hand the distance between the parallel parts of the electrode 6 causes the image sharpness, so that this distance should not be chosen too large. Since the electrode parts mentioned are the one just below If parts of the luminous layer 3 are shielded from the electrical panel, dark lines can arise in the luminous image. This can be countered by increasing the width of the parallel parts of the electrode 6 is chosen to be as small as possible, of course the technological ones Possibilities and sufficient conductivity of these parts must be taken into account. The amplifier after Pig. With the dimensions of the various layers given above, 1 gives a good result, when the width of the electrode parts is 200 / U and the mutual distance be about 500 / U. In this PaI-Ie a thickness of layer 7 of about 300 / rev is well suited.

If with the amplifier according to Pig. 1 luminescent light from the layer 3 can influence the conductivity of the layer 5, it is a negative (optical) feedback, which on the one hand reduces the sensitivity of the amplifier and on the other hand the characteristic curve, ie the relationship between L _? and L ₁ can be flatter at a certain supply voltage so that it becomes more linear. The light shielding layer 4 serves to limit this negative feedback, if necessary to suppress it completely.

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BSK-:

Known according to 2 March 8, 1963 1

21s, 29.'4a. 1S69 477. N.V. Philips "ν

Glocilampcnfabrickcn, Eindhoven (Nic- ^: |

dcrl.indc); Vice-President: Dr. P. Rossbach. Pat .-- |

> \ n \ v .. Hamburg. | Plastic image strength - |

kcr. JO. 5. 61. N 12 564. Japan 14. 5. 60. | f

- 13 -

The capacitances C _a between the electrodes 12 and

6 are, as I said, to the supply voltage source 10 ; closed. If the layer 7 is relatively high ; Has dielectric losses, a considerable amount of heat can occur therein, which in itself breaks down

can bring with it. The capacity C can be reduced;

by not placing the electrode 12 over the entire layer j

7 is extended, but this electrode is similar to

the electrode 6 from parallel, electrically to each other;

connected parts is assembled, which is above j

i half of the spaces between the electrode 6 parallel with the \

Parts of the latter extend. This means that those parts of the Jig. 1 illustrated, flat I. Electrodes 12 are omitted, which are directly t are located above the parts of the electrode 6. Opposite plane [ if so, the parts of the layer 7 directly above the electrode 6 can also be omitted.

; The embodiment of the IPesti shown in Fig. 4-; fabric image intensifier according to the innovation has with the Γ embodiment according to I ¹ Ig. 1 shows the following difference.

The luminescent layer on the electrode 2 is divided into two parallel sub-layers 3 and 16, of which the sub-layer 3 forms the starting layer, which _{provides the image L 9 to be} perceived, while the sub-layer 16 is a luminescent layer that provides an optical feedback to the photoconductive layer 5 brings about. The amount of feedback is primarily determined by the overlap of the spectral emission curve of the partial layer 16 and the spectral sensitivity curve of the photoconductive

ß:

capable layer 5 is determined. Between layers 3 and 16

Bek-acc. 2 March 8, 1953

21 *, 29/40. 1869477. NV Philips' Glocjlampcnfabrickcn. Eindhoven (Nic- ^: dcrlandc); Rep .: Dr. P. Koßbadi. Pat.- · > \ nw. HamburR. | Plastic image intensifier ίο. 5. 61. N 12 564. Japan, 14. 5. 60.] 55/24 542 and 50.6.60. 55/29 9S7. (T. 50; line 2) I.

- 14 -

15 is mounted, for example, from a mixture of very fine carbon powder and a resin, a thin opaque layer which prevents inter alia, that light from the room side, where the light image observed can v / earth (which is light in Mg. 4 symbolized by L , is referred to), the photoconductive layer 5 can reach. The luminescent light of the layer 16 reaches the photoconductive layer 5 through a partially permeable layer 4, which is inserted if necessary, and the openings of the electrode 6 formed as a reticulated grid 17 with square meshes below the photoconductive layer 5. Since the reticulated electrode 17 is opaque - this electrode can e.g. consist of a metal grid or wires of a conductive lacquer, e.g. silver powder with Kumstjuarz, added to the finely divided carbon - lateral scattering of the feedback light emitted from the luminous layer 16 to the photoconductive layer 5 is prevented, which promotes the sharpness of the image. The net-shaped electrode 17 can be seen along one side of the image intensifier with a strip-shaped power supply conductor 18, e.g. made of opaque, conductive varnish ν, which is connected via the supply wire 9 and an impedance 19 to the same terminal of the voltage source 10 to which the electrode 2 is also connected is. The insertion of the impedance 19 in the supply line after the network electrode 17 has the effect that the shielding effect of the electrode 17, which counteracts the penetration of the electric field after the luminous layer 3, is reduced. This can also be achieved in that the electrode 17 is connected directly to a point whose potential lies between that of the terminals of the voltage source 10, for example with a tap of a bypassing the voltage source 10.

