JP6497204B2 - Power-on sequence controller - Google Patents

Description

  The present invention relates to a power-on sequence control device.

  Conventionally, power distributors for distributing and supplying power to a plurality of audio devices have been developed. In recent power distributors, the power-on timing is adjusted between each power supply unit in order to prevent noise generation at the time of power-on to the connected audio equipment and to plan the power-on timing considering the start-up time of the audio equipment. A power-on sequence is set in which a delay time is set and power is sequentially applied to the connected audio equipment.

  The following patent documents describe a power-on sequence in which the power is sequentially turned on based on the delay time and a power-on sequence in which the delay time can be arbitrarily set.

Utility model registration No. 3008783 JP 05-168152 A Japanese Patent No. 3776678

  However, although the delay time between the power supply units in the conventional power distributor is a fixed value or can be arbitrarily set, it varies depending on the product specifications, but little consideration is given to setting flexibility.

  If the delay time between the power supply units is a fixed value, the delay time cannot be adjusted in the first place, and therefore the power-on timing cannot be adjusted in accordance with the characteristics of the connected audio equipment. In addition, since the priority of power-on for each power supply unit is determined in advance, if you want to change the power-on timing of the audio equipment connected to the power distributor, change the connection status of the audio equipment to the power supply unit. It must be physically changed and is not easy to use. In particular, when the power distributor is mounted on a rack, the power distributor itself must be removed from the rack, and the usability is remarkable.

  On the other hand, if the delay time between the power supply units can be set arbitrarily, the power-on timing can be adjusted according to the characteristics of the audio equipment connected between the power supply units, but the usage status of the audio equipment connected to the power distributor ( If it is desired to change the power-on timing in accordance with the characteristics of the newly connected audio equipment or the like, it must be readjusted for each delay time between the power supply units, which is troublesome. In addition, when it is desired to change the power-on timing of the audio equipment connected to the power distributor, the connection state of the audio equipment to the power supply unit must be physically changed as well.

  An object of the present invention is to provide an apparatus capable of adjusting the power-on timing according to the characteristics of the connected audio equipment and the like, in particular, the startup time by a simple operation.

The present invention includes a power switch, a first power supply unit that is turned on after a first delay time from when the power switch is turned on, and a power supply that is turned on after the power switch is turned on or the first power supply unit is turned on. A second power supply unit that is turned on after a second delay time different from the first delay time after being turned on, and the power switch is turned on by switching the first delay time and the second delay time. And a change-over switch for increasing / decreasing a power-on timing of the first power supply unit and the second power supply unit while maintaining a total delay time after being set.

The present invention also provides a power switch, a first power supply unit that is turned on after a first delay time after the power switch is turned on, and a second delay after the first power supply unit is turned on. A second power supply unit that is powered on in time, a third power supply unit that is powered on after a third delay time different from the second delay time after the second power supply unit is powered on, By switching the delay time of 2 and the third delay time, the power-on timing of the second power supply unit and the third power supply unit is maintained while maintaining the total delay time after the power switch is turned on. And a change-over switch for adjusting the increase / decrease.

  In another embodiment of the present invention, an input device is connected to the first power supply unit, an adjustment device is connected to the second power supply unit, and an output device is connected to the third power supply unit. The

  According to the present invention, the power-on timing can be adjusted by a simple operation in accordance with the characteristics of the connected audio equipment or the like.

It is the front view and back view of the apparatus which concern on embodiment. 1 is a configuration block diagram of an apparatus according to an embodiment. It is a timing chart (the 1) which shows a power-on sequence. It is a timing chart (the 2) which shows a power-on sequence. It is a timing chart (the 3) which shows a power-on sequence. It is a timing chart (the 4) which shows a power-on sequence. It is a timing chart (the 5) which shows a power-on sequence. It is explanatory drawing which shows the cascade connection state of the apparatus which concerns on embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  FIG. 1 is a front view and a rear view of a power distributor as a power-on sequence control device according to the present embodiment, FIG. 1 (A) is a front view, and FIG. 1 (B) is a rear view.

