DE1789105A1 - Electronic mAs relay - Google Patents

Description

Electronic mAs Relay The invention relates to an electronic one mAs relay of an X-ray diagnostic apparatus that has a measuring capacitor, the one falling through the measuring resistor through which the X-ray tube current flows Voltage across a charging resistor and electronic ones in the charging circuit Elements is charged and which is connected to a switching element that is at a predetermined value of the voltage reached at the measuring capacitor, a switch-off signal for the X-ray machine.

As is known, the X-ray tube can only be loaded according to the nomogram. if the values for kV and mA are set and not switched off after the resulting time destruction of the tube is to be expected. About such tube damage to prevent when using an electronic mAs relay, according to the invention suggested that the recording button for triggering the X-ray exposure actuated, an auxiliary voltage is applied to the resistor through which the tube current flows that involves taking an x-ray with a corresponding shutdown of all components of the mAs relay is simulated and triggers a pulse that reacts to a bistable multivibrator given, the X-ray exposure via a relay releases and the measuring capacitor within the usually available synchronization time of the X-ray machine by short-circuiting it across a resistor, i.e. for makes the following X-ray operational. Through such training an X-ray machine with mAs relays will damage the X-ray tube Failure of one of the components of the mAs relay made impossible. In training the invention is the auxiliary voltage in which the pulse is obtained and the X-ray image must be released, only created for a defined period of time, this time depending on the charging time of the capacitor at a certain value of the Charging resistor is selected. This switching measure can be used to check whether the capacitor is not defective, d. H. any leakage currents the charging time of the capacitor and thus overload the tube.

If you were to test with the adjustable for different mAs values Carry out charging resistance, then strongly fluctuating times would result. One separately intended resistor, which is only switched on for testing, would turn exclude the charging resistor from the thorough test. For equal and short times for the thorough testing and the charging resistor also a test to undergo, it is suggested that for the pre-test the one for the different mAs values adjustable To divide the charging resistor into several groups and to connect them in parallel.

In the figure is a purely schematic embodiment of the Invention shown.

The distance between points 1 and 2 is determined by the rectified Tube current flowed through. This distance is usually in the grounded center point the high voltage winding. The resistor 3 is a resistor 4 in parallel and with this in series a variable resistor 5 in the form of a transistor. In The opening across the resistor 4 is dependent on the opening of the transistor Voltage different. In conjunction with the adjustable resistor 6, the has to be changed for the different mAs values, you get the charging current for by means of the capacitor 7. Via the voltage source 8, / the Zener diode 9, is to the base of the transistor 5 is a constant voltage and the transistor opened. The resistor 10 through which the tube current also flows, or the corresponding one Voltage drop counteracts this voltage and controls the transistor, so depending on the tube current, too. This enables a correction for small mA values achieved. At around 100 mA the transistor has a very high resistance and the Current flows through the resistor 11. The adjustable resistor 12 can be used to set the mA value from which the control of the transistor begins.

A resistor 13 is connected in series with the capacitor 7.

The voltage drop across this resistor is added to the charging voltage of the capacitor and together result in the defined cut-off voltage. Through this Resistance causes a short-term undermining.

In the device 14 is a feedback transistor circuit the slowly rising voltage of the capacitor 7 is converted into a pulse. This Pulse is given to input 15 of a bistable multivibrator 16. Over the line 17, the tilting stage 16 is given a defined position after each X-ray exposure. A relay 18, which takes the X-ray exposure, is controlled via the output of the flip-flop 16 for switching via the contactor 19 releases.

A test voltage is applied to the terminals 20, 21, which via the Contact 22 of a relay, not shown, is turned on. The same relay switches the contacts 23, 24 over. If all components are functional, an impulse is generated given to the bistable multivibrator. This enables the X-ray exposure. Simultaneously if contact 25 is briefly closed via another relay, the capacitor 7 discharged and thus made ready for the actual X-ray exposure.

By using electronic members, the pre-dead time is very great small amount.

- Patent clause -

Claims (3)

Claims 1.) Electronic mAs relay of an X-ray diagnostic apparatus, which has a measuring capacitor, which is connected to one of the X-ray tube current through the measuring resistor, the voltage drop across a charging resistor and in Charging circuit lying electronic elements is charged and with a Switching element is connected, which at a predetermined value of the measuring capacitor The voltage reached triggers a switch-off signal for the X-ray apparatus, characterized in that that actuated by the recording button for triggering the X-ray exposure to the an auxiliary voltage is applied to the resistor through which the tube current flows, an X-ray with a corresponding shutdown, including all Components of the mAs relay is simulated and triggers a pulse that reacts to a bistable Given flip-flop, releases the X-ray recording via a relay and the measuring capacitor within the usually existing synchronization time of the X-ray apparatus discharges by short-circuiting across a resistor, d. H. for the subsequent x-ray makes the recording operational. 2.) Electronic mAs relay according to claim 1, characterized in that that the auxiliary voltage is only applied for a defined time in which the pulse is obtained and the x-ray must be released, this time depending on the charging time of the capacitor at a certain value of the charging resistance will. 3.) Electronic mAs relay according to claims 1 and 2, characterized in that that for the pre-testing of the adjustable charging resistance for the different mAs values is divided into several groups that are connected in parallel.