- 15 -

Known-acc. March 23, 1S53

*. _ζ , 29.'4O. 1869477. NW. Philip "". Glocilampcnfabrickcn. Eindhoven (Netherlands) · Verfr .: Dr. P. Roßbach. Pat. Japan May 14, 60, 55/24 542 and June 50, 60, 55/29 9S7. (T. 50; line 2) j

- - ^: rj ι

- 15 -

the voltage divider. This reduction in the shielding effect of the grille 17, which can otherwise be carried out in the same way in the image intensifier according to FIG. 1 and also in the exemplary embodiments to be described below (with the exception of the example shown in FIG. 7), allows a reduction in size the mesh size or the mutual spacing of the parallel parts of the electrode 6 which is in contact with the photoconductive layer.

Instead of a net-shaped electrode 17, an electrode with the shape of equidistant lines can be used, whereby a scattering of the luminescent light emerging from the layer 16 in directions parallel to the lines of this electrode can be prevented by applying opaque insulating lines transversely to these electrode lines, so that, nevertheless, an opaque, reticulated grid is present between the luminous layer 16 and the photoconductive layer 5. By designing the electrode not in the form of a network but in the form of a line, the shielding effect of this electrode £ '\ r the electric field after the luminous layer 3 is reduced.

When using a transparent synthetic resin as material for the layer 7, the application of the transparent Electrode 12 on this layer is not always convenient to carry out. Therefore, in the embodiment 4, the electrode 12 is attached to a separate glass plate or film 14, which is then connected to the Electrode 12 carrying side is connected to the layer 7. The electrode 12 on the plate 14 is made preferably made of conductive tin oxide.

Bek-sem. 2 March 8, 1S53 ^l

ς, 29/40. 1869477. NV Philips * Glocilampenfabrickcn. Eindhoven (Nieder- ^! DcrLwdc); Vice-President: Dr. P. Rossbach. Pal.-; > \ nw .. Hamburg. | Plastic image intensifier. JO. 5. 61. N 12 564. Japan 14. 5. 60. ■■ 35/24 542 and 30.6.60. 55/29 9S7.

pan May 14th, 60th vf 7. [T. 30; Line 2) I.

- 16 -

A similar support plate 14 for the electrode 12 is "in the embodiment" for example according to Pig. 5 used. This embodiment further differs from that according to FIG. 1 essentially in that the photoconductive layer 5 does not have the shape of a layer of the same thickness everywhere, but consists of a number of parallel, relatively thick ribs. Between these ribs there are more or less V-shaped butes that run as far as the light shielding layer 4. The layer 7 obtained by assembling the neutral impedance elements extends over these ribs and fills the jutes between the ribs. The lenticular parts of the electrode 6 are mounted on the tops of the photoconductive ribs. The electrode 6 is connected via the conductor 9 to the movable contact 41 of a changeover switch 40, the fixed contacts 42 and 43 of which are connected to the terminals b_ and a. the voltage source 10 are connected. In a similar manner, the electrode 12 is connected via the conductor 13 to the movable contact 51 of a changeover switch 50, the fixed contacts 53 and 52 of which are also connected to the terminals b_ and a of the voltage source 10, respectively. With these switches 40 and 50, the image intensifier according to Pig. 5 can be used as an image intensifier of the first type (series connection of photoconductive and luminescent elements) or as an image intensifier of the second type (parallel connection of photoconductive and luminescent elements with one neutral in each case Use impedance element). In the position illustrated in Pig. 5, in which the switch 40 connects the electrode 6 to the terminal b_, and thus also to the electrode 2, and the switch 50 connects the electrode 12 to the terminal a, the image intensifier shown is

