WO2014170059A1 - Dc-to-dc converter assembly having modular components, for simplified configuration - Google Patents

Abstract

The invention relates to a DC-to-DC converter assembly (10) for converting an input direct voltage (U1) into an output direct voltage (U2), comprising a coupling module (16), an input module (12) for transmitting the input direct voltage (U1) to the coupling module (16) by means of a first switching device (26), and an output module (14) for providing the output direct voltage (U2) from a voltage on the coupling module (16), wherein the input module (12), the output module (14), and the coupling module (16) are each designed as a separate module element, the input module (12) is electrically connected to the coupling module (16), and the coupling module (16) is electrically connected to the output module (14).

Description

description

DC-DC CONVERTER ARRANGEMENT WITH MODULAR COMPONENTS FOR EASY configurability The present invention relates to a DC ^¬ transducer assembly for converting a DC input voltage into a DC output voltage. The DC-DC converter arrangement comprises a coupling module, an input module for ^transmitting the input direct voltage to the coupling module by means of a first switching device and an output module for providing the DC output voltage from an electrical voltage applied to the coupling module. Moreover, the present invention relates to a method of manufacturing a DC-DC converter arrangement.

With the proliferation of renewable energy sources and electric vehicles, the demand for high-performance battery charging stations is increasing. Furthermore, stationary batteries in homes are used, for example, to store energy from photovoltaic systems during sun-rich periods, then retrieve them in low sunlight or at night and thus generate the energy locally or consume. Bidirectional DC battery charging stations also make it possible to stabilize the energy distribution grids by absorbing energy in the event of electricity surplus and by regenerating energy in the absence of electricity. At Bat ^¬ criteria of electric vehicles is the need to load them to the corresponding charging stations as quickly as possible to avoid long waiting times.

On DC-DC converter circuits which are used, for example, for battery charging and discharging, there are also technical quality requirements with regard to the current and voltage ripples. For example, the current ripple for charging and discharging lithium-ion batteries should not exceed 2 to 3% of the nominal charge or discharge current. For the applications described above, corresponding DC-DC converter arrangements are used whose central components are identical in all battery charging stations of similar power class. The electrical voltage and the current through these components in predetermined ranges are adjustable. An essential structural difference of the DC-DC converter arrangements lies in the galvanic isolation. A galvanic isolation between an input module to which a DC input voltage is applied, and an output module to which a DC output ^¬ voltage of the voltage is provided, is required beispielswei ^¬ se for DC rapid charging stations for electric vehicles, but not for the coupling of photovoltaic systems with battery storage indispensable. The galvanic isolation is realized by means of suitable transformers. Here, more transistors are used, which are operated with high switching frequencies up to 20 kHz. This space and weight can be saved. In addition, the use of materials can be reduced.

Decisive devices with and without electrical isolation are known from the prior art. For example, bidirectional DC-DC converters without electrical isolation based on thyristor technology are offered by the applicant. Furthermore, MOSFET or IGBT-based topologies for unidirectional and bidirectional DC-DC converters with electrical isolation are known from the literature. Such DC-DC converters are described, for example, in the article "A comparision of high-power DC-DC soft-switched converter topologies" by R. Steigerwald et al., IEEE Transactions on Industry Applications, 1996.

It is an object of the present invention to provide a DC-DC converter arrangement of the type mentioned at the beginning, which can be produced and operated more flexibly. Furthermore, the mentioned technical quality requirements should be met as economically as possible. This object is achieved by a DC-DC converter arrangement according to claim 1 and by a method according to claim 13. Advantageous developments of the vorlie ^¬ ing invention are the subject of the dependent claims.

The DC-DC converter arrangement according to the invention for converting a DC input voltage into a DC output voltage comprising a coupling module, an input module for Übertra ^¬ gene of the DC input voltage to the switching module by means of a first switching means, and an output module for providing the output DC voltage from a voltage applied to the switching module electrical voltage, wherein the Input module, the output module and the coupling module are each formed as a separate module element, the input module is electrically connected to the coupling module and the coupling ^¬ module is electrically connected to the output module.

