DE102021117076A1 - DC voltage converter and converter arrangement with a DC voltage converter - Google Patents

Abstract

DC-DC converter for converting a first DC voltage V1 into a second DC voltage V2, comprising a converter unit (2) with a number M of electronically controllable half-bridges (3, 3'), where M is greater than one, and a control unit (4) which is designed for this purpose to activate the half-bridges (3, 3') in a modulation method with a time delay with an essentially identical switching frequency fr, the outputs of the half-bridges (3, 3') each being connected together via interleaving chokes (5, 5'), and wherein a first LC filter stage (11) formed by the interleaving chokes (5, 5') and first filter capacitors (8, 8') is provided for deriving high-frequency interference from the direct voltage V2, as well as a converter arrangement with such a direct voltage converter.

Description

The invention relates to a DC voltage converter and a converter arrangement with a DC voltage converter of this type.

Direct voltage converters, also called DC-DC converters, are used to convert a first direct voltage V ₁ into a second direct voltage V ₂ at a higher, lower or inverted level and are basically known from the prior art. The voltage is converted using a switched converter unit with electronically controllable semiconductor bridge circuits that sample the first DC voltage at a high frequency using a modulation method, for example pulse width modulation (PWM), as well as an inductance as an energy store. The switching frequency of the modulation method is far above the mains frequency and mostly in the range of over 20 kHz.

Such DC voltage converters are suitable for a wide range of applications in the industrial sector, but also for applications in the automotive sector. For example, a DC voltage from a battery or a DC voltage intermediate circuit for supplying various electrical loads can be converted to different voltage levels, for example in order to transform the battery voltage in the vehicle to the level of the on-board network. In test stands for electrical and mechanical drives, too, a centrally available high-level direct voltage is converted to voltages of significantly lower levels to supply the load machines (dynamometers). With additional rectifiers or inverters on the input side, multi-stage converter arrangements can be created for a wide variety of applications.

In industrial applications and test stands, converter arrangements of this type are preferably designed for bidirectional operation, ie they enable electrical power to flow from the first direct voltage V ₁ to the second direct voltage V ₂ and vice versa. This is made possible by the use of bidirectionally switched converters.

Due to the high switching frequency of the modulation method of the converter unit, however, high-frequency interference occurs, which superimposes the generated signals. These disturbances lead to a violation of regulations regarding EMC (electromagnetic compatibility). In order to divert the interference, it is known to provide LC filter arrangements at the output of the converter unit. However, due to the LC components used, such filter arrangements are large and make a compact design more difficult, which in turn makes their use in vehicles more difficult.

It is an object of the invention to solve these and other problems and to provide a compact DC-DC converter and a modular converter arrangement that can be used, for example, in a vehicle as a DC / DC converter, in an industrial application or in a test bench to generate a trouble-free DC voltage intermediate circuit can be used. The generation of high-frequency interference in the generated direct voltage should be avoided or reduced to a minimum.

These and other objects are achieved by a DC voltage converter according to claim 1.

A DC voltage converter according to the invention is designed to convert a first DC voltage V ₁ into a second DC voltage V ₂ and comprises a switched converter unit with at least M electronically controllable half bridges, M being greater than one. The converter unit can be single-phase or multi-phase; the number M of half bridges per phase can be, for example, two, three, four, five, six or more. Each of the half bridges can comprise two controlled semiconductor switches, preferably SiC transistors or GaN transistors.

According to the invention, an electronic control unit is provided which is designed to activate the M half-bridges in a modulation method with a time delay at a substantially identical switching frequency f _T. This results in an increase in the effective switching frequency by the factor M to M × f _T at the output of the converter unit, and a more precise resolution and conversion of the direct voltage can be achieved.

According to the invention, the outputs of the half bridges are each interconnected via interleaving chokes. That is, the M half bridges of the converter unit are interconnected via M interleaving chokes. This has the advantage that a smooth transition of the current between the switched half bridges is possible and interference is reduced. The interleaving chokes can be current-compensated chokes. In particular, this can mean that their windings are arranged in opposite directions on a common iron core.

