KR920007745Y1 - Back-up electric source system - Google Patents

Abstract

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Description

Spare power system of electrical equipment

1 is a reference diagram of a backup power system in a conventional electric equipment.

2 is a spare power supply system of the present invention.

3 is a circuit diagram of one embodiment of FIG.

4 is a sequence diagram of a timer in FIG.

* Explanation of symbols for main parts of the drawings

1: reserve power system 11: rated voltage detection unit

12: power switch control unit 13: switch drive

2: 2nd battery part 32: 1st battery part

The present invention relates to a spare power system that supplies driving power to a battery, which is a spare power supply, when an abnormal state such as a power failure occurs while a load of an electric device is in progress, which is particularly used in such a reserve power system. The spare power supply system which improves the disadvantages which may be caused by the change of the driving conditions when the factors such as the lack of the rated voltage enough to drive the load to drive the load or the fluctuation of the drive voltage such as the load occurs. will be.

Such a reserve power supply system prevents loss of continuity of the operation of the device caused by fluctuations such as power failure of commercial voltage in battery electronic devices (vending machines, VTRs, computers, communication devices, etc.) or automatic control systems. It is usually provided.

In particular, such a preliminary power supply system is an essential part of a system that can be damaged by the loss of the continuous operation of the device.

In addition, in semiconductor processors and memory devices, such as LSI, which operate sensitively according to the level of the main power supply voltage, the reserve power supply must be replaced at a voltage level higher than the prescribed value to proceed with the normal operation. To be sustainable.

In one example, a typical type of such a reserve power system is shown in FIG.

In this case, when AC is input to the power supply side, it provides a predetermined rated DC voltage to the load 35 via a DC power supply 31 switching means 34 including a transformer and a bridge rectifier and the like. The battery unit 32, which is a power source, provides a charging voltage to the battery.

In this state, when the AC changes in the load such as a power failure, the input sensing unit 33 detects this and transfers the battery voltage of the battery unit 32 side to the load 35 side through the switching unit 34. To be provided.

In addition, if the load 35 is an AC device, a DC-AC conversion power supply such as an SMPS may be provided between the output of the DC power supply 31 and the load 35.

Prior art related to such a reserve power system is a number other than the " floating battery power supply device for floating charge " introduced in Korean Patent No. 83-3393 or the " auxiliary power circuit " introduced in Korean Utility Model No. 86-1299. Is known.

However, in the prior art, since a single spare power battery having a single rating for a single load is used, the backup power supply to the load provides a predetermined rating due to the deterioration of the spare battery or during the use process. If the spare power supply time according to the preset battery capacity is actually shorter than expected, or if the load variation for a given battery is short or the load variation for a given battery is caused, There was a problem that it was difficult to expect a reliable backup power supply, and in particular, it could not be suitably used for a large number of motors equipped with individual power supplies in different places such as an automatic control system or a backup power supply for electronic control. There was this.

In other words, if the power supply device under such an environment has a backup battery and a power supply device, and the good, the bad, or the old one of the batteries exist at the same time, the old one is normally charged and charged. Even if it is, it is likely that the use time until the rating becomes lower than the new one is much shorter than the new one, and on the other hand, when a change in the load connected to the predetermined power supply is caused, a plurality of driving load time As a result, there may be a load that loses persistence, which causes the overall system control behavior to fail.

An object of the present invention has been devised in view of the above-mentioned problems, and in particular, in the case of having the spare power battery as described above, assuming that the spare power battery is the first battery of the shock capacity, A second battery is provided to provide a predetermined driving power supply from the second battery when the first battery is below the rated level, thereby providing a backup power system that can ensure the reliability of continuous continuous operation of such a system.

Another object of the present invention is to detect when any one or more of the plurality of spare batteries are introduced at a voltage below the rated value in a system having respective spare batteries for a plurality of loads, and replace the battery with the rated value below the rated value. It is intended to provide a backup power system that enables the supply of drive power to a single load or to multiple automatic sources.

In particular, the present invention includes a second battery part having a capacity much larger than that of the first battery part in addition to the first battery part, and at the output of the first battery part, a battery energized voltage sensing part, a first battery part or a second battery part is provided. When switching the output of the battery part to the load, the power switching control part performs timing operation to eliminate the switching operation and the power supply disconnection phenomenon at the time of power switching, and the output of the first and second battery parts by the output of this power switching control part. It is characterized by a preliminary power supply system including integrally a switching drive unit for selective switching driving.