The DC-DC converter arrangement represents a DC-DC converter with which an input DC voltage can be converted into an output DC voltage. In other words, with the DC-DC converter arrangement, a first

DC voltage to be converted into a second DC voltage. In this case, a bidirectional operation of the DC-DC converter arrangement can be provided. The input module may have corresponding input terminals to which the input DC voltage can be applied. Furthermore, the input module may have an input capacitance in the form of a capacitor electrically connected to the input terminals. In addition, the input module has a switching device in which the input ^DC voltage can be connected to corresponding output ^{terminals of} the input ^module . With the first switching device, the input DC voltage can be switched to the output terminals at predetermined times. The input DC voltage can be applied to the output terminals of the input module pulsed, for example, with the first switching device. The output terminals of the input module are connected to a coupling module or its input terminals. The coupling module is in turn electrically connected to an output module which provides the DC output voltage. In the simplest case, the coupling module an electrical connection can be provided at ^¬ play, via cable, between the input module and the output module. The coupling module may also include passive electrical filters. The DC output voltage can be generated, for example, by a second switching device of the output module from the electrical voltage that is emitted by the coil element of the coupling module. The DC-DC converter assembly may be configured so that the functionality of the high ^¬ boost converter or a buck converter is provided with it.

The input module, the output module and the coupling module are each designed as a separate module element. The individual modules may be formed as a single, separately constructed from elements ^¬. The individual modules may each be ^¬ weils arranged on a separate module carrier for example. For example, the modules can each be arranged on a separate heat sink. The electrical connection between the input module and the switching module and the coupling ^¬ module and the output module can be via electric Verbin ^¬-making lines, in particular cables. In this case, the input module, the output module and the coupling module can be arranged in a common housing. Thus, a Be ^¬ stückungskonzept for a DC-DC converter is provided. In addition, a modular Gleichspannungswandleranord ^¬ tion is provided, in which the individual modules can be easily replaced. Thus, the DC-DC converter arrangement can be adapted particularly effectively to the particular application.

In one embodiment, the input module, the output module are off ^¬ and the coupling module respectively disposed in a separate housing overall. In this case, the input module may have corresponding connection elements with which it can be connected to the Koppelmo ^¬ module. Also, the output module may have corresponding connecting elements with which it with can be connected to the coupling module. These Verbindungsele ^¬ elements can be provided for example in the form of screw or terminal contacts. By connecting ^¬ devices the input module with the coupling module and the coupling module with the output module can be connected reversibly detachable and non-destructive.

Preferably, the coupling module comprises at least one coil, which provides a galvanic connection between the input module and the output module in a connection of the input module to the coupling module and the coupling module with the output module. The coupling module can have at least one coil on ^¬, which is electrically connected to an input terminal and an output terminal of the switching module. The coupling module may also have two coils, wherein a first coil with a first input terminal and a first output terminal and the second coil with a second input ^terminal and ei ^¬ ner second output ^terminal are electrically connected. Thus, a galvanic connection between the input module and the output module of the DC-DC converter arrangement is provided. Thus, a DC-DC converter arrangement can be provided for applications in which a galvanic connection between the input module and the output module is not required. Such an application ^¬ case may for example consist of photovoltaic systems, in which energy is stored in a battery.

In a further embodiment, the coupling module comprises a transformer, which provides a galvanically isolated coupling between the input module and the output module in a connection of the input module to the coupling module and a connection of the coupling module with the output module. In this case, a first coil in the primary circuit of the transformer may be connected to the input terminals of the coupling module and a second coil in the secondary circuit of the transformer may be connected to the output terminals of the coupling module. Thus, a DC-DC converter is provided with a galvanic isolation between the input module and the output module. provides. When using a transformer or a separating transformer, the winding ratio can be selected so that it corresponds to the ratio between minimum DC input voltage and maximum DC output voltage. Such a DC-DC converter can, for example, for

 Fast charging stations for electric vehicles can be used.

