CN212258933U - Inductive coupling isolator, high-voltage signal acquisition system and industrial control system - Google Patents

Inductive coupling isolator, high-voltage signal acquisition system and industrial control system Download PDF

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CN212258933U
CN212258933U CN202021422371.6U CN202021422371U CN212258933U CN 212258933 U CN212258933 U CN 212258933U CN 202021422371 U CN202021422371 U CN 202021422371U CN 212258933 U CN212258933 U CN 212258933U
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data
side controller
coding
termination signal
decoding circuit
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翟理
王建国
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Hangzhou ruimeng Technology Co.,Ltd.
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Hangzhou Ruimeng Technology Co ltd
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Abstract

The application discloses an inductive coupling isolator, a high-voltage signal acquisition system and an industrial control system. Wherein, the inductive coupling isolator includes: the first coding and decoding circuit is used for transmitting first data to the second coding and decoding circuit through the coupling inductance pair when receiving a first starting signal; when receiving the first termination signal, stopping sending the first data to the second coding and decoding circuit, and informing the non-isolated side controller to prepare to send the second data; the second coding and decoding circuit is used for receiving the first data, informing the non-isolation side controller to prepare to send second data when receiving the first termination signal, and transmitting the second data to the first coding and decoding circuit through the coupling inductor pair; and when the second termination signal is received, stopping sending the second data to the first coding and decoding circuit, and informing the isolation side controller to send the data of the next period by using the second termination signal.

Description

Inductive coupling isolator, high-voltage signal acquisition system and industrial control system
Technical Field
The utility model relates to an isolator technical field, in particular to inductive coupling isolator, high-voltage signal acquisition system and an industrial control system.
Background
In the field of industrial control, there are many industrial electrical systems that operate at currents as high as hundreds of amperes, which can create large instantaneous surge currents between the power supply and ground and cause significant damage to electrical control equipment. In the prior art, in order to collect and control data signals in an industrial electrical system, an isolator is usually used to isolate a high-voltage system with a large surge current from a low-voltage system with a small surge current, and an independent power system and an independent ground wire are respectively used on two sides of the high-voltage system and the low-voltage system, so that only digital signals can be transmitted between the high-voltage system and the low-voltage system. The side where the high-voltage system is located is referred to as a non-isolated side, and the side where the low-voltage system is located is referred to as an isolated side.
There are roughly 3 types of isolators currently on the market, namely, an optical coupling isolator, a capacitive coupling isolator, and an inductive coupling isolator. The optical coupling isolator has the advantages of large power consumption, low signal frequency and short service life, and cannot perform bidirectional data transmission; the capacitive coupling isolator has a complex circuit structure and a large chip area, can couple a certain isolated side instantaneous voltage to a non-isolated side, and is inferior to an optical coupling isolator in voltage withstanding property; the inductive coupler is a mainstream structure of the current data isolator because the inductive coupler has better voltage withstanding characteristic, longer service life and a simple coding and decoding circuit.
In the process of isolating the non-isolated side and the isolated side by using the inductive coupling isolator, as the isolated side and the non-isolated side cannot directly perform data bidirectional transmission, two pairs of coupling inductor pairs are required for data transmission between the isolated side and the non-isolated side, that is, a pair of coupling inductor pairs is required for data transmission from the non-isolated side to the isolated side, and the other pair of coupling inductor pairs is required for data transmission from the isolated side to the non-isolated side. At present, no effective solution exists for the technical problem.
Therefore, how to reduce the space volume occupied by the inductive coupling isolator to widen the application range of the inductive coupling isolator in practical production is a technical problem to be solved by those skilled in the art.
