KR101318259B1 - Power supply with high quality by cut off noise - Google Patents

Abstract

PURPOSE: A power supply unit with high quality without noises is provided to supply power with the high quality by completely separating a battery from an external power source. CONSTITUTION: A charging unit (10) charges a first battery and a second battery with external power. A discharge power supplying unit (20) supplies power discharged from the first battery and the second battery to a load. A switching unit selectively connects the first battery and the second battery to the charging unit or the discharge power supplying unit. A control unit (40) senses the power inputted to the discharge power supplying unit and controls the switching unit. [Reference numerals] (10) Charging unit; (20) Discharge power supplying unit; (41) Sensing unit; (43) Driving unit; (45) Lock function unit; (47) Unlocking unit

Description

Power Supply with high quality by cut off noise}

The present invention does not directly output the power input from the outside to the load side, the power input from the outside to charge the battery, discharge the charged battery to output to the load side, so that more stable power is supplied to the load side In more detail, the present invention relates to a power supply device, which includes a plurality of batteries and separates the charging and discharging of the battery so that noise and electromagnetic waves are inherently prevented from flowing into the power supplied to the load side. When the voltage drops below a certain level due to the discharge of the battery, other batteries can be discharged immediately so that continuous high-quality power can be supplied, and the high-quality that cuts out the noise that the charging or discharging of the battery is stable is performed. It relates to a power supply.

As is well known, a power supply device is a device for converting power supplied from an external source into power required for a load side.

When a DC power source is required on the load side, a regulator for supplying power to the load side by constant voltage (or constant current) input from the outside is provided.

When an AC power source is required on the load side, a converter for converting power input from the outside into a direct current (DC) and an inverter for converting the DC power output from the converter into an alternating current to be supplied to the load side.

The normal electric device connected to the load side is not a big problem even if the power is supplied from the power supply device including the regulator or the converter and the inverter as described above, but the electric device that requires precise work or the audio device used by the mania is common. The power supply can be a problem.

As the external power input to the power supply, commercial AC power does not become a very stable power source because it contains noise, surge, and electromagnetic waves. An external power source provided in front of the power supply and an adapter for converting a commercial AC power into a DC power input to the power supply also alleviates noise, surge, electromagnetic waves, etc. of the commercial AC power, but this is also not a stable power supply.

Since a general power supply converts such unstable external power and supplies it directly to an electric device on the load side, the power supplied to the load side is also not stable.

Thus, when operating a computer connected to the load side, data, etc. disappear momentarily, the TV screen is distorted, and the audio quality is different, mostly because of the instability of the supplied power supply, not the electric device itself.

In order to solve the problem that the power supplied to the load side is also unstable due to the instability of the external power as described above, in the power supply device such as Patent No. 0177949

Instead of converting the power input from the outside and outputting directly to the load side, the power input from the outside is charged to the battery once, and discharges the charged power to the load side to solve the problem caused by the instability of the external power. have.

In the power supply apparatus according to the prior art, including the registered Patent No. 0177949, and having a battery in the power supply device to supply power to the load side with the discharge power of the battery

Since the battery is charged and discharged at the same time so that power supply to the load side is not interrupted due to insufficient capacity of the battery,

The electrical connection between the external power source and the load side is maintained, and thus there is a problem of limitation that surge, noise, electromagnetic waves, etc. of the unstable external power source are not completely interrupted and are only supplied to the electrical device on the load side in a relaxed state.

That is, the power supply device according to the prior art using the battery has improved the stability of the power supply to the load side, but the power supply is not stable enough to meet the needs of the consumer who requires a precise electrical device or high quality power supply.

In the power supply apparatus according to the related art using a battery, a situation in which the power consumed by the load side is insufficient as the power for discharging the battery may occur, and at that time, the discharge of the battery may occur. There may be a problem that the power supply to the load side again after a suspend to charge the battery to a certain level or more.

That is, the power supply device according to the prior art using the battery has a problem that the continuous power supply to the electrical device of the load side can not be guaranteed.

