EP0019911A1 - Thermal-image pick-up target - Google Patents

Abstract

In the case of a rasterized thermal imaging plate, it is proposed to produce the rasterization by means of a line network of holes 1 or slots (2, 3, 5, 6), whereby the lateral heat conduction of the individual image elements to one another is kept low and a high image resolution is thereby achieved, but also that mechanical stability of the thermal imaging plate is maintained. An electrode layer (4) can easily be applied to the perforated but coherent surface. Use with thermal imaging devices, in particular with a pyroelectric thermal imaging tube.

Description

The invention relates to a thermal imaging plate which, via a physical conversion effect, generates a corresponding image of locally distributed property from the thermal radiation corresponding to a thermal image and incident locally distributed, e.g. a charge image via a pyroelectric effect, i.e. an image with locally distributed electrical charge, with a conversion layer that is screened to prevent lateral heat conduction and the associated image blur.

Such a thermal imaging plate serves in the most general sense as a receiver of a thermal image which is imaged on the plate via an optical device and generates a corresponding locally distributed temperature relief there by absorption and heating.

As an essential component, the thermal imaging plate has a conversion layer as a carrier of the temperature relief, which translates the temperature relief into a usable property. Depending on the material used, this can be a locally distributed charge relief via the pyroelectric effect mentioned, but also a voltage relief with respect to a base electrode via a thermoelectric effect, or an image of locally distributed electrical resistance via a thermoresistive effect. Not only electrical quantities as image content are conceivable; it can also be others such as a local distribution of the optical refractive index generated by the thermal radiation. Depending on the evaluability that is favorable for the respective use, the suitable effect will be selected.

Apart from a pure conversion of the thermal image into an image that is visible to the eye, the most common evaluation of the generated image is the scanning via a sharply focused electron beam in an image pickup tube, which generates an electrical signal corresponding to the time. This is then either saved or displayed as a visible image via a picture tube.

The build-up of the temperature relief through the thermal radiation imaged on the thermal imaging plate takes place according to an exponential function. There has to be one hand time be given enough to allow the T _e mperaturrelief can build up in the converting layer and enables a sufficient intensity of the image produced by the converting layer. On the other hand, the sharpness of the image is determined by the lateral thermal conductivity of the conversion layer or of the layers which are still present. The built-up local temperature differences have a tendency to flow into one another and thus reduce the image sharpness in accordance with the lateral thermal conductivity.

To reduce the lateral heat conduction and thus to increase the optical resolution, it is known and described, for example, in DE-OS 22 23 288, to rasterize the pyroelectric conversion layer of a pyroelectric image recording tube. The conversion layer then consists of a mosaic made of pyroelectric elements. which are separated from each other by a network of channels and attached to a thin support with low lateral thermal conductivity. The crosstalk of the individual pixels is reduced. It is disadvantageous, however, that the support is necessary for this case, where the channels run through the entire thickness of the reaction layer and the individual grid elements have to be held together. With its low lateral thermal conductivity, this also has a heat capacity which reduces the sensitivity of the reaction layer.

In contrast, the present invention is based on the object of providing the grid of the conversion layer in such a way that sufficient mechanical stability is achieved within the conversion layer, but a separate carrier layer as a support film is not necessary.

• a) die Rasterung wird erreicht durch Löcher in der Umsetzschicht;
• b) die Löcher sind voneinander getrennt;
• c) die Löcher sind in einem Netz von Linien angeordnet, dessen Maschen regelmäßige Vielecke sind.

To achieve this object, the following features are proposed according to the invention in a thermal imaging plate of the type mentioned at the outset:

• a) the screening is achieved through holes in the conversion layer;
• b) the holes are separated from each other;
• c) the holes are arranged in a network of lines, the meshes of which are regular polygons.

The holes can be designed differently. It is essential that the grid elements lying in the mesh of the line network are not completely separated from one another, i.e. that the entire reaction layer represents a coherent body with sufficient mechanical stability and breaking strength. ' By designing the holes, the lateral heat conduction can be restricted as desired.

For this purpose, according to an advantageous embodiment, it is provided that a plurality of holes are combined to form elongate slots which are separated from one another in the course of a line by remaining webs of the conversion layer. The holes separated from each other in this case are elongated holes.

On the one hand, there is the possibility that the webs are at the intersection points of the network lines, that is, where the grid elements in the network mesh are connected to one another via webs at each intersection point.

Another possibility is not to make this identical for each crossing point, but to carry out a structure in such a way that there is a web at each crossing point of the network lines, the slots in the course of a line each extending over at least two meshes and the successive slots webs separating this line are each interrupted by a slot of a crossing line.

In addition, there is also the possibility, in order to increase the mechanical strength, that the holes or slots do not extend from one surface side of the conversion layer to the other side, so that this other side has a closed surface.