In a further embodiment the coupling module comprises at least one electrical filter element, the circle in a primary and / or is integrally ^¬ assigns a secondary circuit of the transformer. The electrical filter element may be formed, for example, as a passive electrical filter element. The filter element may comprise a capacitor and a coil. This can be provided in a simple manner, for example, a resonant converter.

The first control device preferably comprises at least one semiconductor switch. The first switch means, with the DC input voltage is switched to the output terminals of the input gear module can, for example be formed by at least ^¬ a transistor or a thyristor. Preferably, the first switching device is formed by at least one IGBT or MOSFET. In this case, the first switching device can also be designed as a half bridge or full bridge. With such a first switching device, the DC input voltage can be transmitted to the coil element of the coupling module in a particularly effective manner.

In one embodiment, the output module has a second switching device for switching the voltage applied to the coupling module electrical voltage. Preferably, the two ^¬ th switching device comprises at least one diode and / or at least one semiconductor switch (IGBT, MOSFET). Thus, with the second switching device, the loading provided by the coil member riding electric voltage can be easily transferred to the output terminals of the output module ^¬. When using at least one diode as a second switching device, the DC-DC converter arrangement can be used as a unidirectional DC-DC converter can be used. When using at least one semiconductor switch, which can be actively controlled, a bidirectional DC-DC converter can be provided with the second switching device. Again, the diodes or semiconductor switches can be connected as a half-bridge or full bridge.

In a further embodiment, the DC-DC converter arrangement comprises a first terminal module, which is electrically connected to the input module, and / or a second terminal module, which is electrically connected to the output module, wherein the first and / or the second terminal ^{module ¬} an electrical Includes filter element. The first and the second terminal module can each be arranged in a separate housing. The electrical filter element in the first terminal module is used to filter Oberwel ^¬ len the electrical voltage in the input module. The electrical filter element in the second terminal module is used to filter harmonics of the electrical voltage in the output module. In particular, the electrical filter ^¬ elements serve for Stromrippleglättung.

Preferably, the DC-DC converter arrangement comprises a control device for controlling the first switching device and / or the second switching device. With the control device, the first and / or the second switching device can be controlled as a function of time. In this case, the first and / or the second switching device can be operated hard switching. Alternatively, the first and / or the second switching device can be operated according to a time offset with a so-called interleaved or phase-shifted switch control. Thus, the DC-DC converter arrangement can be adapted to the particular application.

In a further embodiment, the DC-DC converter arrangement has a detection device for detecting a type of the input module, the coupling module and / or the Output module on. With the detection device and the first and / or the second terminal module can be detected. In this case, the DC-DC converter arrangement can have a higher-level detection device with which the individual modules can be detected. Alternatively, such detection means may be vorgese ^¬ hen in each of the modules. With the detection device can be detected, for example, which switching devices are arranged in the input module and in the output module. In addition, it can be detected with the detection device whether the coupling module has at least one coil or a transformer. In this case, the detection device can also be designed to detect a faulty connection between the individual modules of the DC-DC converter arrangement. In this case, the first or the second switching device can be controlled with ^{¬ means of} the control device so that no damage to the respective modules of the DC-DC converter arrangement can take place. Thus, damage to the respective modules can be prevented and the safety in the operation of the DC-DC converter arrangement can be increased.

Preferably, the first switching means and / or said second switching means by the control means in dependence is controlled by a detected with the detection device type of the input module, the coupling module and / or the Ausgangsmo ^¬ duls. The control device may be coupled to the detection device. Depending on which type or construction of the individual modules is detected by the detection device, the switching devices can be controlled.

The inventive method for producing a DC-DC converter arrangement for converting a Eingangsgleich- voltage into a DC output voltage comprises providing a switching module, providing an input ^¬ module for transmitting the input DC voltage to the switching module by means of a first switching device, the ready provide an output module for providing the output ^¬ DC voltage from an applied voltage to the coupling module, the respective formation of the input module, the output module and the coupling module as a separate module element, the electrical connection of the input module with the coupling module and the electrical connection of Kop ^¬ pelmoduls with the output module.