The present invention has been made in order to solve the problem of the power supply device according to the prior art having a battery as described above, the battery which discharges and supplies power to the load side is completely separated and cut off from the external power side effect of unstable external power It is an object of the present invention to provide a high-quality power supply device that cuts off noise that supplies high-quality power that does not include surge, noise, electromagnetic waves, and the like to the load side.

When the discharge voltage level of the battery that discharges and supplies power to the load side falls below the reference value, another battery discharges immediately to supply power to the load side, and the battery that has fallen below the reference value is charged by external power. It is another object of the present invention to provide a high-quality power supply device that cuts off noise by supplying power to the power supply, so that power supply to the load side is not interrupted due to insufficient battery capacity.

In addition, once the discharge voltage of the battery being discharged falls below the reference value, the battery to be discharged to the load side is replaced regardless of the change in the discharge voltage level of the battery thereafter, but the newly replaced battery is stably discharged to the load side. After the battery is discharged until the battery starts to be connected to the load side, the battery is charged by connecting the existing battery from the load side to the external power side, thereby eliminating noise instability of the load side power supply caused by the replacement of the charge / discharge battery. Another object is to provide a high quality power supply which is cut off.

High-quality power supply cut off the noise according to the present invention for achieving the above object

A first battery and a second battery;

A charging unit configured to charge the first battery and the second battery with power input from the outside;

A discharge power supply unit supplying power discharged from the first battery and the second battery to a load side;

A switching unit for selectively connecting each of the first battery and the second battery to the charging unit or the discharge power supply unit;

Sensing the power input to the discharge power supply unit to control the switching unit, any one of the first battery and the second battery is connected to the discharge power supply to supply power to the load side, the other is the charging unit And a control unit connected to be charged.

And the control unit

A detection unit for detecting the intensity of power input to the discharge power supply unit;

A driving unit which outputs and drives a control signal to the switching unit when a power below a reference value is detected by the sensing unit;

And a lock function unit provided between the sensing unit and the driving unit and locking the sensing unit below the reference value when the sensing signal below the reference value is input to the driving unit so that the sensing signal below the reference value is maintained for a predetermined time thereafter. Characterized in that,

The control unit

Characterized in that the lock function further comprises a release unit for releasing the locked state after a predetermined time after the lock is locked,

When the control unit switches and connects the first battery (or second battery) connected to the power supply unit to the charging unit through the switching unit, the second battery (or first battery) connected to the charging unit is discharged beforehand. After a predetermined time after switching to the power supply connected, it is characterized in that the switching to the charging unit.

The high-quality power supply device which cuts noise according to the present invention having the configuration as described above discharges and supplies the power to the load side, so that the battery is completely disconnected from the external power side and the instability of the external power does not affect the load side. Sources of surge, noise, electromagnetic waves, etc. are contained in the power supply to be cut off at the source to supply high quality power.

And while the battery is discharged and supplying power to the load side, the other battery is charged with external power.If the voltage level of the discharged battery falls below the standard value, the charged battery is immediately connected to the load side to supply power. Since charging is performed by being connected to the external power side, continuous power supply is possible without interruption of power supply to the load side due to insufficient battery capacity.

In addition, if the discharge voltage level of the battery during discharge falls below the reference value, a lock is applied to detect that the reference value or less is detected, and the charge / discharge of the battery is replaced regardless of the change in the discharge voltage level thereafter. Until the discharge of the battery is performed stably, the existing discharge is maintained to maintain the load side connection of the battery, so that the power supplied to the load side becomes unstable when the charge / discharge battery is replaced.

1 is a block diagram of a high-quality power supply cut off the noise according to the present invention.
Figure 2 is a circuit diagram of a high quality power supply cut off the noise according to the present invention.

Hereinafter, a circuit diagram of a high quality power supply device which cuts off noise according to the present invention will be described in more detail with reference to the accompanying drawings.