SUMMERY OF THE UTILITY MODEL
In view of this, the present invention provides an inductive coupling isolator, a high voltage signal acquisition system and an industrial control system to reduce the required space volume occupied by the inductive coupling isolator and widen the application range of the inductive coupling isolator in the actual production. The specific scheme is as follows:
an inductively coupled isolator comprising:
the first coding and decoding circuit is used for transmitting first data sent by the isolation side controller to the second coding and decoding circuit through the coupling inductor pair when receiving a first starting signal sent by the isolation side controller; when a first termination signal sent by the isolation side controller is received, stopping sending the first data to the second coding and decoding circuit, and informing a non-isolation side controller to prepare to send second data by using the first termination signal;
one inductor of the coupling inductor pair is connected with the first coding and decoding circuit, and the other inductor of the coupling inductor pair is connected with the second coding and decoding circuit and used for transmitting data;
the second codec circuit is configured to receive the first data, and when receiving the first termination signal, notify the non-isolated side controller to prepare to send the second data, so that the non-isolated side controller inputs the second data to the second codec circuit and transmits the second data to the first codec circuit through the pair of coupling inductors; and when a second termination signal sent by the non-isolation side controller is received, stopping sending the second data to the first coding and decoding circuit, and informing the isolation side controller to send data of the next period by using the second termination signal.
Preferably, the number of turns, the shape and the material property of the two inductors in the coupled inductor pair are the same.
Preferably, the coupling inductor pair is an inductance transformer integrated on a chip.
Preferably, the pair of coupling inductors is embodied as a discrete transformer.
Preferably, the first codec circuit includes:
a first decoder for decoding data;
the first gating unit is used for closing the first decoder and opening the first encoder when the first starting signal is received; when the first termination signal is received, the first encoder is closed, the first decoder is started, and the non-isolated side controller is informed of sending the second data by the first termination signal;
and the first encoder is used for encoding the first data into a first pulse signal and sending the first pulse signal to the second encoding and decoding circuit through the coupling inductor pair.
Preferably, the first gating unit is a logic gate circuit.
Preferably, the second codec circuit includes:
a second decoder for decoding the first pulse signal into the first data;
the second gating unit is used for closing the second decoder and opening a second encoder when the first termination signal is received so as to send the second data to the first coding and decoding circuit; when the second termination signal is received, the second decoder is started, the second encoder is closed, and the isolation side controller is informed of sending data of the next period by the second termination signal;
the second encoder is used for encoding the second data into a second pulse signal and sending the second pulse signal to the first encoding and decoding circuit through the coupling inductor.
Correspondingly, the utility model also discloses a high-voltage signal acquisition system, include as aforementioned a disclosed inductive coupling isolator.
Correspondingly, the utility model also discloses an industrial control system, include as aforementioned a high-pressure signal acquisition system who discloses.
Therefore, in the utility model, when the first codec circuit receives the first start signal sent by the isolation side controller, the first data sent by the isolation side controller is sent to the second codec circuit through the coupling inductance pair; when a first termination signal sent by the isolation side controller is received, stopping sending the first data to the second coding and decoding circuit, and informing the non-isolation side controller to prepare to send the second data by using the first termination signal; when the second coding and decoding circuit receives the first termination signal for a certain time, the non-isolation side controller is informed to prepare to send second data, then the non-isolation side controller inputs the second data into the second coding and decoding circuit and transmits the second data to the first coding and decoding circuit through the coupling inductor pair; and when the second coding and decoding circuit receives a second termination signal sent by the non-isolation side controller, stopping sending the second data to the first coding and decoding circuit, and informing the isolation side controller to prepare to send data of the next period by using the second termination signal. Obviously, in the inductive coupling isolator provided by the utility model, the bidirectional data transmission of isolating side and non-isolating side can be realized by designing the receiving and sending data time sequence of the first coding and decoding circuit and the second coding and decoding circuit, and only one coupling inductance pair needs to be used in the process. Compared with the prior art that two pairs of coupling inductors are needed to realize the bidirectional data transmission of the digital signals at the isolation side and the non-isolation side, the space volume occupied by the inductive coupling isolator can be obviously reduced, and the application range of the inductive coupling isolator in actual production can be widened. Correspondingly, the utility model provides a high-pressure signal collection system and an industrial control system have above-mentioned beneficial effect equally.
Drawings
In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.
