KR20230168997A - Voltage-Sense Current-Compensation Active Electromagnetic Interference filter - Google Patents

Abstract

Embodiments of the present disclosure relate to an active EMI filter, and in particular, to a VSCC active EMI filter that senses a voltage that reduces common mode (CM) noise and minimizes the impact on other devices. Embodiments of the present disclosure include an active EMI filter that includes a sensing unit that generates a sensing voltage based on the noise voltage when a noise voltage corresponding to a noise current on a high current path is detected, an amplification unit that amplifies the sensing voltage and generates an amplification voltage, It includes a compensation unit that outputs a compensation voltage based on the amplified amplification voltage, and a compensation capacitor unit that absorbs at least a portion of the noise current based on the compensation voltage from each of at least two large current paths.

Description

VSCC active EMI filter {Voltage-Sense Current-Compensation Active Electromagnetic Interference filter}

Embodiments of the present disclosure relate to an active EMI filter, and in particular, to a VSCC active EMI filter that senses voltage to reduce common mode (CM) noise.

In general, electrical devices such as home appliances, industrial electrical appliances, or electric vehicles emit noise during operation. For example, noise may be generated due to switching operations inside electrical devices. This noise is not only harmful to the human body, but also causes malfunction or failure of other connected electronic devices.

The electromagnetic interference that electronic devices cause to other devices is called EMI (Electromagnetic Interference), and in particular, noise transmitted via wires and board wiring is called conducted emission (CE) noise.

In order to ensure that electronic devices operate without causing malfunctions in surrounding components and other devices, the amount of EMI noise emissions from all electronic products is strictly regulated. Therefore, most electronic products necessarily include noise reduction devices such as EMI filters that reduce EMI noise in order to satisfy regulations on noise emissions.

For example, noise reduction devices are essential in white appliances such as air conditioners, electric vehicles, aviation, and energy storage systems (ESS). A conventional active EMI filter uses a common mode choke (CM choke) to reduce common mode (CM) noise among conducted emission (CE) noise.

Meanwhile, as high-power products are released, the needs for noise reduction devices for high-power systems are increasing. However, in high-power/high-current systems, the noise reduction performance of common mode (CM) chokes rapidly deteriorates due to magnetic saturation.

Therefore, in order to prevent magnetic saturation and maintain noise reduction performance in high-power/high-current systems, conventionally it is necessary to increase the size or number of common mode chokes, which greatly increases the size and price of active EMI filters for high-power products. A problem arose.

The present invention is intended to improve the above problems and provide an active EMI filter that reduces common mode (CM) noise. However, these tasks are illustrative and do not limit the scope of the present invention.

An active EMI (Electro Magnetic Interference) filter that actively reduces the first current input in common mode to each of at least two large current paths connected to the first device according to an embodiment of the present invention is an active EMI (Electro Magnetic Interference) filter that actively reduces the first current input to the high current path. A sensing unit that generates a sensing voltage based on the noise voltage corresponding to the first current in the phase; an amplification unit that amplifies the sensing voltage to generate an amplified voltage; a compensation unit that outputs a compensation voltage based on the amplified amplification voltage; and a compensation capacitor unit that absorbs at least a portion of the first current from each of the at least two high current paths based on the compensation voltage.

In addition, the sensing unit may include a sensing transformer that generates the sensing voltage on the secondary side based on the noise voltage applied to the primary side; and a sensing capacitor unit generating the noise voltage corresponding to the first current on the primary side of the sensing transformer.

Additionally, the sensing capacitor unit may include at least two or more capacitors connecting each of the at least two high current paths and the primary side of the sensing transformer.

In addition, the compensation capacitor unit includes at least two compensation capacitors, wherein first ends of the at least two compensation capacitors are connected to each of the at least two high current paths, and second ends of the at least two capacitors are connected to the at least two high current paths. It is connected to a node that outputs the compensation voltage of the compensation unit, and the at least two or more compensation capacitors have an effective impedance reduced based on the compensation voltage, and a portion of the current corresponding to the effective impedance among the first current is converted into at least two or more large currents. It may be absorbed from each route.

Other aspects, features and advantages in addition to those described above will become apparent from the following drawings, claims and detailed description of the invention.

According to various embodiments of the present invention as described above, it is possible to provide an active EMI filter or noise reduction device that does not significantly increase the price, area, volume, or weight even in a high-power system.

Specifically, the active EMI filter or noise reduction device according to various embodiments may have reduced price, area, volume, and weight compared to a passive compensation device including a CM choke.

Additionally, the active EMI filter or noise reduction device according to various embodiments of the present invention can provide an active EMI filter that can operate independently without being parasitic on the CM choke.