First, as shown in FIG. 1, the high-quality power supply device which cuts noise according to the present invention includes a first battery BAT1, a second battery BAT2, a charging unit 10, a discharge power supply unit 20, and a switching unit ( 30) divided into components of the control unit 40.

The first battery BAT1 and the second battery BAT2 are representative of a plurality of batteries BAT1 and BAT2 and illustrate two batteries BAT1 and BAT2 and include first batteries BAT1 and BAT2, ) And the second battery BAT2, but it is noted that the batteries BAT1 and BAT2 may be provided in three or four or more batteries.

A plurality of batteries BAT1 and BAT2 are selectively connected to the charging unit 10 side or the discharge power supply unit 20 through the switching unit 30, respectively. That is, each of the batteries BAT1 and BAT2 is separated on the discharge power supply 20 side when connected to the charging unit 10 side, and separated on the charge unit 10 side when connected to the discharge power supply 20 side.

There are various types of secondary batteries that can be charged. In the present invention, which is intended to supply a high-quality power source to the load side, a lithium ion battery having high stability of charging and discharging is preferable.

The charging unit 10 charges the first battery BAT1 and the second battery BAT2 with external power input from the outside.

As shown in FIG. 2, the charging unit 10 includes a capacitor C2 connected to the input terminal J1 to smooth external power and a diode D1 rectified.

For reference, the external power source input at the input terminal J1 may be a commercial AC power source, and an adapter connected in front of an input terminal may be a DC power source that converts a commercial AC power source to a DC power source.

Although not particularly shown in the drawing, the charging voltage of the first battery BAT1 and the second battery BAT2 being charged is sensed to prevent unnecessary power waste by stopping the charging of the charging unit 10 when fully charged. It may be desirable to include a full detection unit.

The discharge power supply unit 20 supplies the power discharged from the first battery BAT1 and the second battery BAT2 to the load side connected to the output stage J2.

The discharge power supply unit 20

A constant voltage regulator IC2 for making the power supplied from the first battery BAT1 and the second battery BAT2 discharged,

Capacitors C7 and C8 and diodes D2 and D3 for smoothing and rectifying the power output from the constant voltage regulator IC2 and supplying the power to the load side connected to the output stage J2,

A capacitor C14 and a resistor R4 and R5 for feeding back the output voltage of the constant voltage regulator IC2 and outputting a constant voltage of constant magnitude at constant voltage regulator IC2,

And a volume resistor (VR1) for adjusting the output voltage magnitude of the constant voltage regulator (IC2).

The switching unit 30 selectively connects the first battery BAT1 and the second battery BAT2 to the charging unit 10 or the discharge power supply unit 20, respectively.

In the present invention as the switching unit 30, a relay composed of a magnet switch and a drive coil for driving the magnet switch by electromagnetic force was used.

The switching unit 30 may be a semiconductor device such as a transistor, a thyristor, a triac, and the like, in addition to the relay, but the semiconductor device serving as the switching device may include the batteries BAT1 and BAT2 and the charging unit 10 or the discharge. Since the electrical connection of the power supply 20 is not completely interrupted, it is somewhat inadequate for the purpose of the present invention to supply high quality power.

As a relay of the present invention, as shown in FIG. 2, a magnet switch is formed by using a pair of batteries (BAT1, BAT2) that use a pair of two power lines (ie, + power line and-power line) to simultaneously open or short. The electrical connection of the charging unit 10 or the discharge power supply unit 20 is more completely separated and cut off, thereby supplying higher quality power.

The switching unit 30 includes a first front relay K1 and a first rear relay K3 that are connected to the front and rear of the first battery BAT1 to charge or discharge the batteries BAT1 and BAT2, And a second front relay K2 and a second rear relay K4 which are respectively connected to the front and rear of the second battery BAT2 to charge or discharge the batteries BAT1 and BAT2.