The use of current-compensated interleaving chokes is particularly advantageous when using SiC transistors in the half bridges.

According to the invention, a first LC filter stage is provided to divert high-frequency interference from the direct voltage V _2. This first LC filter stage is formed by the interleaving chokes and first filter capacitors. The first LC filter stage is arranged at the output of the converter unit, in particular between the DC voltage connections of the DC voltage V ₂ . In particular, the first filter capacitors can be arranged symmetrically between the DC voltage connections of the DC voltage V ₂ .

According to the invention, the interleaving chokes have longitudinal and transverse inductances which can be dimensioned separately. According to the invention, the longitudinal inductance or longitudinal reactance of the interleaving choke, which is not required in generic DC voltage converters, is dimensioned in such a way that the desired filter effect is obtained. By using the longitudinal reactance of the interleaving chokes to form the first LC filter stage, it is not necessary to provide a separate filter element.

In particular, it can be achieved that a total harmonic content (distortion factor) of the direct voltage V ₂ of 3% is not exceeded.

For this purpose it can be provided that the cutoff frequency of the first LC filter stage is in the range of M times the switching frequency f _T , preferably in the range of approximately 0.8 × M × f _T to 1.2 × M × f _T. As a result, this filter stage ensures the efficient removal of interference that occurs with approximately M times the switching frequency.

The ratio of the longitudinal inductance to the transverse inductance of the interleaving chokes can be in a range from approximately 100 to approximately 10,000. The interleaving chokes can in particular have a longitudinal inductance of approximately 7.5 μH and a transverse inductance of approximately 1.94 mH. The first filter capacitors can, for example, have a capacitance of approximately 30 μF.

Furthermore, a second filter stage can be provided according to the invention, which is formed by a filter choke and second filter capacitors. The cutoff frequency of the first LC filter stage can differ from the cutoff frequency of the second LC filter stage. In particular, the cutoff frequency of the first LC filter stage can be smaller than the cutoff frequency of the second LC filter stage. The inductance of the filter choke can be around 1 µH. The cutoff frequency of the second LC filter stage can be in the range of a multiple of the M times the switching frequency f _T , preferably in the range of approximately 4 × M × f _T to approximately 10 × M × f _T. As a result, this filter stage ensures the efficient derivation of harmonics of the switching frequency.

The first filter capacitors and second filter capacitors can be separate components. However, embodiments are also provided in which the first filter capacitors and the second filter capacitors are formed by one and the same components.

The second filter capacitors can be arranged symmetrically between the DC voltage connections of the DC voltage V ₂ .

The filter reactor can connect the symmetry points of the first filter capacitors and the second filter capacitors.

The first LC filter stage and possibly also the second LC filter stage can be dimensioned in such a way that a total harmonic content (distortion factor) of the direct voltage V ₂ of 3% is not exceeded.

The control unit can be designed to control the half bridges of the converter unit with different switching frequencies. For example, when using SiC transistors in the converter unit, a switching frequency f _T of 24 kHz, 33 kHz, 75 kHz or higher up to 200 kHz can be provided. In contrast, when using GaN transistors in the converter unit, a significantly higher switching frequency fr can be provided, for example up to 2 MHz. The converter unit can also be designed to generate a DC voltage V ₂ of up to 60 V, up to 200 V, up to 1000 V or up to 1500 V, with voltages of up to 200 V preferably provided when using GaN transistors and SiC transistors are used for higher voltages. If the DC voltage converter is connected to a fuel cell, for example, the DC voltage V ₁ can assume a value of 200V to 400V, for example. In industrial applications (DC voltage island network) or when operating a test bench (DC voltage intermediate circuit), V ₁ can be 850 V, for example.

According to the invention, the DC voltage converter can also have several converter units connected in parallel, each with M half bridges, the outputs of the half bridges being connected together via interleaving chokes. For example, two converter units connected in parallel can be provided, each of which has two half bridges, the outputs of which are connected together via two interleaving chokes.