Additionally, the active EMI filter or noise reduction device according to various embodiments of the present invention can stably protect elements included in the active circuit stage by having an active circuit stage that is electrically insulated from the power line.

Additionally, the active EMI filter or noise reduction device according to various embodiments of the present invention can be protected from external overvoltage.

Figure 1 is a diagram schematically showing the configuration of a system including an active EMI filter 100 according to an embodiment of the present invention.
FIG. 2 is a diagram schematically showing the configuration of an active EMI filter 100A used in a second line system according to an embodiment of the present invention.
Figure 3 is a diagram for explaining the specific operation of the active EMI filter (100A) according to an embodiment of the present invention.
Figure 4 is a diagram for explaining the impedance reduction of the compensation capacitor unit according to an embodiment of the present invention.
FIG. 5 is a diagram illustrating the flow of first currents I11 and I12 on the active EMI filter 100A according to an embodiment of the present invention.
Figure 6 is a simulation graph comparing the noise reduction performance of a VSCC active EMI filter (100A) and a passive EMI filter having the same capacitance value as the VSCC active EMI filter (100A) according to an embodiment of the present invention.
Figure 7 is a diagram schematically showing the configuration of an active EMI filter (100B) according to another embodiment of the present invention.
Figure 8 is a diagram schematically showing the configuration of an active EMI filter (100C) according to another embodiment of the present invention.
FIG. 9 is a diagram schematically showing the configuration of a system in which the active EMI filter 100B according to the embodiment shown in FIG. 7 is used.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. The effects and features of the present invention and methods for achieving them will become clear by referring to the embodiments described in detail below along with the drawings. However, the present invention is not limited to the embodiments disclosed below and may be implemented in various forms.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. When describing with reference to the drawings, identical or corresponding components will be assigned the same reference numerals and redundant description thereof will be omitted. .

In the following embodiments, terms such as first and second are used not in a limiting sense but for the purpose of distinguishing one component from another component. In the following examples, singular terms include plural terms unless the context clearly dictates otherwise. In the following embodiments, terms such as include or have mean that the features or components described in the specification exist, and do not exclude in advance the possibility of adding one or more other features or components. In the drawings, the sizes of components may be exaggerated or reduced for convenience of explanation. For example, the size and shape of each component shown in the drawings are arbitrarily shown for convenience of explanation, so the present invention is not necessarily limited to what is shown.

Figure 1 is a diagram schematically showing the configuration of a system including an active EMI filter 100 according to an embodiment of the present invention.

The active EMI filter 100 according to an embodiment of the present invention uses a first current (I11) input in common mode to each of at least two large current paths 111 and 112 connected to the first device 300. , I12) or the noise current can be actively reduced. To this end, the active EMI filter 100 according to an embodiment of the present invention includes at least two large current paths 111 and 112, a sensing unit 120, an amplification unit 130, a compensation unit 140, and a compensation capacitor unit ( 150) may be included.

The two or more large current paths 111 and 112 may be paths for transferring the second currents I21 and I22 supplied by the second device 200 within the active EMI filter 100 to the first device 300. For example, it may be a power line. According to one embodiment, each of the two or more high current paths 111 and 112 may be a live line and a neutral line.

In this specification, the second device 200 may be a device of various types for supplying power to the first device 300 in the form of current and/or voltage. For example, the second device 200 may be a device that produces and supplies power, or it may be a device that supplies power generated by another device (for example, an electric vehicle charging device). Of course, the second device 200 may be a device that supplies stored energy. However, this is an example and the spirit of the present invention is not limited thereto.

In this specification, the first device 300 may be a device of various types that uses power supplied by the above-described second device 200. For example, the first device 300 may be a load driven using power supplied by the second device 200. Additionally, the first device 300 stores energy using power supplied by the second device 200 and may be a load (eg, an electric vehicle) driven using the stored energy. However, this is an example and the spirit of the present invention is not limited thereto.

As described above, each of the two or more large current paths 111 and 112 may be a path for transmitting the power supplied by the second device 200, that is, the second currents I21 and I22, to the first device 300. According to one embodiment, the second currents I21 and I22 may be alternating currents having a frequency in the second frequency band. At this time, the second frequency band may be, for example, a band ranging from 50Hz to 60Hz.

In addition, each of the two or more large current paths 111 and 112 may be a path through which at least a portion of the noise generated in the first device 300, that is, the first currents I11 and I12, is transmitted to the second device 200. At this time, the first currents I11 and I12 may be input in common mode to each of the two or more large current paths 111 and 112.

The first currents I11 and I12 may be currents unintentionally generated in the first device 300 due to various causes. For example, the first currents I11 and I12 may be noise currents generated by virtual capacitance between the first device 300 and the surrounding environment.