Known according to 28.Man 1363

21 ζ, 29/40. 1869477. N.V. Philips * Glocilampfabrickcn. Eindhoven (Netherlands): Vice President: Dr. P. Koßbadi. PaI .-) \ nu. Hamburg. | Plastic image intensifier. May 10, 61, N 12 564. Japan, May 14. 35/24 542 and 6/30/60. 35/29 9S7. (T. 30; line 2)

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stronger of the second type v / ineffective, liacii flipping the switches 40 and 50, whereby the electrode 6 is connected to the terminal a and the electrode 12 to the terminal b_ (to which the electrode 2 remains connected), the image intensifier acts as an amplifier of the first type are effective. The impedances formed by parts of the layer 7 between the electrode 6 and the electrode are connected directly to the voltage source 10. In order to obtain an image intensifier of the first type, however, it is not absolutely necessary for the contact 53 of the switch 59 to be connected to the terminal b of the voltage source 10. The contact 53 could be loose, so that the impedance between the electrodes 6 and 12 does not load the voltage source. On the other hand, there is a risk of crosstalk due to the mutual coupling of the photoconductive elements belonging to the various elementary groups via the impedance between these elements and the electrode 12 common to these groups feasible, with the exception of the Pig example. 7 »

In the embodiment according to Pig. 6, the electrode 6 consists of a number of parallel wires that are embedded in the photoconductive layer 5. These conductive wires that are of equal strength (about 50 / u) as the photoconductive layer are preferably made made of metal, e.g. brass, tungsten or steel; however, they can also be made of textile or synthetic resin wires which are provided with a conductive coating, e.g. made of a conductive lacquer »The wires of the Electrode 6, which is a distance of about 500 / α between

Bek-sem. 28. Resin 1SB3 Ill clocil lamp factory. Eindhoven (never

derland); Vice-President: Dr. P. Rossbach. Patient > \ n \ v .. Hamburg. | Plastic wall thickness: kcr. May 10, 61. N 12 56 *. Japan May 14, 35/24 542 and 6/30/60. 55/29 9S7. (T. 30: Z. 2)

ίο

other are alternately connected to each other, so that two groups of electrode wires are formed One group is across a DC battery 22 and the other group is across a DC voltage source connected to that terminal of the supply voltage source 10 to which the electrode 2 is also connected. the DC voltage sources 22 and 23 are of opposite polarity as seen from AC voltage source 10. With this circuit arrangement it is ensured that the elements of a photoconductive powder and a Binder existing photoconductive layer 5 are fed by a pulsating DC voltage while the luminous layer 3 is fed by alternating voltage. This was done because one of one photoconductive powder and a binder consisting of a photoconductive element when supplied with direct voltage is more sensitive than with AC voltage supply.

For the production of the image intensifier according to Pig. 6 the following procedure can be carried out. On the Support plate 1 are successively the transparent electrode 2, the luminous layer 3 and the light shielding layer 4 attached, which layer 4 limits or completely suppresses the optical feedback. Then become a Number of V-shaped grooves e.g. with a depth of 2 mm along two opposite longitudinal sides of this Formation by means of a cutting or grinding tool at a mutual distance equal to the desired Distance between the wires of the electrode 6 attached. Then on the carrier 1 with the different layers spirally wound a wire forming the electrode 6, with sufficient tension in the above-mentioned Herding is housed. Thereupon are the coils

- 19 -

Noted according to March 2, 1S53

2U, 29/40. 1? 69 477. NV Philips' Glocilampcnf.ibrickcn. Eindhoven (Nicdcrl.indc); Rep .: Dr. P. Rossbach. Pat.- _: "■» \ nw .. IIamburs. I Plastic Image Intensifier V kcr. May 10, 61, N 12564. Japan, May 14, 35/24 542 and 6/30/60. 35/29 9S7. (T. 3C; line 2)

- 19 -

the wire along hardening thermo-the side edges of the carrier 1 with a conductive coating attached, wherein Z, is obtained by mixing with an epoxy resin SiIberpulver ₀ B. After the windings have been fastened in this way, those parts which lie on the side of the carrier 1 facing away from the electrode 2 are cut through and removed. The photoconductive layer 5 is then applied to the wires then stretched over the light-shielding layer 4, e.g. by pressing a suspension of the photoconductive powder, a synthetic resin and a suitable solvent onto the surface with the wires of the electrode 6 using a silk screen (screen printing of the photoconductive layer ). After removing the silk screen, the solvent is evaporated from the photoconductive layer. An adhesive layer 21 consisting of a synthetic resin is connected to the neutral impedance elements combined to form an uninterrupted layer 7. The layer 7, which can consist, for example, of a glass film, is provided on the side facing away from the photoconductive layer 5 with the flat electrode 12, which is transparent and preferably consists of conductive tin oxide.

