DE102020001985A1 - AC / DC SWITCHING POWER SUPPLY WITH 10 MHZ TIME BASE - Google Patents

Abstract

An AC / DC switched-mode power supply with a 10 MHz time base consists of a master (10) and at least one slave (201), each of which has a time base generator (11, 211). With this time base generator (11, 211) a 10 MHz time base can be generated. The slave (201) has a selector switch (241), and when the master (10) is coupled to the slave (201), the slave (201) receives a time base from the time base generator (11) of the master (10) through the selector switch (241) ) in order to fully synchronize the time base of the slave (201) with the master (10) and to improve the output power quality of the AC / DC switched-mode power supply system.

Description

Technical area

The present invention relates to an AC / DC power supply, in particular an AC / DC switched-mode power supply system with a 10 MHz time base.

State of the art

AC / DC power supplies are divided into linear AC / DC power supplies and switching AC / DC power supplies according to their working principles and design structures. The basic structure of a linear AC / DC power supply consists of a linear amplifier with the first quadrant as DC, the first and fourth quadrants as AC and a bipolar DC power supply. If it is bidirectional DC power, these will be the first and second quadrants. Linear amplifiers are generally classified into A, B, AB, etc. and use the linear region of the network components. The basic working quadrant of the switching AC / DC power supply is the same as that of the linear AC / DC power supply except that the amplifier works with a D amplifier. The D amplifier as a changing operating mode has the advantage of high efficiency. Thanks to the further development of the broadband semiconductor (WBG) and the popularity of the network components silicon carbide (SiC) and gallium nitride (GaN), the switching process has been further improved. The main difference between a linear amplifier and a switching amplifier is that the former uses the linear region of the network components, while the latter is just a simple switching process. Since the linear amplifier is not a switching process, it is completely different from the switching amplifier made up of several amplifiers.

Since the switching amplifier is a switching process, it must have a frequency ratio, while the network components determine the switching frequency. For example, the switching frequency of the insulated gate bipolar transistor (IGBT) is mostly below 20 KHz. The switching frequency of the MOSFET is around 30 KHz-100 KHz, while the switching frequency of SiC MOSFETs is more than 100 KHz. It can be seen that the differences in the working frequencies of the above components are due to the properties of the material itself. Due to the limited working frequency of the network components, the phase-shifted approach can be chosen to solve the above-mentioned problems. In addition, the frequency must be present in the switching process. If several switching amplifiers are connected in parallel, the phase relationship must be observed for the switching frequency in order to establish a complete frequency and time domain relationship. If the switching frequency can be synchronized, the filtering of electromagnetic interference (EMI) can be better controlled. If several switched-mode power supplies operate with the same potential, the synchronization or frequency multiplication and the opposite phase relationship have the same purpose. If there are several switched-mode power supplies connected in parallel after a phase shift, it is necessary to establish a phase relationship. Obviously, in the past, the time base, the point in time and the phase were not included in the necessary considerations for the structure of the linear power supply unit, but the switching power supply unit is the opposite. In addition to the above-mentioned phase-shifted technology for increasing the equivalent working frequency, the following advantages are also present: 1. Lower frequencies are multiplied as a power source with a high-frequency effect. 2. The equivalent frequency is high, with the subsequent ripple frequency also increasing. 3. The reaction is faster and the current density increases. 4. The pulsating current is also reduced for the previous stage, which improves the durability of the previous stage.

The AC / DC power supply can be achieved by a linear structure or a switching structure. If necessary, it can be a hybrid structure that consists of a switching structure and a line structure. In short, all power supplies that use switching must use a common time base to give a time ratio as functions of synchronization, frequency multiplication, antiphase and phase shift.

With regard to the time base, this works for all analog and digital devices in order to handle the processes in the frequency or time domain. For example, radio transmitters and receivers, high and low frequency signal generators, frequency counters, spectrum analyzers, oscilloscopes, power analyzers and the aforementioned switched-mode power supplies require a time base as a reference. If the time base is not working with sufficient accuracy, this is a major source of "jitter". The time base generators available on the market are based on their accuracy - from low to high - quartz, oscillators (OSC), temperature-compensated crystal oscillators (TCXO), temperature-constant crystal oscillators (OCXO), rubidium atomic clocks, etc. Even satellite positioning systems (GPS) can provide the time base, required by the above digital devices. The frequency generated by the time base generator is currently mostly 10 MHz.