The first currents I11 and I12 may be currents having a frequency in the first frequency band. At this time, the first frequency band may have a higher frequency band than the above-described second frequency band, for example, it may be a band ranging from 150 KHz to 30 MHz.

Meanwhile, the two or more large current paths 111 and 112 may include two paths as shown in FIG. 1, or may include three paths or four paths as shown in FIGS. 7 and 8. . The number of high current paths 111 and 112 may vary depending on the type and/or type of power source used by the first device 300 and/or the second device 200.

The sensing unit 120 may generate a sensing voltage based on the noise voltage corresponding to the first currents I11 and I12 on the high current path. To this end, the sensing unit 120 may be electrically connected to each of the high current paths 111 and 112. In other words, the sensing unit 120 may mean a means for detecting the first currents I11 and I12 on the large current paths 111 and 112.

According to one embodiment, the sensing unit 120 may be differentially connected to the input terminal of the amplifying unit 130, which will be described later.

The amplification unit 130 is electrically connected to the sensing unit 120 and can amplify the sensing signal output by the sensing unit 120 to generate an amplified signal. For example, the amplification unit 130 may generate an amplified voltage by amplifying the sensing voltage for the noise current generated by the sensing unit 130. In the present invention, 'amplification' by the amplification unit 130 may mean adjusting the size and/or phase of the amplification target.

By amplifying the amplification unit 130, the active EMI filter 100 can amplify the noise voltage corresponding to the first currents I11 and I12 and adjust the size of the first current absorbed in the compensation capacitor unit. In other words, the active EMI filter 100 reduces the effective impedance of the capacitor of the compensation capacitor unit based on the amplification voltage generated by the amplification unit 130, so that at least a portion of the first currents I11 and I12 It can be allowed to flow into the active EMI filter (100).

The amplifier 130 may be implemented by various means. In one embodiment, the amplifier 130 may include OP-AMP. In another embodiment, the amplifier 130 may include a plurality of passive elements such as a resistor and a capacitor in addition to the OP-AMP. In another embodiment, the amplifier 130 may include a Bipolar Junction Transistor (BJT). In another embodiment, the amplifier 130 may include a plurality of passive elements such as resistors and capacitors in addition to the BJT. In another embodiment, the amplifier 130 may be implemented as an inverting amplifier, and the gain of the inverting amplifier may be adjusted depending on the frequency.

However, the above implementation method of the amplifying unit 130 is illustrative and the spirit of the present invention is not limited thereto, and the means for 'amplification' described in the present invention can be used without limitation as the amplifying unit 130 of the present invention. You can.

The amplification unit 130 receives power from the third device 400, which is distinct from the first device 300 and/or the second device 200, and amplifies the sensing voltage output by the sensing unit 120. Voltage can be generated. At this time, the third device 400 may be a device that receives power from a power source unrelated to the first device 300 and the second device 200 and generates input power to the amplifier 130. Optionally, the third device 400 may be a device that receives power from any one of the first device 300 and the second device 200 to generate input power for the amplifier 130.

The compensation unit 140 is electrically connected to the amplification unit 130 and may generate a compensation voltage based on the amplification voltage generated by the amplification unit 130 described above.

In one embodiment, the compensation unit 140 includes a compensation transformer including a first side electrically connected to the amplification unit 130 and a second side electrically connected to a compensation capacitor section 150 to be described later. can do.

The compensation capacitor unit 150 may absorb at least a portion of the first currents I11 and I12 from the large current paths 111 and 112 based on the compensation voltage generated by the above-described compensation unit 140. In other words, the compensation capacitor unit 150 may provide a path through which the current corresponding to the compensation voltage among the first currents I11 and I12 flows from at least two large current paths 111 and 112.

According to one embodiment, the compensation capacitor unit 150 is implemented so that the current corresponding to the compensation voltage among the noise currents flowing through the two or more large current paths 111 and 112 flows in according to the capacitors connected to each of the large current paths 111 and 112. It can be. At this time, the compensation capacitor unit 150 may include at least two or more compensation capacitors connecting the reference potential (reference potential 1) of the active EMI filter 100 and each of the two or more large current paths 111 and 112.

The active EMI filter 100 configured as described above detects the noise voltage corresponding to the noise current on the two or more large current paths 111 and 112, and can actively reduce the noise current based on this, and the device 100 Despite miniaturization, it can be applied to high current, high voltage and/or high power systems.

Hereinafter, the active EMI filter 100 according to various embodiments will be described with reference to FIGS. 2 to 9 together with FIG. 1.

FIG. 2 is a diagram schematically showing the configuration of an active EMI filter 100A used in a second line system according to an embodiment of the present invention.

