DE2919724C2 - Device for monitoring a rotating anode x-ray tube by means of optical scanning of the rotating anode by means of light emitted by the filament - Google Patents

Description

hen is and that with the help of the forked light guide (5) from the filament (1) of the cathode emitted light initially directed to the reflective surface (4) and from there to the photoelectric receiver (6) is fed.

2. Device according to claim 1 with a protective tube housing, characterized in that both the light guide (5) and the photoelectric receiver (6) within the tube protection housing are arranged.

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The invention relates to a device for monitoring a rotating anode X-ray tube by means of optical Scanning of the rotating anode by the light emitted by the filament of the cathode, with one on the rotating anode provided and moved with it light modulation device, with a reflective optical element having means for transmitting the light from? Filament on the light modulating device and of the modulated light to a photoelectric receiver arranged outside the tube piston and with means for displaying the operating status of the X-ray tube or for influencing the Heating and / or high voltage circuit of the X-ray generator.

Modern X-ray generators are equipped with overload protection devices for the X-ray tubes, which can be freely adjusted with the imaging Factors prevent the exposure from being triggered if the X-ray tube is overloaded. When monitoring rotating anode X-ray tubes, the over- Monitoring of the temperature of the anode plate in connection with the speed control of the rotating anode in the foreground.

It has long been known to determine the focal point temperature of the X-ray tube anode by the focal point eo monitor outgoing light radiation by transmitting it to a light-sensitive via an optical system Element is supplied which is arranged in a control circuit z. B. affects the X-ray tube current.

It is also known to use a light guide with an attached photoelectric element to detect the rotating anode temperature (DE-OS 20 31 590). This facility is proving itself however, inasmuch as it is not sufficient as it neither does Operation of the rotating anode X-ray tube when it is at rest Rotating anode still enables direct monitoring of the cathode heating. ,. .

A protective device is also already known at which the speed of rotation of the rotating anode, which has a reflective surface on its anode stem, thereby it is monitored that a light beam emitted by a lamp is reflected -and by a photocell in electrical impulses are converted, which are amplified and guided via a speed-dependent resonance element, actuate switching devices of the X-ray generator (DD-PS 2 507). However, this arrangement is only difficult to use in an oil-filled X-ray tube protection case, and with it only one is for one possible overloading of the X-ray tube to register decisive factors a but it is also known to detect several of the parameters influencing the operating conditions of an X-ray tube directly. So for a rotating anode x-ray tube is one

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known, with which both the anode speed and the condition of the hot cathode are to be determined directly in order to allow the application of the anode voltage to the X-ray tube only when the rotating anode has reached the correct speed and the filament has reached the correct operating temperature (US PS 32 14 589). Here, the anode plate is provided with a bore and, viewed from the hot cathode, behind the anode plate, a reflection surface is attached to the stator winding, which reflects the light radiation emitted by the cathode through the bore to a transparent exit window in the protective X-ray tube housing, behind the one Photo element is arranged for converting the light signals into electrical signals. The high voltage is switched to the X-ray tube as a function of the pulse frequency of these light signals, which are obtained by the rotation of the anodetizer functioning as a perforated disk. However, since the temperature of the entire rotating anode plate is extremely high during operation and, in particular in the area of the focal spot or the focal point path, values are achieved that are higher than those of the filament of the cathode, but the hole serving as a light modulation device is attached directly to the anode plate and Although in the immediate vicinity of the focal point path, the radiation components from the anode plate are not to be neglected and act as a significant source of interference, especially when working in series recording mode.

The invention is based on the object of providing a monitoring device for a rotating anode X-ray tube as described in the preamble of claim 1 to improve the named type in such a way that the recording of the parameters Katodenheszung and anode rotation of external interference becomes independent.

According to the invention, this object is achieved by that means for transmitting the light a forked light guide and as a light modulation device at least one reflective surface attached to the rotating anode rotor is provided and that with the help of the forked light guide from the filament of the cathode light emitted first on the Reflection surface directed and fed from there to the photoelectric receiver.

A structurally advantageous solution consists in this.

both the light guide and the photoelectric To arrange the receiver inside the protective tube housing.

Using a drawing in which a device for monitoring the speed of the rotating anode and the Cathode heating of a rotating anode X-ray tube is shown schematically, the invention is hereinafter explained in more detail. The rotating anode x-ray tube is through the filament 1 of the cathode as well as through the rotating anode 2 symbolizes. The latter shows the anode plate on one supporting part, such as the rotor 3 of a drive motor not shown here, at least one reflective surface 4 on. The arrangement of several reflection surfaces 4 on the circumference of the rotor 3 is to be achieved a higher pulse frequency possible. As the central is The element of the device is a Y-shaped forked light guide 5, which is on the one hand on the transmission side the filament 1 of the cathode and, on the other hand, on the one provided with the reflective surface (s) 4 Area of the rotor 3 is directed, while a phototransistor 6 mii downstream on the receiving side Evaluation elements works The device, which the speed measurement, in particular the control of the Rotating anode to the nominal speed with simultaneous monitoring of the function of the cathode heating serves, this is achieved in a simple manner in that the light guide 5 emits that from the filament 1 of the cathode Receives light and directs it to the reflective surface (s) 4 on the rotor 3. When rotating the rotating anode 2 Resulting light pulses are then arranged through the light guide 5 on the light exit side Photo transistor 6 supplied. In a downstream Counting circuit 7, the pulse sequence is evaluated and a switching amplifier 8 z. B. the high voltage circuit or the motor circuit of the rotating anode drive influenced. It is of course also possible to activate the function of the cathode heating or the rotation of the Rotating anode 2 can alternatively be indicated by an L / 0 signal. It is advisable to place the light guide 5 and the phototransistor 6 inside the oil-filled X-ray tube protective housing to arrange "to an oil-tight implementation of the light guide 5 through the X-ray tube protective housing to avoid. It is of course also possible to use the forked single light guide 5 to be replaced by two independent, forked light guides, with one light guide the optical connection between cathode and anode and with the other light guide the connection between Anode and photoelectric receiver is realized. It is also possible to further subdivide the Light guide 5 or use of an additional light guide directed at the rotating anode plate with a separate light guide Receiver the anode plate or spot temperature to monitor or derive a pause time determination for the X-ray tube from this.

The invention enables the monitoring of several more important for the operation of a rotating anode x-ray tube Parameters have a direct effect on the X-ray tube itself. This makes it particularly reliable and ensures reliable protection of the Rotating anode x-ray tube from overload.

For this purpose I sheet drawings

Claims (1)

Patent claims: 1. Device for monitoring a rotating anode tube by means of optical scanning of the Rotating anode (2) through the light emitted by the filament (1) of the cathode, with one on the rotating anode (2) provided and moved with it light modulation device, with a reflective optical element having means for transmitting the light from the filament (1) to the to Light modulating device and the modulated Light on, a photoelectric receiver (6) arranged outside the tube flask and with means for displaying the operating status of the X-ray tube or for influencing the heating and / or high-voltage circuit of the X-ray generator, characterized in that as Means for transmitting the light a forked light guide (5) and as a light modulation source at least one on the rotating anode