In response to industry testing needs for large industrial devices or various products, a high-performance power supply system is required. When the demand for large capacity is achieved with a single power supply, the cost is too high. Therefore, multiple power supplies are switched in parallel by phase shifting to meet the need for large capacity and high frequency. If several power supplies are connected in parallel and the time bases of the power supplies cannot be synchronized, this leads to errors in the switching frequency and thus to electromagnetic interference and resonances. The inventor of the present invention has therefore devoted himself to solving these problems based on his many years of practical experience.

Object of the invention

The main aim of the present invention is to provide an AC / DC switching power supply with a 10 MHz time base to fully synchronize the time bases of several AC / DC power supplies connected to one another, thereby eliminating electromagnetic interference, reducing output ripple, the Eliminate frequency errors between power supplies and provide a high quality AC / DC power source.

In order to achieve the above-mentioned purpose, the present invention creates a switching AC / DC power supply system with a 10 MHz time base, which consists of a master, at least one slave and at least one connection cable. The master consists of a time base generator, a time base circuit and a port. The time base generator is configured for a 10 MHz time base and connected to the time base circuit. The port is connected to the time base generator. The slave also consists of a time base generator, a time base circuit, a selector switch and a port. The time base generator of the slave is configured in such a way that it provides a 10 MHz time base. The port is connected to the time base generator. The time base circuit is optionally connected to the time base generator of the slave or the port of the slave via the selector switch. The connection cable is connected to the port of the master and the port of the slave for connecting the master and the slave.

If the slave is connected to the master via the connection cable and the selector switch for connection to the port is switched, the time base generated by the time base generator of the master is fed into the time base circuit of the slave via the connection cable. The time base generator of the master is connected to the time base circuit of the master and the time base circuit of the slave so that the slave and the master have the synchronized time base to obtain high quality AC / DC performance with low output ripple and low EMI noise.

Figure list

• 1 Figure 3 illustrates a block diagram according to a first embodiment of the present invention;
• 2 shows a schematic view of a port according to the first embodiment of the present invention;
• 3 shows a schematic view of a port according to a second embodiment of the present invention;
• 4th Fig. 3 is a block diagram according to a third embodiment of the present invention;
• 5 Fig. 10 is a block diagram according to a fourth embodiment of the present invention;
• 6th shows a schematic view of a port according to a fifth embodiment of the present invention; and
• 7th Fig. 10 is a block diagram according to the fifth embodiment of the present invention.

Ways of Carrying Out the Invention

The exemplary embodiments of the present invention are described below using only an example with reference to the accompanying drawings.

the 1 shows that the present invention is an AC / DC switched mode power supply system with a 10 MHz time base. The system includes a master 10 , at least one slave 20th and at least one connection cable 30th .

With the master 10 either a DC voltage is fed in or a DC voltage is converted into an AC voltage in order to supply the AC / DC power source with current. The master 10 consists of a time base generator 11 , a selector switch 14th , a time base circuit 13th and a port 12th .

The time base generator 11 is configured for a 10 MHz time base. In this version is the time base generator 11 a temperature compensated crystal oscillator.

The selector switch 14th is a hand switch. One end of the selector switch 14th is having a first contact 141 and a second contact 142 while the other end of the selector switch 14th with a third contact 143 is provided. The third Contact 143 is optional with the first contact 141 or the third contact 143 is optionally with the second contact 142 connected to form a path. The first contact 141 is with the time base generator 11 tied together. The second contact 142 is connected to an external port. When the selector switch 14th in the first embodiment of the present invention no external connection to the second contact 142 becomes the third contact 143 optionally with the first contact 141 tied together.

The time base circuit 13th will be on the third contact 143 of the selector switch 14th connected to the time base of the time base generator 11 or to receive an external time base and perform a frequency division so that the desired frequency is available for each electronic component or each control circuit.

The port 12th is with the selector switch 14th tied together. In the first embodiment of the present invention, there is the port 12th of the master 10 from an input port 121 and an output port 122 . The input port 121 is with the second contact 142 of the selector switch 14th connected while the output port 122 with the third contact 143 of the selector switch 14th connected is. the 2 shows that the input port 121 and the output port 122 can be designed as RJ45 ports. However, this is only an exemplary embodiment and is not a restriction on the implementation of the present invention. The input port 121 and the output port 122 can be other communication ports such as SMA, BNC or fiber optic ports.