The active EMI filter (100A) according to an embodiment of the present invention actively filters the first currents (I11 and I12) input in common mode to each of the two large current paths (111A and 112A) connected to the first device (300A). It can be reduced.

To this end, the active EMI filter (100A) according to an embodiment of the present invention includes two large current paths (111A, 112A), a sensing unit (120A), an amplification unit (130A), a compensation transformer (140A), and a compensation capacitor unit (150A). ) may include.

The sensing unit 120A according to an embodiment of the present invention may generate a sensing voltage based on the noise voltage corresponding to the first currents I11 and I12 on the two or more large current paths 111 and 112.

According to an embodiment of the present invention, the above-described sensing unit 120A may include a sensing capacitor 121A and a sensing transformer 122A. Specifically, the sensing unit 120A is connected to the sensing transformer 122A, which generates a sensing voltage on the secondary side based on the noise voltage applied to the primary side, and the primary side of the sensing transformer, and the It may include a sensing capacitor unit 121A that generates a noise voltage corresponding to 1 current. At this time, the sensing transformer 122A may include a first secondary side 123A connected to the sensing capacitor 121A and a second secondary side 124A connected to the amplifier 130A.

The sensing capacitor 121A may be a means for detecting the first currents I11 and I12 or a noise voltage corresponding to the noise current. At this time, the sensing capacitor 121A may include as many capacitors as the number of high current paths. In this embodiment, the sensing capacitor 121A may include a first capacitor C1 and a second capacitor C2.

At this time, the first capacitor C1 of the sensing capacitor 121A may be connected to the first high current path 111A, and the second capacitor C2 of the sensing capacitor 121A may be connected to the second large current path 112A. there is. Specifically, the first ends of the first capacitor C1 and the second capacitor C2 may be connected to the first high current path 111A and the second high current path 112A, respectively, and the first capacitor C1 and the second capacitor C2 may be connected to the first high current path 111A and the second high current path 112A, respectively. 2 The second terminal of the capacitor C2 may be connected to one node and connected to the first secondary side 123A of the sensing transformer 122A. That is, the first capacitor C1 and the second capacitor C2 may connect each of the at least two high current paths 111A and 112A to the primary side 123A of the sensing transformer 122A. At this time, the sensing capacitor 121A may be a means for detecting the noise voltage corresponding to the first currents I11 and I12 on the high current paths 111A and 112A while being insulated from the high current paths 111A and 112A.

Meanwhile, among the first currents (I11, I12) flowing in the two large current paths (111A, 112A), a micro current corresponding to the impedance of the active EMI filter (100A) connects the first capacitor (C1) and the second capacitor (C2). can flow through According to one embodiment of the present invention, the sensing capacitor 121A may further include a sensor for detecting a minute current flowing through the first capacitor C1 and the second capacitor C2.

A noise voltage corresponding to the first currents I11 and I12 may be applied to the node between the second terminal of the sensing capacitor 121A and the sensing transformer 122A. Thereafter, the sensing transformer 122A may generate and output a sensing voltage based on the noise voltage. That is, a sensing voltage may be applied between the second secondary side 124A of the sensing transformer 122A and the amplifier 130A. At this time, the secondary side 124A of the sensing transformer 122A may be differentially connected to the input terminal of the amplifier 130A, which will be described later.

The amplifying unit 130A of the present invention can generate an amplified voltage by amplifying the sensing voltage output by the above-described sensing unit 120A. In the present invention, 'amplification' by the amplification unit 130 may mean adjusting the size and/or phase of the amplification target. For example, the amplification unit 130A may generate an amplification voltage that increases the magnitude of the sensing voltage by K times (K>=1).

The amplification unit 130A may generate an amplification voltage by considering the transformation ratio of the above-described sensing transformer 120A and the transformation ratio of the compensation unit 140 described later. At this time, the amplification unit 130A may be implemented by various means. For example, the amplification unit 130A may include OP-AMP. Optionally, the amplification unit 130A may include a plurality of passive elements such as resistors and capacitors in addition to the OP-AMP. Additionally, the amplifier 130A may include a Bipolar Junction Transistor (BJT). Optionally, the amplification unit 130A may include a plurality of passive elements in addition to the BJT. However, the above implementation method of the amplifying unit 130A is illustrative and the spirit of the present invention is not limited thereto, and the means for 'amplification' described in the present invention can be used without limitation as the amplifying unit 130A of the present invention. You can.

