RU2769675C2 - Apparatus for transmitting information through a galvanic isolation barrier - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: invention relates to electrical engineering, in particular, to information and power converter equipment. The technical result is achieved due to the fact that electricity and information are transmitted through a single transformer, and the amplitude value of current of the primary winding of the transformer or the amplitude value of the reverse voltage thereon is used as an information carrier.

EFFECT: increase in the linearity and accuracy of transmitting a signal through a galvanic isolation barrier, reduction in the influence of interference, and expansion of the capabilities of the channel with the maintained low cost thereof.

4 cl, 3 dwg

Description

The invention relates to electrical engineering, in particular to information and power converting technology.

There are 4 main ways to create a galvanic isolation barrier between the information source and the control object - magnetic, capacitive, light and using a radio channel.

To transfer information through a galvanic isolation barrier (BGR), two channels are usually used - information and energy [1]. The energy channel provides the transfer of the necessary energy from the "receiver" of information through the BGR to the "transmitter" - the scheme for processing and transmitting information, which, using the received energy, transmits information through exactly the same BGR to the "receiver". In the practical implementation of this principle, specialized microcircuits are used [2, 3, 4].

The disadvantage of the classical principle of information transfer is the high cost of implementation, the difficulty of transferring information through a galvanic isolation barrier exceeding 5000 volts, and relatively high energy costs for the transfer of small amounts of information.

A cheap, simple and low-power device (prototype) is known that allows information and energy to be transmitted through just one transformer [5]. As practice has shown, it has the following disadvantages.

1. Non-linearity and low accuracy of analog signal transmission

2. Low noise immunity when transmitting both analog and digital signals.

3. Low bit rate of both analog and digital signal.

4. High energy consumption during the transmission of both analog and digital signals.

The purpose of the invention is to reduce energy consumption, increase the linearity and accuracy of analog signal transmission, as well as reduce the effect of interference and increase the transmission rate of analog and digital signals when information moves through the galvanic isolation barrier.

This goal is achieved by:

1. The device for transmitting information through the barrier of galvanic isolation, for transmitting an analog signal, includes a short voltage pulse generator connected to a circuit containing the primary winding of the transformer, information about the current through which it enters the amplitude detector, while the secondary winding of the transformer is connected to resistance, the value of which depends on the initial information.

2. The device according to claim 1, characterized in that the generator of short voltage pulses through a resistor is connected to the primary winding of the transformer, to which an amplitude detector is connected, which determines the amplitude of the reverse voltage surge on the primary winding of the transformer after the end of the short pulse caused by the energy stored in the inductance leakage of the transformer during the passage of a short pulse, and the secondary winding of the transformer is associated with resistance, the value of which depends on the initial information.

3. The device according to claim 1 or 2, characterized in that a device for compensating for non-linearity and increasing the accuracy of analog information transmission is installed at the output of the amplitude detector.

4. The device according to claim. 1, for transmitting a digital signal, contains a generator of short voltage pulses associated with a circuit containing the primary winding of the transformer, information about the amplitude of the current through which enters the signal processing unit, and the secondary winding of the transformer is connected to a switch, the resistance of which changes in accordance with the original digital information.

On FIG. 1 shows a simplified block diagram of a device for transmitting information through a galvanic isolation barrier for transmitting an analog signal, including a generator of short voltage pulses 1.1, connected to a circuit containing the primary winding of a transformer 1.2, information about the current through which is fed to the amplitude detector 1.3, while the secondary winding of the transformer 1.4 is connected with a resistance 1.5, the value of which depends on the initial information.

On FIG. 2 shows a simplified block diagram of a device for transmitting analog information through a galvanic isolation barrier. The generator of short voltage pulses 2.1 through a resistor 2.3 is connected to the primary winding of the transformer 2.2, with which the amplitude detector 2.4 is connected, which determines the amplitude of the reverse voltage surge on the primary winding of the transformer 2.2 after the end of the short pulse caused by the energy stored in the leakage inductance of the transformer during the passage of the short pulse , and the secondary winding of the transformer 2.5 is connected to the resistance 2.6, the value of which depends on the initial information.

On FIG. 3 shows a simplified block diagram of a device for transmitting information in digital form through a galvanic isolation barrier. The device contains a generator of short voltage pulses 3.1 connected to a circuit containing the primary winding of the transformer 3.2, information about the amplitude of the current through which enters the signal processing unit 3.3, and the secondary winding of the transformer 3.4 is connected to the switch 3.5, the resistance of which changes in accordance with the original digital information .

Work devices for transmitting information through the barrier of galvanic isolation as follows.

The device according to claim 1. A simplified block diagram of the device is shown in FIG. 1. A short voltage pulse from the generator 1.1, applied to the winding 1.2, causes the current to flow through the resistance 1.5 associated with the secondary winding 1.4 of the transformer. Amplitude detector 1.3 captures the maximum amplitude of the current pulse through the primary winding 1.2 of the transformer during the passage of a short voltage pulse from the generator 1.1. The maximum amplitude of the current through the primary winding 1.2 depends on the value of the resistance 1.5. The lower the resistance 1.5, the greater the value of the current through the primary winding 1.2 during the passage of a short pulse. Thus, information about the resistance value of 1.5 is transmitted through the galvanic isolation barrier. This device can be used to transmit information about the angle of rotation of a variable resistor, the temperature value from a temperature sensor, an audio signal from a carbon microphone, and from other primary sources of analog information.