  The power distributor 10 is a device that distributes and supplies power to a plurality of connected devices, and is a device that can adjust the power-on timing of the plurality of connected devices. Although the apparatus connected to the power distributor 10 is not specifically limited, an acoustic apparatus is illustrated as an example in this embodiment. The power-on timing is adjusted by the delay time of the power supply unit to which each of the plurality of audio devices is connected. The power distributor 10 is normally used mounted on a rack.

  On the front panel of the power distributor 10, a power switch 12, an LED group 14, a delay time adjustment table 16, a changeover switch (SW) 18, and a power supply unit 20 are provided. Further, three power supply units 22, 24, and 26 are provided on the rear panel of the power distributor 10.

  The power supply unit 20 is a power supply unit in which no delay time is set, and power is always distributed and supplied. In the figure, only one power supply unit 20 is provided on the front panel, but two or more power supply units may be provided as necessary. On the other hand, the power supply units 22, 24, and 26 are power supply units for which delay times are set. When the power switch 12 of the power distributor 10 is turned on, power is distributed based on the set delay times.

  The power switch 12 is a power switch of the main body of the power distributor 10, and the user distributes and supplies power to each connected audio device based on the delay time by turning on / off the power switch 12.

  The LED group 14 is an LED that notifies the power-on state of the power supply units 22, 24, and 26, and includes three LEDs corresponding to the power supply units 22, 24, and 26, respectively. Each LED constituting the LED group 14 blinks when the corresponding power supply unit 22, 24, 26 is in the power-on standby state (within the delay time) and lights up in the power-on state (after the delay time has elapsed).

The delay time adjustment table 16 is a table that is referred to by the user when setting the delay times of the power supply units 22, 24, and 26. In the figure, the delay times of the power supply units 22, 24, and 26 are Timing1, Timing2, and Timing3, respectively. Three combinations of patterns A to C are shown. That is, pattern A is
Timing1 = 1s (seconds)
Timing2 = 5s (seconds)
Timing3 = 5s (seconds)
And pattern B is
Timing1 = 1s (seconds)
Timing2 = 5s (seconds)
Timing3 = 5m (min)
And pattern C is
Timing1 = 1s (seconds)
Timing2 = 5m (min)
Timing3 = 5s (seconds)
It is.

“Timing1” is a delay time from when the power switch 12 is turned on until the power supply unit 22 is turned on, “Timing2” is a delay time from when the power supply unit 22 is turned on until the power supply unit 24 is turned on, “Timing3” "Is a delay time from when the power supply unit 24 is turned on until the power supply unit 26 is turned on. That is,
This is a sequence in which the power switch 12 is turned on → the power supply unit 22 is turned on after the lapse of Timing1 → the power supply unit 24 is turned on after the lapse of Timing2 → the power supply unit 26 is turned on after the lapse of Timing3.

  The power supply units 22, 24, and 26 provided on the rear panel are displayed with “Timing 1”, “Timing 2”, and “Timing 3”, respectively. The correspondence between 22, 24 and 26 and the delay time can be grasped. Further, the user can grasp that the power is turned on in the order of the power supply unit 22, the power supply unit 24, and the power supply unit 26 by referring to the table 16, and should be used as a reference when connecting the audio equipment. Can do.

The changeover switch 18 is a manually operable switch that selectively switches between pattern A, pattern B, and pattern C. The correspondence between each pattern and the delay time is defined in Table 16,
Pattern A:
Timing 1 of the power supply unit 22 = 1s
Timing 2 of power supply unit 24 = 5 s
Timing 3 of the power supply unit 26 = 5 s
Pattern B:
Timing 1 of the power supply unit 22 = 1s
Timing 2 of power supply unit 24 = 5 s
Timing 3 of the power supply unit 26 = 5 m
Pattern C:
Timing 1 of the power supply unit 22 = 1s
Timing 2 of power supply unit 24 = 5 m
Timing 3 of the power supply unit 26 = 5 s
It is.