Instead of forming the electrode 6 on the carrier with the layers 2, 3 and 4 applied thereon, a conductive one To wind up wire, the wire can be placed on a separate tensioning frame with the correct mutual spacing be wound up, e.g. on a frame with two metal rods with a screw thread with a Y / winding pitch are provided equal to the desired spacing of the wires, whereupon the obtained grid or grid, formed by the corresponding halves of the Y / indings

- 20 -

Known according to 2 3rd War: 1S63

21 ς, 29 / W. 1869477. N.V. Philips " GlocilaniDcnfabrickcn. Eindhoven (Netherlands): Representative: Dr. P. Rossbach. Pal.- j Λη-.ν., II.imburK. | Plastic image intensifier kcr. JO. 5. 61. N 12 564. Japan 14. 5. 60/35/2 + 542 and 50.6.60. 35/29 9S7. (T. 30; line 2)

- 20 -

det is stretched over the layer 4 , is fixed at the edge of the carrier 1 and the photoconductive layer is pressed in the manner described above into the spaces in the grid .

The electrode 6 can not only consist of parallel wires with equal spacings, but also of a reticulated grid. For this purpose, a net-like grid is first stretched onto the frame and then over the light-shielding layer 4. Then the procedure described above is continued.

The conductors of the electrode 6 do not need to have the same thickness as the photoconductive layer 5. In view of the penetration of the primary radiation image into the photoconductive layer 5, with a thinner electrode 6 it is advantageous not to let this electrode rest on the light-shielding layer 4 , but rather in or on the surface of the photoconductive layer facing the electrode 12. Thinner wires for the electrode 6 have the advantage that their electrical "shadow ^M" effect is less and that the mutual distance can be selected to be smaller, so that an improved image sharpness is obtained Layer attached, which has, for example, a thickness of 30 / u. The electrode 6, which consists of thin parallel wires or is formed by a reticulated grid, is then tensioned, whereupon the spaces in this electrode are filled with the remaining thickness of the photoconductive layer 5. Both the application of the first part of the layer 5 as well as the aforementioned filling can be carried out again

- 21 -

• ϋίΐΐύ -Z ^ i ""'""~'

Fy 'Betcgem. 2 March 8, 1963

ψ '-' 2I ₅ , 29/40. I $ 69 477. NV Philips "

'' ■ 'Glocilampcnf.ibnckcn. Eindhoven (Nic-

clerl-indc); Rep .: Dr. P. Koßbach. Patient ^:

■. ) \ nw., Hamburs. | Plastic image intensifier "

; kcr. May 10, 61, N 12 564. Japan, May 14, 60.1

35/24 542 and 6/30/60. 35/29 VS7. (T. 30; line 2) '

- 21 -

Screen printing can be done. In this method, a net-shaped grid similar to the usual net-shaped electrode in a television camera tube of the vidicon type or a storage tube can be used for the electrode 6. Such a net-like grid can have a thickness of 8 / u, while the mesh dimensions can be 150 χ 150 / u.

; ' The photoconductive layer 5 can also be made of sintered, photoconductive material z.3. sintered cadmium sulfide or cadmium selenide, whichever is faster

as cadmium sulfide responds to radiation. To produce the image intensifier according to the innovation with such a sintered, photoconductive layer, the following process can be carried out. A self-supporting plate or film made of a transparent material with a high melting point, for example glass with a high melting point or material known under the name "Pyroceram", is used for the layer. A grid 6 made of parallel wires or in the form of a net and made of a metal with a high melting point, for example tungsten, is stretched over one side. A thin layer of cadmium sulfide or cadmium selenide powder is stretched over this electrode, whereupon this layer is ^{sintered at a temperature of about 600 °} C. in a suitable gas atmosphere, for example air or nitrogen. The electrode 12 can then be attached to the other side of the plate 7 and the plate obtained in this way can be attached with an adhesive layer to the further part of the image intensifier consisting of layers 1, 2, 3 and 4. In layers 3 and 4, glass can be used as a binder, so that the various layers can pass through

Noted according to March 3, 1S63

21g, 29/40. 1569477. NV Philips' Glocilampenfabrickcn. Eindhoven (Netherlands): Vice President: Dr. P. Rossbach. Pat- »\ nw., Hamburg. | Solid image enhancer. May 10, 61. Ni 12 564. Japan May 14, 35/24 542 and 6/30/60. 35/29 9S7. (T. 30; line 2)

- 22 -

a heat treatment can be rigidly connected to each other. (This naturally also applies to the other exemplary embodiments). The layers 4, 3, 2 and 1 can also be applied one after the other in this order on the sintered, photoconductive layer.

