DE2125787A1 - Arrangement for monitoring a bio function-controlled triggering device for a workplace for X-ray function diagnostics - Google Patents

Description

arrangement for monitoring a biofunction-controlled release device For a workstation for X-ray function diagnostics The invention relates to a Arrangement with the help of which the monitoring of a release device controlled by bio-voltages for a workstation to carry out the X-ray function diagnostics is possible.

In the X-ray functional diagnostics is in ever increasing measure the use of an increasing number of devices and facilities is required. To control one or more X-ray generators and the associated film or cassette changers or cinema cameras and high-pressure injection devices a cardiac phase controlled switch provided0 This cardiac phase controlled switch in turn is from a Biofunction, from the EKG, especially from the R-wave controlled by the heart phase.

It is known to use the cardiac phased switch that is used for examination required devices, in a chain according to the respective examination program put together, with a functional dependency between the individual devices consists. The first device in the chain is triggered with the help of an in the phase-controlled switch arranged switching stage made. The message the readiness of the individual devices in the chain is confirmed by a simple switch-on control taken soæ.

To increase the clarity during operation or to partially It is known to monitor the devices from a central control panel to control. The detention of the devices becomes the sequence of the examination program to the central control panel via the standby contacts in the individual devices like 1-det. The biofunction-controlled release device is ready with the Switching on this and only provides a switch-on control and does not constitute a functional check. It is easy to see that with these two known facilities, the readiness message has very little information content owns.

It is the purpose of the invention to show a possibility that one precise statement about the functionality of a release device for one Workplace for X-ray function diagnostics allowed.

The invention is based on the task of monitoring the The triggering device uses the BioSunction as a control signal for the triggering device to monitor0 The object is achieved according to the invention in that from the biofunctional voltage after reshaping in processing stages and / or in impulse formers a pulse voltage for controlling a control circuit is obtained, which at approximately constant frequency u «d / or amplitude of the pulse voltage and at pressed start button the activation of a switch for tripping of the examination program. The switch, in turn, is preset Criteria controlled in the course of the I pulse voltage. The input voltage, i.e. the Biofunctional voltage is initially used in processing stages or in pulse shaping circuits transformed into a needle-shaped pulse voltage. This needle-shaped pulse voltage serves to further control all subsequent circuits and to generate the Trigger command for the connected peripheral devices. As a result, only after a signal voltage is obtained after complete conversion of the biofunctional voltage, which is simultaneously fed to the control circuit for monitoring.

it is guaranteed that if the input signal or one of the Conversion stage no control signal to trigger the investigation pregrane is produced. In the control circuit is approximately the needle-shaped pulse voltage into a symmetrical Redhteck voltage and this in turn is converted into a DC voltage transformed into a work contact for tax infllg. This liget in series with the start button, making the circuit for the switch can be closed. To generate the symmetrical square-wave signal, it is advantageous to use the needle-shaped To convert the impulse voltage into a saw-like signal and this without direct voltage, 1.B. lit help of coupling through a capacitor on one. Limiter circuit to give which has such a bias that an approximately symmetrical Square-wave signal is present at the start.

This invention makes it possible to monitor the triggering device self-sufficient in that there is no output signal in the event of an error, as well as monitoring the rhythm of the biofunction to make @, The invention is to hand below an exemplary embodiment and a drawing are explained in more detail.

In the drawing, FIG. 1 shows a principle circuit diagram for monitoring Fig. 2 shows a grounding for generating a symmetrical square pulse In the pig. 1 is in the block diagram of the signal course between a Suslb device 1, a control circuit 2 and a central Schatfeld 3 by the drawn Arrows indicated. The triggering device 1 contains several signal processing stages 4. However, only one was shown in the figure. This is done with a biofunctional signal, z. B. controlled the body action tension. The EKG is taken from a patient 5 accepted. After the EKG has been processed, it goes to signal processing stage 4 this modified control signal 6 to a switching stage 7. The modified control signal 6 can e.g. B. be a needle-shaped pulse voltage. With the help of the needle-shaped Pulse voltage is controlled by a switch 8, which ultimately results in the analog solution of the Examination program via that central control panel 3 is made possible.

