TWM507115U - Energy-saving power supply apparatus - Google Patents

Description

Energy-saving power supply device 【0001】

This creation relates to a power supply device, and more particularly to an energy-saving power supply device.

【0002】

The power supply device is a very common electronic device; the power supply device is used to supply power to the load device to drive the load device; therefore, the power supply device is very important. Typically, the power supply unit is connected to an AC power supply to receive AC power.

[0003]

When the AC power supply device or the load device is just started, an inrush current (inrush current) is easily generated; therefore, the power supply device usually includes a negative temperature coefficient thermistor to suppress the sudden rise. Wave current. When the AC power supply device or the load device is just started, the temperature of the negative temperature coefficient thermistor is low, so the impedance is large, and the generation of the surge current can be suppressed. The two-pole system of the bridge rectifier of the power supply device is used to limit the flow of current, and therefore the diode of the bridge rectifier of the power supply device also plays an important role in suppressing the surge current.

[0004]

When no surge current is generated, the diode of the bridge rectifier of the power supply device (even the negative temperature coefficient thermistor) consumes a large amount of energy, and this problem needs to be solved to save energy.

[0005]

In order to improve the above disadvantages of the prior art, the purpose of the present invention is to provide an energy-saving power supply device.

[0006]

In order to achieve the above object of the present invention, the energy-saving power supply device of the present invention comprises: a bridge rectifier; a diode bypass circuit electrically connected to the bridge rectifier; and a control circuit electrically connected to the second A pole bypass circuit and the bridge rectifier. Wherein the bridge rectifier comprises a plurality of diodes. After the control circuit receives a power start signal, the control circuit controls the diode bypass circuit such that a portion of the diodes are bypassed to save energy.

【0007】

Furthermore, the energy-saving power supply device as described above further includes: a negative temperature coefficient thermistor electrically connected to the diode bypass circuit and the bridge rectifier.

[0008]

Furthermore, the energy-saving power supply device as described above further includes: a DC-DC converter that is electrically connected to the bridge rectifier and the control circuit.

【0009】

Furthermore, the energy-saving power supply device as described above further includes: a filter capacitor electrically connected to the bridge rectifier and the DC-to-DC converter.

[0010]

Furthermore, the energy-saving power supply device as described above, wherein the bridge rectifier comprises: a first diode, electrically connected to the diode bypass circuit and the control circuit.

[0011]

Furthermore, the energy-saving power supply device as described above, wherein the bridge rectifier further comprises: a second diode electrically connected to the diode bypass circuit, the control circuit and the first diode .

[0012]

Furthermore, the energy-saving power supply device as described above, wherein the bridge rectifier further comprises: a third diode, electrically connected to the diode bypass circuit and the first diode.

[0013]

Furthermore, the energy-saving power supply device as described above, wherein the bridge rectifier further comprises: a fourth diode, electrically connected to the diode bypass circuit, the second diode, and the third Diode.

[0014]

Furthermore, the energy-saving power supply device as described above, wherein the diode bypass circuit comprises: a first switch electrically connected to the bridge rectifier and the control circuit.

[0015]

Furthermore, the energy-saving power supply device as described above, wherein the diode bypass circuit further comprises: a second switch electrically connected to the bridge rectifier, the control circuit and the first switch.

[0016]

The effect of the present invention is that after the control circuit receives the power-on signal (there is no surge current generated at this time), the control circuit controls the diode bypass circuit such that the two poles of the bridge rectifier A portion of the body is bypassed to save energy.

[0042]

10‧‧‧Energy-saving power supply unit

[0043]

20‧‧‧AC power supply unit

[0044]

30‧‧‧Loading device

[0045]

102‧‧‧Bridge rectifier

[0046]

104‧‧‧ diode bypass circuit

[0047]

106‧‧‧Control circuit

[0048]

108‧‧‧Negative temperature coefficient thermistor

[0049]

110‧‧‧DC to DC converter

[0050]

112‧‧‧Filter capacitor

[0051]

114‧‧‧Switch unit

[0052]

116‧‧‧Switch control unit

[0053]

118‧‧‧Switch subunit

[0054]

120‧‧‧First resistance

[0055]

122‧‧‧second resistance

[0056]

124‧‧‧ Third resistor

[0057]

202‧‧‧Power supply

[0058]

D1‧‧‧First Diode

[0059]

D2‧‧‧ second diode

[0060]

D3‧‧‧ third diode

[0061]

D4‧‧‧ fourth diode

[0062]

S1‧‧‧ first switch

[0063]

S2‧‧‧ second switch

[0017]

1 is a block diagram of a first embodiment of the energy-saving power supply device of the present invention.

