WO2008142018A1

WO2008142018A1 - Lossy low-pass filter

Info

Publication number: WO2008142018A1
Application number: PCT/EP2008/056040
Authority: WO
Inventors: Hubert Schierling
Original assignee: Siemens Aktiengesellschaft
Priority date: 2007-05-23
Filing date: 2008-05-16
Publication date: 2008-11-27
Also published as: DE102007023845A1; DE102007023845B4

Abstract

The invention relates to a lossy low-pass filter (22) having a filter inductor (16), a filter capacitor (18), and a damping resistor (32), which is electrically connected in series to the filter capacitor (18). According to the invention, the filter capacitor (18) is divided into at least two capacitor branches (36, 38) and a separating device is provided in at least one capacitor branch (38). In this way, a lossy low-pass filter is obtained, which has low power dissipation and is robust compared to arbitrary networks.

Description

description

Lossy low-pass filter

The invention relates to a lossy low-pass filter according to the preamble of claim 1.

Filter circuits, in particular LC low-pass filters, have a resonance frequency. If such a filter is excited in the vicinity of this resonance frequency, this excitation is greatly enhanced. This excitation can be done by mains harmonics or harmonics of a connected to a network inverter.

Because of this problem, a filter is designed so that no excitation occurs near the resonance frequency. Since suggestions can not be completely ruled out, damping resistances are provided which keep an occurring resonance peak within tolerable limits. However, one must reckon with these low-pass filters with an increased power loss.

These LC low-pass filters, in particular lossy low-pass filters, can be used as mains filters or as output filters in a converter. Filters that have the described problem can be seen from the fact that in them the rms value of the capacitor current in the event of excitation in the resonance is greater than in normal operation.

FIG. 1 shows a block diagram of an inverter 2 without a DC link capacitor, which is provided with a line filter 4. This converter 2 has a regenerative network-clocked power converter 6, which is also referred to as a fundamental frequency front end converter (FE), and a self-commutated pulse-controlled converter 8 on the load side. These two power converters 6 and 8 are the direct voltage side electrically conductive with each other connected. The network-side terminals 10, 12 and 14 of the network-side regenerative power converter 6 are electrically connected by means of the network filter 4 with a network, not shown. As a line filter 4, an LC low-pass filter is provided, which has a filter inductor 16 and a filter capacitor 18 for each mains phase. The filter inductance 16 can be generated by a choke or by the internal resistance of the network. The filter capacitors 18 are electrically connected in this illustration in delta, but can also be electrically connected in star. This voltage intermediate-circuit converter 2 with a FE feed-in converter 6 is described in detail in the publication "PCIM 2003 - Nuremberg", May 2003, so that it is not necessary to discuss this converter in more detail here.

FIG. 2 shows a block diagram of a load-side converter 20 of a voltage intermediate-circuit converter (not shown in full) with an output filter 22 (FIG. 1 of EP 0 682 402 A1). From the voltage source inverter also a DC link capacitor 24 is shown. The output-side terminals 26, 28 and 30 of the load-side converter 20, which is also referred to as an inverter, are associated with inputs of the output filter 22, at whose outputs a load is connected. As output filter 22, a lossy LC low-pass filter is provided. This lossy low-pass filter 22 has a filter inductor 16, a filter capacitor 18 and a damping resistor 32 for each output phase of the inverter 20. The filter capacitors 18 are electrically connected in star in this illustration, but can also be electrically connected in a triangle. In each case a damping resistor 32 is electrically connected in series with a filter capacitor 18. By means of these damping resistors 32, the rms values of the

Capacitor currents damped in the event of excitation in the resonance. Through the use of damping resistors 32, the power loss of this filter 22 increases. The invention is based on the object of developing a lossy low-pass filter in such a way that its power loss is reduced.

This object is achieved with the characterizing features of claim 1 according to the invention.

Characterized in that a respective filter capacitor is divided into at least two capacitor branches, a separating device can be arranged in one of these capacitor branches. By means of this separation device, this capacitor branch is separated at a resonance frequency excitation. As a result, the capacitance value of the filter capacitor changes, causing this lossy low-pass filter to be detuned. As a result, the lossy low-pass filter closes its resonance range, so that the excitation is not amplified so much. The detuning of this lossy low-pass filter depends on the number of separable capacitor branches. By virtue of this refinement of the lossy low-pass filter according to the invention, the existing damping resistances can be reduced in their values, as a result of which the resulting power loss is likewise reduced.

As a disconnecting device, a switch and a temperature measuring device may be provided, wherein the temperature measuring device with a damping resistor of a capacitor branch of a capacitor strand of the lossy low-pass filter is thermally and output side linked to a control input of the switch. As a result, the separation of a capacitor branch of a capacitor strand is achieved as a function of the temperature of this resistor.