The further developments described above in connection with the DC voltage converter arrangement according to the invention can be transferred to the method according to the invention.

The present invention will now be explained in more detail with reference to the accompanying drawings. Showing:

1 shows a DC voltage converter arrangement in a schematic representation;

2 shows the DC-DC converter arrangement in a first

 Embodiment, wherein the DC-DC converter arrangement is designed as a unidirectional buck-boost converter without galvanic isolation;

3 shows the DC-DC converter arrangement of another

 Embodiment, wherein the DC-DC converter arrangement is designed as a bidirectional buck-boost converter without galvanic isolation;

4 shows the DC voltage converter arrangement in a further embodiment, wherein the DC voltage ^¬ converter arrangement is designed as a unidirectional phase-shift converter with galvanic isolation;

Figure 5 illustrates the DC-DC converter arrangement in a further embodiment in which the DC voltage wall ^¬ leranordnung as a unidirectional phase-shift

Transducer is designed with galvanic isolation; Figure 6 shows the DC-DC converter arrangement in a further embodiment in which the DC ^¬ transducer assembly is formed as a bi-directional phase-shift converter with galvanic isolation;

7 shows the DC voltage converter arrangement in a further embodiment, wherein the DC voltage ^¬ converter assembly is designed as a bidirectional phase-shift converter with galvanic isolation and has a filter element; and

8 shows a coupling module for the DC-DC converter arrangement in a further embodiment. The embodiments described in more detail below represent preferred embodiments of the invention.

1 shows a DC voltage converter arrangement 10 in a schematic representation. The Gleichspannungswandleran- assembly 10 comprises an input module 12 to which a gear ^¬ A DC voltage Ul can be applied. The DC input voltage U1 can be applied to the input terminals 22, 24 of the input module 12. Furthermore, the DC-DC converter arrangement 10 comprises an output module 14, with which a DC output voltage U2 can be provided at the output terminals 28 and 30. In addition, the DC voltage ^¬ transducer assembly 10 includes a coupling module 16, which is connected to the input module 12 and output module 14 electrically verbun ^¬. Includes the input module 12, a not shown here presented first switching means 26 for transmitting the DC input voltage Ul to the switching module 16. In the output module 14, a second switching means 32 may be angeord ^¬ net, with the voltage dropped across the switching module 16 elekt ^¬ generic voltage the output terminals 28 and 30 is transmitted. Furthermore, the DC-DC converter 10 includes a first terminal module assembly 18 and a second termi ^¬ nalmodul 20. The terminal module 18 is connected to the input module 12 electrically connected and the second terminal module 20 is electrically connected to the output module.

In addition, the DC-DC converter arrangement 10 comprises a control device 46. The control device 46 is connected to the input module 12, the output module 14, the coupling module 16 and the terminal modules 18 and 20. This is illustrated by the dashed lines. In this way, the control device 46 can receive a respective identifier or an ID from the input module 12, the output module 14, the coupling module 16 and the terminal modules 18 and 20, or interrogate them from the modules 12, 14, 16, 18, 20. For this purpose, a detection device not shown here can be used. From the respective identifier, the control means 46 can determine the type 18 and 20 of the input module 12, the Ausgangsmo ^¬ duls 14, the coupling module 16 and the terminal modules. Depending on the detected type of the respective modules 12, 14, 16, 18 and 20 a respective control signal to the first switching input device 26 of the input module 12 and / or the second switching ^¬ device 32 of the output module 14 can be transmitted to the control device 46 ,