[0018]

2 is a block diagram showing a second embodiment of the energy-saving power supply device of the present invention.

[0019]

The detailed description and technical contents of the present invention are described in the following detailed description and the accompanying drawings.

[0020]

Please refer to FIG. 1, which is a block diagram of a first embodiment of the energy-saving power supply device of the present invention. An energy-saving power supply device 10 is applied to an AC power supply device 20 and a load device 30. The energy-saving power supply device 10 includes a bridge rectifier 102, a diode bypass circuit 104, a control circuit 106, a negative temperature coefficient thermistor 108, a DC-DC converter 110, and a filter capacitor 112. The bridge rectifier 102 includes a plurality of diodes; that is, the bridge rectifier 102 includes a first diode D1, a second diode D2, a third diode D3, and a fourth diode. Body D4. The diode bypass circuit 104 includes a first switch S1 and a second switch S2.

[0021]

The diode bypass circuit 104 is electrically connected to the bridge rectifier 102; the control circuit 106 is electrically connected to the diode bypass circuit 104 and the bridge rectifier 102; the negative temperature coefficient thermistor 108 is electrically The DC-DC converter 110 is electrically connected to the bridge rectifier 102 and the control circuit 106; the filter capacitor 112 is electrically connected to the bridge. The rectifier 102 and the DC to DC converter 110.

[0022]

The first diode D1 is electrically connected to the diode bypass circuit 104 and the control circuit 106; the second diode D2 is electrically connected to the diode bypass circuit 104, the control circuit 106, and The first diode D1 is electrically connected to the diode bypass circuit 104 and the first diode D1; the fourth diode D4 is electrically connected to the diode The body bypass circuit 104, the second diode D2, and the third diode D3. The first switch S1 is electrically connected to the bridge rectifier 102 and the control circuit 106; the second switch S2 is electrically connected to the bridge rectifier 102, the control circuit 106 and the first switch S1.

[0023]

After the control circuit 106 receives a power-on signal (when no surge current is generated), the control circuit 106 controls the diode bypass circuit 104 to make the diodes (ie, the first two) a portion of the pole body D1, the second diode D2, the third diode D3, and the fourth diode D4) (eg, the second diode D2 or the fourth diode D4) is bypassed The road is energy-saving, as detailed below. The power-on signal indicates that the DC-to-DC converter 110 is to be operated (ie, no surge current is generated at this time).

[0024]

When the AC power supply device 20 or the load device 30 is just activated (the surge current is easily generated), the first switch S1 and the second switch S2 are non-conductive, so that the AC power supply device 20 provides A power source 202 flows through the negative temperature coefficient thermistor 108 to suppress the surge current. Since the temperature of the negative temperature coefficient thermistor 108 is low at this time, the impedance is large, and the generation of the surge current can be suppressed.

[0025]

At this time, the positive half-circle path of the power source 202 is: the first diode D1, the DC-to-DC converter 110, the load device 30, the negative temperature coefficient thermistor 108, the fourth diode D4, and The AC power supply device 20. The negative half-cycle path of the power source 202 is: the third diode D3, the DC-to-DC converter 110, the load device 30, the negative temperature coefficient thermistor 108, the second diode D2, and the alternating current Power supply device 20.

[0026]

The power start signal may be from a pulse width modulation controller (not shown in FIG. 1) or the AC power supply device 20 of the DC to DC converter 110; after the control circuit 106 receives the power start signal (at this time) There is no surge current generated):

[0027]

The control circuit 106 turns on the second switch S2 in the positive half of the power source 202 without turning on the first switch S1. The path is: the first diode D1, the DC-to-DC converter 110, the load. The device 30, the second switch S2 and the AC power supply device 20 thus save energy consumption of the negative temperature coefficient thermistor 108 and the fourth diode D4.

[0028]

The control circuit 106 turns on the first switch S1 in the negative half cycle of the power source 202 without turning on the second switch S2. The path is: the third diode D3, the DC-to-DC converter 110, the load. The device 30, the first switch S1 and the AC power supply device 20 thus save energy consumption of the negative temperature coefficient thermistor 108 and the second diode D2.

[0029]

Moreover, in order to avoid the malfunction of the zero point switching, the flow after the control circuit 106 receives the power start signal may be modified as follows:

[0030]

The control circuit 106 still does not turn on the first switch S1 during the positive half cycle of the power source 202; the control circuit 106 is in the positive half of the power source 202 and the absolute value of the voltage of the power source 202 is greater than a predetermined voltage value (for example, 5 The second switch S2 is turned on when volts or 10 volts. The control circuit 106 still does not turn on the second switch S2 during the negative half cycle of the power source 202; the control circuit 106 is turned on when the negative half of the power source 202 and the absolute value of the voltage of the power source 202 is greater than the preset voltage value. The first switch S1. In this way, the malfunction of the zero point switching can be avoided.

