JP3186001U - Power supply device - Google Patents

Abstract

A small-sized power supply device with low standby power consumption is provided.
An inverter is electrically connected to a rectifier and has a first power output end VA and a standby power output end Vsb, and the standby power output end Vsb is electrically connected to the electronic system PS. Connected. The control device 26 is electrically connected to the inverter 24. The power management device 28 is electrically connected to the control device 26 and the electronic system PS. The switch device 30 is electrically connected to the first power output end VA, the power management device 28, and the electronic system PS, and the power output from the first power output end VA is controlled by the power management device 28. Switch on or off.
[Selection] Figure 2

Description

  The present invention relates to a power supply device, and more particularly to a power supply device with low standby power consumption.

The prior art will be described below with reference to the drawings. Please refer to FIG. FIG. 1 is a block diagram showing a circuit of a conventional power supply device. As shown in FIG. 1, the power supply device 1 is connected to an AC power supply ACP and an electronic system PS. The power supply device 1 receives AC power output from the AC power supply (power source) ACP, performs energy conversion, and supplies it to the electronic system PS. The power supply device 1 operates in a normal mode or a standby mode. The normal mode means that the power supply device 1 supplies power necessary for the operation of the electronic system PS. At this time, the electronic system PS connected to the power supply device 1 is on. In the standby mode, the electronic system PS is in an off state.

  The power supply device 1 includes an EMI filter 10, a rectifier 11, a main inverter 12, a sub inverter 13, a first control device 14, a second control device 15, a power management device 16, a first isolator OC1, and a second isolator. OC2, a third isolator OC3, and a fourth isolator OC4 are included.

  The EMI filter 10 is electrically connected to the rectifier 11, the rectifier 11 is electrically connected to the main inverter 12 and the sub inverter 13, and the first controller 14 is electrically connected to the rectifier 11 and the main inverter 12. The second control device 15 is electrically connected to the sub-inverter 13, and the power management device 16 is electrically connected to the main inverter 12 and the sub-inverter 13.

  The first isolator OC1 is electrically connected to the first power supply output end VA of the main inverter 12 and the first control device 14, and the second isolator OC2 is connected to the standby power output end Vsb of the sub inverter 13. The third isolator OC3 and the fourth isolator OC4 are electrically connected to the power management device 16 and the first control device 14, respectively. For example, each of the first isolator OC1, the second isolator OC2, the third isolator OC3, and the fourth isolator OC4 may be a photocoupler.

  The power supply device 1 receives the AC power output from the AC power supply ACP. When AC power is input to the power supply device 1, the EMI filter 10 removes electromagnetic noise in the AC power, and the rectifier 11 converts the AC power output from the EMI filter 10 into DC power and outputs it. A power factor correction circuit 110 can be added to the rectifier 11 to reduce the amount of input current.

  The main inverter 12 receives the DC power output from the rectifier 11, receives control from the first control device 14, and changes the power output to the first power output end VA and the second power output end VB. The main inverter 12 is a DC-DC converter, and may be, for example, an LLC current resonance converter, a double forward converter, or a single forward converter. The sub-inverter 13 receives the DC power output from the rectifier 11, receives control from the second control device 15, and changes the output power. The sub inverter 13 may be a flyback converter, for example.

  In the normal mode, the main inverter 12 performs energy conversion, converts DC power to main power, and outputs the main power from the first power output end VA and the second power output end VB. In standby mode, energy conversion is not performed and power is not output. In short, power is not output from the first power output end VA and the second power output end VB.

  Since the power supply device 1 includes both the main inverter 12 and the sub inverter 13, the volume is large. Further, since the main inverter 12 and the sub-inverter 13 simultaneously perform energy conversion in the normal mode, the power consumption of the power supply device 1 is large.

JP 2002-368903 A JP 2004-2474897 A

An object of the present invention is to provide a power supply device that is small in size and has low standby power consumption.

In order to achieve the above object, the present invention provides a power supply device. The power supply device of the present invention is connected to an AC power supply device and an electronic system, receives AC power output from the AC power supply device, performs energy conversion, and supplies it to the electronic system. Includes rectifier, inverter, control device, power management device and switch device. The inverter is electrically connected to the rectifier and has a first power output end and a standby power output end. The standby power output end is electrically connected to the electronic system. The control device is electrically connected to the inverter. The power management device is electrically connected to the control device and the electronic system. The switch device is electrically connected to the first power output end, the power management apparatus, and the electronic system, and switches on or off the power output from the first power output end based on the control of the power management apparatus. .