Such an arrangement can be used on the one hand to distribute the transmitted electrical power to the converter units connected in parallel, so that the semiconductor switches have to switch a lower power. In this case, the control unit is designed to activate the converter units synchronously with one another. The effective switching frequency in this case is approximately M times the switching frequency f _T.

In addition, such an arrangement can also be used to increase the effective switching frequency. For this purpose, the control unit can be designed to activate the converter units connected in parallel with one another in a time-shifted manner. The effective switching frequency is then approximately N × M × f _T , where N denotes the number of converter units connected in parallel. The filter components can be made smaller due to the higher effective switching frequency.

The invention also extends to a converter arrangement for converting an alternating voltage V _ac into a direct voltage V _2, comprising a direct voltage converter according to the invention. For this purpose, a switched rectifier, which is preferably also activated by the control unit, is provided for converting the alternating voltage V _ac into a direct voltage V ₁ . This can be used in particular to generate a DC voltage intermediate circuit.

The rectifier and the converter unit can preferably be designed as an integrated converter assembly, so that a particularly compact solution is achieved. Such an integrated converter assembly can also be referred to as an “inverter stack”.

According to the invention it can also be provided that an inverter is provided for converting an input direct voltage Vin into the alternating voltage V _ac . If necessary, a network converter can be provided to provide the DC input voltage V _in . Furthermore, a transformer can be provided for transforming the alternating voltage V _ac into a galvanically separated alternating voltage V _ac '. The converter unit and possibly also the inverter can be designed for bidirectional operation, so that the converter arrangement is also designed to convert a direct voltage V ₂ into an alternating voltage V _ac . If necessary, the inverter can also be designed for bidirectional operation, so that the converter arrangement is also designed to convert a direct voltage V ₂ into another direct voltage Vin. These and a large number of other applications are made possible by the use of a DC voltage converter according to the invention with a first and optionally also a second filter stage.

• 1a - 1d zeigen schematische Ausführungsbeispiele verschiedener Ausführungsformen erfindungsgemäßer Gleichspannungswandler als Blockschaltbild und als vereinfachtes elektrisches Schaltbild;
• 2a - 2d zeigen weitere schematische Ausführungsbeispiele von erfindungsgemäßen Gleichspannungswandlern anhand vereinfachter Schaltbilder;
• 3 - 4 zeigen zwei schematische Ausführungsbeispiele von Ausführungsformen erfindungsgemäßer Umrichteranordnungen anhand von vereinfachten Blockschaltbildern.

Further features according to the invention emerge from the patent claims, the figures and the following description of the figures. The invention is explained below using non-exclusive exemplary embodiments:

• 1a - 1d show schematic exemplary embodiments of various embodiments of DC voltage converters according to the invention as a block diagram and as a simplified electrical circuit diagram;
• 2a - 2d show further schematic exemplary embodiments of DC voltage converters according to the invention on the basis of simplified circuit diagrams;
• 3 - 4th show two schematic exemplary embodiments of embodiments of converter arrangements according to the invention on the basis of simplified block diagrams.

1a shows a schematic embodiment of an embodiment of a DC voltage converter according to the invention as a simplified block diagram. The DC voltage converter comprises a switched converter unit 2, controlled by an electronic control unit 4 via an interface, for converting a direct voltage V ₁ into a direct voltage V ₂ . The DC voltage V ₁ is provided by a battery.

1b shows a schematic embodiment of a further embodiment of a DC voltage converter according to the invention as a simplified block diagram. The DC voltage converter comprises a switched converter unit 2, controlled by an electronic control unit 4, for converting a direct voltage V ₁ into a direct voltage V ₂ . The direct voltage V ₁ is made available in a direct voltage intermediate circuit 15 by a rectifier ₁ which converts _{an input alternating voltage V ac} into an intermediate circuit direct voltage V 1. The converter unit 2 converts the intermediate circuit direct voltage V ₁ into the output direct voltage V ₂ . An electronic control unit 4 is provided, which is connected to the rectifier 1 and the converter unit 2 via an interface to control them. The control unit 4 can also be divided into separate units.