In the embodiment according to FIG. 7, the electrode becomes 6 of the photoconductive layer 5 formed by a reticulated grid that is directly connected to the electrode 2 and whose wires have a thickness that is at least equal to the thickness of the luminous layer 3. This layer 3 consists of elements, which the Mascuen the grid-shaped electrode 6 more or less filling The elements of the light-blocking layer 4 are brought over the elements of the layer 3. On the electrode 6 and the shielding layer 4 has the photoconductive layer 5, the other side of which extends through the adhesive layer 21 is in contact with the neutral impedance elements combined to form an uninterrupted layer 7. The upper The side of the wires of the electrode 6 extends into the photoconductive layer 5; should be this top side with a very thin layer of luminescent material and / or material of the light shielding layer 4 covered If the image intensifier is fed with alternating voltage, this is of little concern. If necessary For example, the upper side of the electrode 6 can be cleaned before the application of the photoconductive layer by means of, for example, planarization will.

It is not necessary for the electrode 6 to be made up of parallel or independent lattices combined to form a reticulated grid Wires. An uninterrupted luminous layer 3 can also initially be placed on the carrier with the electrode 2

■ 'Noted according to March 8, 1S63

21e, 29/40. IS69 477. NV Philips "Clocilampcnfabrickcn. Eindhoven (Nicdcrb.ndc); Verir .; Dr. P. Roßbach. Pat.

■> \ nw .. II.imburR. | Plastic image intensifier

i | ker. May 10, 61. N 12 564. Japan May 14 (C.

t | 35/2 + 542 and 6/30/60. > 5/29 V.X7. CT. "50- 7. 7 \

\ t

- 23 -

and a cable shielding layer 4 is attached to it, whereupon parallel or a grid with more or less square meshes in the last two layers mentioned Forming grooves are cut, which are then filled with a preferably opaque, conductive paint will. The opacity of the electrode 6 does not matter whether it is made of metal wires or opaque, There is conductive lacquer, has the advantage that the negative feedback as a result of the in the direction of the photoconductive Layer emitted luminescent light of the luminous layer 3 remains spatially limited.

In the examples outlined above, this takes place the supply of the luminescent layer 3 always by V / alternating voltage « The innovation is also useful for solid-state image intensifiers in which the luminescent elements respond to DC voltage. In this case you have to the various layers in the star- direction have sufficient direct current conductivity so that they are not only capacitively effective.

Also mentioned, for example, as a luminescent material in the luminescent elements is a substance which Electroluminescent is »It will be evident that without Changing the principle in these elements a luminescent material can be used, which has the property which has field deletion. In operation of a solid image intensifier according to the innovation with such luminescent Material must of course have an auxiliary source of radiation be provided, which is suitable for the luminescent elements by means of irradiation Bring light up.

24

2Ie, 29/40 1869 477. NV Philips' Oloeilampcnfabrickcn, Eindhoven (The Netherlands); Vcrtr .; Dr. P. Rossbadi. Pat- '> \ nw., HamburR. | Plastic image intensifier 5/10/61 N J2 564 Japai> 5/14/60. 35/24 542 and 6/30/60. 35/29 VS7. (T. 30; line 2)

The solid image intensifier according to the innovation not only needs to process a primary radiation image to be suitable, which is formed by radiation in the visible part of the spectrum. The image intensifier is for Invisible rays such as infrared, ultraviolet and X-rays are suitable when the photoconductive material in the layer 5 responds to this radiation and the electrode 12 and the material of the neutral impedance elements, which in the illustrated embodiment are combined to form an uninterrupted layer 7, such are chosen are that they allow this radiation to pass through or absorb it too weakly.