Unlike the conventional power supply device, the power supply device of the present invention does not require the attached power converter and can effectively reduce the volume of the power supply device. In addition, energy consumption can be reduced, and energy saving during standby can be realized.

It is a block diagram which shows the circuit of the power supply device by a prior art. 1 is a block diagram showing a circuit of a power supply device according to a first embodiment of the present invention. It is a figure which shows the circuit of the power supply converter by the 1st Embodiment of this invention. It is a figure which shows the circuit of the power supply converter by the 2nd Embodiment of this invention. It is a figure which shows the circuit of the power supply converter by the 3rd Embodiment of this invention. It is a sequence diagram which shows operation | movement of the power supply apparatus of FIG. It is another sequence diagram which shows operation | movement of the power supply apparatus of FIG. It is a block diagram which shows the circuit of the power supply device by the 2nd Embodiment of this invention. It is a block diagram which shows the circuit of the power supply device by the 3rd Embodiment of this invention.

Embodiments of the present invention will be described below with reference to the drawings.

Please refer to FIG. FIG. 2 is a block diagram illustrating a circuit of a power supply device according to an embodiment of the present invention. As shown in FIG. 2, the power supply device 2 of the present invention is connected to an AC power supply ACP and an electronic system PS. The power supply device 2 receives the AC power output from the AC power supply ACP, performs energy conversion, and supplies it to the electronic system PS.

The power supply device 2 includes an EMI filter 20, a rectifier 22, an inverter 24, a control device 26, a power management device 28, and a switch device 30. The EMI filter 20 is electrically connected to the AC power supply ACP, receives AC power provided by the AC power supply device ACP, and removes electromagnetic noise in the AC power.

The rectifier 22 converts AC power output from the EMI filter 20 into DC power and outputs the DC power. A power factor correction circuit 110 is added to the rectifier 22 to reduce the amount of input current.

The inverter 24 is electrically connected to the rectifier 22 and the control device 26, and has a standby power output end Vsb, a first power output end VA, and a second power output end VB. The inverter 24 is supplied with the AC power output from the rectifier 22 and is controlled by the control device 26 to output the standby power output end Vsb, the first power output end VA, and the second power output end VB. Change the voltage value of the power.

The power management device 28 is electrically connected to the inverter 24, the control device 26 and the electronic system PS, transmits a signal to the electronic system PS via the signal output end PG, and passes through the signal input end PS-On. A signal transmitted by the PS is received.

The switch device 30 is electrically connected to the power management device 28, the first power output terminal VA, the second power output terminal VB, and the electronic system PS, and the switch control signal transmitted from the power management device 28 is transmitted to the switch device 30. Based on this, the electric power output from the first power output end VA and the second power output end VB and transmitted to the electronic system PS is switched on or off.

The inverter 24 may be a DC-DC converter, for example. The DC-DC converter may be, for example, an LLC current resonance converter (see FIG. 3), a double forward converter (see FIG. 4), or a single forward converter (see FIG. 5).

Please refer to FIG. FIG. 3 is a diagram illustrating a circuit of the power converter according to the first embodiment of the present invention. As shown in FIG. 3, the inverter 24 is an LLC current resonance converter, and includes switch devices Q <b> 1 and Q <b> 2, an Lr circuit Lr, a CR circuit Cr, a transformer T, a rectifier circuit 240, and a filter circuit 242.

The switch devices Q1 and Q2 are electrically connected to the rectifier 22 and the control device 26, respectively, receive DC power output from the rectifier 22, and switch on or off according to a signal provided by the control device 26. A pulsation (pulse) signal is output. In the present embodiment, the switch devices Q1 and Q2 are MOSFETs, and the gate electrodes are electrically connected to the control device 26, respectively. A diode to which a diode D is connected between the source and drain of the switch devices Q1 and Q2. D may be a parasitic diode of the switch devices Q1 and Q2.