Fig. 1 is a structural diagram of an inductive coupling isolator according to an embodiment of the present invention;
fig. 2 is a structural diagram of another inductively coupled isolator according to an embodiment of the present invention;
fig. 3 is a timing diagram illustrating the operation of the inductively coupled isolator shown in fig. 2.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1, fig. 1 is a structural diagram of an inductive coupling isolator according to an embodiment of the present invention, the inductive coupling isolator includes:
the first codec circuit 10 is configured to, when receiving a first start signal sent by the isolation-side controller, transmit first data sent by the isolation-side controller to the second codec circuit 30 through the coupling inductor pair 20; when receiving a first termination signal sent by the isolated side controller, stopping sending the first data to the second codec circuit 30, and notifying the non-isolated side controller of preparing to send the second data by using the first termination signal;
a coupling inductor pair 20, one inductor of the coupling inductor pair 20 is connected to the first codec circuit 10, and the other inductor of the coupling inductor pair 20 is connected to the second codec circuit 30 for data transmission;
the second codec circuit 30 is configured to receive the first data, and when receiving the first termination signal, notify the non-isolated side controller to prepare to send second data, so that the non-isolated side controller inputs the second data to the second codec circuit 30 and transmits the second data to the first codec circuit 10 through the coupling inductor pair 20; when receiving the second termination signal sent by the non-isolated side controller, the controller stops sending the second data to the first codec circuit 10, and notifies the isolated side controller to send the data of the next period by using the second termination signal.
In this embodiment, a novel inductive coupling isolator is provided, by which the space volume required by the inductive coupling isolator can be significantly reduced, and thus the application range of the inductive coupling isolator in practical production can be widened.
Referring to fig. 1, a first codec circuit 10, a second codec circuit 30 and a coupling inductor pair 20 for data transmission are disposed in the inductive coupling isolator; the first codec circuit 10 is connected to the isolated-side controller for receiving the instruction signal sent by the isolated-side controller, and the second codec circuit 30 is connected to the non-isolated-side controller for receiving the instruction signal sent by the non-isolated-side controller. One of the pair of coupling inductors 20 is connected to the first codec circuit 10 and the other of the pair of coupling inductors 20 is connected to the second codec circuit 30.
Specifically, when the first codec circuit 10 receives a first start signal sent by the isolation-side controller, it indicates that the isolation-side controller is ready to send first data to the non-isolation-side controller, and in this case, the first codec circuit 10 transmits the first data sent by the isolation-side controller to the second codec circuit 30 through the coupling inductor pair 20; when the first data transmission in the isolation side controller is finished, the isolation side controller sends a first termination signal to the first codec circuit 10; when the first codec circuit 10 receives the first termination signal sent by the isolated-side controller, it will stop sending the first data to the second codec circuit 30, and will notify the non-isolated-side controller to prepare to send the second data by using the first termination signal, that is, the non-isolated-side controller needs to send the data to the isolated-side controller.
Correspondingly, when the second codec circuit 30 receives the first data transmitted through the coupling inductor pair 20, the first data is received and transmitted to the non-isolated side controller; when the second codec circuit 30 receives the first termination signal sent by the first codec circuit 10, the first termination signal is fed back to the non-isolated side controller, so that the non-isolated side controller is ready to send the second data to the isolated side controller, and then after the second codec circuit 30 receives the first termination signal for a certain time, the second data sent by the non-isolated side controller is sent to the first codec circuit 10 through the coupling inductor pair 20, so that the first codec circuit 10 sends the second data to the isolated side controller. When the non-isolated side controller finishes transmitting the second data, the non-isolated side controller sends a second termination signal to the second codec circuit 30, so that the second codec circuit 30 stops sending the second data to the first codec circuit 10, and meanwhile, the second codec circuit 30 also informs the isolated side controller to send the data of the next period by using the second termination signal sent by the non-isolated side controller.
It can be understood that, in the inductive coupling isolator provided in the present application, only the data transceiving logic of the first codec circuit 10 where the isolated side is located and the data transceiving logic of the second codec circuit 30 where the non-isolated side is located need to be designed and modified, so that the isolated side controller and the non-isolated side controller can perform bidirectional data transmission, and only one coupled inductor pair 20 is used in the inductive coupling isolator, compared with the prior art where two coupled inductor pairs are used to perform bidirectional data transmission of digital signals on the isolated side and the non-isolated side, the space volume required to be occupied by the inductive coupling isolator can be significantly reduced by such an arrangement manner.
