PRODUCING A MOTOR VOLTAGE FOR A SWITCH DRIVE

Abstract

A method for producing a voltage for an electric motor of a drive of an electrical switch includes producing a DC link direct voltage from a supply voltage and producing the motor voltage by pulse-width modulation of the direct voltage. A tolerance range for changing the direct voltage is specified, and an actual value of the direct voltage is continually measured. After first measuring the actual value, it is stored in a voltage variable. After each additional measurement, it is checked whether the deviation of the actual from the stored value lies within the tolerance range. The actual value is stored if the deviation from the stored value lies outside of the tolerance range. After each storage, a duty cycle of the pulse-width modulation dependent on the actual value is calculated, and the pulse-width modulation occurs with the duty cycle. A power converter is also provided.

Claims

1-15. (canceled)

16. A method for producing a motor voltage for an electric motor of a switch drive of an electrical switch, the method comprising: producing a DC link direct voltage from a supply voltage; producing the motor voltage by pulse-width modulation of the DC link direct voltage; specifying a tolerance range for a change in the DC link direct voltage; continually measuring an actual value of the DC link direct voltage; after a first measurement of the actual value, storing the actual value in a voltage variable; after each additional measurement of the actual value, checking whether a deviation of the actual value from the value stored in the voltage variable lies within the tolerance range, and storing the actual value in the voltage variable when the deviation of the actual value from the value stored in the voltage variable lies outside of the tolerance range; and after each storage of an actual value in the voltage variable, calculating a duty cycle, being dependent on the actual value, of the pulse-width modulation and carrying out the pulse-width modulation with the duty cycle.

17. The method according to claim 16, which further comprises specifying the tolerance range symmetrically around the value stored in the voltage variable.

18. The method according to claim 16, which further comprises specifying the tolerance range asymmetrically around the value stored in the voltage variable.

19. The method according to claim 16, which further comprises specifying limits of the tolerance range by absolute values of the deviation of the actual value from the value stored in the voltage variable.

20. The method according to claim 16, which further comprises specifying limits of the tolerance range by relative values of the deviation of the actual value from the value stored in the voltage variable.

21. The method according to claim 16, which further comprises detecting a calculation number of calculations of the duty cycle.

22. The method according to claim 21, which further comprises specifying a threshold value for the calculation number, comparing the calculation number with the threshold value and producing a warning signal when the calculation number reaches or exceeds the threshold value.

23. The method according to claim 21, which further comprises displaying the calculation number on a display unit.

24. A power converter for producing a motor voltage for an electric motor of a drive of an electrical switch, the power converter comprising: a first power converter unit configured to produce a DC link direct voltage from a supply voltage; a measuring unit configured to continually measure an actual value of the DC link direct voltage; a second power converter unit configured to produce the motor voltage by pulse-width modulation of the DC link direct voltage; and a control unit configured: to store a specifiable tolerance range for a change in the DC link direct voltage, after a first measurement of the actual value, to store the actual value in a voltage variable, after each additional measurement of the actual value, to check whether a deviation of the actual value from the value stored in the voltage variable lies within the tolerance range, and to store the actual value in the voltage variable when the deviation of the actual value from the value stored in the voltage variable lies outside of the tolerance range; and after each storage of an actual value in the voltage variable, to calculate a duty cycle, being dependent on the actual value, of the pulse-width modulation and to control the pulse-width modulation with the duty cycle.

25. The power converter according to claim 24, wherein said control unit is configured to detect a calculation number of calculations of the duty cycle.

26. The power converter according to claim 25, wherein said control unit is configured to store a specifiable threshold value for the calculation number, to compare the calculation number with the threshold value and to produce a warning signal when the calculation number reaches the threshold value.

27. The power converter according to claim 24, which further comprises a display unit configured to display the calculation number.

28. An electrical switch, comprising: a switch drive having an electric motor; and a power converter according to claim 24 for producing the motor voltage for the electric motor.