More advantageous and less expensive is the use of a resistor with a positive temperature coefficient, a so-called PTC resistor. This PTC resistor is electrically in series with a capacitor of a capacitor branch each connected to a capacitor strand of the lossy low-pass filter. The electrical resistance of this PTC resistor increases with increasing temperature so much that this capacitor branch appears to be separated for the capacitor current. Since this resistor with positive temperature coefficients can conduct a current only at low temperatures, this is also referred to as a PTC thermistor.

The dependent claims 4 to 6 can be seen how the components of several capacitor branches of a capacitor strand can be combined.

By dividing a respective filter capacitor of a capacitor strand of, for example, a multiphase lossy low-pass filter into at least two capacitor branches, it is now possible to detune the resonant frequency of this multiphase lossy low-pass filter by separating at least one capacitor of a capacitor strand such that an excitation of the Filters in the vicinity of the non-detuned resonant frequency no longer leads to an overload of the filter. Therefore, such a filter according to the invention can be designed with less damping, that is, with lower losses. A filter according to the invention, which is used as a line filter, can be used for a wide range of network inductance. This makes such a filter robust against any network.

To further explain the invention, reference is made to the drawing, in which several embodiments of a capacitor string of a lossy low-pass filter according to the invention are schematically illustrated.

Figure 1 shows a block diagram of an inverter with a line filter, in the Figure 2 is a block diagram of an inverter of an inverter with associated output filter shown, the

FIG. 3 shows a first embodiment of a capacitor string of a lossy one

Low-pass filter according to the invention, wherein in the

Figure 4 shows an advantageous embodiment of a capacitor string of a lossy low-pass filter according to the invention is shown and wherein in the

Figures 5 to 7 show different embodiments of the capacitor string according to Figure 4 are shown.

FIG. 3 shows a first embodiment of a capacitor string 34 of a lossy, for example polyphase, low-pass filter 22. In FIG. 2, a series connection of a damping resistor 32 and a filter capacitor 18 forms a capacitor string 34. According to the invention, this filter capacitor 18 is split into two capacitor branches 36 and 38. In the capacitor branch 36, a capacitor 40 and the damping resistor 32 are electrically connected in series, wherein in the capacitor branch 38, a capacitor 42 and a switch 44 are electrically connected in series. The sum of the two capacitance values of the two capacitors 40 and 42 corresponds to the capacitance value of the filter capacitor 18, for example the lossy low-pass filter 22 of FIG. 2. Compared to the conventional capacitor string, this capacitor string 34 also has a temperature measuring device 36 which thermally couples with the damping resistor 32 is linked. On the output side, this temperature measuring device 46 is electrically conductively connected to a control input of the switch 44. As switch, any switchable semiconductor switch or mechanical switch (relay) can be provided. As soon as the temperature of the damping resistor 32 exceeds a predetermined temperature value, the capacitor branch 38 of this capacitor string 34 is separated. This halves the capacitance value of the filter capacitor 18, as a result of which this filter 22 is detuned. As a result, excitation in the vicinity of the resonance frequency of the filter 22 is canceled because the resonance frequency of the detuned filter 22 is not equal to the resonance frequency of the un-detuned filter 22. As a result, the resistance of the damping resistor 32 may be lower, whereby the lossy low-pass filter 22 according to the invention has a lower attenuation. Because of the lower attenuation, this filter 22 also has a lower power loss.

4 shows an advantageous embodiment of a capacitor string 34 of the lossy low-pass filter 22 is shown schematically. This advantageous embodiment differs from the embodiment according to FIG. 3 in that, instead of the switch 44 and the temperature measuring device 46, a resistor 48 with positive temperature coefficients is provided. This PTC thermistor 48 is connected electrically in series with the capacitor 42 of the capacitor branch 38 of the capacitor string 34. With reaching a PTC temperature of this PTC thermistor 48 is very high. The transition from low-impedance to high-impedance state is very steep. In high-resistance state, this PTC resistor 48 can no longer conduct electricity. As a result, the capacitor 42 is switched out of this capacitor string 34, whereby the capacitance value of the filter capacitor 18 has been halved.

