阅读说明：本技术 初级脉冲开关电源 (Primary pulse switch power supply ) 是由 马克斯·耶勒 马克斯·鲍尔 帕特里克·盖布 于 2018-05-09 设计创作，主要内容包括：本发明涉及一种初级脉冲开关电源(1),用于将输入电压(Ue)转换成输出电压(Ua),该初级脉冲开关电源至少包括：初级侧电路分支(2),输入电压(Ue)能够施加到该初级侧电路分支；次级侧电路分支(4),其与该初级侧电路分支(2)隔离开,并且从该次级侧电路分支能够分接输出电压(Ua)；电流隔离(3),其在初级侧电路分支和次级侧电路分支(4)之间；熔断器(5),其布置在初级侧电路分支(2)中,从而以基本上无电压的方式切换初级侧电路分支；第一可切换开关元件(6),其布置在初级侧电路分支(2)中,使得该切换元件在切换时触发初级侧熔断器(5)；以及监视单元(7),其与第一开关元件相连接并且布置在初级侧电路分支(2)中,并且设计成监视由第二初级线圈(11)所确定的特征电信号,并且当该特征电信号超过阈值时,切换第一开关元件(6)。(The invention relates to a primary pulse switching power supply (1) for converting an input voltage (Ue) into an output voltage (Ua), comprising at least: a primary-side circuit branch (2) to which an input voltage (Ue) can be applied; a secondary-side circuit branch (4) which is isolated from the primary-side circuit branch (2) and from which an output voltage (Ua) can be tapped; a galvanic isolation (3) between the primary-side circuit branch and the secondary-side circuit branch (4); a fuse (5) arranged in the primary side circuit branch (2) to switch the primary side circuit branch in a substantially voltage-free manner; a first switchable switching element (6) which is arranged in the primary-side circuit branch (2) in such a way that it triggers the primary-side fuse (5) when switching; and a monitoring unit (7) which is connected to the first switching element and is arranged in the primary-side circuit branch (2) and is designed to monitor a characteristic electrical signal determined by the second primary coil (11) and to switch the first switching element (6) when the characteristic electrical signal exceeds a threshold value.)

1. A primary clocked switching power supply (1) for converting an input voltage (Ue) to an output voltage (Ua), and comprising:

a primary-side circuit branch (2) at which the input voltage (Ue) can be applied;

a secondary side circuit branch (4) which is isolated from the primary side circuit branch (2) and at which the output voltage (Ua) can be tapped;

a galvanic isolation (3) which is present between the primary-side circuit branch (2) and the secondary-side circuit branch (4), the galvanic isolation comprising at least one transformer, wherein the transformer comprises at least a first primary winding arranged in the primary-side circuit branch (2) and a first secondary winding arranged in the secondary-side circuit branch for galvanic isolation of an energy transmission from the primary-side circuit branch to the secondary-side circuit branch, wherein the transformer further has a second primary winding arranged in the primary-side circuit branch for energy supply of at least a part of the primary-side circuit branch (2);

a fuse or circuit breaker (5) arranged in the primary side circuit branch (2) and adapted to interrupt a primary side current

a first switchable switching element (6) arranged in the primary side circuit branch (2) with respect to the fuse or circuit breaker (5) such that switching causes the primary side fuse or circuit breaker (5) to trip;

a monitoring unit (7) connected with the first switching element and arranged in the primary side circuit branch (2) and adapted to monitor a characteristic electrical signal determined by the second primary winding (11) and to switch the first switching element (6) such that the primary side fuse or circuit breaker (5) is tripped when the characteristic electrical signal exceeds a threshold value.

2. Switching power supply according to claim 1, wherein the characteristic electrical signal comprises a voltage signal dependent on the second primary winding, in particular a voltage signal on the output of the second primary winding (11).

3. Switching power supply according to claim 1 or 2, further comprising a diode (22) arranged in the primary side circuit branch, wherein the diode (22) is connected with the second primary winding via its anode and the characteristic electrical signal comprises a voltage signal on the cathode of the diode (22).

4. Switching power supply according to one or more of the preceding claims, wherein the monitoring unit (7) has at least one comparator (7b), in particular a schmitt trigger, which is supplied with the electrical signal and which compares it with the threshold value, switching the first switching element (6) when it exceeds the threshold value.

5. Switching power supply according to at least one of claims 2 to 4, wherein the monitoring unit (7) has an RC unit (7a) which is connected with the second primary winding (11) such that the RC unit (7a) will be dependent on the voltage summation of the second primary winding.