In addition, the inductive coupler can also keep the advantages of the inductive coupler in the prior art, namely, the inductive coupler has simple modulation and coding mode, only needs to carry out coding transmission and decoding on the rising edge and the falling edge of data respectively, and has better inhibiting effect on middle and low frequency surge large voltage signals. In addition, after the space occupied by the inductive coupling isolator is reduced, the chip area and the design cost needed by the isolation side controller and the non-isolation side controller in the bidirectional data transmission process are greatly reduced, and therefore the application range of the inductive coupling isolator in actual production can be widened.
It can be seen that, in this embodiment, when the first codec circuit receives the first start signal sent by the isolation-side controller, the first data sent by the isolation-side controller is sent to the second codec circuit through the pair of coupling inductors; when a first termination signal sent by the isolation side controller is received for a certain time, stopping sending the first data to the second coding and decoding circuit, and informing the non-isolation side controller to prepare to send the second data by using the first termination signal; when the second coding and decoding circuit receives the first termination signal, the non-isolation side controller is informed to prepare to send second data, then the non-isolation side controller inputs the second data into the second coding and decoding circuit and transmits the second data to the first coding and decoding circuit through the coupling inductor pair; and when the second coding and decoding circuit receives a second termination signal sent by the non-isolation side controller, stopping sending the second data to the first coding and decoding circuit, and informing the isolation side controller to prepare to send data of the next period by using the second termination signal. Obviously, in the inductive coupling isolator provided in this embodiment, bidirectional data transmission on the isolated side and the non-isolated side can be achieved by designing the data receiving and transmitting timing sequence of the first codec circuit and the second codec circuit, and only one coupling inductor pair needs to be used in this process. Compared with the prior art that two pairs of coupling inductors are needed to realize the bidirectional data transmission of the digital signals at the isolation side and the non-isolation side, the space volume occupied by the inductive coupling isolator can be obviously reduced, and the application range of the inductive coupling isolator in actual production can be widened.
Based on the above embodiments, this embodiment further describes and optimizes the technical solution, and as a preferred implementation, the number of turns, the shape, and the material properties of the two inductors in the coupling inductor pair 20 are the same.
In the present embodiment, the coupling inductance pair 20 in the inductive coupling isolator is configured in a manner that the number of turns, the shape and the material property of the two inductances are the same, which is equivalent to configuring the coupling inductance pair 20 as an air-core transformer for one-to-one coupling voltage pulse, thereby ensuring the complete consistency of the electrical characteristics from the primary side to the secondary side and from the secondary side to the primary side in the coupling inductance pair 20.
Obviously, the technical scheme provided by the embodiment can further improve the overall working performance of the inductive coupling isolator in the using process.
Based on the above embodiments, this embodiment further describes and optimizes the technical solution, and as a preferred implementation, the coupling inductor pair 20 is specifically an on-chip inductor transformer.
The coupled inductor pair 20 may be configured as an on-chip inductor transformer according to the isolation withstand voltage requirement of the inductively coupled isolator during actual operation. For example: when the isolation withstand voltage of the inductive coupling isolator is required to be 3kV to 6kV, the coupling inductance pair 20 may be provided as an on-chip inductive transformer. Obviously, because the on-chip inductive transformer is relatively inexpensive, the design cost of the inductively coupled isolator can be relatively reduced by such an arrangement.
Based on the above embodiments, this embodiment further describes and optimizes the technical solution, and as a preferred implementation, the coupling inductor pair 20 is specifically a discrete transformer.
In the actual operation process, if the isolation withstand voltage value of the inductive coupling isolator is required to be more than 7kV, in this case, the coupling inductance pair 20 can be set as a separate transformer, so as to meet the actual application requirement of the inductive coupling isolator.
Obviously, by the technical scheme provided by the embodiment, not only can the design modes of the coupling inductor pair 20 be more flexible and diversified, but also the safety performance of the inductive coupling isolator in the use process can be further improved.