The control unit 40 senses a discharge voltage of the batteries BAT1 and BAT2 input to the discharge power supply unit 20 and controls the switching unit 30 according to a detection result to generate a first battery BAT1, One of the two batteries BAT2 and BAT2 is connected to the charging unit 10 and the other batteries BAT1 and BAT2 are connected to the discharging power supply unit 20. [

The control unit 40 includes a sensing unit 41, a driving unit 43, a locking function unit 45, and a releasing unit 47.

The sensing unit 41

Distribution resistors R2 and R3 for distributing and sensing the discharge power of the first battery BAT1 or the second battery BAT2 inputted to the discharge power supply unit 20,

A resistor Rl, a zener diode D3, and a capacitor C3 for setting a reference voltage (i.e., a reference value) for comparison with a discharge voltage sensed through the distribution resistors R2 and R3,

A comparator IC1B for inputting and comparing the reference voltage and the discharge voltage with the inverting terminal and the non-inverting terminal,

And a photocoupler PT1-1 which is turned on and off according to a comparison signal of the comparator IC1B.

The signal of the photocoupler PT1-1 is transmitted to the driving unit 43 through the locking function unit 45 to drive the switching unit 30. [

The input side and the output side of the photocoupler PT1-1 are electrically insulated so that the discharge power source of the batteries BAT1 and BAT2 (that is, the power source sensed by the sensing unit 41) does not adversely affect the control unit 40 do.

The driving unit 43 receives a sensing signal output from the photocoupler PT1-1 of the sensing unit 41 as a pulse signal through the locking function unit 45, Off.

The driving unit 43

A flip-flop CPU (IC5B) for receiving a detection signal from the sensing unit (41) and outputting a control signal to the switching unit (30)

The first battery BAT1 and the second battery BAT2 provided between the flip-flop CPU IC5B and the switching unit 30 are selectively connected to the charging unit 10 or the discharging power supply unit 20, NAND gates (IC4A, IC4B, IC4C, and IC4D) and NOT gates (IC3A, IC3B, IC3E, and IC3F)

The flip-flop CPU IC5B outputs a control signal (0 or 1) opposite to the first battery BAT1 and the second battery BAT2 to output the control signal 0 or 1 to the first battery BAT1 and the second battery BAT2, One of the batteries BAT1 and BAT2 is connected to the charging unit 10 and the other batteries BAT1 and BAT2 are connected to the discharging power supply unit 20,

IC3A and IC3B serving as the NOT gates function as the switching portion 30 in such a manner that the first front relay K1 and the first rear relay K3, which are connected to the front and rear sides of the first battery BAT1, And the second front relay K2 and the second rear relay K4 connected to the front and rear sides of the second battery BAT2 are operated to be turned on or off as opposed to each other, 2 battery BAT2 are selectively connected to the charging unit 10 or the discharge power supply unit 20, respectively.

The two output terminals Q and 1Q of the flip-flop CPU IC5B do not output control signals opposite to each other, that is, 0 (Low) and 1 (High) (BAT1 or BAT2) connected to the discharge power supply unit 20 through the discharge power supply unit 20, the main output terminals are alternately changed, It is preferable to have a time delay time (about 1 second to 2 seconds) and to output a control signal at another output terminal.

This is, for example, an operation of connecting the first battery BAT1 from the discharging power supply unit 20 to the charging unit 10 and connecting the first battery BAT1 from the charging unit 10 to the discharging power supply unit 20 A blank space for power supply to the discharge power supply unit 20 can be generated for a very short period of time when the two output terminals Q and 1Q simultaneously output control signals which are opposite to each other and the battery BAT1, BAT2 may be unstable due to the discharge of the batteries BAT1 and BAT2.

That is, before the first battery BAT1 connected to the discharge power supply unit 20 is replaced with the charging unit 10, the second battery BAT2 is replaced with the discharge power supply unit 20, The first battery BAT1 is replaced with the charging unit 10 after the discharge of the second battery BAT2 is stabilized and the stability of the power supplied to the load side through the discharge power supply unit 20 is improved.

