DE19802816A1 - Image recording apparatus with image recording chip - Google Patents

Abstract

The apparatus includes light sensitive cells provided by an recording chip (14) forming a sensor field. An image window (5) masks the sensor field and screens the surroundings of the sensor field especially against infrared radiation. Preferably, the image recording chip is a CMOS sensor with logarithmic convertible light sensitive cells. The image window is arranged at the end of the body of a tube (1) which is turned to the imaging plane. The tube chamber encloses the optical path of the recording lens at the image side.

Description

The invention relates to an image recording device, the to capture the imaging rays Chip with a variety of photosensitive cells having.

In known image recording devices, the image is on acceptance chips arranged in the imaging plane that both the light sensor used for image recording union cells as well as their environment, e.g. B. the bond field of imaging chips from the imaging Irradiation can be detected. In particular, highly dynamic photosensitive cells such as logarithmic converting MOS sensors are highly susceptible to any kind of disturbing radiation, so that when they occur the Quality of the images to be recorded is at risk.

The object of the invention is one of disruptive radiation largely free arrangement of the image recording chips in Image recorder.

According to the invention, this is achieved by taking measures corresponding to Main claim achieved. Appropriate designs are the subordinate claims.

The invention is illustrated and described on hand Exemplary embodiments explained. Show it

Fig. 1 shows an arrangement for image recording in the section AA,

Fig. 2 is an enlarged representation of the arrangement of the image sensing chips,

Fig. 3 is the rear view of the arrangement and

Fig. 4 is a representation with stereo attachment.

The preferably metallic tube body 1 is provided in a housing of an image recording device (not shown ) (see FIG. 1). On the front of the tube body 1 is the lens plate 2 , in which a lens 3 is expediently exchangeably attached. The image-side beam path of the taking lens 3 is enveloped by a preferably tapered tube space 4 . The tube space 4 ends with an image window 5 near the imaging plane.

The threaded bolts 6 , which carry the printed circuit board 7, are fastened in the tube body 1 outside the picture window 5 . The threaded bolts 6 protrude through openings 8 in the printed circuit board 7 (see FIG. 2). The openings 8 are designed to be significantly larger than the diameter of the threaded bolts 6 . On the side of the circuit board 7 facing the tube body 1 , each threaded bolt 6 is provided with a flange-like ring 10 against which a helical spring 11 presses. This will possibly thread play between the threaded bolt 6 and the tube body 1 ineffective. On the side of the circuit board 7 facing away from the tube body 1 , each threaded bolt 6 carries a lock nut 12 . Between each lock nut 12 and the circuit board 7 there is a disk 13 , the outside diameter of which is larger than the corresponding opening 8 in the circuit board 7 . A further disk 13 is provided between each ring 10 and the printed circuit board 1 . The disks 13 are suitably made of a material with good electrical and / or thermal conductivity.

On the tube body 1 facing side of the circuit board 7 , the image recording chip 14 is attached, preferably glued on. Arranged in the manner of a two-dimensional array, the photosensitive cells 15 of the image recording chip 14 form the sensor field receiving the imaging rays in the imaging plane. The sensor field is masked in a frame-like manner by the image window 5 , the surroundings of the sensor field or the surroundings of the image-recording light-sensitive cells 15 , in particular the bonding region 16 of the image recording chip 14 , being shielded against undesired irradiation by infrared light.

The light-sensitive cells 15 used for image recording are advantageously covered by an image-neutral glass plate 17 , which is also cemented neutral to the front surface of the image recording chip 14 receiving the imaging rays. To hide an undesired spectral range, the glass plate 17 can be designed as an optical filter.

The surroundings of the image recording chip 14 , which at least encompass the bond area 16 , are covered with an electrically insulating casting compound 18 . About this potting compound 18 , a metal-containing and expediently elastic potting material 19 is placed, which is in thermally conductive connection with the circuit board 7 and with the metallic tube body 1 .

Positioning arms 20 and holding arms 21 are provided on tube body 1 (see FIG. 3). Positioning screws 22 are arranged in the positioning arms 20 and lie at one end on the printed circuit board 7 . The positioning screws 22 can be moved by turning in the direction of the arrows 24 . On the holding arms 21 leaf springs 23 are BEFE Stigt which screw the circuit board 7 against the positioning 22 press.