29. The electrical switch according to claim 28, wherein the electrical switch is a power switch or a circuit breaker.

30. A non-transitory computer program product with instructions stored thereon, that when executed by a control unit, perform the steps of claim 16.

Description

[0016] The above described properties, features and advantages of this invention as well as the manner in which they are achieved become clearer and more clearly comprehensible in the context of the subsequent description of exemplary embodiments which are explained in greater detail in the context of the drawings. In the drawings:

[0017] FIG. 1 shows a block diagram of an electrical switch,

[0018] FIG. 2 shows a circuit diagram of a power converter,

[0019] FIG. 3 shows a flow diagram of a method for producing a motor voltage.

[0020] Mutually corresponding parts are provided with the same reference numbers in the figures.

[0021] FIG. 1 (FIG. 1) shows a block diagram of an exemplary embodiment of an electrical switch 1 according to the invention, for example a power switch or a circuit breaker. The switch 1 comprises a power converter 3 according to the invention, a switch drive 5 with an electric motor 7 and an energy storage device 9 and a switch element 11. The power converter 3 is set up to produce a motor voltage for the electric motor 7 from a supply voltage in the manner described in more detail below based on FIG. 3 (FIG. 3). The energy storage device 9 can be charged by the electric motor 7. The energy storage device 9 is a spring accumulator with a spring which can be tensioned by the electric motor 7, for example. The switch element 11 is movable by way of energy stored in the energy storage device 9. A current path can be interrupted and closed by moving the switch element 11. Alternative exemplary embodiments of the switch 1 make provision for the switch element 11 to be able to be driven by the electric motor 7 directly or via a gearbox, instead of an energy storage device 9, for example.

[0022] FIG. 2 (FIG. 2) shows an exemplary embodiment of a power converter 3 according to the invention. The power converter 3 has two power converter units 13, 15, a DC link 17, a measuring unit 19 and a control unit 21. Each power converter unit 13, 15 has two series connected switch units 23, 24, between which a power converter connection 25, 26 is arranged in each case. The switch units 23, 24 are controllable semiconductor switches, for example, such as an IGBT or MOSFET. Alternatively, the switch units 23 of the first power converter unit 13 are diodes and the switch units 24 of the second power converter unit 15 are controllable semiconductor switches such as an IGBT or MOSFET. The DC link 17 comprises two DC link lines 27, 28, which connect the two power converter units 13, 15 to one another, and a DC link capacitor 29, the electrodes of which are connected to one of the DC link lines 27, 28 in each case. The measuring unit 19 is set up to measure a DC link direct voltage between the DC link lines 27, 28. The controllable switch units 23, 24 can be controlled by means of the control unit 21.

[0023] During operation of the power converter 3, a supply voltage is applied between the power converter connection 25 of a first power converter unit 13 and one of the DC link lines 27, 28. The DC link direct voltage is produced from the supply voltage by means of the first power converter unit 13. The supply voltage can be a single-phase alternating voltage or a direct voltage. If the supply voltage is a single-phase alternating voltage, it is rectified by the first power converter unit 13 to the DC link direct voltage. If the supply voltage is a direct voltage, it is used directly as a DC link direct voltage, for example, wherein a switch unit 23 of the first power converter unit 13 is permanently open and the other switch unit 23 of the first power converter unit 13 is permanently closed. The motor voltage for the electric motor 7 is produced by pulse-width modulation of the DC link direct voltage by means of the second power converter unit 15 in the manner described in more detail below. For this purpose, a motor winding of the electric motor 7 is connected to the power converter connection 26 of the second power converter unit 15.

