DE102015110064B4 - Arrangement for protecting electronic assemblies - Google Patents

Abstract

Arrangement for protecting electronic components, which has an input (1) for applying an input voltage, an output (2) for outputting an output voltage and capacitive and / or inductive and / or ohmic components, characterized in that the input (1) with a first terminal of a first winding (10) of a transformer (7) and the output (2) with a second terminal of the first winding (10) of the transformer (7) are connected, that a first capacitor (4) directly between the first terminal the first winding (10) and a reference potential and a second capacitor (5) are arranged directly between the second terminal of the first winding (10) and the reference potential, that a second winding (11) of the transformer (7) with an ohmic resistance ( 6) is connected and that at the second winding (11) of the transformer (7) connected to the ohmic resistance (6) is connected to a heat sink (9), wherein the cooling body he (9) is a housing of an electric refrigerant compressor for active cooling and wherein the input (1) is a differential input and the output (2) is a differential output, wherein between the input (1) and the output (2) has a third winding (12), wherein a capacitor (4a) is mirror-inverted to the first capacitor (4) and a capacitor (5a) is arranged in mirror image to the second capacitor (5) and wherein an input-side additional capacitor (13) and an output-side additional capacitor ( 13) is arranged.

Description

The invention relates to an arrangement for the protection of electronic components, which has an input for applying an input voltage, an output for outputting an output voltage and capacitive, inductive and ohmic resistors.

To operate electronic assemblies operating voltages must be provided, which must meet the predetermined requirements both in terms of their deviation from a nominal value as well as their quality with respect to ripple and noise components. This is necessary to ensure the trouble-free functioning of the electronic module and to protect the module from destruction, for example, by brief overvoltages. Furthermore, it must be prevented that electrically operated assemblies generate inadmissible high electromagnetic interference, which in turn could disturb other assemblies and can lead to malfunction.

Any electronic components that are to be supplied with a supply voltage, which may include a large number of active and / or passive electronic components, are understood as electronic components. Such assemblies can be used in any devices, for example in the field of control engineering. In one example, such an arrangement is an electronic assembly for driving an electric refrigerant compressor.

The present invention relates to an assembly for filtering the interference components of the operating voltage, also referred to as a filter, for the electromagnetic compatibility (EMC filter) (EMC filter).

This EMC filter is used to attenuate noise in the line-bound disturbances, for example, disturbances that could act on the supply line of the modules, in the amplitude. Furthermore, it should be prevented that occurring in the electrical assembly disturbances that may arise, for example, by rapid switching operations can act on the power cable into the environment outside the module. If there are several supply or connection cables required for an assembly, one EMC filter per supply or connection cable may be required.

Compliance with electromagnetic compatibility is specified by corresponding standards and test guidelines.

The signals to be filtered by the EMC filter may have the characteristics of both low and high frequency noise components. These can occur both as a DC and as a push-pull signal. In the worst case threatens by an insufficient EMC filtering the malfunction or even destruction of electronic components and assemblies.

For this reason, arrangements are used to protect electronic assemblies for compliance with the electromagnetic compatibility of electrical assemblies. These arrangements are also referred to as EMC filters. These EMC filters must be partially attenuated to avoid resonant oscillations. These oscillations can arise through unwanted interactions between energy stores (capacitors, inductors), which then lead to a swinging of currents in the filter itself or between other electrical components.
Furthermore, the working bandwidth can be increased by a reduction of the filter quality by a targeted damping.

These EMC filters are connected on the input side with a supply voltage intended for the electronic module to be protected and on the output side with the operating voltage input of the electronic module itself. By such a pre-switching of the EMC filter, the conducted noise is suppressed.

The attenuation of the EMC filter is usually done with one or more damping resistors. These damping resistors arranged in the EMC filter cause ohmic losses, ie heat, which must be dissipated.

These losses in the EMC filter also occur when only pure DC components, ie a DC voltage without any interference component to be filtered, are conducted through the EMC filter. For this reason, the resistors must be correspondingly large in terms of the allowable power loss.