The Lr circuit Lr is electrically connected to the switch devices Q1 and Q2. In the present embodiment, the Lr circuit Lr is connected between the source electrode of the switch device Q1 and the drain electrode of the switch device Q2, and a DC pulsation signal is used when the switch devices Q1 and Q2 are alternately switched on and off. Receive. The CR circuit Cr is electrically connected to the Lr circuit Lr and the primary side coil Np of the transformer T. The CR circuit Cr forms a resonance circuit together with the Lr circuit Lr and Lm of the primary side coil Np, in addition to isolating the DC component of the DC pulsation signal. In the present embodiment, the transformer T is a center tap type transformer.

The rectifier circuit 240 includes rectifier diodes D1 and D2. The rectifier diodes D1 and D2 are electrically connected to the secondary coil Ns of the transformer T, respectively, to convert the AC power of the transformer T into DC power having a high-frequency pulsating component. The filter circuit 242 is electrically connected to the rectifier circuit 240. The filter circuit 242 is, for example, a CLC circuit, but is not limited to this. The filter circuit 242 has smoothing capacitors C1 and C2 connected to both ends of the filter inductor L and the filter inductor L, respectively, and removes the high-frequency pulsation component of the DC power output from the rectifier diodes D1 and D2, thereby smoothing the filter circuit 242. Outputs DC power.

Please refer to FIG. FIG. 4 is a diagram illustrating a circuit of a power converter according to the second embodiment of the present invention. As shown in FIG. 4, the inverter 24 is a double forward converter, and includes active switch devices S1 and S2, passive switch devices DR1 and DR2, a rectifier circuit 240, a filter circuit 242 and a transformer T. The transformer T has a primary side coil Np and a secondary side coil Ns.

The active switch devices S1 and S2 are electrically connected to the rectifier 22 and the control device 26, respectively, receive DC power output from the rectifier 22, and switch on or off according to a signal provided by the control device 26. The pulsation signal is output. In the present embodiment, the active switch devices S1 and S2 are MOSFETs, and the gate electrodes are electrically connected to the control device 26, respectively. A diode D is connected between the source and drain of each of the active switch devices S1 and S2. The diode D may be a parasitic diode of the active switch devices S1 and S2.

The passive switch device DR1 bridges the active switch device S1 and the primary coil Np, and the passive switch device DR2 bridges the active switch device S2 and the primary coil Np. In the present embodiment, the passive switch devices DR1 and DR2 are diodes.

The rectifier circuit 240 includes rectifier diodes D1 and D2, and is electrically connected to the secondary coil Ns to convert the AC power of the transformer T into DC power having a high-frequency pulsating component. The filter circuit 242 is electrically connected to the rectifier circuit 240. The filter circuit 242 is, for example, a CLC circuit, but is not limited to this. The filter circuit 242 has smoothing capacitors C1 and C2 connected to both ends of the filter inductor L and the filter inductor L, respectively, and removes the high frequency pulsation component of the DC power output from D1 and D2, thereby reducing the gentle DC power. Is output.

Please refer to FIG. FIG. 5 is a diagram illustrating a circuit of a power converter according to a third embodiment of the present invention. As shown in FIG. 5, the inverter 24 is a single forward converter and includes an active switch device S, passive switch devices DR, C, R, a transformer T, a rectifier circuit 240 and a filter circuit 242.

The active switch device S is electrically connected to the rectifier 22 and the control device 26, receives the DC power output from the rectifier 22, and switches on or off according to a signal provided by the control device 26. Is output. In the present embodiment, the active switch device S is a MOSFET, and the gate electrodes are electrically connected to the control device 26, respectively. A diode D is connected between the source and drain of the active switch device S. The diode D may be a parasitic diode of the active switch device S. The passive switch device DR and the capacitor C are connected in series and bridge-connected to the primary coil Np of the transformer T. Resistor R and capacitor C are connected in parallel. In the present embodiment, the passive switch device DR is a diode.

The rectifier circuit 240 includes passive switch devices D1 and D2, and is electrically connected to the secondary coil Ns, and converts the AC power of the transformer T into DC power having a high-frequency pulsating component. The filter circuit 242 is electrically connected to the rectifier circuit 240. The filter circuit 242 is, for example, a CLC circuit, but is not limited to this. The filter circuit 242 has smoothing capacitors C1 and C2 connected to both ends of the filter inductor L and the filter inductor L, respectively, and removes the high frequency pulsation component of the DC power output from D1 and D2, thereby reducing the gentle DC power. Is output.