6. Switching power supply according to the preceding claim, wherein the RC-unit (7a) and the comparator (7b) are connected to each other such that the comparator (7b) is supplied with the voltage summed by the RC-unit (7a), and wherein the comparator (7b) compares the summed voltage with the threshold value.

7. Switching power supply according to at least one of claims 4 to 6, wherein the comparator (7b) is embodied such that the threshold value is fed to the first input.

8. Switching power supply according to at least one of claims 4 to 7, wherein the comparator (7b) is further embodied such that the electrical signal is fed to a second input.

9. The switching power supply according to one or more of the preceding claims, wherein said first switching element (6) comprises a thyristor, a transistor, in particular a field effect transistor, or a relay.

10. The switched mode power supply according to one or more of the preceding claims, wherein said primary side circuit branch (2) has a second switching element (9) connected in series with said first primary winding (8) and clocking said first primary winding (8).

11. Switching power supply according to the preceding claim, wherein the primary side circuit branch (2) has a control unit (10) connected with the second switching element (9) for activating the second switching element (9).

12. Switching power supply according to the preceding claim, wherein a starter circuit (12) is provided in the primary side circuit branch (2), which starter circuit supplies the control unit (10) with the required energy at start-up.

13. Switching power supply according to claim 11 or 12, further comprising a first feedback element (13) implemented such that it directs a feedback signal from the secondary side circuit branch (4) across the galvanic isolation (3) to the control unit (10) arranged on the primary side, whereby the control unit (10) activates the second switching element (9) to clock the first primary winding (8) in correspondence with the feedback signal.

14. Switching power supply according to the preceding claim, wherein the first feedback element (13) comprises at least one optocoupler, preferably an optocoupler or an infrared light emitting diode.

15. An automation-technology field device comprising a primary clocked switching power supply (1) according to at least one of the preceding claims.

Technical Field

The invention relates to a primary pulse or primary clock-controlled switching power supply and to a field device having such a switching power supply.

Background

At present, switching power supplies are used in virtually all electronic devices, both in the private consumer sector (for example in the case of television sets) and in the industrial environment (for example in the case of field devices in automation technology).

Automation field devices are used to record and/or influence process variables. Examples of such field devices are fill level measurement devices, mass flow measurement devices, pressure and temperature measurement devices, pH oxidation-reduction potential measurement devices, conductivity measurement devices, etc., which record corresponding process variables, fill level, flow, pressure, temperature, pH values, and conductivity values as sensors. What are used to influence the process variables are so-called actuators (e.g. valves or pumps) which control the flow of liquid in a pipe, tube or line section and which change the filling level in the container. In principle, all the following devices are therefore referred to as field devices: these devices are used in the vicinity of the process and these devices convey or process-related information. Thus, in connection with the present invention, the concept of field device refers to all types of measuring devices and actuators. The concept of a field device also includes, for example, gateways, radio adapters and other bus participants which are integrated/can be integrated in the bus system.

A large number of such field devices are manufactured and sold by the enges plus hause group of companies.

As previously mentioned, such field devices require an energy supply. For this purpose, so-called primary-clocked (primary-clocked) switching power supplies are currently used, which usually have galvanic isolation between a primary side, at which an input voltage can be fed in, and a secondary side, at which an output voltage can be tapped off. In this case, energy is transferred to the secondary side by a high clock (high clocking) of the transformer.

In order to avoid switching off the switching power supply in the event of a fault and thus to avoid damage to downstream devices (in particular field devices), safety measures are implemented in the switching power supply. Therefore, so-called crowbar circuits (crowbar circuits) are currently applied, which limit the output voltage of the switching power supply as a last resort. In the case of such crowbar circuits, in the event of a fault, in particular in the event of an overvoltage, a secondary-side thyristor (thyristor) is triggered, which leads to a short circuit between the output voltage and ground. In this way, the secondary side current rises to the extent that the fuse melts or the circuit breaker trips, so that the secondary side current is interrupted, isolating the circuit of the downstream equipment from the primary side of the switching power supply. At the same time, however, the control loop (which typically similarly has a switching power supply) is also isolated from the primary side of the switching power supply, so that the switching power supply detects the primary side, finds that the secondary side output voltage is too low, and the control loop correspondingly attempts to counteract this. The result of this is, in turn, that the output voltage can rise to several hundred volts due to the open secondary side. However, the introduced power can only be removed via the primary side circuit branch region (which has an additional primary winding of the transformer), and therefore, the primary side circuit branch region is very burdened. This leads to the following fact: the participating components can become very hot and thus fail to meet certain temperature levels for intrinsic safety, in particular temperature level 6, according to which the maximum surface temperature should not exceed 85 ℃/80 ℃. Furthermore, even if the input voltage is relatively low, dangerous voltages are present in the circuitry of the switching power supply.