This in turn has a negative effect on the requirements of the damping resistance and the total cost of the EMC filter or the electrical assembly. Furthermore, the power loss reduces the overall efficiency of the electrical assembly.

The documents DE 197 57 452 A 1, DE 295 06 951 U 1, DE 102 25 409 A 1, US 2008/0 170 667 A 1 and DE are known from the prior art DE 10 2007 054 872 A1 known.

The object of the invention is therefore to provide an arrangement for the protection of electronic assemblies, with which interference components of the input side applied supply voltage filtered as possible and interference-free DC components of the supply voltage of the downstream to be supplied electronic module with the lowest possible losses are fed, with a reduction of cost , space and circuit complexity is achieved.

The object is achieved by an article having the features according to patent claim 1. Further developments are specified in the dependent claims.

It is envisaged to carry out the arrangement for the protection of electronic assemblies such that in a longitudinal branch of the arrangement between their input and output, for example, a primary winding of a transformer is introduced. Furthermore, it is provided to connect the secondary side with an ohmic damping resistor and thus to damp. The arrangement also has a first capacitance disposed between the input of the device and a reference ground potential, and a second capacitance located between the device output and the reference potential.

The primary side of the transformer is used as a choke coil to eliminate disturbing signal components. The arrangement allows DC components to pass through the device without attenuation, while parasitic AC components are filtered out by means of the transformer's own inductance and the capacitive effect of the capacitors.

It is advantageous that the first winding of the transformer is the primary winding, while the second winding is formed by the secondary winding.

Also advantageous is the galvanic separation of the two windings of the transformer from each other. This leads to a reduction of the expense for isolation on the secondary side of the transformer.

It is also advantageous to connect the ohmic resistance on the secondary side of the transformer with a heat sink. Thus, a cooling of this damping resistor can take place. Such a heat sink may for example also represent a housing of an electric refrigerant compressor.

It is also advantageous to perform the input and the output of the arrangement in each case differentially. This makes it possible to work with differential signals or differential voltages.

• 1: ein beispielhaftes Ausführungsbeispiel eines EMV-Filters aus dem Stand der Technik,
• 2: eine beispielhafte Ausführung der erfindungsgemäßen Anordnung zum Schutz einer elektronischen Baugruppe (EMV-Filter), und
• 3 eine beispielhafte Ausführung der erfindungsgemäßen Anordnung zum Schutz einer elektronischen Baugruppe (EMV-Filter) mit einem differenziellen Ein- und Ausgang.

Further details, features and advantages of embodiments of the invention will become apparent from the following description of exemplary embodiments with reference to the accompanying drawings. Show it:

• 1 FIG. 1 shows an exemplary embodiment of an EMC filter from the prior art, FIG.
• 2 : An exemplary embodiment of the inventive arrangement for protecting an electronic assembly (EMC filter), and
• 3 an exemplary embodiment of the inventive arrangement for protecting an electronic module (EMC filter) with a differential input and output.

The 1 shows an example of a known from the prior art EMC filter with an input 1 at which the input voltage U _e is created and an exit 2 at which an output voltage U _a in which disturbances are reduced as best as possible is output. This filter is called a so-called PI-filter with an inductance 3 in a longitudinal branch and a first capacity 4 and a second capacity 5 executed in the shunt branches. The EMC filter also has several resistors 6 for damping on. These resistors 6 can also find only one application in one filter.

Such EMC filters may alternatively be constructed in a known manner from any combination of capacitances, inductances and resistors.

In the 2 an inventive EMC filter is shown in an exemplary embodiment. This EMC filter in turn has an input 1 on to which the input voltage U _e is created and an exit 2 at which an output voltage U _a is spent on.

On the input side is the first capacity 4 and on the output side, the second capacity 5 arranged in transverse branches of the arrangement. The invention provides, for example, as a first winding, a primary winding 10 a transformer 7 between the entrance 1 and the exit 2 use.