Based on the above embodiments, the present embodiment further describes and optimizes the technical solution, please refer to fig. 2, and fig. 2 is a structural diagram of another inductive coupling isolator provided by the embodiment of the present invention. As a preferred embodiment, the first codec circuit 10 includes:
a first decoder 101 for decoding data;
a first gating unit 102, configured to turn off the first decoder 101 and turn on the first encoder 103 when receiving the first start signal; when receiving the first termination signal, closing the first encoder 103, opening the first decoder 101, and notifying the non-isolated side controller to send the second data by using the first termination signal;
the first encoder 103 is configured to encode the first data into a first pulse signal, and send the first pulse signal to the second codec circuit 30 through the coupled inductor pair 20.
In the present embodiment, a specific implementation of the first codec circuit 10 is provided, that is, the first codec circuit 10 is provided with a first decoder 101, a first encoder 103 and a first gating unit 102; the working principle of the first encoder 103 and the first decoder 101 is well known to those skilled in the art, and therefore, detailed descriptions of the first encoder 103 and the first decoder 101 are omitted in this embodiment.
When the first gating unit 102 receives a first start signal sent by the isolation-side controller, the first gating unit 102 turns off the first decoder 101 and turns on the first encoder 103; after the first encoder 103 is turned on, the first encoder 103 may encode the first data transmitted by the isolated-side controller into a first pulse signal, and transmit the first pulse signal to the second codec circuit 30 through the coupled inductor pair 20. When the first gating unit 102 receives the first termination signal sent by the isolation-side controller, the first gating unit 102 turns off the first encoder 103 and turns on the first decoder 101, and notifies the non-isolation-side controller to send the second data by using the first termination signal. It is conceivable that the first decoder 101 is in a state of receiving data transmitted by the non-isolated side controller after the first encoder 103 is turned off and the first decoder 101 is turned on.
As a preferred embodiment, the first gating unit 102 is embodied as a logic gate circuit.
Specifically, in practical applications, the first gating unit 102 may be configured as a logic gate circuit, because the logic gate circuit has the advantage of relatively low manufacturing cost compared to other logic circuits having logic calculation function, and the logic executed by the first gating unit 102 is relatively simple, when the first gating unit 102 is configured as a logic gate circuit, not only the logic function requirement of the first gating unit 102 can be met, but also the design cost required by the first gating unit 102 can be relatively reduced.
As a preferred embodiment, the second codec circuit 30 includes:
a second decoder 301 for decoding the first pulse signal into first data;
a second gating unit 302, configured to turn off the second decoder 301 and turn on the second encoder 303 when receiving the first termination signal, so as to send the second data to the first codec circuit 10; when receiving the second termination signal, turning on the second decoder 301, and turning off the second encoder 303, so as to notify the isolated side controller of sending the data of the next period by using the second termination signal;
and the second encoder 303 is configured to encode the second data into a second pulse signal, and send the second pulse signal to the first codec circuit 10 through the coupling inductor.
In the present embodiment, a second codec circuit 30 corresponding to the first codec circuit 10 is provided, and a second decoder 301, a second gating unit 302 and a second encoder 303 are provided in the second codec circuit 30. In actual operation, in order to reduce the design cost of the second gating unit 302, the second gating unit 302 may also be configured as a logic gate circuit.
When receiving the first termination signal sent by the first codec circuit 10, the second gating unit 302 indicates that the first data has been transmitted, and at this time, the non-isolated side controller may send the second data to the isolated side controller, and in this case, the second gating unit 302 may close the second decoder 301 and open the second encoder 303; when the second encoder 303 is turned on, the second encoder 303 encodes the second data sent by the non-isolated side controller into a second pulse signal, and transmits the second pulse signal to the first codec circuit 10 through the coupling inductor pair 20; when the second gating unit 302 receives the second termination signal sent by the non-isolation side controller, it indicates that the second data sent by the non-isolation side controller to the isolation side controller has been completely transmitted, at this time, the second gating unit 302 will turn on the second decoder 301 and turn off the second encoder 303, and notify the isolation side controller that it is ready to send data of the next cycle to the non-isolation side controller by using the second termination signal. It can be understood that after the second decoder 301 is turned on and the second encoder 303 is turned off, the second decoder 301 is in a state of receiving the next cycle of data sent by the isolated-side controller, so that the data transmission process between the isolated side and the non-isolated side can be completed.
