DE8908668U1 - Infrared detector - Google Patents

Description

· · I

Heimann GmbH GR 88 G 8582 DE

Infrared detector 5

The invention relates to an infrared detector with at least one detector element which is housed in a housing which has a window above the detector element which is permeable to infrared radiation.

An infrared detector of this type is shown in Fig. 1. It has a radio-opaque housing 1 in which two detector elements 2, 3 are arranged on ^a base plate 4. The detector elements 2, 3 arranged in a detection plane are usually oppositely connected. For impedance conversion, they are hermetically sealed in the housing 1 together with a field effect transistor and a bleeder resistor or two parallel diodes (components 10). The base plate 4 is tightly connected to the housing.

A window 6 that is transparent to infrared radiation and blocks radiation in the visible range is glued into an opening 5 of the housing 1. The ambient radiation reaches the detector elements 2, 3 through the window 6. The monitored Space can be divided into different detection segments using a mirror or lens optic. This arrangement enables the temporally separated imaging of moving objects onto the detector elements 2, 3. The size of the opening 5 and the distance and thickness of the window 6 result in the maximum angular range that the detector can detect. With infrared detectors without optics, a maximum detection range of 120* is possible.

To extend the angular range that the detector can detect, solutions are known (US-A-4 644 147) that extend the normal detection range by using optics. The mirrors located in front of the infrared detector

Tp 2 Ler / 15.07.1989

'..* i *-.'..' GR 88 G 8582 DE the detector elements are partially covered, which leads to a deterioration of the detector compensation and to a lower sensitivity in certain spatial directions.

The invention is based on the task of designing an infrared detector of the type mentioned at the beginning in such a way that a large spatial angle is achieved within which radiation is detected, whereby uniform radiation detection should be provided within the entire spatial angle. 10

This object is achieved according to the invention in that a second window permeable to infrared radiation is arranged on the housing side opposite the window and the detector element is held and connected in such a way that infrared radiation hits the detector element through both windows and generates an electrical signal in each case. The infrared detector according to the invention detects infrared radiation on two opposite sides and accordingly has a large solid angle within which radiation is detected. By means of suitable optics assigned to the underside of the detector, it is possible to detect an additional spatial area via the underside of the detector without disturbing the normal detection area to the front.

The invention is explained in more detail below using two exemplary embodiments shown in Figs. 2 and 3.

In Fig. 2 and 3, parts that are the same as parts in Fig. 1 are designated by the same reference numerals. The Bo The plate 4a, on which the detector elements 2, 3 are filtered with the interposition of a carrier plate 7, has an opening 8 in which a second window 9 permeable to infrared radiation is glued. The detector elements 2, 3 are thus contacted and connected to the other electrical components, which are shown schematically and designated 10, are connected together so that infrared radiation hits the detector elements 2, 3 through the two windows 6, 9 and each

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electrical signal is generated. The detector elements 2, 3 are hit by infrared radiation from the underside of the infrared detector through an opening 11 in the carrier plate 7. They are coated on both sides so that they absorb the incident infrared radiation.

A practical embodiment of the detector elements ?, 3 consists of two pyroelectric disks of size 2 × 1 mm ² and approximately 100 pm thick.

Due to the structure according to Fig. 2 and 3, radiation in an angular range of 60° can be received through the window 9 in the underside of the infrared detector in addition to the radiation through the window 6 in an angular range of 120°.

Fig. 3 shows that the angular range for the reception of infrared radiation through the window 9 can be extended by a mirror optic 12 under the infrared detector. This is particularly important when using the infrared detector as a switch or in an alarm device. The mirror optics 12 thus allows areas of the room to be detected that can only be reached through the window 6 by means of a mirror optics if other areas of the room are shaded. By using several mirror surfaces, the angle range within which the radiation data collection is divided into different segments.

Claims (4)

·■'··' '·>' k *..·..' GR 88 G 8582 DE Protection claims 1. Infrared detector with at least one detector element (2, 3) which is held in a housing (1) which has a window (6) permeable to infrared radiation above the detector element (2, 3), characterized in that a second window (9) permeable to infrared radiation is arranged on the side of the housing opposite the window (6) and the detector element (2, 3) is held and wired in such a way that infrared radiation strikes the detector element (2, 3) through both windows (6, 9) and generates an electrical signal in each case. 2. Infrared detector according to claim 1, characterized in that two detector elements (2, 3) lying in a detection plane are provided. 3. Infrared detector according to claim 1 or 2, characterized in that all detector elements (2, 3) have an infrared-absorbing coating on the sides that receive the infrared radiation. 4. Infrared detector according to one of claims 1 to 3, characterized in that an optic (12) is arranged in front of the lower window (9).