With the control device 46 or the detection device, an electrical connection between the individual modules 12, 14, 16, 18, 20 can be determined. With the control device 46, a signal can be output, depending on which the first and second switching means 26, 32 can be controlled. In this case, the individual modules 12, 14, 16, 18, 20 of the DC-DC converter arrangement 10 can be equipped with sensors and communication technology such that an impermissible combination of the modules 12, 14, 16, 18, 20 leads to a blockage of the control units of the active components Ql, Q2, Q3, Q4 of the first switching device 26 and / or the active components Qsl, Qs2, Qs3 and Qs4 of the second switching device 32, so that the DC-DC converter 10 can not be operated in such an improper combination. 2 shows the DC-DC converter arrangement 10 in a first embodiment. The input module 12 includes an input capacitance C1 that is electrically connected to the input terminals 22 and 24 of the input module 12. Furthermore, the input module 12 comprises a first switching device 26, which in the present embodiment is formed by the IGBTs Q1, Q2, Q3 and Q4. IGBTs Q1, Q2, Q3 and Q4 are in the present case connected to a full bridge. In addition, the output module 14 comprises an output capacitance C2, which is electrically connected to the output terminals 28 and 30. Furthermore, the output module 14 comprises a second switching device 32 which is formed by four diodes Dl, D2, D3 and D4, which are connected in a full bridge.

The coupling module 16 comprises a coil element 34, which is formed by the two coils LI and L2. The first coil LI or throttle is connected between a first input terminal VI and a first output terminal V3 of the coupling module. The second coil L2 and the throttle is connected V4 of the coupling module 14 between a second ^¬ A ^¬ through terminal V2 and a second output terminal. In the present embodiment ^¬ to the first terminal module 18 combines an electrical conductor 36, which serves as the electrical connection of the circuit in the input module 12th The second terminal module 20 comprises ei ^¬ NEN electrical conductor 38, which serves the electrical connection of the circuit in the output module 14.

The DC-DC converter assembly 10 according to FIG 2 illustrates a unidirectional buck-boost converters without galvanic isolation is. In this case, the input module 12 and the off ^¬ output module 14 by means of the two coils LI and L2 of the coupling ^¬ module electrically connected 16 with each other. In the DC-DC converter arrangement 10, the input module 12, the output module 14, the coupling module 16, the first terminal module 18 and the second terminal module 20 are each arranged in a separate housing. The housings of the input module 12, the output module 14, the coupling module 16 and the terminal modules 18, 20 are all designated 40 in the present case. The electrical see contacts between the modules 12, 14, 16, 18, 20 can be provided for example by screw or clamp connections. 3 shows the DC-DC converter arrangement 10 in a further embodiment. In the DC-DC converter assembly 10 according to FIG 3, the input module 12 which Kop ^¬ pelmodul 14, the terminal modules are made up 18 and 20 on the DC clamping voltage ^¬ transducer assembly 10 of FIG. 2 The output module 14 of the DC-DC converter arrangement 10 according to FIG. 3 has four IGBTs Qsl, Qs2, Qs3 and Qs4, which are connected in a full bridge. Thus, a bidirectional buck-boost converter can be provided without galvanic isolation with the DC clamping voltage ^¬ transducer assembly 10 of FIG. 3 Due to the modular design of the DC-DC converter 10, a simple replacement of the output module 14 can be made possible. Thus, the unidirectional buck-boost converter can be converted into 2 to a bidirectional buck-boost converter of Figure 3 by an off ^¬ exchange of the output module 14 in accordance with FIG.

4 shows a DC voltage converter arrangement 10 in a further embodiment. In the DC-DC converter arrangement 10 according to FIG. 4, the coupling module 16 is replaced in comparison to the DC voltage converter arrangement 10 according to FIG. The switching module 16 comprises in this case as a coil ^¬ element 34 includes a transformer Tl. Here, a primary circuit 42 of the transformer Tl to the input terminals VI and V2 of the switching module 16 is connected. A secondary circuit 44 of the transformer Tl is connected to the output terminals V3 and V4 of the coupling module 16. Thus, a galvanically isolated ^¬ coupling between the input module 12 can be provided and the off ^¬ output module fourteenth Furthermore, the second terminal module 20 comprises a filter comprising a coil L3 and a capacitor C3, which are electrically connected to the output module 14. With the DC voltage ^¬ converter arrangement 10 according to FIG 4, a unidirectional phase Shift converters are provided with galvanic isolation.