  When paying attention to pattern A and pattern B, in pattern A, Timing3 is 5 s, but in pattern B, Timing3 is as long as 5 m. Further, when attention is paid to the pattern B and the pattern C, Timing1 is the same, but Timing2 and Timing3 are alternately switched. That is, the user can easily increase the delay time of the power supply unit 26 from 5 s to 5 m by operating the changeover switch 18 to switch from the pattern A to the pattern B, and switch from the pattern B to the pattern C. Thus, the delay times of the power supply unit 24 and the power supply unit 26 can be exchanged. In Pattern B, the delay time of the power supply unit 24 is 5 seconds after the power-on timing of the power supply unit 22. In Pattern C, the delay time of the power supply unit 24 is 5 minutes after the power-on timing of the power supply unit 22. This means that the power-on timing of the power supply unit 24 is changed from 5 seconds to 5 minutes even if it takes time from the power-on of the power supply unit 22 to the activation of the audio equipment connected to the power supply unit 22. The delay means that the acoustic device connected to the power supply unit 24 can be prevented from being turned on unexpectedly before the acoustic device connected to the power supply unit 22 is activated.

  This point will be described more specifically.

  As described above, the power supply units 22, 24, and 26 are powered on in this order, and energized to the audio equipment connected thereto. Therefore, an input device such as a CD player or a multi-track recorder is connected to the power supply unit 22, an adjustment device such as a mixing console is connected to the power supply unit 24, and an output device such as a power amplifier or a powered speaker is connected to the power supply unit 26. . If the power to the adjustment device is turned on before the input device is activated, the level meter will malfunction, and noise will be generated if the output device is turned on before the adjustment device is activated. It is necessary to turn on the power of the adjustment device after the device is started, and turn on the output device after the adjustment device is started.

  There is no problem as long as the device is activated immediately after the audio device is turned on, but it may take time for the device to be activated for various reasons even if the audio device is turned on. For example, since a specific OS is used as the OS of the input device, it takes time to start up, or it takes time to start up to connect the input device to the network. In particular, in the latter case, the time required for activation can be indefinite because it depends on communication traffic that can change dynamically. If the input device is within 5 seconds from when the input device is turned on until the input device is activated, there is no problem because the adjustment device is turned on after the input device is activated even with pattern A or pattern B. If it takes more than 5 seconds for the input device to start after the input device is turned on, in Pattern A and Pattern B, the adjustment device is turned on before the input device is started.

  In such a case, the user switches the delay time of the power supply unit 24 from 5 seconds to 5 minutes by operating the changeover switch 18 to switch from the pattern A or the pattern B to the pattern C. Even if it takes more than 5 seconds for the input device to start after the input device is turned on, there is a delay of 5 minutes before the adjustment device is turned on. The power of the adjustment device can be turned on after starting up.

  Here, in the case of the pattern C, the delay time of the power supply unit 24 is changed from 5 seconds to 5 minutes in order to interchange the delay times of the power supply unit 24 and the power supply unit 26 of the pattern B. The delay time is shortened from 5 minutes to 5 seconds. Therefore, compared with the case where the delay time of the power supply unit 26 remains 5 minutes, there is an advantage that the total delay time (Timing 1 + Timing 2 + Timing 3) after the power switch 12 of the power distributor 10 is turned on can be shortened. That is, the total delay time of the pattern B and the pattern C is the same. In other words, the user can increase / decrease the delay time of a specific power supply unit while maintaining the total delay time constant only by operating the changeover switch 18.