The output signal 11 arrives at a decoupling stage 10 Square-wave voltage generator 12. There, the output signal 11 emgeformt into an approximately symmetrical square-wave voltage of the same frequency. These symmetrical square wave voltage 13 is once directly to the central Control panel 3 to an optical display device, not shown in the figure guided.

Furthermore, the positive half-wools become the right tension 13 so extended by time that it is longer than the longest occurring period of the biofunctional signal. This time expansion takes place in a hold circuit 14. As a result, it supplies a DC voltage signal 15.

which is supplied to the central control panel 3. This is where the DC voltage signal takes place 15 in the wise application that a triggering of the examination program only when Presence of this DC voltage signal 15 is possible.

In the pig. 2 is an advantageous circuit for converting the output signal 11 shown in an approximately symmetrical square wave voltage 13. A transistor 16 is controlled by the output signal 11 and ont loads during each pulse a capacitor s7, which is charged via a resistor 18 in the pulse pauses will. A sawtooth voltage 19 also arises at transistor 16 relatively large amplitude. This is via a capacitor 20 on the basis of another Given transistor 21, which is thereby overdriven. Because of the positive tips the sawtooth voltage 19, the transistor 21 becomes conductive and causes during this time at the collector the right EC 13 has its minimum value while it is in the rest of the time is approximately equal to the supply voltage Ub. As a result of the strong Overdrive, the transistor 21 outputs the square-wave voltage 13 on the output side away. When the base voltage of transistor 21 is positive, a base current flows from the capacitor 20 cannot be supplied continuously, but only for a short time.

Therefore a direct current is supplied to the base via the resistor 22, which is as large as the time average of the base current during a period amounts to. The necessary size of the current through the resistor 22 depends on while which time, based on the period, the transistor 21 should be conductive sdn0 The resistor 22 is expediently chosen so that a symmetrical square-wave voltage 13 is generated.

Changes socj mim doe Freqiemz of the Aisgamgssignals 11> so changes also the frequency and the amplitude of the sawtooth voltage 190 Da but the on the period duration related to the time in which the transistor 21 is conductive, almost only from the resistor 22 with sufficient overdrive but not significantly from the sawtooth voltage 19 depends, the square wave voltage 13 remains approximately symmetrical.

This is important for the readiness display in the central scoreboard 3.

Because if the display by flacrn the optical display device takes place in the rhythm of the heart rate, the light and dark times must be independent of the frequency about the same length to use this display device with success to be able to.

Claims (5)

Claims 1. Arrangement for transferring a biofunction-controlled release device for a workstation for X-ray function diagnostics, characterized in that from the biofunctional voltage after the reshaping in processing stages and / or Pulse shaping circuits provide a pulse voltage for controlling a control circuit is obtained with an approximately constant frequency and / or amplitude of the Pulse voltage and, when the start button is pressed, the activation of a predefinable Criteria in the course of the pulse voltage responding switch to trigger the Examination program enables. 2. Arrangement according to claim 1, characterized in that the biofunctional voltage in the processing stages or pulse shaping circuits into a needle-shaped pulse voltage is reshaped. 3. Arrangement according to claim 1 and 2. characterized in that in the control circuit converts the needle-shaped pulse voltage into a symmetrical square-wave voltage and this is converted into a DC voltage to control an operating contact and the normally open contact in series with the start button the circuit to control the switch closes 0 4. Arrangement according to claim 1 to 3, characterized g * indicates that the square wave voltage is sent to an optical display device is led 5. Arrangement according to claim 1 to 4, characterized in that from the pulse voltage in the control circuit initially has an approximately sawtooth shape Signal is generated, which via a capacitor without DC voltage to a Inpulsformerstufe is given, which as a result of their limitation, a square wave signal supplies, which is approximately symmetrical due to the preload. Blank page