[0031]

However, in the positive half cycle of the power source 202 and the absolute value of the voltage of the power source 202 is not greater than the predetermined voltage value, and in the negative half cycle of the power source 202 and the absolute value of the voltage of the power source 202 is not greater than the preset voltage. In the case of the value, the control circuit 106 does not turn on the first switch S1 and the second switch S2; the positive half-circle path of the power source 202 is: the first diode D1, the DC-to-DC converter 110, The load device 30, the negative temperature coefficient thermistor 108, the fourth diode D4 and the AC power supply device 20; the negative half-cycle path of the power source 202 is: the third diode D3, the DC transfer The DC converter 110, the load device 30, the negative temperature coefficient thermistor 108, the second diode D2, and the AC power supply device 20. The energy consumption of the negative temperature coefficient thermistor 108, the fourth diode D4, and the second diode D2 is wasted compared to the absence of the preset voltage value. The energy consumption of the fourth diode D4 and the second diode D2 cannot be avoided, but the energy consumption of the negative temperature coefficient thermistor 108 can be avoided by the following embodiments.

[0032]

Please refer to FIG. 2 , which is a block diagram of a second embodiment of the energy-saving power supply device of the present invention. The components shown in FIG. 2 are similar to those in FIG. 1 , and are not described here. The energy-saving power supply device 10 further includes a switch unit 114 and a switch control unit 116. The switch control unit 116 includes a switch subunit 118, a first resistor 120, a second resistor 122, and a third resistor 124.

[0033]

The switching unit 114 can be, for example, but not limited to a transistor switch, such as a MOS field effect transistor or a bipolar junction transistor, the power consumption of which is much smaller than that of the negative temperature coefficient thermistor 108. Power consumption; the switch subunit 118 can be, for example, but not limited to a transistor switch, such as a gold oxide half field effect transistor or a bipolar junction transistor, the power consumption is much smaller than the negative temperature coefficient heat The power consumption of the varistor 108.

[0034]

The switch unit 114 is electrically connected to the negative temperature coefficient thermistor 108; the switch control unit 116 is electrically connected to the switch unit 114 and the control circuit 106; the switch subunit 118 is electrically connected to the switch unit 114 and The control circuit 106; the first resistor 120 is electrically connected to the switch subunit 118 and the control circuit 106; the second resistor 122 is electrically connected to the switch subunit 118 and the first resistor 120; the third resistor 124 is electrically connected to the switch subunit 118 and the switch unit 114.

[0035]

When the AC power supply device 20 or the load device 30 is just activated (the surge current is easily generated), the first switch S1, the second switch S2, and the switch unit 114 are non-conducting, so that the AC power source is The power source 202 provided by the supply device 20 flows through the negative temperature coefficient thermistor 108 to suppress the surge current. Since the temperature of the negative temperature coefficient thermistor 108 is low at this time, the impedance is large, and the generation of the surge current can be suppressed.

[0036]

After the control circuit 106 receives the power-on signal (there is no surge current generated at this time):

[0037]

The control circuit 106 does not turn on the first switch S1 during the positive half cycle of the power source 202; the control circuit 106 turns on the first half of the power source 202 and the absolute value of the voltage of the power source 202 is greater than the preset voltage value. Two switches S2. The control circuit 106 does not turn on the second switch S2 during the negative half cycle of the power source 202; the control circuit 106 turns on the first half of the power source 202 and the absolute value of the voltage of the power source 202 is greater than the preset voltage value. A switch S1. In this way, the malfunction of the zero point switching can be avoided.

[0038]

In the positive half cycle of the power source 202 and the absolute value of the voltage of the power source 202 is not greater than the preset voltage value, the control circuit 106 does not turn on the second switch S2 but the control circuit 106 controls the switch control unit 116 to Turning on the switch unit 114; the impedance of the switch unit 114 is much smaller than (or less than) the impedance of the negative temperature coefficient thermistor 108, so the negative temperature coefficient thermistor 108 is bypassed and hardly turned on, so that The path is: the first diode D1, the DC-to-DC converter 110, the load device 30, the switch unit 114, the fourth diode D4, and the AC power supply device 20. Therefore, the energy consumption of the negative temperature coefficient thermistor 108 is saved compared to the absence of the switching unit 114 and the switch control unit 116.