The compensation unit 140 may generate a compensation voltage based on the amplification voltage generated by the amplification unit 130 described above. The compensation unit 140 of the present invention may be implemented as a compensation transformer 140A. At this time, the compensation transformer 140A is insulated from the above-mentioned large current paths 111A and 112A, and compensates the large current paths 111A and 112A (or the secondary side 142A, which will be described later) based on the amplification voltage. It may be a means for outputting voltage.

More specifically, the compensation transformer 140A is a magnetic flux induced by the current corresponding to the amplification voltage generated by the amplification unit 130A at the first primary side 141A differentially connected to the output terminal of the amplification unit 130A. Based on the density, an induced current may be generated in the secondary side (142A). That is, a compensation voltage corresponding to the above-described induced current may be applied to the second side (142A). At this time, the second secondary side 142A may be placed on a path connecting the compensation capacitor unit 150A, which will be described later, and the reference potential (reference potential 1) of the active EMI filter.

Meanwhile, the primary side 141A of the compensation transformer 140A, the amplifier 130A, and the secondary side 122A of the sensing transformer 120A are separated from the remaining components of the active EMI filter 100A. It can be connected to the reference potential (reference potential 2).

As such, the present invention uses a different reference potential for the component that generates the compensation voltage from the remaining components and uses a separate power source, thereby allowing the component that generates the compensation voltage to operate in an insulated state. The reliability of the active EMI filter (100A) can be improved.

As described above, the compensation capacitor unit 150 of the present invention is a partial current corresponding to the compensation voltage generated by the compensation transformer 140A among the first currents I11 and I12 flowing in the two large current paths 111A and 112A. Can be absorbed by the active EMI filter (100A) from each of the two large current paths (111A, 112A).

Specifically, the first terminal of each capacitor included in the compensation capacitor unit 150 may be connected to the first high current path 111A and the second large current path 112A, respectively, and is included in the compensation capacitor unit 150. The second terminal of each capacitor may be connected to one node and connected to the second secondary side 142A of the compensation transformer 142A. Accordingly, each capacitor included in the compensation capacitor unit 150 can provide a path through which current absorbed from each of the two large current paths 111A and 112A flows to the active EMI filter 100A.

Figure 3 is a diagram for explaining the specific operation of the active EMI filter (100A) according to an embodiment of the present invention.

The sensing capacitor unit 121A may sense the noise current flowing in the large current paths 111A and 112A or the noise voltage Vn corresponding to the first currents I11 and I12. Specifically, the noise voltage (Vn) is a voltage applied due to the first currents (I11 and I12) flowing in the large current paths (111A and 112A), and is a node between the second terminal of the sensing capacitor (121A) and the sensing transformer (122A). The voltage applied to (a) is a voltage similar to the noise voltage ( Vn). Hereinafter, for convenience, the voltage applied to node (a) will be referred to as noise voltage (Vn).

That is, when the noise voltage (Vn) is applied to the node (a) of the active EMI filter (100A) or the primary side of the sensing transformer (122A), the sensing transformer (122A) generates a sensing voltage based on the noise voltage (Vn). can be created. Specifically, assuming that the transformation ratio of the sensing transformer (122A) is 1:N _sen , the inductance of the first secondary side (123A) inductor is L _sen , and are perfectly coupled, the second secondary inductor (124A) of the sensing transformer (122A) The inductance of N _sen ² * It can be L _sen .

At this time, the noise voltage (V _n ) passing through the sensing transformer 122A may be converted into a sensing voltage, and the sensing transformer may be N _sen * V _n . That is, the sensing voltage (N _sen * V _n ) may be applied to the node (b) between the second side (124A) and the amplification unit (130A).

The amplifier unit 130A may be an inverting amplifier using an OP-amp. According to one embodiment of the present invention, an isolated voltage-sense current-compensation (VSCC) topology AEF can be implemented using an OP-amp powered through direct current power through the third device 400.

The amplifier unit 130A may be an inverting amplifier including R1 and R2-. The inverting amplifier is one of the basic circuit structures of an operational amplifier. A is the voltage gain of the amplifier body, In the case of =R ₁ /(R ₁ +R ₂ ), the closed loop voltage gain A _{v .amp} is equal to Equation 1.

At this time, If so, It can be, and the polarity of the output voltage is reversed.

According to one embodiment of the present invention, the amplification unit 130A may further include C _O . C _O It may be a high-pass filter to block the amplifier included in the amplifier 130A from operating at a low frequency below the noise reduction target band.

On the other hand, when the sensing voltage (N _sen * V _n ) is amplified through the amplifier (130A), the amplification voltage is at the node (c) between the amplifier (130A) and the first side (141A) of the compensation transformer (140A). may be approved. At this time, the amplification voltage may be -N _sen * A _v,amp * V _n .