Hereinafter, another feature of the present invention will be understood by looking at it in detail with an embodiment of the present invention.

That is, Figure 2 shows a backup power system according to the present invention.

In this case, the DC power supply unit 31, the battery unit 32, the input sensing unit 33, and the like, into which the AC is input, are connected with the load 35, which is much larger than the battery capacity of the battery unit 32. A second battery part 2 having a large capacity is provided, and the battery part 32 (hereinafter referred to as the first battery part) is activated by the output of the rated voltage detection part 11 and the rated voltage detection part 11 and thus the first battery. Power supply switching control unit 12 for controlling timing so that output is not disconnected when switching these outputs while connecting the output of the second battery unit 2 instead of the negative output 32 to the load 35 and the power supply switching. The output of the control part 12 has a related structure with the switching drive part 13 which switches and drives the output of the 2nd battery part 2 instead of the output of the 1st battery part 32. As shown in FIG.

In addition, according to the present invention, the first battery part 32, the rated voltage sensing part 11, the power switching control part 12, and the switching driving part 13 are elements that are common to one load 35, and the second The battery part 2 may have another form in which the output is implemented as one second battery part 2 with respect to the plurality of loads 35 up to (2a to 2n).

Meanwhile, one embodiment of the present invention of the second embodiment is shown in FIG.

Here, the first battery unit 32, the rated sensing unit 11, and the power switching control unit 12, which receive power from the DC output of the DC power supply device 31 including the bridge diode BD ₁ and the regulator RE, etc. ), A load 35, and a second battery part 2 that receives power from another bridge rectifier BD ₂ on the AC side. a first gate (a _1), a first gate (a ₁₎ a second gate (a ₂₎ and, to be active in the output logic of the second gate output active memory is to detect an output of the first battery part (32) A flip-flop (FF) as an element and an oscillator (OS) for providing timing pulses to the flip-flop (FF). The power switching controller 12a includes a programmable controller 12a, which is a one-chip logic, and a commercial AC. claim that is active according to the line-state relay 1, the first relay contact (Ra) and a flip-flop (FF) of the nominal sensing unit 11 side that is driven by the (RY ₁₎ A second relay contact (Rb) of the second relay (RY ₂₎ is controlled by a transistor (T) is switched to the power it has a structure connected to the input layer.

In addition, the switching drive unit 13 includes relays Ma and Mb respectively driven by the output of the power control unit 12 and interlocking contacts Ma ₁ , Ma ₂ , Mb ₁ , and Mb of the relays Ma and Mb. ₂ ) and a diode (D), and the interlocking contacts (Ma ₁ , Ma ₂ , Mb ₁ , Mb ₂ ) are turned off when Ma ₁ , Ma ₂ , Mb ₁ , Mb ₂ , respectively, in the presence of a corresponding alternating current (AC). The first battery part 32 has no change in the state of connecting the output of the first battery part 32 to the load 35 even in the first stage of the on, off, and on state, and in the absence of commercial AC. When the output of the power goes below the rated value, Ma ₁ and Ma ₂ on the side of the relay Ma are connected to the second battery part 2 in the on and off states, respectively, to supply power to the load 35, and the relay (Ma) In order to prevent instantaneous power interruption when the) is switched, the interlocking contacts Mb ₁ and Mb ₂ of the relay Mb are connected to the load 35 through the diode D to the first battery part 32 in the off and on states, respectively. Phase 2, after a period of 0.1 to 2 SEC, and the interlocking contacts Mb ₁ and Mb ₂ of the relay Mb connected to the first battery part 32 and the load 35 through the diode D are turned on and off, respectively. The third step of switching between the second battery unit 2 and the load 35 through the configuration is configured.

The present invention of such a configuration is as follows.

That is, according to the present invention, the commercial AC is converted into the rated current source of the predetermined load through the DC power supply device 31 as shown in FIG. 2, and then provides driving power to the load 35 via the switching driver 13.

In addition, when the commercial AC is disconnected, this is detected by the input sensing unit 33 and provides the driving output of the load 35 by the first battery unit 32 via the switching driving unit 13.