In the tube body 1 bores 25 are also provided for fastening gene optical accessories. For example (see FIG. 4), columns 26 are inserted into the bores 25 , which carry a stereo attachment 27 .

As a result of the metallic image window 5 provided near the imaging plane, the quality of the image recording is disrupted by irradiation of the surroundings of the sensor field with in particular infrared light. Unwanted operating heat is dissipated from the printed circuit board 7 into the tube body 1 via the metal-containing potting material 19 . This derivation is supported by metallic disks 13 , threaded bolts 6 and leaf springs 23 .

By means of an adjusting device, which is essentially characterized by the threaded bolts 6 and the lock nuts 12 , the image recording chip 14 can be aligned parallel to the imaging plane in such a way that the plane of the sensor field coincides with the imaging plane.

The image recording chip 14 is aligned after loosening the lock nuts 12 by turning the threaded bolts 6 , as a result of which the image recording chip 14 together with the circuit board 7 carrying it can be tilted relative to the imaging plane. The coil springs 11 suppress any thread play between the threaded bolt 6 and the tube body 1 . When adjustment is complete, the position of the circuit board 7 is locked with the lock nuts 12 .

A positioning device for moving the image recording chip 14 parallel to or in the imaging plane is essentially formed by the positioning screws 22 and the leaf springs 23 . By turning the positioning screws 22 , the circuit board 7 with the image recording chip 14 is moved parallel to the image window 5 . The openings 8 , which are significantly larger than the threaded bolts 6, permit this displacement of the printed circuit board 7 . The leaf springs 23 ensure that the printed circuit board 7 is constantly touched with the positioning screws 22 . Advantageously, a stereo header 27 may be between the partial images existing parting line in accordance with the optical axis of the taking lens 3 associated with this positioning during use.

The invention is not limited to the illustrated and described embodiment. It is conceivable not only to design an image window by appropriate shaping of the end of the tube space 4 facing the imaging plane, but also by a frame which surrounds the sensor field of the image recording chip 14 as a separate component. It is particularly important that masking covers the surroundings of the image-recording sensor field against radiation, in particular with infrared light. The intended positioning and positioning devices can also be used with image recording devices regardless of masking of the sensor field.

Claims (9)

1. An image recording device which has an image recording chip with a large number of light-sensitive cells for detecting the imaging rays, characterized in that the photosensitive cells ( 15 ) used for image recording form a sensor field and an image window masking this sensor field ( 5 ). is provided, which shields the surroundings of the sensor field, in particular against infrared radiation. 2. Image recording device according to claim 1, characterized in that the image recording chip ( 14 ) is a CMOS sensor with logarithmically converting photosensitive cells ( 15 ). 3. Image recorder according to claim 1 or 2, characterized in that the image window ( 5 ) at the imaging plane facing end of a tube body ( 1 ) is arranged, which surrounds with its tube space ( 4 ) the image-side beam path of the taking lens ( 3 ). 4. Image recorder according to claim 3, characterized in that on the tube body ( 1 ) a the image recording chip ( 14 ) carrying circuit board ( 7 ) is mounted in a variable position, and that an adjusting device ( 6 , 12 ) for congruent alignment of the plane of the sensor field with the imaging plane and a positioning device ( 22 , 23 ) for moving the sensor field in the imaging plane are provided. 5. Image recording device according to claim 4, characterized in that the circuit board ( 7 ) via metallic components of the actuating device ( 6 , 12 ) with a metallic tube body ( 1 ) is in a heat-conducting connection. 6. Image recording device according to claim 4, characterized in that the circuit board ( 7 ) outside of the electrically insulated and at least the bonding area ( 16 ) comprise the surroundings of the sensor field via a preferably elastic and metal-containing potting material ( 19 ) with a metallic tube body ( 1 ) in is a thermally conductive connection. 7. Image recording device according to one of claims 4 to 6, characterized in that the tube body ( 1 ) has suitable means ( 25 ) for attaching an optical attachment ( 28 ) for stereo images. 8. Image recorder according to one of the preceding claims, characterized in that the sensor field is covered by an image-neutral glass plate ( 17 ) which is also cemented neutral with the active front surface of the image recording chip ( 14 ). 9. An image recording device according to claim 8, characterized in that the glass plate ( 17 ) is an optical filter for fading out an undesired spectral range.