The locking function unit 45 allows the driving unit 43 to transmit a sensing signal that is lower than the reference value sensed by the sensing unit 41 for a predetermined period of time.

That is, once the sensing signal of the reference value or less is inputted from the sensing unit 41, the sensing unit 41 senses a sensing signal of a reference value or less to the driving unit 43 for a predetermined time, To lock the input continuously.

The discharge voltage of the batteries BAT1 and BAT2 due to the discharge is reduced in a macroscopically linear manner but is not reduced completely linearly in a microscopic manner, Thus, even if the discharge voltage of the batteries BAT1 and BAT2 falls below the reference value, the discharge voltage may instantaneously rise above the reference value.

When the battery BAT1 or BAT2 drops below the reference value and the batteries BAT1 and BAT2 connected to the charger 10 are connected to the discharge power supply 20 in a short time, If the drive unit 43 operates in response to a detection signal that is detected later, an error may occur or the drive unit 43 may be damaged.

When the detection signal of the reference value or less is detected in the sensing unit 41, the locking function unit 45 (BAT1, BAT2) is connected to the charging unit 10 until the batteries BAT1, BAT2 are stably connected to the discharging power supply unit 20 ) Locks the sensing signal to the driving unit 43 so that the sensing signal less than the reference value sensed by the sensing unit 41 is not changed.

The locking function (45)

A thyristor Q2 which is turned on to a sensing signal 1 (high signal) which is lower than a reference value transmitted by the photocoupler PT1-1 of the sensing unit 41,

And a transistor Q3 that is turned off when the thyristor Q2 is turned on and inputs the output voltage of the regulator IC6 as a pulse signal to the flip-flop CPU IC5B of the driving unit 43. [

The thyristor Q2 of the lock function unit 45 is not turned off until the release signal is input to the release unit 47 in cooperation with the release unit 47, So that a detection signal equal to or lower than the reference value is held and input.

The release unit 47 receives the detection signal of the reference value or less from the sensing unit 41 and supplies the battery BAT1 and BAT2 connected to the charging unit 10 to the discharge power supply unit 20 The lock function unit 45 is released and the detection unit 41 detects that the discharge voltage of the replaced battery BAT1 or BAT2 falls below the reference value, ) Normally locks and the driving unit 43 normally outputs a control signal.

The release unit 47

When the detection unit 41 detects a signal below the reference value and the output voltage of the driving power source regulator IC6 starts to be input to the CPU IC5B as a pulse signal via the lock function unit 45, charging is started A capacitor C10,

A first transistor Q4 which is turned on when a pulse signal is inputted to the CPU IC5B in a turned off state and is turned off when a pulse signal is blocked due to a buffer of the capacitor C10,

When the first transistor Q4 is turned on, the output power of the driving power supply regulator IC6 is supplied to the thyristor Q2 of the lock function unit 45 to maintain the thyristor Q2 in a turned-on state A second transistor Q2 turning off when the first transistor Q4 is turned off to shut off the output power of the driving power supply regulator IC6 from being supplied to the thyristor Q2, (Q1).

The operation of the control unit 40 is summarized as follows.

The photocoupler PT1-1 is turned on and the output power of the driving power source regulator IC6 is supplied to the thyristor Q2 of the lock function unit 45 And turned on.

When the thyristor (Q2) is turned on, the output power of the driving power supply regulator (IC6) is input to the CPU (IC5B) as a high pulse signal.

The first transistor Q4 is turned on simultaneously with the input of the high pulse signal and the second transistor Q1 is turned on in response to the turning on of the first transistor Q4 so that the output power of the driving power source regulator IC6 is supplied to the thyristor Q2 so that the thyristor Q2 is continuously turned on irrespective of the operation of the porter coupler PT1-1. That is, it is locked.