  FIG. 2 is a configuration block diagram of the power distributor 10 according to the present embodiment. The power distributor 10 includes a power plug 30, a main controller 32, and a sub-controller 34 in addition to the power supply units 20, 22, 24, 26, the power switch 12, the LED group 14, and the changeover switch 18.

  The main controller 32 controls the entire power distributor 10. When the power plug 30 is connected to an external AC power source, the main controller 32 supplies AC power from the external AC power source to the sub-controller 34 and also distributes and supplies it to the power source units 20, 22, 24, and 26, respectively. The main controller 32 supplies the N (neutral) line of the external AC power supply lines to the N terminals of the power supply units 22, 24, and 26, and connects the L (live) line to the terminals of the sub-controller 34. Further, the main controller 32 directly connects the N line and the L line among the external AC power supply lines to the N terminal and the L terminal of the power supply unit 20. Therefore, AC power is always supplied to the power supply unit 20 regardless of whether the power switch 12 is on or off.

  The sub-controller 34 includes a timing controller 36 that adjusts the power-on timing of the power supply units 22, 24, and 26. Further, the power switch 12, the LED group 14, and the changeover switch 18 are connected to the sub-controller 34. The sub-controller 34 is activated when the power switch 12 is turned on, adjusts the power-on timing of the power supply units 22, 24, and 26 according to the switching state of the changeover switch 18, and states the power supply units 22, 24, and 26. The lighting state of the three LEDs constituting the LED group 14 is controlled accordingly. The main controller 32 and the sub controller 34 are configured by, for example, IC circuits.

  The power supply unit 22 includes two power supply units and includes an L (live) terminal, an N (neutral) terminal, and an FG terminal. The N terminal is connected to the main controller 32 as described above, the L terminal is connected to the Timing 1 terminal of the sub-controller 34, and the FG terminal is grounded.

  The power supply unit 24 includes two power supply units and includes an L (live) terminal, an N (neutral) terminal, and an FG terminal. The N terminal is connected to the main controller 32 as described above, the L terminal is connected to the Timing 2 terminal of the sub-controller 34, and the FG terminal is grounded.

  The power supply unit 26 includes two power supply units and includes an L (live) terminal, an N (neutral) terminal, and an FG terminal. The N terminal is connected to the main controller 32 as described above, the L terminal is connected to the Timing 3 terminal of the sub-controller 34, and the FG terminal is grounded.

  The power supply unit 20 includes two power supply units and includes an L (live) terminal, an N (neutral) terminal, and an FG terminal. The N terminal and L terminal are connected to the main controller 32, and the FG terminal is grounded.

  The timing controller 36 of the sub-controller 34 adjusts the timing of signals output from the Timing 1 terminal, Timing 2 terminal, and Timing 3 terminal according to the switching state of the changeover switch 18. That is, when the changeover switch 18 is set to the pattern A, the timing controller 36 outputs a signal (voltage signal) from the Timing1 terminal after a delay time of 1 second with reference to the ON timing of the power switch 12, and Timing2 A signal is output after a lapse of a delay time of 5 seconds with reference to the output timing of the Timing1 terminal from the terminal, and a signal is output after a delay time of 5 seconds with respect to the output timing of the Timing2 terminal from the Timing3 terminal. When the pattern B is set, the timing controller 36 outputs a signal from the Timing 1 terminal after the delay time of 1 second has elapsed with reference to the ON timing of the power switch 12, and the output timing from the Timing 2 terminal to the Timing 1 terminal as a reference. A signal is output after a delay time of 5 seconds elapses, and a signal is output after a delay time of 5 minutes elapses with reference to the output timing of the Timing 2 terminal from the Timing 3 terminal. When the pattern C is set, the timing controller 36 outputs a signal after a delay time of 1 second from the Timing1 terminal with respect to the ON timing of the power switch 12, and based on the output timing from the Timing2 terminal to the Timing1 terminal. A signal is output after a delay time of 5 minutes has elapsed, and a signal is output after a delay time of 5 seconds has elapsed with reference to the output timing of the Timing2 terminal from the Timing3 terminal.