Protection & n3T) odors:

Claims (1)

Occupy*. March 23, 1S63 2Ιζ, 29'40. 1869 477. NV Philips "C.JociIampcnfabrickcn. Eindhoven (Netherlands); Sales: Dr. P. Roßbach Pm- > \ nw., Hamburg. 5 35/24 542 and 30.6.60. 35/29 VS7. (T. 30 Z 2) - 25 - Protection claims: 1β solid image intensifier with electrodes to be connected to a supply voltage source and a luminous layer with a luminance dependent on the electrical field intensity therein, with a first electrode on one side and a photoconductive layer on the other side of this luminous layer and neutral, radiation-permeable impedance elements on that of the side of the photoconductive layer facing away from the luminous layer are provided, which impedance elements are provided with a second electrode on the side applied by the photoconductive layer, characterized in that the photoconductive layer is provided with a third electrode which is lattice-shaped and that the second electrode is attached at least above the openings of this third electrode, the openings of the third electrode having such dimensions that when connecting the first and the second electrode to the terminals of a supply voltage source, while d The third electrode with the first electrode or with a tap of the mentioned voltage source, such that the potential of this tap is between that of the first and that of the second electrode, is coupled in the state of minimal conductivity of the photoconductive layer in the luminous layer through the openings of the third electrode Hendes executed, the luminance of the luminescent layer occurs bedingendes, electric field decreases with increasing conductivity of the photoconductive layer in the intensity _o - 26 - BeLgem. 2 March 8, 1S63 ?. * ·., ²⁹ '* \ J ^{% 9} * 77. NV Philips' Olocil Lamp Factory. Eindhoven (Niciicrlnndc); Vsrtr.j Dr. P. Rossbach. Pat-Anw. Hamburg. | Enhance solid image «» J?:, ⁵ · ⁶ - ^{KN 12564} · J ^a P ^{ai> I4} - ⁵ · «·" 35/24 5t2 u.) 0.6.60. 35/29 9S7. (T. 30-7 2) - 26 - Second solid-state liquid amplifier according to Claim 1, characterized in that the third electrode consists of linear, equidistant, highly conductive elements connected to one another. 3 β Peststüff image intensifier according to claim 2, as characterized by that the third electrode is formed by parallel wires. 4. Solid image intensifier according to claim 3> characterized in that the wires are made of metal. 5ο solid image intensifier according to claim 2, 3 or 4, characterized in that the second electrode is also connected by mutually connected, äauiaistante, highly conductive elements are formed which extend parallel to the elements of the third electrode and are each arranged above the fillet of an intermediate space in the third electrode. 6o solid image intensifier according to claim 1, characterized characterized in that the third electrode consists of a metallic, net-shaped grid with more or less diamond-shaped meshes. 7. Solid image intensifier according to claim 1, wherein the photoconductive layer consists of a powdery, photoconductive material and a binder, characterized in that the third electrode is formed by equidistant, conductive, linear electrode elements that are alternately connected to each other such that:?; two electrically separated groups Noted according to March 3, 1S63 21s. 29/40 1869 477. NV Philips' ylocilampcnfabricfecn. Eindhoven (Nicdcri.inde); Ex. _: Dr. P. Rossbach. Pm.- | \ nu .. ManiburR. | Plastic image intensifier ! i'P ⁵ · ⁶ l · ^{N 12564} · ^Japan »* - ⁵ « v and 30.6.60. 55/29 i> S7. (T. 50- Z 2) - 27 - of electrode elements, which groups each have a DC voltage source when the image intensifier is in operation be connected to the first electrode, the voltages of this DC voltage source, viewed from the first electrode, the polarity is opposite » 8e solid image intensifier according to claim 1, with internal, optical feedback, characterized in that the luminescent layer consists of two parallel sub-layers with a thin, light-impermeable intermediate layer and that the luminescent light of the sub-layer lying on the side of the photoconductive layer is achieved by matching the spectral Emission curve of this sublayer and the spectral sensitivity curve of the photoconductive layer and / or through the interposition of a thin shielding layer that partially suppresses the luminescent light of this sublayer, thus acting back on the photoconductive layer! can that a linearization of the characteristic curve of the image intensifier is obtained _o 9ο solid image intensifier according to claim 1 with internal, optical feedback, characterized in that between the photoconductive layer and the luminous layer a reticulated lattice made of opaque material is attached, especially those in one direction extending grid elements are highly conductive and form the third electrode and those in the other direction running elements are electrically non-conductive o 10. Solid image intensifier according to claim 1, characterized characterized in that the neutral impedance elements uelcgem. 