DE2712352A1 - Defibrillator electrode testing circuit - has load resistance followed by rectifier bridge and measuring instrument with quenching switch - Google Patents

Abstract

Defibrillators for applying stimulation pulses to the heart, are tested on a circuit which has receiving electrodes (6, 7) for the defibrillator electrodes, across which is a load resistance (8) simulating the resistance of the human body. Across the electrodes is also a rectifier bridge (11) forming an integrator circuit, and connecting them to the measuring instrument (14). Across this is a quenching switch (13). An alternative design, designed to retain the test signals for a given time has the simulated resistance formed by two separate resistances, and the electrodes are connected by load resistances to a rectifier bridge. This is followed by an active integrator fed by a storage capacitor.

Description

Testing device for defibrillators

The invention relates to a testing device for defibrillators.

Defibrillators are used to eliminate ventricular fibrillation. the Electrodes provided on them are attached to the human body or directly attached to the exposed ## rz itself and deliver electrical impulses to the heart, which bring the heart and thus the ventricular fibrillation to a standstill, so that the Heart rate can start again undisturbed.

The power delivered by the defibrillator is generally below Presettable choice. To check the correct function and the selected presetting there is still no suitable device. The examination was generally carried out by the examining staff in the clinic according to those developed by these staff themselves or methods specified by the es creators. The ones used so far However, methods do not produce exact values, as is desirable for such devices were.

The object of the invention is to provide a testing device for defibrillators create, that by connection to the electrodes of the defibrillator a control and verification of the same back to the power source is permitted the test device according to the invention is intended to determine the exact values of the Allow energy emitted by electrodes.

The test device according to the invention is characterized by two attachment electrodes for the electrodes of the defibrillator, one connected via the attachment electrodes, The equivalent resistance simulating the human body and one connected in parallel to it Integrator circuit with voltage measuring device calibrated to energy values.

When triggering the defibrillator shows on the in the invention Test device provided by the SkB device a pointer deflection that slowly decreases again, but in its end position it is possible to read the energy released.

Since with many defibrillators the pulse voltage occurring on the patient often represents an alternating pulse voltage, is in lleiterbildung of the invention provided to incorporate a rectifier into the integrator circuit.

In order to create the possibility of several exams in quick succession without waiting for the pointer deflection on the measuring instrument to subside be nut, is proposed in a further embodiment of the invention, parallel to To put a delete button on the capacitor of the integrator circuit.

Since it can often be desirable, the final deflection of the # ßgerät To hold onto at least for a shorter period of time will be in further training the invention proposed that the equivalent resistor via at least one charging resistor and a rectifier, preferably in the form of at least one storage capacitor an electrolytic capacitor is connected, which feeds the integrator circuit, which in this case is designed as an active integrator.

In order to keep the test device according to the invention as cheap as possible, expediently a possible cheap integrator circuit is also used, but then this requires a symmetrical supply. Therefore, in further training the Invention proposed that the equivalent resistance in two equal partial resistances is divided and two connected one behind the other via a charging station lying storage capacitors are provided, the connection point of which with äem ~! the connection point of the partial resistors is connected and the symmetrical supply of the active integrator.

It is of particular advantage in the inventive test device, that a separate power supply is not required. The device works exclusively with the energy coming from the defibrillator, which not only shows the pointer deflection of the # ßinstrurentes supplies, but also recognizable by their size from the pointer deflection will. The invention is to be described in more detail below with the aid of two exemplary embodiments explained.

The drawings show in Fig. 1 a simple embodiment of the Test device and in Fig. 2 an embodiment in which care is taken is that the final deflection on the measuring device is retained for a short time.

The defibrillator, whose output circuit is reproduced in both Embodiments consisting of Iflduktiuität 1, capacitance 2 and energy switch 3 is shown, its electrodes 4 and 5 are drawn to the right of it Tester circuit connected.

The output circuit of the defibrillator is only chosen here as an example.

In principle, it is unimportant for the test device according to the invention. from Only the two electrodes to be connected to the test device are important 4 and 5. Electrodes 4 and 5 are placed on attachment electrodes 6 and 7, Via which a single equivalent resistor 8 is connected in the embodiment according to FIG. 1 that simulates the human body and is of the order of magnitude from for example 50 ohms is chosen.

From this equivalent resistor 8 is a via the resistors 9, 10 Rectifier 11 from this rectifier 11 becomes the capacitor 12 of the integrator circuit charged, parallel to which an ihschpaste 13 is connected. In addition, it is parallel to the capacitor 12, the measuring instrument 14, which is an energy value calibrated # tension measuring device. With 15 is a series resistor of the measuring device 14 and 16 indicated a trim resistor for the same.

When the eye button 13 is open and the electrodes 4, 5 are placed on the attachment electrodes 6 and 7 and when the defibrillator is actuated, the capacitor is charged 12, which is discharged again via the # ßinstrument 14. The # ßinetrunent shows first a rapid increase to the final value. Then the pointer stop sounds out again.

The delete button 13 can be used to quickly reset the pointer deflection be operated.

At the resistance 17 still drawn in the circle of the eye button it is just a simple current limiting resistor. In the The embodiment of FIG. 2 is the back rectifier 11 through the full wave rectifier 1 la and 1 1b replaced and the equivalent resistor 8 in two equal partial resistances 8a and 8b divided. The resistors 9 and 10 are a single resistor 9a summarized. The bridge rectifier 18 are two charging resistors 19 and 20 upstream. The output of the bridge rectifier is connected to the two storage capacitors 21 and 22 placed, which are connected in series and their junction 23 connected to the junction 24 of the two spare part resistors 8a and 8b is. The integrator resistor 9a is at the input of the active integrator 25, in whose negative feedback path of the integration capacitor 1 2a is connected to the Integraticnskondensator 12 corresponds in the embodiment of FIG. The measuring instrument 14a lies between the output of the integrator 25 and the connection point 23 of the two storage capacitors 21 and 22.

Here, too, a trimming for the measuring instrument is indicated again at 16a.

13a is again the delete key and 17a is its series resistor designated.

The components at 26 are used to correct the error of the active element and are not essential for the principle of the test device according to the invention Meaning.

Claims (5)

Claims 1. Test device for defibrillators, g e k e n n z e i c h n e t by two attachment electrodes (6, 7) for the electrodes (4, 5) of the defibrillator, one connected to the contact electrodes (6, 7) simulating the human body Equivalent resistor (8 or 8a, 8b) and a parallel integrator circuit with voltage device calibrated to energy values (14 or 14a). 2. Testing device according to claim 1, characterized in that it is e k e n n e i c h n e t that the integrator circuit incorporates a rectifier (11 or 1 1a, 1 1b) is. 3. Test device according to claim 1 or 2, g e k e n n z e i c h n e t through a parallel to the capacitor (12 or 12a) of the integrator circuit placed i cancel button (13 or 13a). 4. Test device according to claim 1, 2 and / or 3, characterized g e k e n n z e i c h -n e t that to the equivalent resistor (8a, 8b) via at least one charging resistor (19, 20) and a rectifier (18) at least you storage capacitor (21, 22) is connected, which feeds the integrator circuit, which acts as an active integrator (25) is formed. 5. Testing device according to claim 4, characterized in that it is e k e n n e i c h n e t that the equivalent resistance is divided into two equal partial resistances (8a and 8b) is and two connected via a charging resistor (19 and 20), one behind the other horizontal storage capacitors (21 and 22) are provided, their connection point (23) is connected to the connection point (24) of the partial resistors (8a and 8b) and which serve to symmetrically feed the active integrator (25).