The at least one slave 20th in this exemplary embodiment consists of a first slave 201 and a second slave 202 . The at least one slave 20th optionally outputs a direct voltage or converts the direct voltage source into an alternating voltage to supply an AC / DC power source.

The first slave 201 consists of a time base generator 211 , a selector switch 241 , a time base circuit 231 and a port 221 .

The time base generator 211 is configured for a 10 MHz time base. In this version is the time base generator 211 a temperature compensated crystal oscillator.

The selector switch 241 is a manual switch. At one end of the selector switch 241 are a first contact 2411 and a second contact 2412 provided while at the other end of the selector switch 241 a third contact 2413 is provided. The third contact 2413 is optional with the second contact 2412 connected to form a path, or the third contact 2413 is optional with the first contact 2411 connected to form a path. The first contact 2411 of the selector switch 241 is with the time base generator 211 connected so that the selector switch 241 is optionally switched to with the time base generator 211 to be connected or disconnected from it. In the first embodiment of the present invention, the selector switch 241 manually switched to a status in which the second contact 2412 with the third contact 2413 is connected.

The time base circuit 231 is with the third contact 2413 of the selector switch 241 connected to that of the third contact 2413 to receive the entered time base and to perform the frequency division in order to provide the required frequency for each electronic component or for each control circuit.

The port 221 is with the selector switch 241 tied together. In the first embodiment of the present invention, there is the port 221 of the first slave 201 from an input port 2211 and an output port 2212 . The input port 2211 is with the second contact 2412 of the selector switch 241 tied together. The output port 2212 is with the third contact 2413 of the selector switch 241 connected and can be connected to the time base circuit 231 can be connected to form a path, that is, by toggling the selector switch 241 can use the time base circuit 231 with the port 221 connected and not with the time base generator 211 get connected. the 2 shows that the input port 2211 and the output port 2212 are also RJ45 ports.

The second slave 202 consists of a time base generator 212 , a selector switch 242 , a time base circuit 232 and a port 222 .

The time base generator 212 is configured for a 10 MHz time base. In this version is the time base generator 212 a temperature compensated crystal oscillator (TCXO).

The selector switch 242 is a manual switch. One end of the selector switch 242 has a first contact 2421 and a second contact 2422 on while the other end of the selector switch 242 a third contact 2423 having. The third contact 2423 can optionally with the second contact 2422 connected to form a path, or the third contact 2423 can optionally with the first contact 2421 connected to form a path. The first contact 2421 of the selector switch 242 is with the time base generator 212 connected to the selector switch 242 optionally for connection to the time base generator 212 or to separate it from the time base generator 212 to switch. in the The first embodiment of the present invention becomes the selector switch 242 manually switched to a status in which the second contact 2422 with the third contact 2423 is connected.

The time base circuit 232 will be with the third contact 2423 of the selector switch 242 connected to that of the third contact 2423 to receive the entered time base, to carry out the frequency division and to provide the required frequency for each electronic component or for each control circuit.

The port 222 is with the selector switch 242 tied together. In the first embodiment of the present invention, there is the port 222 of the second slave 202 from an input port 2221 and an output port 2222 . The input port 2221 is with the second contact 2422 of the selector switch 242 tied together. The output port 2222 is with the third contact 2423 of the selector switch 242 and continue with the time base circuit 232 connected to form a path, that is, by switching the selector switch 242 becomes the time base circuit 232 with the port 222 and not with the time base generator 212 tied together. the 2 shows that the input port 2221 and the output port 2222 are also designed as RJ45 ports.

In this exemplary embodiment, there is at least one connection cable 30th from a first connection cable 301 and a second connection cable 302 . The first connection cable 301 will be sent to the exit port 122 of the master 10 and the input port 2211 of the first slave 201 connected to the master 10 and the first slave 201 connect to. The second connection cable 302 will be sent to the exit port 2212 of the first slave 201 and the input port 2221 of the second slave 202 connected to the first slave 201 and the second slave 202 connect to.

For a better understanding of the structural features, the technical means and the expected effects of the present invention, it will be described in more detail below.