When the amplification voltage (-N _sen *A _v,amp *V _n ) is applied to the node (c) of the active EMI filter (100A), the compensation transformer (140A) applies the amplification voltage (-N _sen *A _v,amp *V A compensation voltage can be generated based on _n ). Specifically, assuming that the transformation ratio of the compensation transformer (140A) is 1:N _inj , the inductance of the first secondary (141A) inductor is L _inj , and are perfectly coupled, the second secondary (142A) inductor of the compensation transformer (140A) The inductance of N _inj ² * It can be L _inj .

At this time, the amplified voltage (-N _sen *A _v,amp *V _n ) passing through the compensation transformer (122A) can be converted to a compensation voltage, and the compensation transformer is -N _sen *N _inj *A _v,amp *V _n It can be. That is, a compensation voltage (-N _sen *N _inj *A _v,amp *V _n ) may be applied to the node d between the second secondary side 142A of the compensation transformer and the compensation capacitor unit 150A.

The first end of at least two compensation capacitors of the compensation capacitor unit 150A may be connected to the high current paths 111A and 112A, respectively, and the second end of the compensation capacitor may be connected to the compensation transformer 140A through one node d. can be connected The effective impedance value of each capacitor included in the compensation capacitor unit 150A is reduced by the voltage applied to the high current path 111A and 112A and the voltage applied to the node d.

Accordingly, the compensation capacitor unit 150A can absorb at least a portion of the first currents I11 and I12 flowing in the large current paths 111A and 112A. That is, as some of the noise current is absorbed or introduced into the active EMI filter (100A), the noise current transmitted to the second device (200A) can be reduced or compensated. This will be explained in detail with reference to FIGS. 4 and 5.

Figure 4 is a diagram for explaining the impedance reduction of the compensation capacitor unit according to an embodiment of the present invention.

Referring to FIG. 4, the first impedance-frequency graph (thin straight line) shows the impedance change according to frequency of a general capacitor. On the other hand, the second graph (thick line) shows the impedance change according to the frequency of the compensation capacitor part included in the active EMI filter (100A) of the present invention.

The impedance of the capacitor (C _inj ) of the general compensation capacitor unit can be calculated according to Equation 2 below.

That is, the impedance change according to frequency of a general capacitor can be shown as the first graph (thin straight line).

On the other hand, the impedance of the capacitor C _inj of the compensation capacitor part included in the active EMI filter (100A) of the present invention can be calculated according to Equation 3 below.

In other words, in Equation 3, the effective impedance of the capacitor (C _inj ) can be expressed as Equation 4.

According to Equation 3 or Equation 4, the impedance change with frequency for the capacitor C _inj included in the compensation capacitor unit 150A of the present invention may be shown as a second graph (thick line).

Specifically, looking at Equation 4, the N _sen N _inj A _v,amp value may increase or decrease depending on the design of the sensing transformer (122A), compensation transformer (140A), and amplifier (130A) of the active EMI filter (100A). and may have different characteristics depending on the frequency. For example, referring to Figure 4, the lowest effective impedance is at a frequency of 6 MHz.

That is, by designing the effective impedance of the capacitor C _inj included in the compensation capacitor unit 150A to decrease, the first current or noise current can be absorbed from the high current paths 111A and 112A to the compensation capacitor unit 150A. there is. In this regard, further explanation will be given in FIG. 5.

FIG. 5 is a diagram illustrating the flow of first currents I11 and I12 on the active EMI filter 100A according to an embodiment of the present invention.

Referring to FIG. 5, the compensation capacitor unit 150A may be configured so that the current IL1 flowing between the two large current paths 111A and 112A through the compensation capacitor satisfies a predetermined first current condition. At this time, the predetermined first current condition may be a condition in which the size of the current IL1 is less than the predetermined first threshold size.

Meanwhile. The compensation capacitor unit 150A is configured such that the current Il2 flowing between each of the two large current paths 111A and 112A through the compensation capacitor and the reference potential (reference potential 1) of the active EMI filter 100A satisfies a predetermined second condition. It can be configured to be satisfactory.

Specifically, the compensation voltage applied to the node (d) may be -N _sen N _inj A _v,amp V _n , and accordingly, the effective impedance of the compensation capacitor (C _inj ) is 1/(1+N _sen N _inj A _{v, amp} ) can be reduced by two times.

The first current (I11, I12) or noise current flowing along the two large current paths (111A, 112A) is absorbed or introduced into the capacitor (C _inj ) to flow to the reference potential (reference potential 1) of the active EMI filter (100A). It can be. That is, as the effective impedance of the capacitor C _inj decreases, the current Il2 may increase in response to the decreased effective impedance.