5 shows a DC voltage converter arrangement 10 in a further embodiment. It is compared to the

 DC voltage converter 10 according to FIG 4, the output module 14 replaced. The second switching device 32 of the output module 14 is formed here by a full bridge of four IGBTs Qsl, Qs2, Qs3 and Qs4, as described in connection with FIG. By a corresponding control of the second switching device 32 by means of the control device 46, a shift of the phase of the electrical voltage in the output module 14 can be effected. By using the output module 14 according to FIG. 5, a further variant of a unidirectional phase-shift converter with galvanic isolation can be provided.

FIG 6 shows a further embodiment of the DC ^¬ transducer assembly 10. In this case, compared to the direct voltage transducer assembly 10 is replaced as shown in FIG 5, the first terminal module ^¬ 18th The first terminal module 18 is constructed analogously to the second terminal module 20 and has an electrical ^¬ cal filter comprising a coil L4 and a capacitor C4, which are electrically connected to the input module 12. With the DC-DC converter arrangement 10 according to FIG. 6, a bidirectional phase-shift converter can be provided.

FIG. 7 shows a further embodiment of the DC voltage converter arrangement 10. In this case, in comparison to the DC voltage converter arrangement 10 according to FIG. 6, the coupling module 16 is replaced. Here, the primary side 42 of the transformers Tl ^¬ door additionally comprises an electrical filter element comprising a capacitor C5 and the coil L5. This can be a

Rensonanzwandler be provided.

8 shows a further embodiment of a coupling module 16. Compared to the coupling module 16 shown in FIG In this case additionally arranged in the secondary circuit 44 of the transformer Tl an electrical filter element comprising a Kon ^¬ capacitor C6 and a coil L6. The coupling module 16 ge ^¬ Mäss FIG 8 serves as a resonant converter for a bi-directional DC-DC converter.

The modular design of the DC-DC converter 10 allows, for example, to build the described bidirectional buck-boost converter as shown in FIG 2 as a base product and, if necessary by a galvanic isolation - by the

Exchange of the coupling module 16 - to be extended. In a bidi ^{¬-directional} buck-boost converter without galvanic isolation significantly higher quantities can be achieved than with DC-DC converters with galvanic isolation. Thus, the existing product, with a transformer Tl, Induktivitä ^¬ th L3 and L4, capacitors C3 and C4 are extended. Thus, the costs are lower than in the development of a DC-DC converter with galvanic isolation. This prop ^¬ net to technologies for example for the implementation phases of new tech, such as the DC load Elektrofahrzeu ^¬ gen. Was foreseeable that devices are first required in galvanic isolation only in small quantities. It would be costly to develop a separate DC-DC converter with galvanic isolation.

The DC-DC converter arrangements 10, which are described in connection with FIGS. 1 to 8, can be used, for example, for power classes between 10 kW and a few 100 kW. For example, a 50 kW DC-DC converter with an input voltage Ul of 600 V and an output voltage U2, which is in a range between 200 and 500 V, are provided. The condensate ^¬ capacitors Cl and C2 has a capacity of 40 \ iF and Kondensa ^¬ factors C3 and C4 is a capacitance of 1 mF may have. The coils LI and L2 can have an inductance of 1.2 mH and the coils L3 and L4 an inductance of 40 μΗ. The Trans ^¬ formator Tl, for example, have a transmission ratio of 5: 6. In addition, corresponding auxiliary inductance be used with an inductance of 1 μΗ. The IGBTs of the first and second switching devices 26, 32 may be switched, for example, at a frequency of 20 kHz. Instead of the IGBTs, MOSFETs can also be used.