If the master and each slave are independent and not connected to each other, the master can 10 Output a DC voltage or the DC voltage via the time base of the time base generator 11 convert into an alternating voltage. At the same time, the first slave can 201 and the second slave 202 via the time bases of your own time base generators 211 , 212 also output a direct voltage or convert the direct voltage into an alternating voltage. However, since the time bases of the master 10 and the slaves 201 , 202 from the respective time base generators 11 , 211 , 212 the time bases cannot be synchronized.

If the master and each slave as in the 1 connected to each other is the first slave 201 via the first connection cable 301 with the master 10 tied together. The third contact 143 of the selector switch 14th of the master 10 is optional with the first contact 141 connected so that the time base generator 11 of the master 10 via the selector switch 14th with the time base circuit 13th connected is. The time base circuit 13th can be the time base of the time base generator 11 of the master 10 received to the frequency division by the time base circuit 13th and the time base of the master 10 continue through the output port 122 of the master 10 to spend. The time base of the master 10 can through the first connection cable 301 , the input port 2211 of the first slave 201 and the selector switch 241 for time base switching 231 of the first slave 201 can be entered. When connecting the first connection cable 301 to the first slave 201 can the selector switch 241 of the first slave 201 manually switched to the third contact 2413 with the second contact 2412 connect to. Therefore, the time base circuit 231 of the first slave 201 a frequency division after that with the time base generator 11 of the master 10 the time base generated so that the time base generator 11 of the master 10 generated time base to the time base circuit at the same time 13th of the master 10 and to the time base circuit 231 of the first slave 201 is issued. Therefore, the first slave has 201 via a synchronized time base with the master 10 .

When the second slave is further connected 202 becomes the selector switch 242 of the second slave 202 also for the third contact 2423 on the second contact 2422 switched so that the time base of the master 10 via the second connection cable 302 , the input port 2221 of the second slave 202 and the selector switch 242 into the time base circuit 232 of the second slave 202 can be further entered. The time base circuit 232 can do that from the time base generator 11 of the master 10 Generated time base received and a frequency division by the time base circuit 232 carry out. When the second connection cable 302 to the second slave 202 is connected, the selector switch becomes 242 of the second slave 202 also manually on the third contact 2413 for connection to the second contact 2412 switched. Therefore, the time base circuit performs 232 of the second slave 202 also a frequency division corresponding to that of the time base generator 11 of the master 10 generated time base. The time base of the master is used 10 still synchronous to the time base circuit 232 of the second slave 202 output so that the second slave 202 a synchronized time base with the first slave 201 and the master 10 Has. The master 10 , the first slave 201 and the second slave 202 provide a synchronized AC / DC power source with the same frequency and phase.

It should be noted that with the present invention it is the master 10 allows the first slave 201 and the second slave 202 via a direct point-to-point connection via the first connection cable 301 and the second connection cable 302 to avoid delays for the highest accuracy and the best synchronous output.

the 3 Fig. 3 shows a second embodiment of the present invention. With the exceptions described below, the second exemplary embodiment essentially corresponds to the first exemplary embodiment. One port 42 of a master 40 , one port 521 of a first slave 501 and a port 522 of a second slave 502 use all BNC ports for mutual connection.

the 4th Fig. 3 shows a third embodiment of the present invention. With the exceptions described below, the third exemplary embodiment essentially corresponds to the first exemplary embodiment.

This embodiment also consists of an external device 80 that can provide a 10 MHz time base, such as a standard rubidium frequency oscillator, model SRS FS725, etc. The external device 80 assigns a port 81 for an external connection cable 308 on to the port 81 of the external device 80 to the input port 121 of the master 10 to connect and thus the master 10 and the external device 80 connect to. At this point, the selector switch becomes 14th switched to a state in which the second contact 142 with the third contact 143 connected so that the time base circuit 13th of the mast 10 on the time base of the external device 80 is switched. With the high frequency accuracy of the external device 80 becomes the master 10 a more accurate time base frequency is made available. This is the timing accuracy of the master 10 higher to meet the demand for higher accuracy.

More precisely when the master 10 via the external connection cable 308 to the external device 80 is connected, the selector switch becomes 14th of the master 10 switched so that the third contact 143 with the second contact 142 is connected. The time base generator 11 of the master 10 is not with the time base circuit 13th tied together. Therefore, the time base circuit 13th of the master 10 the time base of the external device 80 receive and perform a frequency division, whereby the master 10 with the time base of the external device 80 can synchronize.

the 5 Fig. 3 shows a fourth embodiment of the present invention. With the exceptions described below, the fourth exemplary embodiment essentially corresponds to the first exemplary embodiment.