Refer to FIG. 2 again. The power supply device 2 further includes a first disconnect switch 32, a second disconnect switch 34, and a third disconnect switch 36. The first disconnect switch 32, the second disconnect switch 34, and the third disconnect switch 36 may be, for example, photocouplers, but are not limited thereto.

One end of the first disconnect switch 32 is a signal emitting end, and is electrically connected to the standby power output end Vsb and the second power output end VB, and the other end receives a signal. By electrically connecting to the control device 26 at the end, the power output from the standby power output terminal Vsb and the second power output terminal VB is detected, and the signal corresponding to this output power is isolated. And transmitted to the control device 26.

One end of the second disconnect switch 34 is a signal emitting end, and is electrically connected to the power management device 28, and the other end is a signal receiving end, and is electrically connected to the control device 26. Connected. If the electronic system PS or the power supply device 2 is working in a state where the working voltage or working current is too large or short-circuited, the power management device 28 transmits these protection signals, and the second disc This is transmitted to the control device 26 via the connect switch 34, and the control device 26 causes the inverter 24 to stop the energy conversion.

One end of the third disconnect switch 36 is a signal emitting end, and is electrically connected to the control device 26, and the other end is a signal receiving end, and is electrically connected to the power management device 28. Connected. When the power after the energy conversion of the inverter 24 is normal, the control device 26 transmits a control signal, but the power management device 28 receives this control signal via the third disconnect switch 36 and outputs a signal. The end PG notifies the electronic system PS that the power supply device 2 is operating normally.

Please refer to FIG. FIG. 6 is a sequence diagram showing the operation of the power supply device of FIG. As shown in FIG. 6, in the first state, time is represented by t1 to t7. In this range, the AC power supply ACP is on (AC-On is high potential) and the electronic system PS is on (signal input end PS-On is low potential). When the switch device 30 is off, all the power output from the standby power output terminal Vsb, the first power output terminal VA, and the second power output terminal VB of the power supply device 2 is transmitted to the electronic system PS.

In the second state, time is represented by t7 to t9. In this range, the AC power supply ACP is on (AC-On is high potential), and the electronic system PS is off (signal input end PS-On is high potential). The switch device 30 is turned on, and the power output from the standby power output terminal Vsb of the power supply device 2 is transmitted to the electronic system PS. The power output from the first power output end VA and the second power output end VB is not transmitted to the electronic system PS because the switch device 30 is on.

In the third state, the time is represented by t9 to t11. In this range, the AC power supply ACP is on (AC-On is high potential) and the electronic system PS is off to on (PS-On is from high potential to low potential). When the switch device 30 is off, the standby power output terminal Vsb, the first power output terminal VA, and the second power output terminal VB of the power supply device 2 simultaneously output power to the electronic system PS.

In the fourth state, the time is a portion after t11. In this range, the AC power supply ACP is off (AC-On is low potential) and the electronic system PS is on (PS-On is low potential). The voltage output from the inverter 24 is smaller than the first predetermined value (t11 to t12). The signal output terminal PG of the power supply device 2 transmits a signal to the electronic system PS, thereby notifying the PS that the voltage output from the power supply device 2 is smaller than the first predetermined value. When the voltage output from the inverter 24 is smaller than the second predetermined value (t12 to t13), the switch device 30 is turned on, and the power output from the first power supply output end VA and the second power supply output end VB is electronic. Not transmitted to system PS. When the voltage output from the inverter 24 is smaller than the third predetermined value, the standby power output terminal Vsb stops outputting power to the electronic system PS.

Please refer to FIG. FIG. 7 is another sequence diagram showing the operation of the power supply device of FIG. As shown in FIG. 7, in the first state, time is represented by t1 to t2. In this range, the AC power supply ACP is on (AC-On is high potential), and the electronic system PS is on (PS-On is low potential). When the voltage output from the inverter 24 is greater than a predetermined value, the standby power output terminal Vsb outputs power to the electronic system PS.

In the second state, the time is represented by t2 to t3. In this range, the AC power supply ACP is on (AC-On is high potential) and the electronic system PS is off (PS-On is high potential). When the switch device 30 is turned on, the power output from the standby power output terminal Vsb of the power supply device 2 is transmitted to the PS. The power output from the first power supply output end VA and the second power supply output end VB is not transmitted to the electronic system PS because 30 is on. That is, the power supply device 2 enters a standby state.

