KR19990033241A - How to save power from the power control unit - Google Patents

Abstract

TECHNICAL FIELD The present invention relates to controlling the power supply of electrical and electronic systems. In particular, the present invention relates to a power save state and an operable state at a predicted power save time interval by predicting a power save time while the electrical and electronic system is not performing an operation. It relates to a power save method in the power control unit to automatically repeat.

Power control devices of conventional electric and electronic systems have a long time that takes a long time to switch from the power save state to the operable state, there is an uncomfortable problem that the user print waiting time is long.

According to the present invention, the power supply control unit predicts the power save time while the electric and electronic system is not performing the operation, and automatically repeats the power save state and the operable state at the estimated power save time interval, thereby saving power. In addition, it may provide convenience to the user by reducing the waiting time when performing the operation again.

Description

How to save power from the power control unit

TECHNICAL FIELD The present invention relates to controlling the power supply of electrical and electronic systems. In particular, the present invention relates to a power save state and an operable state at a predicted power save time interval by predicting a power save time while the electrical and electronic system is not performing an operation. It relates to a power save method in the power control unit to automatically repeat.

Power control devices in general electrical and electronic systems control the supply of power for performing certain operations of the electrical and electronic system. If power is continuously supplied even when the operation is stopped, unnecessary power is supplied. Will be consumed. Therefore, the power control device reduces the amount of power supply after a certain period of time in the state in which the operation is stopped, and then supplies the power back to the original power level when attempting to perform the operation again. Mode).

However, although the power control device is easy in power saving, the standby time for switching to the original power level for performing the operation again in the state of the power save mode is a factor that occurs.

For example, the temperature rise time and fall time of fuse rolls or heat rolls, especially in conventional high speed copiers, are longer than those of low speed copiers, so that they can be copied back from the power save state. The longer the time to conversion, the longer the copy waiting time.

Then, referring to the configuration of a system for power saving in a conventional high-speed copier, as shown in FIG. 1, the temperature sensor unit 11 for measuring the temperature of the fuse roll and converting it to a value of voltage and applying the temperature A power supply control unit 12 that receives the temperature of the fuse roll from the sensor unit 11 and generates and applies a power control signal for controlling the temperature of the fuse roll according to the current state of the high speed copier, and the corresponding power supply control unit 12. A power supply unit 13 for applying power according to a power control signal applied from the power supply unit 13 and a heating wire unit 14 for generating heat or canceling heat at the intensity of the power applied from the power supply unit 13. It consists of

In addition, referring to the graph of FIG. 2, the power save operation in the corresponding high-speed copier will be performed by the power supply control unit 12. It counts during the power save transition set time, which is the set time for switching to the power save mode from when it is stopped.

Accordingly, when the power supply control setting unit 12 counts the power save switching setting time, the power supply control unit 12 generates a power control signal for lowering the temperature of the fuse roll to the set temperature at the time of power saving and applies it to the power supply unit 13. .

Accordingly, the power supply unit 13 does not supply power to the heating unit 14 by a power control signal applied from the power supply control unit 12, thereby lowering heat generated in the heating unit 14. After the fuse roll temperature is lowered to the set temperature at the time of power saving, the set temperature at the time of power saving is maintained.

On the other hand, when it is determined that the power supply control unit 12 needs to switch back to the print mode, the power supply unit 13 is controlled so that power is supplied to the heating unit 14 so that the fuse roll of the fuse roll can be printed. Raise the temperature and try printing again.

In this case, printing is possible only when the printable switching time, which is the time required to perform the operation of printing again, is possible. In particular, a high-speed copier having a long warm-up time has a considerable printable switching time. Longer user print wait time was longer.

As described above, the power control apparatus of the conventional electric and electronic system takes a long time to switch from the power save state to the operable state, and there is an inconvenience in that the user's print waiting time is long.

In order to solve the above-mentioned inconvenience, the present invention relates to a method for controlling the power supply of an electrical and electronic system, which predicts a power save time while the electrical and electronic system is not performing an operation and predicts the corresponding power. By automatically repeating the power save state and the operable state at save time intervals, it not only saves power, but also reduces the waiting time when the power save state is released, providing convenience to users and providing high-speed electronic and electrical systems with relatively long warm-up times. It is intended to be suitable.