This primary winding 10 a transformer 7 is used as a choke coil for filtering noise. To a second winding, which is the secondary side 11 of the transformer 7 represents is a resistance dampening the filter 6 connected, as in the 2 is shown. DC components can be the primary side 10 of the transformer 7 or pass filters without damping and generating losses. Disturbing alternating voltage components are caused by the self-inductance of the transformer 7 and the connected capacities 4 and 5 filtered.

By the damping resistance 6 on the secondary side 11 the filter is damped at the same time. Because the damping resistance 6 Due to the circuit according to the invention, only the interference components must be damped, the requirements with regard to power loss, size and cooling for the damping resistance 6 be reduced. Furthermore arises by the choice of the transmission ratio of the transformer 7 which is determined by the ratio of the number of turns on the primary side 10 of the transformer 7 to the number of turns on the secondary side 11 of the transformer 7 is determined, and the matched resistance value of the damping resistor 6 another degree of freedom in the design of the arrangement.

The through the transformer 7 implicit galvanic isolation 8th between the primary page 10 and the secondary side 11 also allows a simple electrically secure connection of the damping resistor 6 to a heat sink 9 , This makes it possible to omit an insulation pad to the heat sink and at the same time the thermal contact resistance between the damping resistor 6 and the cooling surface of the heat sink 9 to improve.

In an exemplary installation of the arrangement for protecting electronic assemblies, such as in an inverter of an electric refrigerant compressor, the damping resistance 6 to the housing of the refrigerant compressor, which is the heat sink 9 represented, connected and thereby actively cooled. This allows the size of the damping resistor 6 further reduce.

3 shows a filter arrangement according to the invention for a differentially constructed EMC filter. The well-known choke coil (Common Mode Choke) with its first winding 10 This was another third winding 12 added. At the already from the 2 known second winding 11 is analogous to 2 the resistance 6 inserted for damping. The principle of action corresponds already to the 2 described context.

Due to the differential structure of the EMC filter is a mirror image of the first capacity 4 a capacity 4a and to the second capacity 5 a capacity 5a that as so-called Y Capacitors are arranged. In addition, the EMC filter was still on each input side and an output side additional capacity 13 that as so-called X Capacitors are expanding.

Also in this design, the from the 2 known damping resistors 6 be used. In the presentation of the 3 was waived on this.

LIST OF REFERENCE NUMBERS

1

Input of the EMC filter (input voltage U _e )

2

Output of the EMC filter (output voltage U _a )

3

inductance

4

first capacitance / first capacitive resistance

5

second capacitance / second capacitance

6

Damping resistance / ohmic resistance

7

transformer

8th

electrical insulation (galvanic isolation)

9

heatsink

10

first winding / primary winding of the transformer

11

second winding / secondary winding of the transformer

12

third winding

13

additional capacity

Claims (3)

Arrangement for protecting electronic components, which has an input (1) for applying an input voltage, an output (2) for outputting an output voltage and capacitive and / or inductive and / or ohmic components, characterized in that the input (1) with a first terminal of a first winding (10) of a transformer (7) and the output (2) with a second terminal of the first winding (10) of the transformer (7) are connected, that a first capacitor (4) directly between the first terminal the first winding (10) and a reference potential and a second capacitor (5) are arranged directly between the second terminal of the first winding (10) and the reference potential, that a second winding (11) of the transformer (7) with an ohmic resistance ( 6) is connected and that at the second winding (11) of the transformer (7) connected to the ohmic resistance (6) is connected to a heat sink (9), wherein the Kühlkör by (9) is a housing of an electrical refrigerant compressor for active cooling, and wherein the input (1) has a differential input and the output (2) is a differential output, wherein between the input (1) and the output (2), a third winding (12) is arranged, wherein a mirror image of the first capacitor (4), a capacitor (4a) and a mirror image of the second capacitor (5) a capacitor (5a) is arranged and wherein each an input side additional capacitor (13) and an output side additional capacitor (13) is arranged. Arrangement according to Claim 1 , characterized in that the first winding (10) is a primary winding and the second winding (11) is a secondary winding of the transformer (7). Arrangement according to Claim 1 or 2 , characterized in that the first winding (10) and the second winding (11) are arranged galvanically separated from each other.

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