T3 to t5 shown in FIG. 7 are the same as t9 to t11 in FIG. Further, t5 to t8 in FIG. 7 are the same as t11 to t14 in FIG.

As described above, the power supply device 2 of the present invention is different from the conventional power supply device 1 in that it is not necessary to provide an attached power converter, and the volume of the power supply device 2 can be effectively reduced. , Energy consumption can be reduced and energy saving during standby can be realized.

Please refer to FIG. FIG. 8 is a block diagram showing a circuit of a power supply apparatus according to the second embodiment of the present invention. Since the power supply device 2A shown in FIG. 8 is substantially the same as the power supply device 2 of the first embodiment, only different portions will be described. The power supply device 2A further includes a DC-DC converter 38, and the inverter 24 has only the first power output end VA.

The DC-DC converter 38 is electrically connected to the first power output terminal VA of the inverter 24 and the power management device 28. The DC-DC converter 38 has a second power output end VB, a third power output end VC, and a standby power output end Vsb. The DC-DC converter 38 receives the DC power output from the first power output terminal VA of the inverter 24, performs energy conversion on the DC power, and outputs the second power output terminal VB, the third power output. Output from the end VC and the standby power output end Vsb. The switch device 30 is electrically connected to the first power output end VA, the second power output end VB, and the third power output end VC, and the switch control signal transmitted from the power management device 28 The power output from the first power output end VA, the second power output end VB and the third power output end VC and transmitted to the electronic system PS is turned on or off. The standby power output terminal Vsb is electrically connected to the electronic system PS.

The first disconnect switch 32 is electrically connected to the first power output end VA, and transmits the power output from the first power output end VA to the control device 26. Since the operation of each device of the power supply apparatus 2A is the same as that of the power supply apparatus 2 of the first embodiment, the description thereof is omitted, but the power supply apparatus 2A has at least the same function as the power supply apparatus 2.

Please refer to FIG. FIG. 9 is a block diagram showing a circuit of a power supply device according to the third embodiment of the present invention. Since the power supply device 2B shown in FIG. 9 is substantially the same as the power supply device 2 of the first embodiment, only different portions will be described. The power supply device 2B further includes a DC-DC converter 38 and a standby power inverter 40, and the inverter 24 has a first power output end VA and a standby power output end Vsb.

The DC-DC converter 38 is electrically connected to the first power output terminal VA of the inverter 24 and the power management device 28. The DC-DC converter 38 has a second power output end VB and a third power output end VC. The DC-DC converter 38 receives DC power output from the first power output terminal VA of the inverter 24, performs energy conversion on the DC power, and outputs the second power output terminal VB and the third power output. Output from the end VC. The switch device 30 is electrically connected to the first power output end VA, the second power output end VB, and the third power output end VC, and the switch control signal transmitted from the power management device 28 The power output from the first power output end VA, the second power output end VB and the third power output end VC and transmitted to the electronic system PS is turned on or off.

The standby power inverter 40 is electrically connected to the inverter 24, the power management device 28, and the electronic system PS. The standby power supply inverter 40 receives the DC power output from the standby power output terminal Vsb of the inverter 24, performs energy conversion on the DC power, and outputs it to the electronic system PS. The first disconnect switch 32 is electrically connected to the first power output end VA, and transmits the power output from the first power output end VA to 26. Since the function of each device of the power supply device 2B is the same as that of the power supply device 2 of the first embodiment, description thereof is omitted, but the power supply device 2B has at least the same function as the power supply device 2.

  Although the present invention discloses preferred embodiments as described above, these are not intended to limit the present invention in any way, and anyone skilled in the art is within the spirit and scope of the present invention. Various changes and modifications can be made. Therefore, the scope of protection of the present invention is based on the contents specified in the claims of the utility model.