The selector switches 14th , 241 , 242 of the master 10 , the first slave 201 and the second slave 202 are electronic switches. The master 10 , the first slave 201 and the second slave 202 all consist of a detection circuit 15th , 251 , 252 . An end to this detection circuit 15th is electrical with the input port 121 of the port 12th connected while the other end of the detection circuit 15th electrically with the selector switch 14th connected is. One end of the detection circuit 251 is electrical with the input port 2211 of the port 221 connected while the other end of the detection circuit 251 electrically with the selector switch 241 connected is. One end of the detection circuit 252 is electrical with the input port 2221 of the port 222 connected while the other end of the detection circuit 252 electrically with the selector switch 242 connected is.

When connecting the first slave 201 via the first connection cable 301 to the master 10 recognizes the detection circuit 251 automatically that the input port 2211 has a time base signal from the external input. The third contact 2413 of the selector switch 241 is used to connect the second contact 2412 switched to the time base circuit 231 of the first slave 201 for the reception of the by the time base generator 11 of the master 10 to change the generated time base. When connecting the second slave 202 in a similar way via the second connection cable 302 to the first slave 201 recognizes the detection circuit 252 automatically that the input port 2221 has a time base signal from external input. The third contact 2423 of the selector switch 242 is used to connect the second contact 2422 switched to the time base circuit 232 to change and those with the time base generator 11 of the master 10 to receive the provided time base.

the 6th and 7th show a fifth embodiment of the present invention. The fifth exemplary embodiment is essentially similar to the first exemplary embodiment, with the exceptions described below. The system consists of a master 60 , a first slave 701 , a second slave 702 and at least one connection cable 30th .

The master 60 has a port 62 . The port 62 is a common port for input and output, where the port 62 is a BNC port. However, this is only an exemplary embodiment and is not a restriction on the implementation of the present invention. The port 62 can be designed as an SMA, BNC or fiber optic port. A selector switch 64 consists of a first contact 641 , a second contact 642 , a third contact 643 and a fourth contact 644 . The first contact 641 is on a time base generator 61 connected. The third contact 643 is on a time base circuit 63 connected. The fourth contact 644 is with the port 62 tied together. Both the third contact 643 as well as the fourth contact 644 are optional with the first contact 641 connected to form a first path, or both the third contact 643 as well as the fourth contact 644 are optional with the second contact 642 connected to form a path. Has the selector switch 64 via no external input from the fourth contact 644 , become the third contact 643 and the fourth contact 644 optionally with the first contact 641 connected so that the time base of the time base circuit 63 of the master 60 by the time base generator 61 provided.

The first slave 701 assigns a port 721 which is also a common port for input and output. The port 721 is also a BNC port. The selector switch 741 consists of a first contact 7411 , a second contact 7412 , a third contact 7413 and a fourth contact 7414 . The first contact 7411 is on a time base generator 711 connected. The third contact 7413 is on a time base circuit 731 connected. The fourth contact 7414 is with the port 721 tied together. Both the third contact 7413 as well as the fourth contact 7414 are optional with the first contact 7411 connected to form a path, or both the third contact 7413 as well as the fourth contact 7414 are optional with the second contact 7412 connected to form a path.

The second slave 702 assigns a port 722 which is also a common port for input and output. The port 722 is also a BNC port. The selector switch 742 consists of a first contact 7421 , a second contact 7422 , a third contact 7423 and a fourth contact 7424 . The first contact 7421 is with a time base generator 712 tied together. The third contact 7423 is with a time base circuit 732 tied together. The fourth contact 7424 is with the port 722 tied together. Both the third contact 7423 as well as the fourth contact 7424 are optional with the first contact 7421 connected to form a path, or both the third contact 7423 as well as the fourth contact 7424 are optional with the second contact 7422 connected to form a path.

In this exemplary embodiment, there is at least one connection cable 30th from a first connection cable 306 , a second connection cable 307 and from a triple plug 31 . The triple plug 31 is attached to the port 721 of the first slave 701 connected so the port 721 of the first slave 701 through the connector 311 or a second connector 312 of the triple plug 31 can be used as input and output. Two ends of the first connection cable 306 are ever to the port 62 of the master 60 and to the first connector 311 of the triple plug 31 connected to the master 60 and the first slave 701 connect to. Two ends of the second connection cable 307 are each with the second connector 312 of the triple plug 31 and the port 722 of the second slave 702 connected to the first slave 701 and the second slave 702 connect to.