[0039]

In the negative half cycle of the power source 202 and the absolute value of the voltage of the power source 202 is not greater than the predetermined voltage value, the control circuit 106 does not turn on the first switch S1 but the control circuit 106 controls the switch control unit 116 to Turning on the switch unit 114; the impedance of the switch unit 114 is much smaller than (or less than) the impedance of the negative temperature coefficient thermistor 108, so the negative temperature coefficient thermistor 108 is bypassed and hardly turned on, so that The path is: the third diode D3, the DC-to-DC converter 110, the load device 30, the switch unit 114, the second diode D2, and the AC power supply device 20. Therefore, the energy consumption of the negative temperature coefficient thermistor 108 is saved compared to the absence of the switching unit 114 and the switch control unit 116.

[0040]

The main function of the present invention is that after the control circuit 106 receives the power-on signal (when no surge current is generated), the control circuit 106 controls the diode bypass circuit 104 such that the bridge rectifier 102 A portion of the diodes are bypassed to save power; at this time, the negative temperature coefficient thermistor 108 is also bypassed to save energy. Moreover, even if the preset voltage value is set to avoid the malfunction of the zero point switching, the present invention can bypass the negative temperature coefficient thermistor 108 when the absolute value of the voltage of the power source 202 is not greater than the preset voltage value. Energy saving.

[0041]

However, the above is only a preferred embodiment of the present invention, and the scope of the present invention cannot be limited, that is, the equal changes and modifications made by the scope of the patent application of the present invention should still be covered by the patent of the present invention. The scope of the scope is intended to protect. There may be other various embodiments of the present invention, and those skilled in the art can make various corresponding changes and modifications according to the present invention without departing from the spirit of the present invention, but the corresponding changes and modifications are It is intended to fall within the scope of the appended claims. In summary, when Zhiben's creation has industrial applicability, novelty and progressiveness, and the structure of this creation has not been seen in similar products and public use, it fully complies with the requirements of new patent applications and applies for patent law.

10‧‧‧Energy-saving power supply unit

20‧‧‧AC power supply unit

30‧‧‧Loading device

102‧‧‧Bridge rectifier

104‧‧‧ diode bypass circuit

106‧‧‧Control circuit

108‧‧‧Negative temperature coefficient thermistor

110‧‧‧DC to DC converter

112‧‧‧Filter capacitor

202‧‧‧Power supply

D1‧‧‧First Diode

D2‧‧‧ second diode

D3‧‧‧ third diode

D4‧‧‧ fourth diode

S1‧‧‧ first switch

S2‧‧‧ second switch

Claims (11)

[Item 1] An energy-saving power supply device comprising:
a bridge rectifier;
a diode bypass circuit electrically connected to the bridge rectifier; and a control circuit electrically connected to the diode bypass circuit and the bridge rectifier
Wherein the bridge rectifier comprises a plurality of diodes;
After the control circuit receives a power start signal, the control circuit controls the diode bypass circuit such that a portion of the diodes are bypassed to save energy. [Item 2] For example, the energy-saving power supply device described in claim 1 of the patent scope further includes:
A negative temperature coefficient thermistor is electrically connected to the diode bypass circuit and the bridge rectifier. [Item 3] The energy-saving power supply device as described in claim 2, further comprising:
A DC to DC converter is electrically connected to the bridge rectifier and the control circuit. [Item 4] For example, the energy-saving power supply device described in claim 3 of the patent scope further includes:
A filter capacitor is electrically connected to the bridge rectifier and the DC to DC converter. [Item 5] The energy-saving power supply device of claim 1, wherein the bridge rectifier comprises:
A first diode is electrically connected to the diode bypass circuit and the control circuit. [Item 6] The energy-saving power supply device of claim 5, wherein the bridge rectifier further comprises:
A second diode is electrically connected to the diode bypass circuit, the control circuit and the first diode. [Item 7] The energy-saving power supply device of claim 6, wherein the bridge rectifier further comprises:
A third diode is electrically connected to the diode bypass circuit and the first diode. [Item 8] The energy-saving power supply device of claim 7, wherein the bridge rectifier further comprises:
A fourth diode is electrically connected to the diode bypass circuit, the second diode, and the third diode. [Item 9] The energy-saving power supply device of claim 1, wherein the diode bypass circuit comprises:
A first switch is electrically connected to the bridge rectifier and the control circuit. [Item 10] The energy-saving power supply device of claim 9, wherein the diode bypass circuit further comprises: A second switch is electrically connected to the bridge rectifier, the control circuit and the first switch.