FIG. 5 schematically illustrates another embodiment of a capacitor string 34 of a lossy low-pass filter 22 according to the invention. This capacitor string 34 differs from the capacitor string 34 of Figure 4 in that the capacitor branch 38, a further damping resistor 50 is provided which is electrically connected in series with the PTC resistor 48. As a result, a thermistor 48 having a smaller resistance can be used. This PTC thermistor 48 is cheaper compared to the PTC thermistor 48 of the embodiment of Figure 4 and reaches its PTC temperature in a shorter time. This has changed that Response behavior of the lossy low-pass filter 22 is substantially improved according to the invention, whereby this is detuned immediately when excited at resonance frequency. In addition, the attenuation of the filter can be chosen so independent of the availability of PTC resistors of appropriate size by this further damping resistor.

FIG. 6 illustrates a further embodiment of a capacitor string 34 of a lossy low-pass filter 22 according to the invention. This embodiment differs from the embodiment according to FIG. 5 in that the capacitor branch 36, consisting of the series connection of the damping resistor 32 and the capacitor 40, is connected electrically in parallel to the series connection of the cold conductor 48 and the capacitor 42 of the capacitor strand 38. Thereby, the damping resistor 50 for both capacitor branches 36 and 38 is effective. That is, the resistance value of the damping resistor 32 of the capacitor branch 36 can be further reduced without changing the operation of the detuning of the filter 22 anything. In addition, the resistor 50 contributes to detuning the filter for damping.

FIG. 7 shows a further embodiment of a capacitor string 34 of a lossy low-pass filter 22 according to the invention. In this embodiment of the capacitor string 34, a filter capacitor 18 of the filter 22 is divided into three capacitors 40, 42 and 52, which are each arranged in a capacitor branch 36, 38 and 54. These capacitor branches 36, 38 and 54 are electrically connected in parallel, so that the sum of the capacitance values of these three capacitors 40, 42 and 52 is equal to the capacitance value of the filter capacitor 18 of the low-pass filter 22 according to FIG. The two capacitor branches 36 and 38 each have a PTC resistor 48 and 56. These three electrically parallel capacitor branches 36, 38 and 40, a damping resistor 58 is connected in series. In this embodiment, the PTC thermistors 48 and 56 and the capacitor values are chosen so that the detuning of the filter 22 is made stepwise. In the first stage, the capacitance value of the filter capacitor 18 is reduced by one third, wherein in a second stage, the capacitance value is reduced by a third. This also dominates the case that the excitation contains both the resonance of the unvoiced filter and that of the first-stage detuned filter.

The configuration according to the invention of the capacitor strings 34 of a lossy multiphase low-pass filter can be applied to all filter topologies in which the effective value of a capacitor current in the case of excitation in the resonance becomes greater than in normal operation. This means that the invention can be applied not only to the line filter of a F E converter of a voltage source converter 2 according to FIG. 1, but to all types of line filters and also to output filters of converters, for example according to FIG.

Due to the inventive design of each capacitor strand 34 of a lossy low-pass filter 22 reduces the cost of such a filter, because the size of the damping resistors can be reduced. As a result, a lossy low-pass filter 22 with capacitor strands 34 designed according to the invention has a lower power loss. In addition, this filter 22 is more robust against mains harmonics, mains impedance variations, and harmonic distortion of the power converter.

Claims

claims

1. lossy low-pass filter (22) having a filter inductance (16), with a filter capacitor (18) and with a damping resistor (32) which is electrically connected in series with the filter capacitor (18), characterized in that the filter capacitor ( 18) is divided into at least two capacitor branches (36, 38), and that in at least one capacitor branch (38) is provided a separating device.

2. lossy low-pass filter (22) according to claim 1, characterized in that as a separator, a switch

(44) and a temperature measuring device (46) is provided, that this temperature measuring device (46) is thermally connected to a damping resistor (32), and in that this temperature measuring device (46) output with a control input of the switch (44) is linked.

3. Lossy low-pass filter (22) according to claim 1, characterized in that a resistor (48) with a positive temperature coefficient is provided as the separating device.

4. lossy low-pass filter (22) according to any one of the preceding claims, characterized in that in each capacitor branch (36, 38), a damping resistor (32, 50) is arranged.

5. lossy low-pass filter (22) according to any one of claims 1 to 3, characterized in that the capacitor branches (36, 38) together with a damping resistor (50) is associated.

6. lossy low-pass filter (22) according to one of claims 1 to 3, characterized in that in the capacitor branch (38) with the separating device, a damping resistor (50) is arranged.

7. Loss-affected low-pass filter (22, according to claim 2, characterized in that a switch-off semiconductor switch is provided as the switch (44).

8. lossy low-pass filter (22) according to any one of the preceding claims, characterized in that in a three-phase low-pass filter, the capacitors (18) are electrically connected in delta.

9. lossy low-pass filter (22) according to one of claims 1 to 7, characterized in that in a three-phase low-pass filter, the capacitors (18) are electrically connected in star.