[0024] The exemplary embodiment of a power converter 3 shown in FIG. 2 is set up for producing a single-phase motor voltage. Other exemplary embodiments can make provision for the power converter 3 to be able to produce a multiphase motor voltage, wherein the second power converter unit 15 has a pair of switch units 24 and a power converter connection 26 arranged therebetween for each phase of the motor voltage. Additionally or alternatively, other exemplary embodiments can make provision for the first power converter unit 13 to have a pair of switch units 23 and a power converter connection 25 arranged therebetween for each phase of a multiphase supply voltage, in order to produce the DC link direct voltage from a multiphase supply voltage.

[0025] FIG. 3 (FIG. 3) shows a flow diagram 100 of an exemplary embodiment of a method according to the invention for producing a specified motor voltage with a power converter 1 shown in FIG. 1. The method is implemented by a computer program which is executed by the control unit 21 and which evaluates actual values of the DC link direct voltage which are measured by the measuring unit 19.

[0026] In a first method step 101, a tolerance range for a change in the DC link direct voltage is specified. The tolerance range is specified symmetrically or asymmetrically around a value which is stored in a voltage variable during the method. The limits of the tolerance range are specified by absolute values or relative values of the deviation of the actual value from the value stored in the voltage variable in each case.

[0027] In a second method step 102, the power converter 3 is activated and an actual value of the DC link direct voltage is measured for the first time.

[0028] In a third method step 103, the current actual value of the DC link direct voltage is stored in the voltage variable.

[0029] In a fourth method step 104, a duty cycle, which is dependent on the value stored in the voltage variable, of the pulse-width modulation is calculated, in order to produce the motor voltage by pulse-width modulation of the DC link direct voltage.

[0030] In a fifth method step 105, the DC link direct voltage is pulse-width modulated with the duty cycle calculated in the fourth method step 104, wherein the switch units 24 of the second power converter unit 15 are correspondingly controlled by the control unit 21.

[0031] In a sixth method step 106, a current actual value of the DC link direct voltage is measured.

[0032] In a seventh method step 107, it is checked whether a deviation of the actual value measured in the sixth method step 106 from the value stored in the voltage variable lies within the tolerance range specified in the first method step 101. If this is the case, the method continues with an eighth method step 108. Otherwise, the method continues with the third method step 103.

[0033] In the eighth method step 108, it is checked whether the energy storage device 9 is fully charged. If this is the case (i.e. if the energy storage device 9 is fully charged), the method continues with a ninth method step 109. Otherwise, the method continues with the fifth method step 105.

[0034] In the ninth method step 109, the electric motor 7 is switched off and the method is concluded.

[0035] Provision can optionally be made for the calculations of the duty cycle to be counted during the method. Furthermore, provision can be made for the calculation number to be displayed and/or for a warning signal to be produced if the calculation number reaches or exceeds a specifiable threshold value. For this purpose, in the second method step 102, a count variable for the calculation number is initialized with the value zero, for example. Furthermore, provision can be made for a threshold value for the calculation number to be additionally specified in the first method step 101. In the fourth method step 104, the value stored in the count variable is then additionally incremented by one. The value currently stored in the count variable is displayed on a display unit 22 of the power converter 3, for example. If in the first method step 101 a threshold value for the calculation number has been specified, this value can further be compared with the threshold value in the fourth method step 104 after incrementing the value stored in the count variable, and an optical and/or acoustic warning signal can be emitted if the value stored in the count variable corresponds to the calculation number or exceeds the calculation number.

[0036] If the switch 1 does not have an energy storage device 9, but rather the switch element 11 can be driven by the electric motor 7 directly or via a gearbox, it is checked in the eighth method step 108 whether the switch element 11 has reached a switch position into which it is to be moved by the electric motor 7. If this is the case (i.e. if the switch element 11 has reached the switch position), the method continues with a ninth method step 109. Otherwise, the method continues with the fifth method step 105. The other method steps 101 to 107 and 109 are carried out as described previously.

[0037] Despite the fact that the invention has been illustrated and described in greater detail by preferred exemplary embodiments, the invention is not limited by the disclosed examples and other variations can be derived from this by the person skilled in the art, without departing from the scope of protection of the invention.