At this time, when the battery of the first battery part 32 fails to provide the rated voltage due to the aging lamp, the battery is sensed by the rated sensing part 11 and the timer is driven by the power switching control part 12 together with the driving switching driver ( 13) is switched to provide the driving power to the load 35 by the second battery unit (2).

For example, the timer operation is performed by connecting the output of the second battery part 32 to the load 35 before the output line of the first battery part 32 becomes lower than the first battery part 2. This means a series of parallax operations in which the output of the first battery unit 2 is cut off while the output of the battery is connected to the load 35.

In addition, when the output of the second battery unit 2 is provided with a plurality of 32, 11, 12, 13 circuits according to the number of the load 35 is connected to them in common, any of the plurality of loads Even when there are a plurality of batteries falling below one or less than the rated number, all of the predetermined driving power may be provided by the second battery unit 2 having a much larger capacity than the capacity of the first battery unit 32.

For example, the above operation will be described with reference to FIG. 3 as follows.

That is, when power dissipation falls from the rated voltage provided to the load 35 from the first battery part 32, the input of the first gate A ₁ of the rated sensing part 11 becomes logic 0 from logic 1 and the first The gate A ₁ output changes from logic to logic 1 and the second gate A ₂ changes its output from logic 1 to logic 0.

As a result, the flip-flop (FF) output is changed from the initial logic 0 to the logic 1 to turn on the NPN transistor T and drive the second relay RY ₂ .

In addition, the timing at which the second battery unit 2 provides the driving power to the load 35 side instead of the first battery unit 32 will be described with reference to FIG.

That is, when AC power is extinguished (capacitance), Ra moves to input 01.

In this state, when the first battery part 32 starts to discharge and the voltage drops near the inoperable state of the load, Rb is operated by the rated sensing part 11 to apply a signal to 02.

By this, 40 relays operate, 40 relays operate, and 14 outputs are output, and the main contact of Ma is switched from the main power supply to the auxiliary power supply by 10 outputs.

At this time, in order to prevent a momentary power failure and to prevent a circulating current when the first and second battery units 32 and 2 are switched, the power by the diode D is in a state in which the main power is connected, and in this state, a predetermined time is determined by the timer 15. Afterwards (can be modified), the power supply by the diode D is also switched to the auxiliary power supply by the output of the relay of 11.

If the main power is maintained and the main power is supplied, Ra is applied to 00 and if the relay of 41 is operated, the timer 16 operates and the 40 relay power is lost after a certain period of time (modifiable). The output of is lost and Ma returns to the side of the game.

At this time, the power supply by the diode D is connected to the auxiliary power when the power supply is prevented and the main power, the first and second battery parts 32 and 2 are mutually switched.

In this state, after a predetermined time by the timer 17 (can be modified), the power of the diode D is also dissipated to the relay of Fig. 11 and transferred to the main power.

However, if the main power (AC) is extinguished again before the time set in the timer 16 after the main power is energized, the operation of the timer is stopped at the same time as the 1 relay stop and the transfer operation does not proceed.

This is to compensate for frequent power failures caused by AC power.

The present invention is provided with a backup power system in the load of the electrical equipment, such as the failure of the continuous operation of the load in the event of a failure in the commercial power supply can be prevented in advance, but can occur in the aging, failure of the spare battery, etc. It is a beneficial feature to ensure the reliability of use of such a system by providing the rated power by monitoring the rated condition in advance.

Claims (2)

In the preliminary power supply system including the DC power supply battery unit 32 and the input sensing unit 33 to which the AC is input, the second battery unit having a much larger amount than the capacity of the battery unit 32 is provided. (2), the output of the battery unit 32 is activated by the output of the rated voltage sensing unit 11 for sensing its rated voltage and the rated voltage sensing unit 11 at the output of the battery unit 32; The output of the power switch control unit 12 and the power switch control unit 12 for controlling the timing so as not to cause an output disconnection at the time of switching these outputs while connecting the output of the second battery unit 2 replaced with the load 35 to the load 35. A preliminary power supply system for an electric machine, characterized in that the configuration associated with the switching drive unit 13 is driven. The method of claim 1, wherein the second battery unit 2 is provided with a single unit for a plurality of loads, each of the load is rated voltage detection unit 11 and the power switching control unit 12 of each battery unit 32 , The preliminary power supply system of the electric machine, characterized in that the switching drive unit 13 is provided.