Obviously, the technical scheme provided by the embodiment can further improve the stability and reliability of the working performance of the inductive coupling isolator provided by the application.
Based on the technical content provided by the above embodiments, the present embodiment specifically illustrates the working principle of the inductive coupling isolator through a practical application scenario of the inductive coupling isolator. In the present embodiment, the inductively coupled isolator shown in fig. 2 is taken as an example for explanation, please refer to fig. 3, and fig. 3 is a timing diagram of the operation of the inductively coupled isolator shown in fig. 2.
When a first gating unit in the first coding and decoding circuit receives 3 continuous narrow pulses sent by an isolation side controller, that is, a first start signal, the first decoder is turned off, and the first encoder is turned on, in this case, first data sent by the isolation side controller is encoded into a first pulse signal through the first encoder, and in the process of encoding the first data, the first encoder converts a rising edge in the first data into a long pulse and converts a falling edge into a narrow pulse, and the first pulse signal is transmitted to a non-isolation side controller through a coupling inductor pair. It should be noted that, the pulse width of the 3 narrow pulses emitted by the isolation-side controller is T, and in the process of converting the first data into the first pulse signal, the duration of the long pulse is 5T, and the duration of the narrow pulse is 3T.
The second gating unit on the non-isolation side has the highest priority for the pulse transmitted by the coupling inductor pair, that is, as long as the coupling inductor pair has a rising edge to be transmitted to the second gating unit, the second gating unit immediately turns off the second encoder and turns on the second decoder, and informs the non-isolation side controller to prepare for receiving the first pulse signal transmitted by the isolation side controller. It should be noted that the second decoder on the non-isolated side is always turned on, and is not turned off unless a special end bit signal is asserted.
When the isolation side controller finishes transmitting all the first data, the isolation side controller sends 2 continuous pulses, namely a first termination signal, to the first gating unit, and when the first gating unit receives the first termination signal sent by the isolation side controller, the first gating unit starts the first decoder and closes the first encoder so as to prepare for the isolation side to receive the second data sent by the non-isolation side controller. Since the first encoder is turned on when the first termination signal enters the first gating unit, the first encoder encodes 2 consecutive pulses sent by the isolated-side controller into 4 pulses and transmits the 4 pulses to the non-isolated-side controller via the coupled inductor pair.
When the second gating unit on the non-isolation side receives the first termination signal, that is, 4 pulses, after a certain delay, the second gating unit turns off the second decoder and turns on the second encoder, and the second decoder restores the 4 pulse signals to the first termination signal to notify the non-isolation side controller of the preparation for sending the second data.
When the non-isolation side controller outputs second data, the second data is encoded into a second pulse signal through the second encoder, similarly, the second encoder converts a rising edge in the second data into a long pulse and converts a falling edge into a narrow pulse, and the second pulse signal is transmitted to the first coding and decoding circuit through the coupling inductor pair.
When the second data in the non-isolation side controller is completely transmitted, the non-isolation side controller sends a second termination signal to the second coding and decoding circuit, namely, the non-isolation side controller continuously outputs a long-time low level signal, and when the second gating unit detects a low level which is greater than N data periods, the second coder is closed and the second decoder is opened, so that the non-isolation side controller is ready for receiving the data sent by the isolation side controller in the next period.
It should be noted that the data transmission directions in fig. 3 are different, and for the upper half of fig. 3, the signal data enters from a and is output from D; for the lower half of fig. 3, it is from D in and a out. In this embodiment, the data signal period should be at least 5 times the longest pulse time, such as: when the first encoder requires a rising edge modulation of 4T, then the duration of one bit of data at high level or low level should be 20T, the width of 3 consecutive narrow pulses of the first start signal should be the minimum width of the inductively coupled isolator, and the width of 2 consecutive pulses of the first stop signal should be slightly larger than the longest positive pulse time of the first encoder, such as: 6T.