1c FIG. 4 shows a simplified electrical circuit diagram of the exemplary embodiment from FIG 1b . The input alternating voltage V _ac is converted by a switched bridge rectifier 1 into a direct voltage V ₁ at a direct voltage intermediate Schenkkreis 15 provided. A switched converter unit 2 converts the intermediate circuit direct voltage V ₁ into an output direct voltage V ₂ .

The rectifier 1 and the converter unit 2 each comprise two electronically switchable half bridges 3a, 3a ', 3, 3'. The half bridges each include two electronically switchable semiconductor switches that are controlled by an electronic control unit 4. In this exemplary embodiment, the control unit 4 is implemented as an integrated electronic component; the semiconductor switches are designed as SiC transistors with free-wheeling diodes connected in parallel. The control unit 4 is designed to activate the half-bridges 3a, 3a 'of the rectifier 1 and the half-bridges 3, 3' of the converter unit 2 in a modulation method with a period T, a switching frequency f _T and a time-variable duty cycle t _{on / T.} In the present exemplary embodiment, the switching frequency f _{T of} each individual half bridge is approximately 33 kHz.

In this exemplary embodiment, the outputs of the half bridges 3, 3 'of the converter unit 2 are interconnected via two interleaving chokes 5, 5'. The interleaving chokes 5, 5 'each have their own independent iron core. The fact that the control unit 4 activates the half bridges 3, 3 'of the converter unit 2 with a time delay results in a doubling (M = 2) of the effective switching frequency f _T at the output.

A first LC filter stage 11 is provided at the output of the converter unit 2. The first LC filter stage 11 is formed by the longitudinal inductance of the interleaving chokes 5, 5 'and first filter capacitors 8, 8'. The longitudinal inductance here denotes the inductance between the half bridges 3 or 3 'and the point of symmetry 14; The transverse inductance is the inductance between the half bridges 3 and 3 ', i.e. the inductance which limits the circulating currents between the half bridges.

The first filter capacitors 8, 8 'are arranged symmetrically in a star shape between the DC voltage connections 13, 13'. The first filter capacitors 8, 8 ′ interact with the unused longitudinal reactance of the interleaving chokes 5, 5 ′ in order to form the first LC filter stage 11.

1d shows a further development of the embodiment according to 1c . In this exemplary embodiment, a downstream, second LC filter stage 12 is provided. The second filter stage 12 is formed by a filter choke 9 and second filter capacitors 10, 10 '. In this example, both the first filter capacitors 8, 8 'and the second filter capacitors 10, 10' are each in a star shape symmetrically between the DC voltage connections 13, 13 ', and the filter choke 9 connects the star or symmetry points 14, 14' of the first Filter capacitors 8, 8 'with those of the second filter capacitors 10, 10'.

2a shows a schematic electrical circuit diagram of an embodiment of a converter arrangement according to the invention with a DC voltage converter according to the invention. An input AC voltage V _ac is converted into a DC voltage V ₁ , the first LC filter stage 11 and the second LC filter stage 12 essentially as in the exemplary embodiment in FIG 1d are trained. However, the interleaving chokes 5, 5 'are designed here as current-compensated chokes. Such an arrangement, in which two interleaving chokes 5, 5 'are wound on a common iron core, can also be referred to as a single current-compensated interleaving choke with two windings.

The inverter 1 and the converter unit 2 are integrated in a structurally integrated converter assembly 16, namely a so-called inverter stack. This contains four electronically switchable half bridges 3, 3 ', 3a, 3a', which are controlled by the control unit 4 in order to fulfill the function of rectification (half bridges 3a, 3a ') and DC voltage conversion (half bridges 3, 3'). No separate DC voltage intermediate circuit 15 is provided.

The interleaving chokes 5, 5 'are with non-bifilar edgewise windings with about nine windings per leg on a nanocrystalline cut _{ribbon core with high relative magnetic permeability (µ r} of about 40,000), a core cross-section of about 17 cm ² and a very small air gap of about 150 µm. The inductance of each individual winding is about 500 µH, the coupling factor 0.97, the longitudinal inductance about 7.5 µH and the transverse inductance about 1.94 mH.