2 March 8, 1S53 21ζ. 29.40 1869477. NV Philips "Oloc: Iampcnf.ionckcn. Eindhoven (Netherlands); Representative _: Dr. P. Koßbach. Pat- L ^V Vn ^H f ^mbur 5 · I! «Tstofi-BiWsteiger- "Ί - 28 - by parts of an uninterrupted layer extending over the photoconductive layer O 11 β pesticide image intensifier according to claim 2, characterized characterized in that the photoconductive layer has the shape of parallel ribs, each are provided at the apex with a linear electrode, which is part of the third electrode forms, the neutral impedance elements in common form a layer which extends over these ribs and which narrows towards the luminous layer Fills grooves between the mentioned ribs " 12. Pest image intensifier according to claim 1, characterized characterized in that the second electrode is on a separate carrier which is transparent to radiation is attached, which extends across the neutral impedance elements. 13 «Peststoff-image intensifier according to claim 12, characterized characterized in that between the separate carrier and the neutral Iiiipedanzelemente one for Radiation-permeable adhesive layer is located. 14. FeststolT image intensifier according to claim 12, characterized characterized in that between the neutral impedance element and the separate carrier there is a thin, insulating fluid layer is located. 15. Pest image intensifier according to claim 1, characterized characterized in that the third electrode has an electrical impedance with the first electrode connected is. Known according to 2 March 8, 1963 21 ?, 29/40 ι S ₆₉ ^ ^ γ " _Phi j _ips . Glocilampcnfabrickcn. Eindhoven (Nkderlandc); Vc _rt r _.: Dr. P. Κοβί, αώ. Pa, - 16β solid image intensifier according to claim 1, since \ characterized in that the third electrode from on s electrically conductive j Parts and in that the luminescent layer in the Räu-] men is arranged between these parts. j 17 «solid image intensifier according to claim 10, characterized in that the third electrode consists of [conductive elements in or on the; photoconductive layer facing the surface to: ι a separate opaque layer vereinig- ■ th neutral impedance element are mounted en. 18. Solid image intensifier according to claim 3 or 6, characterized in that the third electrode: whose strength is less than that of the photoconductive ones Layer, in this layer is embedded in the part adjoining the neutral impedance elements. 19 «. Method of making a solid image intensifier according to claim 3, characterized in that around a transparent carrier on which one after the other the first electrode, aie luminescent layer and optionally a light-shielding layer are attached, a conductive wire with a pitch equal to the desired one mutual spacing of the elements of the third electrode is wound, whereupon the turns of the wire wound on this y / eise on the Long sides of the carrier attached and on at least; one of these sides are electrically connected to each other, whereupon the wire parts on the side of the Trä- ■ away from the side with the first electrode- ■; taken four den and the photoconductive layer in and Beicgem. March 28, 1963 21ε, 29/43. 1 * 69477. N.V. Philips' Gloeil lamp factory. Eindhoven (Netherlands); Vcrtr .: Dr. P. Koßbadi. PaI.- > \ nw., Hamburg. | Plastic image intensifier. kcr. 10. 5 - ' 35/24 542 ii.uiuc ;; from left to right: ur. r. Koljtucn. rat.-nw., Hamburg. | Plastic image strength. τ. May 10, 61, N 12 564. Japan, May 14, 60.1 / 24 542 and June 30, 60.15/29 9S7. (T. 30; line 2) ' - 30 - is attached to the remaining wire parts running parallel to one another, whereupon the photoconductive layer obtained in this way is brought into contact with the neutral impedance elements, which impedance elements are or will be provided with the second electrode on the side facing away from the photoconductive layer _e 2Oe Method of Making a Solid Image Intensifier according to claim 17, characterized in that an independent carrier consists of a transparent, temperature-resistant material, to which carrier the neutral impedance elements are combined, with a temperature-resistant metal wire is wrapped, or on one side with a net-shaped grid such wire is covered, whereupon one side of the carrier with this wire or the net-shaped grid is covered with a sinterable layer of photoconductive powder, followed by a 7 / heat treatment is subjected, wherein the photoconductive powder to a layer with embedded wire or grid is sintered, after which the other side of the carrier, if necessary after removing wire parts this side, is provided with the second electrode and on the first side with the sintered layer the luminescent layer and the first electrode, optionally with the interposition of a thin one that shields the light Layer to be attached.