Disclosure of Invention

It is an object of the present invention to provide a switching power supply which shuts down or stops functioning as safely as possible in the event of a fault.

This object is achieved by a primary clocked switching power supply as defined in claim 1 and by a field device according to the automation technique as defined in claim 15. Advantageous further developments of the invention are set forth in the dependent claims.

The primary clock-controlled switching power supply of the present invention is for converting an input voltage into an output voltage, and includes:

a primary-side circuit branch at which an input voltage can be applied;

a secondary side circuit branch isolated from the primary side circuit branch and at which an output voltage can be tapped;

having a galvanic isolation between the primary-side circuit branch and the secondary-side circuit branch, the galvanic isolation comprising at least one transformer, wherein the transformer comprises at least a first primary winding arranged in the primary-side circuit branch and a first secondary winding arranged in the secondary-side circuit branch for galvanic isolation of an energy transmission from the primary-side circuit branch to the secondary-side circuit branch, wherein the transformer further has a second primary winding arranged in the primary-side circuit branch for energy supply of at least a part of the primary-side circuit branch;

a fuse or circuit breaker arranged in the primary side circuit branch and adapted to interrupt a primary side current such that the primary side circuit branch is substantially voltage-free;

a first switchable switching element arranged in the primary side circuit branch with respect to the fuse or circuit breaker such that switching trips the primary side fuse or circuit breaker;

a monitoring unit connected with the first switching element and arranged in the primary side circuit branch and adapted to monitor a characteristic electrical signal determined by the second primary winding and, when the characteristic electrical signal exceeds a threshold value, to switch the first switching element such that the primary side fuse or circuit breaker trips.

An advantageous embodiment of the invention provides that the characteristic electrical signal comprises a voltage signal dependent on the second primary winding, in particular a voltage signal at the output of the second primary winding.

A further advantageous embodiment of the invention further provides for a diode to be arranged in the primary-side circuit branch, wherein the diode is connected via its anode to the second primary winding and the characteristic electrical signal comprises a voltage signal at the cathode of the diode.

A further advantageous embodiment of the invention provides that the monitoring unit has at least one comparator, in particular a schmitt trigger, which is supplied with an electrical signal and which compares the electrical signal with a threshold value and switches the first switching element when the electrical signal exceeds the threshold value.

In turn, an advantageous embodiment of the invention provides that the monitoring unit has an RC unit which is connected to the second primary winding such that the RC unit will depend on the voltage summation of the second primary winding. In particular, this embodiment may provide that the RC unit and the comparator are connected to each other such that the comparator is supplied with a voltage summed by the RC unit, and wherein the comparator compares the summed voltage with a threshold value.

A further advantageous embodiment of the invention provides that the comparator is embodied such that the threshold value is fed to the first input.

An advantageous embodiment of the invention then provides that the comparator is further embodied such that the electrical signal is fed to the second input.

A further advantageous embodiment of the invention provides that the first switching element comprises a thyristor, a transistor, in particular a field effect transistor, or a relay.

A further advantageous embodiment of the invention provides that the primary-side circuit branch has a second switching element which is connected in series with the first primary winding and clocks the first primary winding. In particular, the exemplary embodiments can provide that the primary-side circuit branch has a control unit which is connected to the second switching element for activating the second switching element, and/or that a starter circuit is provided in the primary-side circuit branch, which starter circuit supplies the control unit with the required energy when starting up. Furthermore, the exemplary embodiments can have at least a first feedback element which is embodied in such a way that it conducts a feedback signal from the secondary-side circuit branch across the galvanic isolation to a control unit arranged on the primary side, whereby the control unit activates a second switching element for clocking the first primary winding in correspondence with the feedback signal, and/or the first feedback element comprises at least one optocoupler, preferably an optocoupler or an infrared light-emitting diode.

With regard to the field device, the object is achieved by a field device of automation technology, which comprises at least one primary clocked switching power supply according to one of the above-described embodiments.

Drawings

The invention will now be explained in more detail on the basis of the drawings, the views of which are as follows:

fig. 1 is a circuit of a primary clocked switching power supply known from the prior art, and

fig. 2 is a circuit for a primary clocked switching power supply implemented in accordance with the invention.

Detailed Description

Fig. 1 shows a primary clocked switching power supply 1 with a primary-side circuit branch 2 and a secondary-side circuit branch 4, which is isolated from the primary-side circuit branch by a galvanic isolation 3.