The device according to claim 2. A simplified block diagram of the device is shown in FIG. 2. A short voltage pulse from the generator 2.1, through the resistor 2.3 is supplied to the primary winding 2.2 of the transformer. In this case, the lower the resistance 2.6 associated with the secondary winding 2.5 of the transformer, the greater the current reaches the primary winding 2.2 of the transformer during the action of a short pulse and the more energy is stored in the leakage inductance of the transformer. The more energy is stored in the leakage inductance of the transformer, the greater the amplitude of the reverse voltage surge on the primary winding 2.2 of the transformer associated with the amplitude detector 2.4. The lower the resistance 2.6, the higher the amplitude of the reverse voltage surge on the primary winding of the transformer after the end of the short pulse and the greater the output voltage of the amplitude detector 2.4. Thus, information about the resistance value of 1.5 is transmitted through the galvanic isolation barrier. This device can be used to transmit information about the angle of rotation of a variable resistor, the temperature value from a temperature sensor, an audio signal from a carbon microphone, and from other primary sources of analog information.

The device according to p. 3. The disadvantage of the devices according to p. 1 and p. 2 is the non-linearity and low accuracy of the transmission of analog information. To eliminate this drawback, a non-linearity compensation device and an increase in the accuracy of analog information transmission are installed at the output of the amplitude detector, which ensures the alignment of the transfer characteristic and increases the accuracy of matching the primary information to the output voltage.

The device according to claim 4. A simplified block diagram of a device for transmitting a digital signal is shown in FIG. 3. Short voltage pulses from the generator 3.1 are fed to the primary winding 3.2 of the transformer. In this case, the voltage from the secondary winding 3.4 is used to power the switch 3.5 and the source of primary information. For example, a temperature sensor with a digital output. The switch connects the load resistance to the secondary winding 3.4 of the transformer, increasing the maximum value of the current through the primary winding 3.2 of the transformer. The signal processing device 3.3 compares the value of the current through the secondary winding 3.2 of the transformer with the reference voltage, which is set so that when the switch 3.5 connects the load resistance, a logical zero appears, and when the switch disconnects the load resistance, a logical unit. With each short pulse, a logical zero or one is generated in the signal processing device 3.3, corresponding to the state of the load resistance connected or disconnected by the switch 3.5. In the simplest case, short pulses of the generator are unipolar; in a more complex case, the polarity of short pulses alternates. The operation of the switch is synchronized with short pulses and the signal processing device, as a result of which each logical zero or one from the primary source of information at the input of the switch corresponds to zero or one inside the signal processing device, at the output of which a digital code is formed. Thus, information from the primary source of digital information moves through the galvanic isolation barrier.

The device according to claim 1. The principal advantage of the proposed device in comparison with the prototype is that the information is transmitted not by the amplitude of the voltage, but by the amplitude of the current. Therefore, the influence of the leakage inductance of the transformer is reduced to almost zero, since the influence of the leakage inductance of the transformer is subtracted from the useful signal from the "ideal transformer". In this case, the amplitude detector determines the amplitude of the useful signal without parasitic components, since it captures the maximum current amplitude, and everything below this level does not affect it. In addition, the relative value of the useful signal at the input of the amplitude detector increases, which makes it possible to reduce the filter parameters, and thereby increase the information transfer rate.

The device according to claim 2. Due to the fact that the pulse from the generator can be very short, and the duty cycle is large, the energy costs for transmitting information through the galvanic isolation device are extremely small. This circumstance, together with simplicity, a small number of turns of the transformer and low cost, make this device the most preferable in a number of practical cases.

The device according to claim 3. A slight complication of the devices according to claim 1 and item 2 makes it possible to radically improve the accuracy and linearity of information transmission.

The device according to claim 4. This device combines digital accuracy, the ability to transmit information through a galvanic isolation barrier of tens of thousands of volts, ease of technical implementation, low cost and low energy consumption. Moreover, similar characteristics and reliability of analogues are worse at times.

Information sources

1. http://lpadevice.ru/products/galvanical/

2. https://efo.ru/products/integralnie-mikroshemi/mikroshemi-dlya-razvyazki.html

3. https://ryazan.terraelectronica.ru/news/5738

4. data sheet UCC12050.

5. RF patent No. 2420852.

Claims (4)

1. A device for transmitting information through a galvanic isolation barrier for transmitting an analog signal, including a generator of short voltage pulses associated with a circuit containing the primary winding of the transformer, information about the current through which it enters the amplitude detector, while the secondary winding of the transformer is connected to the resistance , information about the value of which is transmitted through the galvanic isolation barrier. 2. The device according to claim 1, characterized in that the generator of short voltage pulses through a resistor is connected to the primary winding of the transformer, to which an amplitude detector is connected, which determines the amplitude of the reverse voltage surge on the primary winding of the transformer after the end of the short pulse caused by the energy stored in the inductance leakage of the transformer during the passage of a short pulse, and the secondary winding of the transformer is associated with resistance, information about the value of which is transmitted through the galvanic isolation barrier. 3. The device according to claim 1 or 2, characterized in that a device for compensating for non-linearity and increasing the accuracy of analog information transmission is installed at the output of the amplitude detector. 4. The device for transmitting information through the barrier of galvanic isolation for transmitting a digital signal contains a generator of short voltage pulses connected to a circuit containing the primary winding of the transformer, information about the current amplitude through which enters the signal processing unit, and the secondary winding of the transformer is connected to a switch, the resistance of which changes in accordance with the information supplied to the switch in the form of a digital code.

Images