In addition, the second gating unit on the non-isolation side can judge the priority, so that when the second gating unit on the non-isolation side receives a pulse signal sent by the isolation side, if the high-voltage high-current electrical system on the non-isolation side triggers by mistake to generate 2 narrow pulses, the second gating unit can shield any request sent by the high-voltage high-current electrical system by taking the coupling inductor as the high priority for the sent pulses, and therefore the problem of data transmission errors of the non-isolation side in a severe high-power working environment is avoided, and the reliability of the inductive coupling isolator in the actual use process is further ensured.
Correspondingly, the embodiment of the utility model provides a high-pressure signal acquisition system is still disclosed, including as aforementioned a disclosed inductive coupling isolator.
The embodiment of the utility model provides a high-voltage signal acquisition system has the beneficial effect that an inductive coupling isolator that aforementioned open has.
Correspondingly, the embodiment of the utility model provides a still disclose an industrial control system, include as aforementioned a high-pressure signal acquisition system who discloses.
The embodiment of the utility model provides an industrial control system has the beneficial effect that aforementioned a high-pressure signal acquisition system disclosed has.
The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (9)

1. An inductively coupled isolator, comprising:
the first coding and decoding circuit is used for transmitting first data sent by the isolation side controller to the second coding and decoding circuit through the coupling inductor pair when receiving a first starting signal sent by the isolation side controller; when a first termination signal sent by the isolation side controller is received, stopping sending the first data to the second coding and decoding circuit, and informing a non-isolation side controller to prepare to send second data by using the first termination signal;
one inductor of the coupling inductor pair is connected with the first coding and decoding circuit, and the other inductor of the coupling inductor pair is connected with the second coding and decoding circuit and used for transmitting data;
the second codec circuit is configured to receive the first data, and when receiving the first termination signal, notify the non-isolated side controller to prepare to send the second data, so that the non-isolated side controller inputs the second data to the second codec circuit and transmits the second data to the first codec circuit through the pair of coupling inductors; and when a second termination signal sent by the non-isolation side controller is received, stopping sending the second data to the first coding and decoding circuit, and informing the isolation side controller to send data of the next period by using the second termination signal.
2. The inductively coupled isolator of claim 1, wherein the number of turns, shape, and material properties of both inductors of the coupled inductor pair are the same.
3. The inductively coupled isolator of claim 1, wherein the coupled inductor pair is in particular an on-chip inductor transformer.
4. The inductively coupled isolator of claim 1, wherein the coupled inductive pair is embodied as a discrete transformer.
5. The inductively coupled isolator of any of claims 1-4, wherein the first codec circuit comprises:
a first decoder for decoding data;
the first gating unit is used for closing the first decoder and opening the first encoder when the first starting signal is received; when the first termination signal is received, the first encoder is closed, the first decoder is started, and the non-isolated side controller is informed of sending the second data by the first termination signal;
and the first encoder is used for encoding the first data into a first pulse signal and sending the first pulse signal to the second encoding and decoding circuit through the coupling inductor pair.
6. The inductively coupled isolator of claim 5, wherein the first gating cell is specifically a logic gate circuit.
7. The inductively coupled isolator of claim 5, wherein the second codec circuit comprises:
a second decoder for decoding the first pulse signal into the first data;
the second gating unit is used for closing the second decoder and opening a second encoder when the first termination signal is received so as to send the second data to the first coding and decoding circuit; when the second termination signal is received, the second decoder is started, the second encoder is closed, and the isolation side controller is informed of sending data of the next period by the second termination signal;
the second encoder is used for encoding the second data into a second pulse signal and sending the second pulse signal to the first encoding and decoding circuit through the coupling inductor.
8. A high voltage signal acquisition system comprising an inductively coupled isolator as claimed in any one of claims 1 to 7.
9. An industrial control system comprising a high voltage signal acquisition system as claimed in claim 8.
CN202021422371.6U 2020-07-17 2020-07-17 Inductive coupling isolator, high-voltage signal acquisition system and industrial control system Active CN212258933U (en)

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