1 is a diagram showing the configuration of a system for power saving in a conventional high speed copying apparatus.

FIG. 2 is a graph illustrating a power save function in the power supply controller of FIG. 1. FIG.

3 is a flow chart showing a power save method in a power supply control apparatus according to an embodiment of the present invention.

FIG. 4 is a flowchart illustrating a process of repeating a power save state and an operable state in FIG. 3. FIG.

FIG. 5 is a graph showing a method of obtaining an average value in FIG. 3. FIG.

FIG. 6 is a graph showing an increase in an average value in a non-operating state in FIG. 3. FIG.

Explanation of symbols on the main parts of the drawings

11: temperature sensor unit 12: power supply control unit

13 power supply 14 hot wire

In the power control apparatus according to the embodiment of the present invention for achieving the above object, the power save method stores only a predetermined number of times in the previous power save mode up to the end user, and at the same time the end user A first step of confirming whether the system is operating; A second step of reading an average value by reading the stored predetermined number of power save times when a power save switching setting time has elapsed after the end user stops performing an operation of an electric and electronic system; And a third step of repeatedly performing the power save state and the operable state by increasing the average value while the end user does not require the electrical and electronic system to perform the operation. The third process includes: a first step of checking whether the average value has elapsed while the end user does not require the electrical and electronic system to perform an operation; A second step of continuously maintaining a power save state when the average value has not elapsed; And a third step of switching to an operational state when the average value has elapsed and switching back to a power save state and adding a predetermined value to the average value to set a new average value.

In addition, the power save method in the power control apparatus according to an embodiment of the present invention for achieving the above object is to check whether the average value obtained in the second process is smaller than the set minimum average value to maintain the operational state at all times Process; And a fifth process of maintaining a power save state at all times by checking whether the average value obtained in the second process is larger than the set maximum average value.

Hereinafter, with reference to the accompanying drawings will be described as follows.

FIG. 3 is a flowchart illustrating a power save method in a power control apparatus according to an exemplary embodiment of the present invention. FIG. 4 is a flowchart illustrating a process of repeating a power save state and an operable state in FIG. 3. 3 is a graph showing a method for obtaining an average value, and FIG. 6 is a graph showing an increase in the average value in a non-operating state in FIG. 3.

In the power control apparatus according to the embodiment of the present invention, the power save system is the same as the conventional configuration, but the power supply control unit predicts the power save time while the electric and electronic system does not perform the operation and the corresponding power save time interval. It further comprises a software configuration for automatically repeating the power save state and the operational state.

First, the operation of saving power in the power control apparatus according to an embodiment of the present invention will be described briefly. In the power supply control unit, the power supply control unit predicts the power save time to control the power supply. Only the number of times (for example, 5) is stored and the averaged values are obtained by averaging the five power-saved times.

After the end user performs the operation and stops, if the power save switching setting time has elapsed, the calculated average value is set as the time to maintain the power save state, and when the corresponding power save state duration has elapsed, the operation is made possible again and then again. Repeat over and over again to power save.

At this time, if the operation is not continuously performed, the duration of the corresponding power save state is increased. In addition, the minimum average value and the maximum average value are set so that the obtained average value is always in an operable state when it is smaller than the set minimum average value, and is always in a power save state when it is larger than the set maximum average value.

Meanwhile, when the operation is performed in the middle, the previous five power saved times are averaged again to determine the average value as the corresponding power save state duration.

Then, the power save method in the power control apparatus according to the embodiment of the present invention will be described with reference to the flowchart of FIG. 3.

First, the power supply control unit calculates an average value to determine the duration of the power save state during the next time the electrical and electronic system is not performing the operation. Only store it in memory. That is, for example, five users up to the end user continue to store only five power save times after operating the electrical and electronic system and then shutting down (step S1).

At the same time, the power supply control unit always checks whether the operation of the electrical and electronic system is performed (step S2), and if the end user continues to operate the electrical and electronic system, to the end user of the first step (S1). After saving the power save time of the electronic device and continue to check the operation of the electrical and electronic system, and if the end user has stopped the operation of the electrical and electronic system, it is checked whether the power save switching set time has passed (step S3) ).

Accordingly, if the power save switching setting time has elapsed, the power supply control unit switches to a power save state, where a predetermined number of power save times stored in the memory are read out and averaged to obtain an average value (step S4).