The assigned first filter capacitors 8, 8 'each have a capacitance of approximately 30 µF per phase, so that the cut-off frequency of the low-pass filter formed by the first filter arrangement 8 assumes a value of approximately 67 kHz: $$ƒ=\frac{1}{\sqrt{\mathrm{L.}\mathrm{C.}}}=\frac{1}{\sqrt{7.5\mu H\cdot \mathrm{30th}\mu \mathrm{F.}}}=66.67kHz$$

This corresponds to about 2 times (M times) the switching frequency of 33 kHz, so that the interference caused by switching processes can be effectively filtered.

2 B shows a schematic electrical circuit diagram of a further embodiment of a converter arrangement according to the invention. The input alternating voltage V _ac is converted into a direct voltage V ₁ , the first LC filter stage 11 and the second LC filter stage 12 essentially as in the exemplary embodiment in FIG 2a are trained.

As in the embodiment according to 2a no separate inverter 1 and converter unit 2 are provided, but these components are integrated in a structurally integrated converter assembly 16, namely a so-called inverter stack. However, this contains six electronically switchable half-bridges 3, 3 ', 3a, 3a', 3b, 3b ', which are controlled by the control unit 4 in order to perform the function of rectification (half-bridges 3a, 3a') and DC voltage conversion (half-bridges 3, 3 ' , 3b, 3b ').

In this exemplary embodiment, the half bridges 3, 3 'and the half bridges 3b, 3b' form two parallel connected converter units 2, 2 ', each half bridge being led to an interleaving throttle 5, 5', 5a, 5a '.

The interleaving chokes 5, 5 'and 5a, 5a' are each wound in opposite directions on a common iron core and are thus current-compensated. Such an arrangement of two current-compensated interleaving chokes can also be referred to as a single interleaving choke with two current-compensated windings.

The control unit 4 is designed in such a way that it activates the half bridges 3, 3 ', 3b, 3b' with a time delay, so that the effective switching frequency f _T quadruples (number of half bridges M = 2 and number of parallel converter units N = 2). Alternatively, the control unit 4 can control the half bridges 3, 3 ', 3b, 3b' synchronously, so that the effective switching frequency doubles (M = 2 and N = 1). In both variants, the transmitted electrical power is divided between the converter units 2, 2 'connected in parallel. Otherwise, this exemplary embodiment corresponds to that from 2a .

2c shows a schematic electrical circuit diagram of a further embodiment of a converter arrangement according to the invention. An input alternating voltage V _ac is converted into a direct voltage V ₂ , only a first LC filter stage 11 being provided. Again, no separate inverter 1 and converter unit 2 are provided, but these components are integrated in a structurally integrated converter assembly 16, namely a so-called inverter stack.

As in the embodiment of 2 B two converter units 2, 2 'connected in parallel, each with two half-bridges 3, 3' and 3b, 3b 'are provided, the outputs of which are interconnected via current-compensated interleaving chokes 5, 5', 5a, 5a '. The control unit 4 is designed to activate the converter units 2, 2 'synchronously with one another. Again, the transmitted electrical power is divided between the converter units 2, 2 '. The effective switching frequency is thus 2 × f _T in this exemplary embodiment. The output DC voltage V ₂ is in this embodiment, in contrast to 2 B , formed as a differential voltage between the outputs of the two converter units 2, 2 '.

2d shows a schematic electrical circuit diagram of a further embodiment of a converter arrangement according to the invention. A three-phase input AC voltage V _ac is converted into a DC voltage V ₂ , a first LC filter stage 11 and a second LC filter stage 12 being provided. Again, a structurally integrated converter assembly 16 with six electronically switchable half bridges 3, 3 ', 3a, 3a', 3b, 3b 'is provided, but only five of which are controlled by the control unit 4 to enable the rectification function (half bridges 3a, 3a ', 3b) and DC voltage conversion (half bridges 3, 3'). The half bridge 3b 'is not used; a division of the transmitted electrical power into two parallel branches or an increase in the effective switching frequency through further interleaving is dispensed with here. Otherwise, this exemplary embodiment corresponds to that from 2a .