  Further, the sub-controller 34 controls the lighting timing of the LED group 14 in synchronization with the timing at which signals (voltage signals) are output from the Timing 1 terminal, Timing 2 terminal, and Timing 3 terminal. When the power switch 12 is turned on, the three LEDs of the LED group 14 are blinked, and when the set delay time has elapsed and a signal is output from the Timing 1 terminal, the LED corresponding to the power supply unit 22 is lit from the blinking state. When the set delay time elapses and a signal is output from the Timing 2 terminal, the LED corresponding to the power supply unit 24 is controlled from blinking to lighting state, and the set delay time elapses from the Timing 3 terminal. When the signal is output, the LED corresponding to the power supply unit 26 is controlled from blinking to lighting state. By visually recognizing the blinking state or lighting state of the LED group 14, the user can easily grasp whether the power supply units 22, 24, and 26 are each in a standby state (delay state) or in a power-on state. When the changeover switch 18 is switched from the pattern B to the pattern C, the delay times of the power supply unit 24 and the power supply unit 26 are changed, so that the timing of transition from blinking to lighting of the corresponding LEDs is also changed.

  3 to 5 are timing charts showing the power-on timing of the power supply units 22, 24, and 26. FIG.

  FIG. 3 shows a case where the changeover switch 18 is set to pattern A. When the power switch 12 is turned on, a signal is output from the Timing1 terminal after 1 second from the timing, and the power supply unit 22 is turned on. In addition, a signal is output from the Timing2 terminal and the power supply unit 24 is turned on 5 seconds after the power supply of the power supply unit 22 is turned on. Further, a signal is output from the Timing3 terminal 5 seconds after the power supply of the power supply unit 24 is turned on, and the power supply unit 26 is turned on.

  FIG. 4 shows a case where the changeover switch 18 is set to the pattern B. When the power switch 12 is turned on, a signal is output from the Timing1 terminal after 1 second from the timing, and the power supply unit 22 is turned on. In addition, a signal is output from the Timing2 terminal and the power supply unit 24 is turned on 5 seconds after the power supply of the power supply unit 22 is turned on. Further, a signal is output from the Timing3 terminal 5 minutes after the power supply of the power supply unit 24 is turned on, and the power supply unit 26 is turned on. This pattern is suitable when it takes time to start up the adjusting device connected to the power supply unit 24.

  FIG. 5 shows a case where the changeover switch 18 is set to the pattern C. When the power switch 12 is turned on, a signal is output from the Timing1 terminal after 1 second from the timing, and the power supply unit 22 is turned on. In addition, a signal is output from the Timing2 terminal 5 minutes after the power supply of the power supply unit 22 is turned on, and the power supply unit 24 is turned on. Further, a signal is output from the Timing3 terminal 5 seconds after the power supply of the power supply unit 24 is turned on, and the power supply unit 26 is turned on. This pattern is suitable when it takes time to start up the input device connected to the power supply unit 22.

  The power-off timing is the reverse order of the power-on timing. That is, when the power switch 12 is turned off, the timing controller 36 first turns off the power supply unit 26 after a predetermined delay time, then turns off the power supply unit 24 after a predetermined delay time, and then after a predetermined delay time. The power supply unit 22 is turned off. The delay time at this time may be a fixed value or may be arbitrarily set.

  In the above embodiment, the delay time of the power supply unit 22 is set with reference to the ON timing of the power switch 12, the delay time of the power supply unit 24 is set with reference to the power ON timing of the power supply unit 22, and the delay of the power supply unit 26 is set. Although the time is set based on the power-on timing of the power supply unit 24, the delay times of the power supply units 22, 24, and 26 may be set based on the on-timing of the power switch 12.