Claims

claims 1. DC-DC converter arrangement (10) for converting a DC input voltage (Ul) into a DC output voltage (U2) with  a coupling module (16),  - An input module (12) for transmitting the input DC voltage (Ul) to the coupling module (16) by means of a first switching device (26), and - An output module (14) for providing the output DC voltage (U2) from a voltage applied to the coupling module (16) electrical voltage, characterized in that - the input module (12), the output module (14) and the LAD pelmodul (16) are in each case as a separate module element ausgebil ^¬ det,  - The input module (12) is electrically connected to the coupling module (16) and  - The coupling module (16) to the output module (14) is electrically connected. 2. DC-DC converter arrangement (10) according to claim 1, characterized in that the input module (12), the output ^¬ outgoing module (14) and the coupling module (16) are each arranged in a separate housing (40). 3. DC-DC converter assembly (10) according to claim 1 or 2, characterized in that the coupling module (16) least at ^¬ comprises a coil (LI, L2) at a junction of the input module (12) with the coupling module (16) and the Kop ^¬ pelmodul (16) with the output module (14) provides a galvanic connection between the input module (12) and the output module (14). 4. DC-DC converter arrangement (10) according to claim 1 or 2, characterized in that the coupling module (16) comprises a transformer (Tl), which in a connection of the input module (12) with the coupling module (16) and the coupling module (16) with the output module (14) provides a galvanically isolated coupling between the input module (12) and the ^{Ausgangsmo ¬} module (14). 5. DC-DC converter arrangement according to claim 4, characterized in that the coupling module (16) comprises at least one electrical filter element, which in a primary circuit (42) and / or a secondary circuit (44) of the transformer (Tl) is arranged. 6. DC-DC converter arrangement (10) according to one of the preceding claims, characterized in that the first switching device (26) comprises at least one semiconductor switch (Ql, Q2, Q3, Q4). 7. DC-DC converter arrangement (10) according to one of the preceding claims, characterized in that the output ^¬ transition module (14) has a second switching means (32) for transmitting the voltage applied to the coupling module (16). 8. DC-DC converter arrangement (10) according to one of the preceding claims, characterized in that the DC-DC converter arrangement (10) comprises a first terminal module (18), which is electrically connected to the input module (12), and / or a second terminal module (20), which is electrically connected to the output module (14), wherein the first and / or or the second terminal module includes an electrical Fil ^¬ terelement. 9. DC-DC converter arrangement (10) according to one of the preceding claims, characterized in that the DC-DC converter arrangement (10) comprises a control device (46) for controlling the first switching device (26) and / or the second switching device (32). 10. DC-DC converter arrangement (10) according to claim 8, characterized in that the Gleichspannungswandleranord (10) a detection device for detecting a type of the input module (12), the coupling module (16), claim 8 of the output module (14), the first terminal module (18) and / or the second terminal module (20). 11. DC-DC converter arrangement (10) according to claim 10, characterized in that the first switching device (26) and / or the second switching device (32) by means of the control device (46) in dependence on the detected with the Erfas- detection device type of the input module (12 ), the coupling module (16) and / or the output module (14) is controllable. 12. DC-DC converter arrangement (10) according to claim 9 or 11, characterized in that the first switching device (26) and / or the second switching device (32) by means of the control device (46) hartschaltend, interleaved or pha ^¬ senverschoben is controlled. 13. A method for producing a DC-DC converter arrangement (10) for converting a DC input voltage (Ul) into a DC output voltage (U2)  Providing a coupling module (16),  - Providing an input module (12) for transmitting the input DC voltage (Ul) to the coupling module (16) by means of a first switching device (26), and  Providing an output module (14) for providing the output direct voltage (U2) from an electrical voltage applied to the coupling module (16), marked by - respective forming the input module (12), the output ^¬ module (14) and the coupling module (16) as a separate module ^¬ element,  - Electrical connection of the input module (12) with the coupling module (16) and - Electrical connection of the coupling module (16) with the output ^¬ gangsmodul (14).