According to an embodiment of the present invention, the above-described second current condition may be a condition in which the magnitude of the current IL2 is greater than or equal to a predetermined second critical magnitude. At this time, the size of the current IL2 may vary depending on the size of the effective impedance of the capacitor C _inj . That is, in the active EMI filter (100A) according to an embodiment of the present invention, the sensing transformer (122A), the compensation transformer (140A), and the amplification unit (130A) may be designed so that the current (Il2) is greater than or equal to the second threshold size. there is.

According to the above-described embodiment, as the first currents I11 and I22 flow from the two large current paths 111A and 112A along the compensation capacitor unit 150A, the first currents I11 and I22 are transferred to the second device. (200A) can be reduced.

As a result, the active EMI filter (100A) according to an embodiment of the present invention transmits the first currents (I11, I12) input in common mode to each of the two large current paths (111A, 112A) connected to the first device (300A). By actively reducing it, malfunction or damage to the second device 200A can be prevented.

Figure 6 is a simulation graph comparing the noise reduction performance of a VSCC active EMI filter (100A) and a passive EMI filter having the same capacitance value as the VSCC active EMI filter (100A) according to an embodiment of the present invention.

Referring to FIG. 6, in the graph, the horizontal axis represents frequency, and the vertical axis represents the noise level of common mode (CM) conducted emission (CE). The solid line represents the EMI noise standard. In other words, if it exceeds the solid line (EMI noise standard), the product cannot be shipped.

As can be seen from the graph, the noise level when using the VSCC active EMI filter unit (100A) of the present invention is stably lower than the EMI noise standard compared to when using a passive EMI filter. Specifically, it is confirmed in simulation that when the VSCC active EMI filter unit (100A) of the present invention operates, an additional noise reduction of 10 to 30 dB occurs.

Therefore, the VSCC active EMI filter unit 100A can reduce area and weight while having better noise reduction performance compared to the passive EMI filter.

Figure 7 is a diagram schematically showing the configuration of an active EMI filter (100B) according to another embodiment of the present invention. Hereinafter, descriptions of content that overlaps with the content described with reference to FIGS. 1 to 6 will be omitted.

The active EMI filter (100B) according to another embodiment of the present invention is a first current (I11, I12, I13) input in common mode to each of the high current paths (111B, 112B, and 113B) connected to the first device (300B). ) can be actively reduced or compensated.

To this end, the active EMI filter (100B) according to another embodiment of the present invention includes three high current paths (111B, 112B, 113B), a sensing transformer (120B), an amplifier (130B), a compensation transformer (140B), and a compensation capacitor. It may include a unit 150B.

In contrast to the active EMI filter 100A according to the embodiment described in FIGS. 2 to 6, the active EMI filter 100B according to the embodiment shown in FIG. 7 has three high current paths 111B, 112B, and 113B. It includes, and accordingly, there is a difference between the sensing capacitor 121B and the compensation capacitor unit 150B. Therefore, the following will describe the active EMI filter (100B) focusing on the above-mentioned differences.

The active EMI filter 100B according to another embodiment of the present invention may include a first large current path 111B, a second large current path 112B, and a third large current path 113B that are distinct from each other. According to one embodiment, the first high-current path 111B may be an R-phase power line, the second high-current path 112B may be an S-phase power line, and the third high-current path 113B may be a T-phase power line. The first currents I11, I12, and I13 may be input in a common mode to each of the first large current path 111B, the second large current path 112B, and the third large current path 113B.

The sensing capacitor 121B according to another embodiment of the present invention is connected to each of the first large current path 111B, the second large current path 112B, and the third large current path 113B to generate a noise voltage corresponding to the first current. can be detected. Since the process of detecting the noise voltage corresponding to the first currents I11, I12, and I13 has already been described, detailed description thereof will be omitted.

Meanwhile, the compensation capacitor unit 150B according to another embodiment of the present invention absorbs at least a portion of the current corresponding to the compensation voltage generated by the compensation transformer 140B among the first currents I11, I12, and I13. A flowing path can be provided.

The active EMI filter 100B according to this embodiment can be used to reduce (or block) the first currents (I11, I12, and I13) moving from the load to the power source of a three-phase, three-wire power system.

Figure 8 is a diagram schematically showing the configuration of an active EMI filter (100C) according to another embodiment of the present invention. Hereinafter, descriptions of content that overlaps with the content described with reference to FIGS. 1 to 7 will be omitted.

The active EMI filter (100C) according to the embodiment is a first current (I11, I12, I13, I14) input in common mode to each of the high current paths (111C, 112C, 113C, and 114C) connected to the first device (300C). can be actively reduced or compensated for.