3 shows a further schematic embodiment of an embodiment of a converter arrangement according to the invention. In turn, an integrated converter assembly 16 is provided which _{converts an alternating voltage V ac} into a direct voltage V2. On the input side, an inverter 17 is provided for converting an input direct voltage V ₁ into the alternating voltage V _ac . The inverter 17 is also controlled by the control unit 4.

_{A transformer 7 for transforming the alternating voltage V ac} into an electrically isolated alternating voltage V _ac 'is provided between the inverter 17 and the integrated converter assembly 16, the transformer 7 being designed with a transformation ratio that is not equal to one.

4th shows a further schematic embodiment of an embodiment of a converter arrangement according to the invention. In this exemplary embodiment, there is a network converter 6 on the input side to provide the input DC voltage voltage V ₁ provided; Otherwise, this embodiment corresponds to that from 3 .

The invention is not restricted to the present exemplary embodiments, but rather comprises all devices and methods within the scope of the following patent claims.

Terms used herein are not intended to be interpreted too narrowly. The specific circuit implementation of the inverter or rectifier is also not essential to the invention. Inverters or rectifiers provided according to the invention can always provide internal galvanic isolation and can be provided for medium to high electrical outputs, for example outputs in the range from 10 kW to 100 kW with a DC voltage of 12V, 24V, 48V, 230V or 850 V or up to 300 kVA AC power.

List of reference symbols

1

Rectifier

2

Converter unit

3, 3 ', 3a, 3a', 3b, 3b '

Half bridge

4th

Control unit

5, 5 ', 5a, 5a'

Interleaving throttle

6th

Grid converter

7th

transformer

8, 8 '

First filter capacitor

9

Filter choke

10, 10 '

Second filter capacitor

11th

First filter stage

12th

Second filter stage

13, 13 '

DC voltage connections

14, 14 '

Symmetry points

15th

DC voltage intermediate circuit

16

Integrated converter assembly

17th

Inverter

Claims (23)

