SU738605A1 - Multichannel electrocardiographic apparatus - Google Patents

Description

(54) MULTI-CHANNEL ELECTROCARDIOGRAPH

I

The invention relates to medical technology and is intended to record the potentials of the bioelectrical activity of the heart simultaneously in many leads, provided that the patient is electrically isolated from the ground and the current-carrying circuits of the electrocardiograph.

A multichannel electrocardiograph is known, which contains preamplifiers connected to electrodes, separation transformers, through which preamplifiers are connected to output amplifiers connected to corresponding recorder channels, and a shielding configured to be connected to a biological object by means of an electrode and covering preamplifiers along with windings of separation transformers connected to them 1.

The disadvantage of this electrocardiograph is the large interplay between the channels, due to the presence of parasitic connections between the windings of the transformers and the shielding.

The aim of the invention is to reduce the interplay between channels.

This goal is achieved by the fact that two shielding shells are additionally introduced into the device, one of which is connected to the preamplifier's zero potential bus and covers the primary windings of isolation transformers together with the preamplifiers connected to them, and the second is connected to the zero potential of the output amplifiers and covers the secondary windings of the isolation transformers together with the output amplifiers connected to them. The drawing shows a block diagram of a multi-channel electrocardiograph ..

Claims (2)

The device contains pre-amplifiers 1 and 2, connected to electrodes 3-6, separation transformers containing primary and secondary windings 7-10, respectively, output amplifiers 11 and 12, connected to a recorder 13, 20, shielding the shell 14 object 15 by means of an electrode 16, and two additional shielding shells 17 and 18. The device operates as follows. The biopotentials of the first channel removed by electrodes 3 and 4 are fed to the preliminary, amplified itel 1, and the biopotentials of the second channel, taken by electrodes 5 and 6, are fed to preamplifier 2. Power. Amplifiers 1 and 2 are supplied from a separate source with a transformer connection (not shown). The output voltages of amplifiers 1 and 2 are converted into voltage pulses of a carrier frequency and are applied to. primary windings 7 and 8 of isolation transformers. The amplitude modulated voltage of the carrier frequency is removed from the secondary windings of 9 T (T isolation transformers, detected by amplitude detectors - (not shown), amplified by output amplifiers 11 and 12, and recorded by the recorder 13. To reduce common-mode noise, preamplifiers 1 and 2 with primary windings 7 and 8 are covered by a shielding shell 14 connected to a biological object 15 by means of an electrode 16 with a transient resistance 19. On the secondary winding there are 9 times a separating transformer The carrier voltage operates modulated in amplitude by the bioelectric signal of the first channel, and this voltage causes current to flow through the circuit: the ungrounded output of the winding 9 - parasitic capacitance 20 - screen 14 - transient resistance of the electrode 19 - biological object 15 - capacitance 21 of the object on ground - ground 22 - grounded terminal of the winding 9. On the transition resistance 19, a voltage drop of the carrier frequency is formed, modulated in amplitude by the output voltage of the amplifier 1 of the first channel. The voltage drop across the transient resistance 19 is applied to the inputs of the amplifier 2 of the second channel as common-mode interference and causes current to flow through the circuit: transient resistance 23 of electrode 5 - capacitance 24 and transient resistance 25 of electrode 6 - capacitance 26. On transient resistances of electrodes 5 and 6 a voltage drop is formed, the difference of which acts on the input of amplifier 2 as a paraphase interference and is amplified by amplifier 2. Thus, at the input of amplifier 2 of the second channel of the electrocardiograph, an interference voltage acts The voltage of the carrier frequency of the first channel, which is a part of the amplitude-modulated bioelectrical signal, i.e. the parasitic interaction between the electrocardiograph channels is realized. To reduce this effect of the first channel on the second, you can reduce the capacitance 20 of the ungrounded output of the secondary winding 9 of the transformer with a shielding 14. In a similar way, the effect of the second channel on the first can be reduced by decreasing the capacitance 27 of the connection. This can be achieved by introducing additional shielding sheath 18, which covers the secondary windings 9 and 10 together with the output amplifiers II and 12 connected to them. On the primary winding 7 of the isolation transformer of the first channel, a non-dry frequency voltage modulated by the first-channel bioelectric potentials amplifier 1. This voltage causes current to flow through the circuits: winding terminal 7 - coupling capacitance 28 - shield 14 - parallel connection of capacitances 29 and 30 with successive centers n, including transition resistances 19, 23, and 25 with input resistances 31 and 32 of amplifier 2 of the second channel - zero potential bus 33 — second winding output 7. Voltage across capacitance 29 and 30 applied between zero potential amplifier bus 33 and screen 14; causes current to flow in the following circuits: resistance 19 - resistance 23 and 25 - input resistance 31 and 32, amplifier 2 bus 33 of zero potential - capacitance 30. On the transition resistance of electrodes 5 and 6, a voltage drop occurs, the difference of which affects the input of the amplifier 2 as a paraphase disturbance and amplified by amplifier 2. Thus, the input voltage of the amplifier 2 is influenced by the interference voltage, which is part of the amplitude-modulated bioelectric potentials of the carrier frequency of the first channel, i.e. The parasitic effect of the first channel on the second channel. This effect can be reduced by decreasing the communication capacitance 28. Similarly, the influence of the second channel on the first can be reduced by decreasing the capacity of the communication 34. This can be achieved by introducing an additional shielding shell 17 connected to the zero potential bus of the preamplifiers and covering the primary windings 7 and 8 together with the amplifiers 1 and 2. Resistors 35 and 36 are transient resistances of electrodes 3 and 4. Resistors 37 and 38 are input resistances of amplifier 1, and capacitances are 39-44 parasitic leakage capacitances. The use of the above-described system of two additional screens allows to significantly reduce interference from the interplay between the channels of the electrocardiograph, due to the presence of parasitic connections between the windings of separation transformers and the shielding connected to the patient. In the model of a three-channel electrocardiograph, made in accordance with the above description, the use of two additional screens reduced the interference from the channels between the channels by about 40 dB. Such a reduction in interference from channel interferences improves the accuracy of measuring the teeth and waves of the electrocardiogram, especially its low-voltage elements, which, in turn, improves the accuracy of diagnostics. Claims of the invention A multichannel electrocardiograph containing preamplifiers connected to electrodes, isolation transformers, through which preamplifiers are connected to output amplifiers connected to the corresponding recorder channels, and a shielding made with the possible connection to a biological object by means of an electrode and. encompassing preamplifiers together with the windings of separation transformers connected to them, characterized in that in order to reduce the interconnection between the channels, two shielding shells are added, one of which is connected to the preamplifier's zero potential bus and covers the primary windings of isolation transformers together with ..... connected to them preamplifiers, and the second is connected to the zero potential bus of the output amplifiers and covers the secondary circuits coils of isolation transformers together with output amplifiers connected to them. Sources of information taken into account in the examination 1. US Patent No. 3868948, cl. 128-2.06, published. 1975 (prototype). / 5 J  / 6 5 6