The primary-side circuit branch 2 of the switching power supply 1 of fig. 1 comprises a first circuit branch region (which has at least one input connection 14), a rectifier unit 15, a starter circuit 12, a first primary winding 8 of a transformer 16, a second switching element 9 and a control unit 10.

The input connection 14 is used to input an input voltage Ue to the switching power supply 1. Depending on the embodiment of the switching power supply 1, both a wide range of ac input voltages (typically 80V to 253V ac) and dc input voltages (typically 18V to 65V dc) can be applied to the input connection 14.

In case the input voltage Ue is an alternating voltage, the input voltage Ue is rectified by the rectifier unit 15. The rectifier unit 15 is typically a bridge rectifier, which is formed by four diodes 18. The rectified input voltage Ue is then fed to a starter circuit 12 which supplies the switching power supply 1 with the required electrical energy during the start-up phase (typically only the first clock cycle). On the basis of the power supplied by the starter circuit 12, a control unit 10 is operated, which is used to activate the second switching element 9 at a desired clock frequency. A typical clock frequency is between 20kHz and 300kHz, depending on power. Modern control units or control chips are capable of driving correspondingly high powers due to high clock frequencies and duty cycles of up to 80%. A second switching element 9 (e.g. a transistor) is connected in series with the first primary winding 8 of the transformer 16 and clocks the first primary winding 8 corresponding to a clock frequency predetermined by the control unit 10, thereby extracting energy portions from the input voltage Ue and transferring or transforming these energy portions to a secondary winding 17 of the transformer 16 in the secondary-side circuit branch 4. Based on these transferred energy portions, power consuming components connectable to the secondary side circuit branches can be supplied with energy.

Furthermore, the primary-side circuit branch 2 of the switching power supply of fig. 1 has a second circuit branch region which is essentially used for supplying energy to the control unit 10. The second circuit branch region comprises the second primary winding 11 of the transformer 16. The second primary winding 11 is connected with the starter circuit 12 via further components such as a resistor, which is arranged in series with the second primary winding, and a diode, which is likewise arranged in series with the resistor and the second primary winding, so that the energy supply takes place via the second circuit branch region as soon as sufficient energy is available via the second primary winding 11 for supplying the control unit 10.

As already mentioned, the secondary-side circuit branch 4 comprises the secondary winding 17 of the transformer 16 and a smoothing device 20 for smoothing the discontinuous energy flux through the transformer 16. In the simplest case, the smoothing means comprise a smoothing diode 20. Furthermore, the secondary side circuit branch 4 comprises a feedback circuit 19 adapted to feed back an electrically decoupled feedback signal from the secondary side circuit branch 4 to the primary side circuit branch 2 in order to adapt the clock frequency of the control unit 10 appropriately. Typically, the feedback circuit 19 comprises for this purpose a voltage reference 21, which is designed such that, when the voltage applied at its input REF exceeds a predetermined threshold (for example 2.5V), the voltage reference 21 induces a current between its connections C and a in order to generate a feedback signal.

For example, the electrical decoupling can be implemented by including a first feedback element 13 in the feedback circuit 19, which connects the secondary-side circuit branch and the primary-side current branch to each other.

The circuit of the switching power supply 1 shown in fig. 1 is very simplified and does not include, for example, the safety measures known from the prior art and mentioned above, in particular the switching elements and fuses arranged on the secondary side, such as are customary in the prior art. Furthermore, the circuit of fig. 1 does not comprise measures with regard to electromagnetic compatibility (EMC).

Fig. 2 shows by way of example a circuit of a primary clocked switching power supply 1 implemented according to the invention, which circuit is extended compared to the circuit of fig. 1 to comprise a monitoring unit 7, which is arranged on the primary side, a first switching element 6, which is likewise arranged on the primary side, and a primary-side fuse or circuit breaker 5. It should be mentioned here that although fig. 1 and 2 show an ac switching power supply, the teachings of the invention can also be applied without problems to a dc/dc power supply.

The monitoring unit 7, the first switching element 6 and the primary-side fuse or circuit breaker 5 serve, in the event of a fault (for example in the event of an overvoltage), to remove the voltage from the primary side of the switching power supply 1, so that no further subsequent faults and/or thermal loads occur. Due to the fact that both the monitoring unit 7 and the first switching element 6 are arranged on the primary side, it is not necessary to have a signal sent across the galvanic isolation 3 from the secondary side to the primary side to activate the first switching element 6. This enables the switching power supply according to the invention to be advantageously used in field devices in automation technology, on which particularly high technical requirements are placed according to SIL (safety integrity level) and/or Ex regulations.