  FIG. 6 is a timing chart when the delay times of the power supply units 22, 24, and 26 are all set on the basis of the ON timing of the power switch 12. When the power switch 12 is turned on, a signal is output from the Timing 1 terminal, for example, after 1 second from the timing, and the power supply unit 22 is turned on. Further, for example, a signal is output from the Timing2 terminal after 5 seconds from the ON timing of the power switch 12, and the power supply unit 24 is turned ON. Further, a signal is output from the Timing3 terminal, for example, one minute after the on timing of the power switch 12, and the power supply unit 26 is turned on.

  Even in this case, by operating the changeover switch 18, the user can easily change the delay time. For example, the delay times of the power supply units 24 and 26 can be changed.

FIG. 7 is a timing chart when the delay times of the power supply units 24 and 26 are switched. When the power switch 12 is turned on, a signal is output from the Timing1 terminal after 1 second from the timing, and the power supply unit 22 is turned on. In addition, a signal is output from the Timing2 terminal after 1 minute from the ON timing of the power switch 12, and the power supply unit 24 is turned ON. Further, a signal is output from the Timing3 terminal 5 seconds after the power switch 12 is turned on, and the power supply unit 26 is turned on. In the timing chart of FIG.
7 where the power switch 12 is turned on, the power supply unit 22 is turned on, the power supply unit 24 is turned on, and the power supply unit 26 is turned on.
It should be noted that the power switch 12 is turned on → the power supply unit 22 is turned on → the power supply unit 26 is turned on → the power supply unit 24 is turned on, and the order of turning on the power supply unit 24 and the power supply unit 26 is switched. The user can change the energization order of the power supply units 24 and 26 simply by operating the changeover switch 18. Even if an output device is connected to the power supply unit 24 and an adjustment device is connected to the power supply unit 26, the energization sequence of the input device → the adjustment device → the output device can be maintained simply by operating the changeover switch 18 provided on the front panel. .

  In FIG. 7, only the power-on timing is replaced, but it goes without saying that the power-off timing may be automatically changed according to the change in the power-on timing. That is, when the power switch 12 is turned off, the power supply unit 24, the power supply unit 26, and the power supply unit 22 may be turned off in this order.

  Further, the power distributor 10 of the present embodiment can be operated by cascading a plurality in addition to operating alone.

  FIG. 8 shows a configuration in which three power distributors 10-1, 10-2, and 10-3 are connected in cascade. The power distributor 10-1 has three power supply units T1, T2, and T3 that can set a delay time (for example, the power supply units 22, 24, and 26 correspond to the power supply units T1, T2, and T3, respectively). The distributor 10-2 has three power supply units T4, T5, and T6 that can set the delay time, and the power distributor 10-3 has three power supply units T7, T8, and T9 that can set the delay time. Exists.

  In the power distributor 10-1, for example, as shown in FIGS. 3 to 5, the delay time of T1 to T3 is set to a desired value by switching the changeover switch 18. The same applies to the power distributors 10-2 and 10-3.

  On the other hand, between the power distributors 10-1, 10-2, and 10-3, in addition to turning on the power in series, the power may be turned on in parallel. In the former case, the power supply of T4 is turned on after a delay time set after the power supply of T3 is turned on, and the power supply of T7 is turned on after a delay time set after the power supply of T6 is turned on. In the latter case, the power on timing of T1, the power on timing of T4, and the power on timing of T7 can be arbitrarily set, and the power on timing of T4 and the power on timing of T7 are adjusted based on the power on timing of T1. Also good.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to this, A various change is possible.

  For example, in the present embodiment, separately from the LED group 14, an LED for the power distributor 10 main body that is turned off / on in conjunction with the on / off of the power switch 12 may be provided on the front panel, and an input voltage indicator is provided. It may be provided on the front panel.

  In this embodiment, the delay time adjustment table 16 is provided on the front panel. However, the delay time adjustment table 16 may be displayed on the liquid crystal display, and the delay time is set as shown in FIG. The delay time setting mode and the delay time setting mode as shown in FIG. 6 may be switchable by the user.