When the first slave 701 with the master 60 connected can be the time base circuit 64 of the master 60 the one with the time base generator 61 of the master 60 through the selector switch 64 generated time base received, with the time base of the master 60 through the port 62 can be output. The time base of the master 60 can through the first connection cable 306 , the port 721 of the first slave 701 and the selector switch 741 to the time base circuit 731 of the first slave 701 can be entered. When the first connection cable 306 with the first slave 701 connected, the selector switch 741 of the first slave 701 manually for the one with the second contact 7412 third contact to be connected 7423 and the fourth contact 7424 be switched. Therefore, the time base circuit 731 of the first slave 701 those by the time base generator 61 of the master 60 generated time base received and the frequency division according to the by the time base generator 61 of the master 60 the generated time base. The first slave 701 therefore has one with the master 60 synchronized time base.

When the second slave 702 continue with the first slave in a similar manner 701 connected, the selector switch becomes 742 of the second slave 702 for the one with the second contact 7422 third contact to be connected 7423 and the fourth contact 7424 also switched so that the time base circuit 732 those by the time base generator 61 of the master 60 provided time base receives and the frequency division according to the by the time base generator 61 of the master 60 generated time base.

The second slave has 702 via a synchronized time base with the first slave 701 and the master 60 . The master 60 , the first slave 701 and the second slave 702 put a synchronized AC / DC power source with the same frequency and phase is available.

• Im schaltenden AC/DC-Netzteilsystem mit einer 10 MHz-Zeitbasis der vorliegenden Erfindung werden die Slaves über die Anschlusskabel mit dem Master verbunden. Wenn die Wählschalter der Slaves so geschaltet werden, dass die Ports der Slaves mit den Zeitbasisschaltungen der Slaves verbunden sind, kann die vom Zeitbasisgenerator des Masters erzeugte Zeitbasis an die Zeitbasisschaltungen der Slaves ausgegeben werden, so dass die Slaves eine mit dem Master synchronisierte Zeitbasis haben. Durch die Synchronisierung der Zeitbasis kann der Anlaufzeitpunkt jedes PWM-ICs sowie die Phase und Frequenz der PWM gesteuert werden. Außerdem kann die gegenphasige und phasenverschobene Technologie weiter verwendet werden, so dass die Ausgangswelligkeit geringer und das EMI-Rauschen geringer ist, um eine hochwertige AC/DC-Ausgangsstromquelle zu erhalten.

The features and expected effects of the present invention are described below:

• In the switching AC / DC power supply system with a 10 MHz time base of the present invention, the slaves are connected to the master via the connecting cables. If the selector switches of the slaves are switched in such a way that the ports of the slaves are connected to the time base circuits of the slaves, the time base generated by the time base generator of the master can be output to the time base circuits of the slaves so that the slaves have a time base that is synchronized with the master. By synchronizing the time base, the start-up time of each PWM IC as well as the phase and frequency of the PWM can be controlled. Also, the anti-phase and out-of-phase technology can continue to be used so that the output ripple is less and the EMI noise is less, for a high quality AC / DC output power source.

While the specific embodiments of the present invention have been described in detail for purposes of illustration, numerous modifications and improvements can be made without departing from the spirit and scope of the present invention. The present invention is therefore intended to be limited only by the appended claims.

List of reference symbols

10

master

11

Time base generator

12th

port

121

Input port

122

Output port

13th

Time base switching

14th

Selector switch

141

First contact

142

Second contact

143

Third contact

15th

Detection circuit

20th

Slave

201

First slave

202

Second slave

211

Time base generator

221

port

2211

Input port

2212

Output port

212

Time base generator

222

port

2221

Input port

2222

Output port

231

Time base switching

241

Selector switch

2411

First contact

2412

Second contact

2413

Third contact

232

Time base switching

242

Selector switch

2421

First contact

2422

Second contact

2423

Third contact

251

Detection circuit

252

Detection circuit

30th

Connection cable

301

First connection cable

302

Second connection cable

306

First connection cable

307

Second connection cable

308

External connection cable

31

Triple plug

311

First connector

312

Second connector

40

master

42

port

501

First slave

502

Second slave

521

port

522

port

60

master

61

Time base generator

62

port

63

Time base switching

64

Selector switch

641

First contact

642

Second contact

643

Third contact

644

Fourth contact

701

First slave

711

Time base generator

721

port

731

Time base switching

741

Selector switch

7411

First contact

7412

Second contact

7413

Third contact

7414

Fourth contact

702

Second slave

712

Time base generator

722

port

732

Time base switching

742

Selector switch

7421

First contact

7422

Second contact

7423

Third contact

7424

Fourth contact

80

External device

81

port

Claims (5)

