KR100663033B1 - Power auto control method in power supply apparatus - Google Patents

Abstract

A power auto control method in a power supply apparatus is provided to prevent a component damage of a board and an unstable state of the board by adjusting and stabilizing a power while supplying the power. A power auto control method in a power supply apparatus includes the steps of: setting a by-pass switch and a normal-delay switch on or off and displaying volt meta voltage when turning on a key switch after setting the switches; turning on the channels(ch1 to ch8) in a case of being by-passed and setting an auto and manual mode in a case of being not by-passed; turning on an auto-on switch in a case of being the auto mode, making a manual control available by turning on or off each channel(ch1 to ch8) in a case of being the manual mode in the auto and manual mode, and turning off the all switches; after the auto-on switch is turned on, turning of the channels(ch8 to ch1) at interval of 1.5 second in a case of a normal delay by an auto-off in an auto-off and quick-off distinguishing mode so as to be a stand-by mode and turning off the channels(ch8 to ch2) at interval of 1.5 second and the channel(ch1) in 3 minutes in a case of non-normal delay mode so as to be the stand-by mode; turning off the channels(ch8 to ch1) at interval of 1.5 second in a case of the normal delay mode by a quick mode in the auto-off and quick-off mode so as to be the stand-by mode and turning off the channels(ch8 to ch2) at interval of 0.5 second and the channel(ch1) in 3 minutes in case of the non-normal delay mode so as to be the stand-by mode; and turning off the all switches under a state of the stand-by mode.

Description

Power auto control method in power supply apparatus

1 is a program of the automatic power adjustment method applied to the present invention.

Figure 2 is an embodiment of a prochart of the automatic power supply adjustment method applied to the present invention.

Figure 3 is another embodiment of the prochart of the automatic power supply adjustment method applied to the present invention.

The present invention relates to a power supply, and more particularly, to a method for automatically adjusting power to install a program for automatically adjusting power to a power supply so as to efficiently regulate power supply.

In the conventional power supply, the power supplied in the board is turned on and is supplied to the entire board at the same time, wherein the amount of transient current drawn is very large compared to the load current in the steady state.

This transient current shortens the life of the component and makes it difficult to reliably guarantee the state of the interface portion in the transient state.

This phenomenon is caused by a weak power control function to supply power stably.

As such, in the related art, a problem in that the power regulation function is vulnerable and a transient current flows to the board during power supply causes damage to components in the board and the board becomes unstable.

Therefore, the present invention was devised to solve the above problems,

The automatic power control program is installed in the power supply to control the power stably.

1 is a program of an automatic power adjustment method applied to the present invention.
1 is a mode switching unit,
s1 (set) turns on RL1 to set s2 (flip flop) at initial power-up, and s2 switches between automatic mode and manual mode with r, s flip-flop.

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P3_5 is all on channel 1 ~ 8, and when RL3 (manual mode state) is on, if P1_3 (automatic switching input) switch is pressed, s2 will switch to auto mode.

RL8 operates with channel 1 ~ 8 ON and P1_4 is a switch used to switch to manual mode.

P1_5 is the Auto on switch. When this switch is pressed, P3_0 COIL is driven via the P1_6, P1_7, and B contact (normal on) switches. The P_3.0 A contact is a switch for self-holding P3_0 COIL.

Thereafter, each channel is turned on with a constant time difference (1.5 seconds).

The lower RL2 switch is in the normal on state, and P1_6 is an auto off switch. When this switch (Auto off switch) is pressed, it is turned off with a constant time difference (1.5 seconds) in the reverse order to channel 8 ~ 1. P3_7 is linked to the Quick off switch.

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Pressing this switch (Quick off switch) will turn off the channel 8 ~ 1 faster every 0.5 seconds. The RL2 contact is a switch to control two cases. It controls Auto off and Quick off operation in manual mode.

The following is a description of the time control unit (2) when turning each channel on and off,
First, the timer is set to 1.5 seconds to set the operation time when the CLK2 Auto on and Auto off switches are pressed. CLK3 is also a timer.

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This timer flashes the P1_2 lamp at 0.5 second intervals for display purposes. Timer CK1 operates when the Quick off switch is pressed and is set to 0.5 seconds.

P1_2 is the lamp output which indicates the operating status, and CNT1 is the UP and DOWN COUNTER. The speed of increase and decrease also changes according to the input counter.

Numbers increment or decrement at 0.5 or 1.5 second input intervals, and there is a time difference.

The following is a description of the output unit (3),
P2_0 ~ 2_7 are operation switches for each channel, RL2 switch is a switch to enable manual operation, and DB1 ~ DB8 are used for chattering (electrical noise) generated during switch operation.

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FF1 to FF8 are D flip-flop to switch on and off by switch operation, and P0_0 to 0_7 are output coils. TH1 ~ TH9 are comparators, and the coils of each channel are turned on and off by comparing the numbers sent from the up and down counters.

The following is a description of the condition determination unit (4),
When P0_0 to P0_7 are all ON and RL2 is ON, P3_5 is ON.

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This circuit is configured to check the status when switching from manual mode to automatic mode.

The lower part of the circuit is the automatic mode or the manual mode. It is ON in automatic mode in RLI and ON in manual mode in RL2.

Reference numeral 5 denotes a determination unit for manual switching.
When P0_0 ~ P0_7 is ON, RL8 is ON. At this time, if P1_4 switch (manual selection) is pressed, the mode is changed to manual mode.