  In this embodiment, a mechanical switch is provided as the changeover switch 18, but a touch switch or an electronic switch displayed on the touch panel may be used.

  In the present embodiment, in consideration of the cascade connection as shown in FIG. 8, a master switch for setting the power distributor 10 to either the parent device or the child device may be provided on the rear panel or the like. When the master switch is turned on, the power distributor 10 functions as a parent device, and when the master switch is turned off, the power distributor 10 functions as a child device. Set the master switch to ON when using it alone. On the other hand, in the cascade connection as shown in FIG. 8, the master switch of the power distributor 10-1 is turned on and set as the master unit, and the master switch of the power distributors 10-2 and 10-3 is turned off and set as the slave unit. . When the power switch 12 is turned on, the power distributor 10-1 set as the master unit outputs a control signal to the power distributors 10-2 and 10-3 as slave units at the timing. The timing controller 36 of the power distributors 10-2 and 10-3 as slave units adjusts the power-on timing of the power supply units T4 and T7 with reference to the control signal.

In this embodiment, the delay time between the power supply unit 24 and the power supply unit 26 is switched by the changeover switch 18. However, the delay time between the power supply unit 22 and the power supply unit 24 or the delay time between the power supply unit 22 and the power supply unit 26 is used. It is good also as a structure which replaces. For example,
Pattern D:
Timing 1 of the power supply unit 22 = 5 s
Timing 2 of power supply unit 24 = 1s
Timing 3 of the power supply unit 26 = 5 m
Pattern E:
Timing 1 of power supply unit 22 = 5 m
Timing 2 of power supply unit 24 = 5 s
Timing 3 of the power supply unit 26 = 1s
Etc.

  Generally, assuming that the delay times of the power supply units 22, 24, and 26 are d1, d2, and d3, respectively, and the basic pattern is (d1, d2, d3), There can be d3), (d1, d3, d2), (d3, d2, d1). These patterns may be displayed as a list on the front panel as in the table 16, or may be displayed in a hierarchy.

  Further, in this embodiment, the power supply unit 20 cannot be adjusted for delay time and the power supply units 22, 24, and 26 can be set for delay time. However, there is no power supply unit that cannot adjust delay time, and the delay time can be adjusted. There may be two or more power supply units. The simplest configuration includes a power supply unit 22 consisting of one power supply unit and a power supply unit 24 consisting of one power supply unit, and the selector switch 18 switches between the delay time of the power supply unit 22 and the delay time of the power supply unit 24. is there.

10 power distributor, 12 power switch, 14 LED group, 16 delay time adjustment table, 18 selector switch, 20 power supply unit (delay time cannot be set), 22, 24, 26 power supply unit (delay time can be set).

Claims (3)

A power switch,
A first power supply unit that turns on after a first delay time from when the power switch is turned on;
A second power supply unit that is turned on after a second delay time different from the first delay time after the power switch is turned on or after the first power supply unit is turned on;
The first power supply unit and the second power supply unit are turned on while maintaining the total delay time from when the power switch is turned on by switching the first delay time and the second delay time. A changeover switch to adjust the timing ,
A power-on sequence control device comprising: A power switch,
A first power supply unit that turns on after a first delay time from when the power switch is turned on;
A second power supply unit that is turned on in a second delay time after the first power supply unit is turned on;
A third power supply unit that is turned on after a third delay time different from the second delay time after the second power supply unit is turned on;
By switching the second delay time and the third delay time, the second power supply unit and the third power supply unit are turned on while maintaining the total delay time after the power switch is turned on. A changeover switch to adjust the timing,
A power-on sequence control device comprising: An input device is connected to the first power supply unit,
An adjustment device is connected to the second power supply unit,
The power-on sequence control device according to claim 2, wherein an output device is connected to the third power supply unit.

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