To this end, the active EMI filter (100C) according to the embodiment includes four high current paths (111C, 112C, 113C, 114C), a sensing transformer (120C), an amplifier (130C), a compensation transformer (140C), and a compensation capacitor unit (150C). ) may include.

In contrast to the active EMI filter 100A according to the embodiment described in FIGS. 2 to 6 and the active EMI filter 100B according to the embodiment described in FIG. 7, the active EMI filter according to the embodiment shown in FIG. 8 ( 100C) includes four large current paths (111C, 112C, 113C, 114C), and accordingly, there is a difference in the sensing capacitor (121C) and compensation capacitor portion (150C). Therefore, the following will describe the active EMI filter (100C) focusing on the above-mentioned differences.

First, the active EMI filter (100C) according to the embodiment may include a first large current path (111C), a second large current path (112C), a third large current path (113C), and a fourth large current path (114C) that are distinct from each other. there is. According to one embodiment, the first large current path (111C) is the R phase, the second large current path (112C) is the S phase, the third large current path (113C) is the T phase, and the fourth large current path (114C) is the It may be an N-phase power line. The first currents (I11, I12, I13, I14) include the first large current path (111C), the second large current path (112C), the third large current path (113C), and the fourth large current path (114C). ) can be input to each in common mode.

The sensing capacitor 121C according to the embodiment is connected to each of the first large current path 111C, the second large current path 112C, the third large current path 113C, and the fourth large current path 114C to generate the first current I11. , I12, I13, I14) can be detected. Since the process of detecting the noise voltage corresponding to the first current (I11, I12, I13, I14) has already been described, detailed description thereof will be omitted.

Meanwhile, the compensation capacitor unit 150C according to the embodiment absorbs and provides a path through which at least a portion of the current corresponding to the compensation voltage generated by the compensation transformer 140C among the first currents I11, I12, and I13 flows. You can.

The active EMI filter (100C) according to this embodiment can be used to reduce (or block) the first current (I11, I12, I13, I14) moving from the load to the power source in a three-phase, four-wire power system. there is.

FIG. 9 is a diagram schematically showing the configuration of a system in which the active EMI filter 100B according to the embodiment shown in FIG. 7 is used.

The active EMI filter 100B according to the embodiment may be used with one or more other compensation devices 500 on a high current path connecting the second device 200B and the first device 300B.

For example, the active EMI filter 100B according to the embodiment may be used together with compensation device 1 (510) that compensates for the first current input in common mode. At this time, compensation device 1 510 may be implemented as an active element similar to the active EMI filter 100B, or may be implemented only as a passive element.

Additionally, the active EMI filter 100B according to the embodiment may be used together with compensation device 2 520 that compensates for the third current input in differential mode. At this time, compensation device 2 (520) may also be implemented as an active element or may be implemented only as a passive element.

Meanwhile, the type, quantity, and arrangement order of the compensation device 500 described in FIG. 9 are exemplary and the spirit of the present invention is not limited thereto. Therefore, depending on the design of the system, various quantities and types of compensation devices may be further included in the system. Additionally, alternatively, the embodiment shown in FIG. 9 may be equally applied to all other embodiments of the present specification.

In addition, of course, the compensation device 500 of FIG. 9 may be a device for compensating current as well as reducing noise flowing into the second device 200B, like the active EMI filter 100B.

The specific implementations described in the present invention are examples and do not limit the scope of the present invention in any way. For the sake of brevity of the specification, descriptions of conventional electronic components, control systems, software, and other functional aspects of the systems may be omitted. In addition, the connections or connection members of lines between components shown in the drawings exemplify functional connections and/or physical or circuit connections, and in actual devices, various functional connections or physical connections may be replaced or added. Can be represented as connections, or circuit connections. Additionally, if there is no specific mention such as “essential,” “important,” etc., it may not be a necessary component for the application of the present invention.

Therefore, the spirit of the present invention should not be limited to the above-described embodiments, and the scope of the patent claims described below as well as all scopes equivalent to or equivalently changed from the scope of the claims are within the scope of the spirit of the present invention. It will be said to belong to

100: Active EMI filter
111, 112: High current path
120: Sensing unit
130: Amplification unit
140: Compensation unit
150: Compensation capacitor unit
200: second device
300: first device

Claims (1)

In the active EMI (Electro Magnetic Interference) filter that actively reduces the first current input in common mode to each of at least two large current paths connected to the first device,
a sensing unit that generates a sensing voltage based on a noise voltage corresponding to the first current on the high current path;
an amplification unit that amplifies the sensing voltage to generate an amplified voltage;
a compensation unit that outputs a compensation voltage based on the amplified amplification voltage; and
Based on the compensation voltage, a compensation capacitor unit absorbing at least a portion of the first current from each of the at least two large current paths.