For example, as shown in FIG. 5, the power save time before the first user operates the electrical and electronic system is 10 minutes, the power save time before the second user is 15 minutes, the third user transition 20 minutes, If the user transition is 10 minutes and the end user transition is 15 minutes, then the average value is (10 + 15 + 20 + 10 + 15) / 5 = 14, so the next power save state duration to be used is 14 minutes.

In addition, the power supply control unit sets a minimum average value so that the electric and electronic systems continue to operate and are always in an operable state when the power save time is quite small. We continue to set the maximum average value to keep the power save state at all times when the power save time becomes quite long.

By the way, the power supply control unit determines the average value as the power save state duration to be used next time, and checks whether the average value is larger than the set minimum average value (step S5).

If the average value is less than the set minimum average value in the fifth step S5, the power supply control unit controls the power supply unit to be always in an operable state so as to continuously supply high power, and again to the first step. An operation of storing previous power save times of S1 is performed (step S6).

On the other hand, if the average value is greater than the set minimum average value in the fifth step S5, the power supply controller checks whether the average value is smaller than the set maximum average value (step S7).

Therefore, when the average value is larger than the set maximum average value in the seventh step S7, the power supply control unit controls the power supply unit to keep the power always in a power save state so as to continuously supply low power and again to the first step ( The operation of storing the previous power save times of S1) is performed (step S8).

On the contrary, if the average value is less than the set maximum average value in the seventh step S7, the power supply controller checks whether the end user is required to perform an operation of the electrical and electronic system (step S9). If it is required to perform the operation of the electrical and electronic system, it is continuously checked whether the electrical and electronic system of the second step (S2) is in operation and updates the average value again, while not being required to perform the operation of the electrical and electronic system. If not, maintain the power-save state by the average value, and then supply power to the operable state again, and then add the predetermined value to the average value to maintain the power-save state by the sum and then put it back into the operational state. The switching timing repeats the process (step S10).

In addition, looking at the tenth step (S10) in more detail with reference to the flow chart of Figure 5, first, when not required to perform the operation of the electrical and electronic system, the power supply control unit checks whether the average value has elapsed (Step S11), if the average value has not passed, the power save state is continuously maintained (step S12), and if the average value has passed, it is switched to an operational state and then switched back to the power save state (step S13). A predetermined value is added to the average value, and the sum is set as a new average value to check whether the average value of the eleventh step S11 has elapsed again (step S14).

For example, as shown in FIG. 6, if the average value is 14 minutes and the predetermined value is 1 minute, the operation after maintaining the power save state during the counting for 14 minutes in the eleventh step S11 is performed. It is enabled, then goes back into power save, lasts for 15 minutes, then lasts for 16 minutes, and then goes into an operational state.

As described above, by estimating the power save time while the electrical and electronic system is not performing the operation and automatically repeating the power save state and the operable state at the corresponding predicted power save time intervals, It also reduces latency during power save states, making it ideal for high-speed electronic and electrical systems with relatively long warm-up times.

As described above, the power supply control unit predicts the power save time while the electric and electronic system does not perform the operation, and automatically repeats the power save state and the operable state at the corresponding power save time interval. In addition to the power saving effect of the user can reduce the waiting time when performing the operation can provide convenience to the user.

Claims (3)

Storing a predetermined number of times of the previous power save mode to the end user and confirming whether the end user is operating the electrical and electronic system; A second step of reading an average value by reading the stored predetermined number of power save times when a power save switching setting time has elapsed after the end user stops performing an operation of an electric and electronic system; And a third process of increasing the average value and repeatedly performing the power save state and the operable state by the average value while the end user does not require the operation of the electrical and electronic system. How to save power. The method of claim 1, further comprising: a fourth process of checking whether the average value obtained in the second process is smaller than a set minimum average value and maintaining an operational state at all times; And a fifth process of checking whether the average value obtained in the second process is larger than a set maximum average value to maintain the power save state at all times. The method of claim 1, wherein the third step comprises: a first step of checking whether the average value has elapsed while the end user does not require the electric and electronic system to perform an operation; A second step of continuously maintaining a power save state when the average value has not elapsed; And a third step of switching to an operational state when the average value has elapsed and switching back to a power save state and adding a predetermined value to the average value to set a new average value. How to save power.