The solution of the invention, shown by way of example in fig. 2, comprises, in the primary side circuit branch 2, a fuse or breaker 5 (preferably a fused fuse) which interrupts the primary side current when a defined current level is exceeded for a defined time

In order to cause the fuse or circuit breaker 5 to interrupt the primary side current, a first switching element 6 is further provided in the primary side of the switching power supply. The first switching element 6 can be switched by a control signal.

In this case, the first switching element 6 is arranged in the primary-side circuit branch, so that, upon switching, the primary-side fuse or circuit breaker 5 trips. This can be implemented, for example, in the following way: when the first switching element 6 switches, i.e. when it becomes conductive, the fuse or breaker 5 is connected to ground through the first switching element 6.

The first switching element 6, which preferably comprises a thyristor or a field effect transistor, is operated by the monitoring unit such that it becomes conductive in the event of a fault (for example, in the event of an overvoltage). The first switching element 6 may alternatively comprise a bipolar transistor or a relay, in addition to a thyristor or a field effect transistor.

The monitoring unit 7 comprises a comparator 7b (for example, a schmitt trigger) whose first input (negative, or inverting input) is fed with a threshold value and whose second input (positive, or non-inverting input) is fed with an electrical signal determined or defined by the second primary winding 11. The electrical signal may for example comprise a voltage signal which is present on the second primary winding of the transformer. In this case, the voltage signal may be tapped at the output of the second primary winding 11 (i.e. at the output opposite to ground) or after a diode 22 connected in series with the second primary winding. In the circuit of fig. 2, the voltage signal is recorded, by way of example, after the diode on the cathode of the diode and fed to the comparator. In addition to the voltage signal as the characteristic electrical signal, in principle it is also possible to consider the current signal as the characteristic electrical signal.

In principle, the characteristic electrical signal can be fed directly (i.e. without interposing other electrical components therebetween) to the comparator 7 b. Advantageously, however, the electrical signal, especially when it comprises a voltage signal, is fed to the comparator 7b via an RC unit (resistance-capacitance unit) 7 a. The RC unit 7a has a summing effect on the electrical signals so that no pure peak detection is performed by the comparator 7 b. This provides the advantage that the electrical signal is less susceptible to disturbances, especially in view of EMC disturbances.

Depending on the specific embodiment of the circuit, an adaptation unit 7d may also be provided, which is used to adapt the characteristic electrical signal, in particular to adapt the voltage. The adaptation unit 7d is fed with the electrical signal or the summed signal. In the example of fig. 2, the adaptation unit 7d comprises a voltage divider having two resistors connected in series with respect to each other and dimensioned such that the level (in particular, the voltage level) of the characteristic electrical signal or of the overall signal is at a desired level.

The desired level depends on a threshold value which is fed via a threshold circuit 7c to the comparator 7b as a comparison reference. This threshold value is then fixed by the threshold circuit 7c depending on whether the electrical signal is tapped directly at the output of the second primary winding 11 or at the cathode of the diode 22. In the circuit of fig. 2, the threshold circuit 7c comprises a zener diode (Zenerdiode) and a resistor connected in series with the zener diode, wherein the threshold value is conducted from an intermediate junction between the zener diode and the resistor to the first input (negative or inverting input) of the comparator 7 b.

The comparator 7b is adapted to compare the supplied electrical signal with a threshold value and to control the first switching element 6 via the control signal in dependence on the comparison. The comparator 7b shown in fig. 2 compares the supplied electric signal with a threshold value and sets a control signal on the output, which shows which of the electric signal and the threshold value is higher. When the electrical signal on the second input (positive, or non-inverting input) is above the threshold applied to the first input (negative, inverting input), then the control signal approaches the positive supply voltage of comparator 7b, so that the first switching element 6 is switched or triggered by the control signal and the fuse or circuit breaker 5 trips. The primary side current flowing due to tripping of the fuse or circuit breaker 5

Interrupted and the switching power supply primary side is turned off.

List of reference numerals

1 primary clock control switch power supply

2 primary side circuit branch

3 galvanic isolation

4 secondary side circuit branch

5 Primary side fuse or circuit breaker

6 first switching element

7 monitoring unit

7a RC unit

7b comparator, especially Schmitt trigger

7c threshold circuit

7d adaptation unit

8 first primary winding

9 second switching element

10 control unit

11 second primary winding

12 starter circuit

13 first feedback element

14 input connection

15 rectifier unit

16 transformer

17 secondary winding of transformer

18 diode for rectification

19 feedback circuit

20 smoothing diode

21 Voltage reference

22 diode

Primary side current

Ue input voltage

Ua output voltage