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In the output unit 3, P3_7 is a switch operating when the DELAY mode is selected. When this switch is turned ON, P3_6 is turned OFF after a delay of about 3 minutes in the delay DLI.

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In real hardware, there is a select switch that switches between P0_0 and P3_6. In addition, the remote part (including the remote control) switch is configured in conjunction with the AUTO ON / OFF and QUICK OFF switches.

2 is an embodiment of a prochart of an automatic power control method applied to the present invention.

Set the by-pass switch and the normal-delay switch to on or off, and after setting the switch, turn on the key switch to display the volt meta voltage.

If by-pass, all of channels ch1 ~ ch8 are on, and if not by-pass, it goes into automatic and manual selection mode.

Automatic and manual selection When auto is selected, auto on switch is turned on. If manual is selected, manu is turned on and off to enable manual control. Then turn off all switches.

After the automatic on switch is turned on, auto-off and auto-off are performed in the quick-off discrimination mode, and when there is a normal delay, ch8 to ch1 are turned off at intervals of 1.5 seconds, and if no normal delay, ch8 to ch2 is displayed. It is turned off at 1.5-second intervals, and only ch1 is turned off after 3 minutes and is in a standby state.

In the auto-off and quick-off discrimination mode, when a quick-off is made and a normal delay is reached, ch8 to ch1 are turned off at 1.5 second intervals, and if not, the ch8 to ch2 are turned off at 0.5 second intervals. Only ch1 turns off after 3 minutes, and enters a standby state.

Then all switches are turned off in standby.

3 is another embodiment of a prochart of a method for automatically adjusting a power source applied to the present invention.

Set the by-pass switch and the normal-delay switch to on or off, and after setting the switch, turn on the key switch to display the volt meta voltage.

If by-pass, all channels ch1 ~ ch8 are on. If not by-pass, auto on switch is activated and each channel is on by 1.5 sec.

After that, if the manual switch is selected, each channel is turned on / off to enable manual control.If the manual switch is not selected, auto-off is performed in the auto-off and quick-off determination modes. This is turned off at the interval of 1.5 seconds and becomes a standby state. If it is not a normal delay, ch8-ch2 is turned off at 1.5 second intervals, and only ch1 turns off and becomes a standby state after 3 minutes.

In the auto-off and quick-off discrimination mode, if a quick-off is made and a normal delay is reached, ch8 to ch1 are turned off at 0.5 second intervals, and if it is not a normal delay, ch8 to ch2 are turned off at 0.5 second intervals. Only ch1 turns off after 3 minutes, and enters a standby state.

Thereafter, it is fed back to the by-pass determination mode in the standby state.

For reference, since the program of FIG. 1 is a ladder program, it has a structure similar to a circuit diagram. 2 and 3 show the leather program of FIG. 1 as a pro chart.

As described above, the present invention by installing a power automatic adjustment program in the power supply device to stably adjust the power supply when the power supply, it is possible to prevent the component damage of the board and the unstable state of the board in advance.

Claims (2)

When the by-pass switch and the normal-delay switch are set to on or off, and after the switch is set, the key switch is turned on to display the volt meta voltage. When bypassing, all channels ch1 to ch8 are turned on, and when bypassing goes to the automatic and manual selection mode, In case of automatic or manual selection, if auto is selected, auto on switch is turned on. If manual is selected, manual control is enabled by turning on and off each channel. After the auto-on switch is turned on, the auto-off and quick-off determination modes are automatically turned off to normal-delay, and the channels ch8 to ch1 are turned off at intervals of 1.5 seconds and are in a standby state. The channel ch8 to ch2 are turned off at intervals of 1.5 seconds, and the channel ch1 is turned off after 3 minutes and is in a standby state if the signal is not normal-delay. In the auto-off and quick-off discrimination mode, when the quick-off is normal-delayed, the channels ch8 to ch1 are turned off at intervals of 1.5 seconds and are in a standby state. If the normal-delay is not normal, the channels ch8 to ch2 are 0.5 seconds. The channel ch1 is turned off at an interval and after 3 minutes, the channel ch1 is turned off to become a standby state; After that, all the switches are turned off in the standby state. When the by-pass switch and the normal-delay switch are set to on or off, and after the switch is set, the key switch is turned on to display the volt meta voltage. When bypassed, all channels ch1 to ch8 are turned on. If the bypass is not enabled, the automatic on-switch is activated. Each channel is turned on by 1.5 seconds. After the manual switch is selected, each channel is turned on and off to enable manual control.If the manual switch is not selected, the auto switch is automatically turned off in the auto-off and quick-off determination modes. Normal-delay causes the channels ch8 to ch1 to be turned off at 1.5-second intervals, leaving the standby state. Otherwise, channels ch8 to ch2 are turned off at 1.5-second intervals and the channel ch1 to 3 minutes later. The process of turning off and waiting, In the auto-off and quick-off discrimination mode, if a quick-off results in normal-delay, the channels ch8 to ch1 are turned off at 0.5 second intervals, and if not, the channels ch8 to ch2 are 0.5 seconds. The channel ch1 is turned off at an interval and after 3 minutes, the channel ch1 is turned off to become a standby state; Thereafter, in the standby state, the automatic power supply adjustment method comprising the step of feeding back to the bypass determination mode.

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