DC voltage converter for converting a first DC voltage V ₁ into a second DC voltage V ₂ , comprising a. a converter unit (2) with at least M electronically controllable half bridges (3, 3 '), where M is greater than one, and b. a control unit (4) which is designed to activate the half bridges (3, 3 ') in a modulation process with a time delay at an essentially identical switching frequency f _T , wherein c. the outputs of the half bridges (3, 3 ') are interconnected via interleaving chokes (5, 5'), characterized in that a first LC filter stage (11) is provided to divert high-frequency interference from the DC voltage V _{2, which is caused by the interleaving} - Chokes (5, 5 ') and first filter capacitors (8, 8') is formed. DC-DC converter according to Claim 1 , characterized in that the interleaving chokes (5, 5 ') are current-compensated. DC-DC converter according to Claim 1 or 2 , characterized in that the cutoff frequency of the first LC filter stage (11) is in the range of M times the switching frequency f _T , preferably in the range of approximately 0.8 × M × f _T to 1.2 × M × f _T. DC voltage converter according to one of the Claims 2 or 3 , characterized in that the ratio of the longitudinal inductance to the transverse inductance of the interleaving chokes (5, 5 ') is in a range from about 100 to about 10,000. DC voltage converter according to one of the Claims 2 until 4th , characterized in that the interleaving chokes (5, 5 ') have a longitudinal inductance of about 7.5 µH and a transverse inductance of about 1.94 mH. DC voltage converter according to one of the Claims 1 until 5 , characterized in that the first filter capacitors (8, 8 ') have a capacitance of about 30 µF. DC voltage converter according to one of the Claims 1 until 6th , characterized in that the first filter capacitors (8, 8 ') are arranged symmetrically between DC voltage connections (13, 13') of the DC voltage V ₂ . DC voltage converter according to one of the Claims 1 until 7th , characterized in that a second filter stage (12) is provided, which is formed by a filter choke (9) and second filter capacitors (10, 10 '). DC-DC converter according to Claim 8 , characterized in that the inductance of the filter choke (9) is approximately 1 µH. DC-DC converter according to Claim 8 or 9 , characterized in that the border frequency of the second LC filter stage (12) is in the range of a multiple of the M times the switching frequency fr, preferably in the range of about 4 × M × f _T to about 10 × M × f _T. DC voltage converter according to one of the Claims 8 until 10 , characterized in that the second filter capacitors (10, 10 ') are arranged symmetrically between DC voltage connections (13, 13') of the DC voltage V ₂ and the filter choke (9) the points of symmetry (14, 14 ') of the first filter capacitors (8, 8 ') and the second filter capacitors (10, 10') connects. DC voltage converter according to one of the Claims 1 until 11th , characterized in that the first LC filter stage (11) and possibly also the second LC filter stage (12) are dimensioned such that a total harmonic content (distortion factor) of the direct voltage V ₂ of 3% is not exceeded. DC voltage converter according to one of the Claims 1 until 12th , characterized in that the number M of half bridges (3, 3 ') of the converter unit (2) is two, three, four, five, six or higher. DC voltage converter according to one of the Claims 1 until 13th , characterized in that each of the half bridges (3, 3 ') of the converter unit (2) comprises two controlled semiconductor switches, preferably SiC or GaN transistors. DC voltage converter according to one of the Claims 1 until 14th , characterized in that the control unit (4) is designed to control the half bridges (3, 3 ') when using SiC transistors with a switching frequency fr of up to 200 kHz, for example 24 kHz, 33 kHz, or 75 kHz, and when using GaN transistors to be controlled with a switching frequency fr of up to 2 MHz. DC voltage converter according to one of the Claims 1 until 15th , characterized in that it is designed to generate a DC voltage V ₂ of up to 60 V, up to 200 V, up to 1000 V or up to 1500 V. DC voltage converter according to one of the Claims 1 until 16 , characterized in that a. several converter units (2, 2 ') connected in parallel, each with a number M half bridges (3, 3', 3b, 3b ') are provided, the outputs of which are interconnected via interleaving chokes (5, 5', 5a, 5a '), where b. the control unit (4) is designed to activate the converter units (2, 2 ') synchronously with one another. DC voltage converter according to one of the Claims 1 until 16 , characterized in that a. several converter units (2, 2 ') connected in parallel, each with a number M half bridges (3, 3', 3b, 3b ') are provided, the outputs of which are interconnected via interleaving chokes (5, 5', 5a, 5a '), where b. the control unit (4) is designed to activate the converter units (2, 2 ') at a time offset from one another in order to increase the effective switching frequency of the DC-DC converter. Converter arrangement for converting an AC voltage V _ac into a DC voltage V ₂ comprising a DC voltage converter according to one of the Claims 1 until 18th , characterized in that a switched rectifier (1), preferably controlled by the control unit (4), is provided for converting the alternating voltage V _ac into a direct voltage V ₁ , for example in the form of a direct voltage intermediate circuit (15). Inverter arrangement according to Claim 19 , characterized in that the rectifier (1) and the converter unit (2) are designed as an integrated converter assembly (16). Inverter arrangement according to Claim 19 or 20th , characterized in that an inverter (17) is provided for converting an input direct voltage V _in into the alternating voltage V _ac , with a network converter (6) optionally being provided for providing the input direct voltage V _in , and a transformer (7) for transforming the alternating voltage V _ac into a galvanically separated alternating voltage V _ac '. Converter arrangement according to one of the Claims 19 until 21 , characterized in that the converter unit (2) and possibly also the inverter (1) is designed for bidirectional operation, so that the converter arrangement is also designed to convert a direct voltage V ₂ into an alternating voltage V _ac . Inverter arrangement according to Claim 22 , characterized in that the inverter (17) is also designed for bidirectional operation, so that the converter arrangement is also designed to convert a direct voltage V ₂ into another direct voltage Vin.

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