1 power supply device 2 power supply device 2A power supply device 2B power supply device 10 EMI filter 11 rectifier 12 main inverter 13 sub inverter 14 first control device 15 second control device 16 power management device 20 EMI filter 22 rectifier 24 inverter 26 control device 28 power management device 30 switch device 32 first disconnect switch 34 second disconnect switch 36 third disconnect switch 38 DC-DC converter 40 standby power inverter 220 power factor improvement circuit 240 rectifier circuit 242 filter Circuit ACP AC power supply C Capacitor CR CR circuit C1 Smoothing capacitor C2 Smoothing capacitor DR Passive switch device DR1 Passive switch device DR2 Passive switch device D1 Rectifier diode D2 Rectifier diode L Filter inductor Lr Lr circuit Np Primary side coil Ns Secondary side coil OC1 First isolator OC2 Second isolator OC3 Third isolator OC4 Fourth isolator PG Signal output end PS Electronic system PS- ON signal input end Q1 switch device Q2 switch device R resistor S active switch device S1 active switch device S2 active switch device T transformer VA first power output end VB second power output end VC third power Output end Vsb Standby power output end

Claims (14)

A power supply device that is connected to an AC power supply device that is a power source and an electronic system that receives power supply, receives AC power from the AC power supply device, performs energy conversion, and supplies power to the electronic system,
A rectifier,
An inverter electrically connected to the rectifier, having a first power output end and a standby power output end, wherein the standby power output end is electrically connected to the electronic system;
A control device electrically connected to the inverter;
A power management device electrically connected to the control device and the electronic system;
Electrically connected to the first power output end, the power management device, and the electronic system, and based on control of the power management device, the power output from the first power output end is turned on or off A power supply device comprising: a switching device for switching. The inverter further includes a second power output end, and on or off the power output by the first power output end and the second power output end based on the control of the power management device The power supply device according to claim 1, wherein the power supply device is electrically connected to the switch device to be switched to. Electrically connected to the second power output end, the standby power output end, and the control device, and the power output from the second power output end and the standby power output end to the control device The power supply device according to claim 2, further comprising a first disconnect switch for transmitting. A standby power inverter electrically connected to the standby power output end; and
The second power supply output end and the third power supply are electrically connected to the first power supply output end and have the second power supply output end and the third power supply output end. An output end is electrically connected to the switch device, and the switch device is configured to control the first power output end, the second power output end, and the third power based on the control of the power management apparatus. The power supply apparatus according to claim 1, further comprising: a DC-DC converter that switches on or off power output from the output end. And a first disconnect switch electrically connected to the first power supply output end and the control device, and transmitting power output from the first power supply output end to the control device. The power supply device according to claim 4. A second disconnect switch that is electrically connected to the power management device and the control device and transmits a protection signal transmitted from the power management device to the control device;
4. A third disconnect switch that is electrically connected to the power management device and the control device and transmits a control signal transmitted from the control device to the power management device. Or the power supply apparatus of 5. The power supply apparatus according to claim 6, further comprising an EMI filter electrically connected to the AC power supply and the rectifier. The power supply device according to claim 7, wherein the inverter is a DC-DC converter. The power supply device according to claim 8, wherein the inverter is an LLC current resonance converter, a double forward converter, or a single forward converter. A power supply device that is connected to an AC power supply device that is a power source and an electronic system that receives power supply, receives AC power from the AC power supply device, performs energy conversion, and supplies power to the electronic system,
A rectifier,
An inverter electrically connected to the rectifier and having a first power output end;
Electrically connected to the first power output end, having a second power output end, a third power output end, and a standby power output end, the standby power output end being connected to the electronic system An electrically connected DC-DC converter;
A control device electrically connected to the inverter;
A power management device electrically connected to the control device, the DC-DC converter and the electronic system;
Electrically connected to the first power output end, the second power output end, the third power output end, the power management device and the electronic system, and based on the control of the power management device A switch device for switching on or off the power transmitted from the first power output end, the second power output end, and the third power output end to be transmitted to the electronic system. A power supply device characterized by that. A first disconnect switch electrically connected to the first power supply output end and the control device, and transmitting power output from the first power supply output end to the control device;
A second disconnect switch electrically connected to the power management device and the control device, and transmitting a protection signal transmitted from the power management device to the control device;
11. A third disconnect switch that is electrically connected to the power management device and the control device and transmits a control signal transmitted from the control device to the power management device. The power supply device described in 1. The power supply apparatus according to claim 11, further comprising an EMI filter electrically connected to the AC power supply unit and the rectifier. The power supply device according to claim 12, wherein the inverter is a DC-DC converter. The power supply device according to claim 13, wherein the inverter is an LLC current resonance converter, a double forward converter, or a single forward converter.

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