A great advantage of a thermal imaging plate according to the invention proves itself in those applications where a continuous signal electrode is required for an electrical reading of the thermal image. This is the case, for example, with the target of a pyroelectric image pickup tube, where the slotted surface side advantageously faces the incident heat radiation. Then the slots can be very narrow; there is no need to consider the scanning electron beam, which then has a continuous surface side facing it. But the slotted surface side must have a continuous sig wear electrode, which is very difficult to apply in the known slotting with continuous channels. In the case of a thermal imaging plate according to the invention, however, there is a perforated but coherent surface which can easily be covered with a continuous conductive electrode layer.

For this purpose, it is then also proposed in a further development of the thermal imaging plate according to the invention that it carries an electrically conductive layer as a signal electrode on that surface side which faces the incident thermal radiation and is used as a target in an imaging tube and further preferably made of pyroelectric or thermoresistive material.

• Fig. 1 die Draufsicht einer Wärmebildaufnahmeplatte mit Lochreihen, die
• Fig. 2 eine schräge Ansicht einer Wärmebildaufnahmeplatte mit durchgehenden Schlitzen, die
• Fig. 3 eine solche mit nicht durchgehenden Schlitzen und die
• Fig. 4 die Draufsicht auf eine Wärmebildaufnahmeplatte mit einer besonderen Schlitzstruktur.

The invention is to be further explained on the basis of four exemplary embodiments shown in the figures of the drawing. The show

• Fig. 1 is a plan view of a thermal imaging plate with rows of holes, the
• Fig. 2 is an oblique view of a thermal imaging plate with continuous slots, the
• Fig. 3 such with non-continuous slots and the
• Fig. 4 is a plan view of a thermal imaging plate with a special slot structure.

1 shows a section of a top view of a thermal imaging plate according to the invention from for example pyroelectric triglycine sulfate single crystal. A grid is formed by holes 1 being drilled in the thermal imaging plate along the lines of a square mesh-forming network. The layer prisms in the mesh with a square collecting area represent the picture elements of the thermal imaging plate that are assigned to the individual pixels. The lateral conductivity present between the picture elements is set by the webs between the mutually adjacent holes 1. This lateral heat conduction can be kept small by a large number of holes per mesh.

An arrangement according to FIG. 2 is better, where the holes are expanded into elongated holes or slots 2. Compared to the rows of holes, all but the webs remaining on the knots fall away. The lateral heat conduction between the picture elements is very low. Sufficient breaking strength can be guaranteed by the coherent laminate. The thermal imaging plate is sufficiently self-supporting.

FIG. 3 shows the design of a thermal imaging plate according to the invention, where a grid of rows of slits with remaining webs is provided on the mesh knots, but where these slits 3 do not pass through the entire layer thickness. This creates a continuous sub-layer at the bottom of the slots 3. It is also shown for example for the Ver used as a target in an image pickup tube is an applied to the slotted surface side for heat radiation permeable and electrically conductive layer 4 made of, for example, chromium-nickel or titanium, which serves as a signal electrode.

4 shows a special slit structure. Rows of slots intersect in the manner of rows and columns and form square meshes. The slots 5 of the rows and the slots 6 of the columns each extend over two mesh sides. However, they overlap in such a way that a web is slit between two row slots 5 through a column slot 6 and vice versa. Due to such a structure, there is only a narrow web between adjacent grid elements for possible lateral heat conduction. Diagonal lateral heat conduction is almost completely prevented. However, the material relationship is sufficient for the mechanical strength of the entire thermal imaging plate. The formation of continuous fault lines is largely prevented.

Claims (8)

1.Thermal image recording plate, which generates a corresponding image of locally distributed property via a physical conversion effect from the thermal radiation corresponding to a thermal image and incident locally distributed, such as, for example, via a pyroelectric effect a charge image, ie an image with locally distributed electrical charge, with a conversion layer which is used for Preventing lateral heat conduction and the associated image blurring is characterized by the following features: a) the screening is achieved through holes (1) in the reaction layer; b) the holes (1) are separated from each other; c) the holes (1) are arranged in a network of lines, the meshes of which are regular polygons. 2. Thermal imaging plate according to claim 1, characterized in that in each case a plurality of holes (1) are combined to form elongate slots (2, 3, 5, 6) which are separated from one another in the course of a line by remaining webs of the conversion layer. 3. Thermal imaging plate according to claim 2, characterized in that the webs are each at the intersection of the network lines. 4. Thermal imaging plate according to claim 2, characterized in that at each crossing point of the network lines there is a web, the slots (5, 6) extending in the course of a line in each case over at least two meshes and the successive slots (5 and 6) webs separating this line are each interrupted by a slot (6 or 5) of a crossing line. 5. Thermal imaging plate according to one of claims 1 to 4, characterized in that the holes (1) or slots (3) starting from a surface side of the conversion layer do not go through to the other side, so that this other side has a closed surface. 6. Thermal imaging plate according to one of claims 1 to 5, characterized in that it carries on the surface side which faces the incident heat radiation, an electrically conductive layer (4) as a signal electrode and is used as a target in an imaging tube. 7. Thermal imaging plate according to claim 6, characterized in that it consists of pyroelectric material. 8. Thermal imaging plate according to claim 6, characterized in that it consists of thernoresistive material.

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