An AC / DC switching power supply system with a 10 MHz time base, comprising: a master (10, 60) configured to supply an AC / DC power source, the master (10, 60) consisting of the following elements: a time base generator (11, 61) configured to provide a 10 MHz time base; a time base circuit (13, 63) connected to the time base generator (11, 61) for performing frequency division; a port (12, 62) connected to the time base generator (11, 61); at least one slave (201, 701) configured to supply an AC / DC power source, the slave (201, 701) consisting of the following elements: a time base generator (211, 711) configured to provide a 10 MHz time base; a selector switch (241, 741), one end of the selector switch (241, 741) being selectively switched for connection to the time base generator (211, 711) of the slave (201, 701) or for disconnection therefrom; a time base circuit (231, 731) connected to another end of the selector switch (241, 741) for performing frequency division; a port (221, 721), whereby by switching the selector switch (241, 741) the time base circuit (231, 731) of the slave (201, 701) at the port (221, 721) of the slave (201, 701) and not on the time base generator (211, 711) of the slave (201, 701) is connected; at least one connection cable (301, 306) which is connected to the port (12, 62) of the master (10, 60) and to the port (221, 721) of the slave (201, 701) in order to connect the master (10, 60) and to connect the slave (201, 701); whereby when connecting the slave (201, 701) with the connecting cable (301, 306) to the master (10, 60) and when switching the selector switch (241, 741) of the slave (201, 701) for the port (221, 721 ) of the slave (201, 701) to be connected to the time base circuit (231, 731) the time base generated with the time base generator (11, 61) of the master (10, 60) through the connecting cable (301, 306) to the time base circuit (231) of the slave (201, 701) is entered so that the slave (201, 701) and the master (10, 60) have synchronized time bases. The AC / DC switching power supply with 10 MHz time base according to Claim 1 wherein the port (221) of the slave (201) has an input port (2211) and an output port (2212); the selector switch (241) consists of a first contact (2411), a second contact (2412) and a third contact (2413); the first contact (2411) is connected to the time base generator (211) of the slave (201); the second contact (2412) with the input port (2211), the third contact (2413) with the time base circuit (231) of the slave (201) and the output port (2212) and the third contact (2413) optionally with the second contact (2412) ) or the first contact (2411) is connected to form a path. The AC / DC switching power supply with 10 MHz time base according to Claim 1 wherein the selector switch (241) of the slave (201) is an electronic switch; the slave (201) further consists of a detection circuit (251); one end of the detection circuit (251) of the slave (201) is electrically connected to the port (221) of the slave (201), while another end of the detection circuit (251) is electrically connected to the selector switch (241) of the slave (201) . The AC / DC switching power supply with 10 MHz time base according to Claim 1 , further comprising an external device (80) having a 10 MHz time base; the external device (80) is connected to the port (12) of the master (10); the master (10) further consists of a selector switch (14); one end of the selector switch (14) of the master (10) for connection to the time base generator (11) of the master (10) or to the external device (80) is optionally switched, while the other end of the selector switch (14) of the master (10) is connected to the time base circuit (13) of the master (10) so that the time base generator (11) of the master (10) the time base of the external device (80) by switching the Selector switch (14) of the master (10) can catch up. The AC / DC switching power supply with 10 MHz time base according to Claim 1 wherein the port (721) of the slave (701) is a common port for input and output; the selector switch (741) consists of a first contact (7411), a second contact (7412), a third contact (7413) and a fourth contact (7414); the first contact (7411) is connected to the time base generator (711) of the slave (701); the third contact (7413) is connected to the time base circuit (731) of the slave (701); the fourth contact (7414) is connected to the port (721) of the slave (701); the third contact (7413) and the fourth contact (7414) are optionally connected to the first contact (7411) or the second contact (7412) to form a path.

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