Simultaneously with the input of the high pulse signal, the output power of the driving power source regulator IC6 is supplied to the capacitor C10 to start charging,

When the capacitor C10 is fully charged after a predetermined time elapses, the output power of the driving power source regulator IC6 is prevented from being supplied to the first transistor Q4 as a pulse signal, so that the first transistor Q4 is turned off,

The second transistor Q1 is also turned off immediately when the first transistor Q4 is turned off so that the output power of the driving power source regulator IC6 supplied to the thyristor Q2 through the second transistor Q1 is also cut off In this state, the batteries BAT1 and BAT2 already connected to the charging unit 10 are connected to the discharging power supply unit 20 so that the sensing unit 41 senses a discharge voltage higher than a reference value, Since the output power of the driving power source regulator IC6 is not supplied to the thyristor Q2 through the second transistor Q1 and the photocoupler PT1-1 through the photocoupler PT1-1, Lister Q2 is turned off,

The transistor Q3 of the lock function unit 45 is turned on when the thyristor Q2 is turned off so that the output power supplied to the CPU IC5B by the driving power source regulator IC6 is shut off and the CPU IC5B A low pulse signal is inputted and then the sensor 41 is ready to receive a detection signal that is lower than the reference value that the sensing unit 41 senses.

As described above, it is preferable that the flip-flop CPU IC5B outputs control signals which are opposite to each other, while the two opposite output signals are outputted with a delay time. The delay time is controlled by the flip-flop CPU IC5B However, if the high-pulse signal is input to the flip-flop CPU IC5B as described above, the preceding control signal may be output, and if the low-pulse signal is input later, the trailing control signal may be output.

For reference, the driving power regulator IC6 converts and outputs the external power input from the input terminal J1 into a constant voltage to output the photocoupler, the lock function unit 45, and the driving unit 30 of the switching unit 30 and the sensing unit 41. Supply power required for the 43 and the like.

In the above description of the present invention with reference to the accompanying drawings has been described with respect to the high-quality power supply is cut off the noise composed of a specific block and circuit diagram, the present invention can be variously modified and changed by those skilled in the art, such variations and Changes should be construed as falling within the protection scope of the present invention.

BAT1: first battery BAT2: second battery
10: charging unit 20: discharge power supply unit
30: switching unit 40: control unit
41: sensing section 43: driving section
45: lock function 47: release

Claims (4)

A first battery and a second battery;
A charging unit configured to charge the first battery and the second battery with power input from the outside;
A discharge power supply unit supplying power discharged from the first battery and the second battery to a load side;
A switching unit for selectively connecting each of the first battery and the second battery to the charging unit or the discharge power supply unit;
Sensing the power input to the discharge power supply unit to control the switching unit, any one of the first battery and the second battery is connected to the discharge power supply to supply power to the load side, the other is the charging unit The control unit is connected to be charged;

When the control unit switches and connects the first battery (or second battery) connected to the power supply unit to the charging unit through the switching unit, the second battery (or first battery) connected to the charging unit is discharged beforehand. The high-quality power supply cut off the noise, characterized in that by switching to the power supply unit after a certain time after switching to connect to the power supply unit. A first battery and a second battery;
A charging unit configured to charge the first battery and the second battery with power input from the outside;
A discharge power supply unit supplying power discharged from the first battery and the second battery to a load side;
A switching unit for selectively connecting each of the first battery and the second battery to the charging unit or the discharge power supply unit;
Sensing the power input to the discharge power supply unit to control the switching unit, any one of the first battery and the second battery is connected to the discharge power supply to supply power to the load side, the other is the charging unit The control unit is connected to be charged;

The control unit
A detection unit for detecting the intensity of power input to the discharge power supply unit;
A driving unit which outputs and drives a control signal to the switching unit when a power below a reference value is detected by the sensing unit;
And a lock function unit provided between the sensing unit and the driving unit and locking the sensing unit below the reference value when the sensing signal below the reference value is input to the driving unit so that the sensing signal below the reference value is maintained for a predetermined time thereafter. High-quality power supply cut off the noise. 3. The method of claim 2,
The control unit
And a release unit for releasing the locked state after a predetermined time elapses after the lock function is locked. delete

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