JPH05130733A - Sequentially operating power device - Google Patents

Abstract

PURPOSE:To prevent elements from being destroyed by implementing a desired sequential operation for two outputs only with the ON/OFF operation of a power switch in a power device used for a printed circuit board or the like. CONSTITUTION:When an interlocking switch 10 is closed, an output 1 is caused to rise immediately through a first power unit 13, and is turned on. Continuously, a second relay switch 12 is closed by the driving of a second relay switch control unit 16 to cause an output 2 to rise through a second power unit 14, and is turned on. In this respect, after the output 2 is turned on, a first relay switch 11 is closed by a first relay switch control unit 15. Then, when the interlocking switch is turned off, the output 2 is immediately turned off. In continuation, the first relay switch 11 is opened by the operation of the first relay switch control unit 15, and the output 1 is also turned off. Accordingly, the required operational sequence at the time of the ON/OFF of the output 1 and output 2 is implemented by the operation of the interlocking switch 10.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sequence operation type power supply device suitable for use as a power supply for a printed board or the like.

At present, when high speed operation is mainly required, an LSI using gallium arsenide is used. This gallium arsenide-based LSI requires two power supplies, and there is a sequence for these two power supply operations. When the power is on, turn on one power supply and then the other. There must be. Further, when the power is off, it is necessary to turn off the power supplied after the power is turned on, and then turn off the power that was turned on first. That is, an LSI using gallium arsenide requires a power supply device that performs the above sequence operation.

[0003]

2. Description of the Related Art Conventionally, by providing a step (difference in length) on a connector pin of a printed board, after turning on a power switch, the printed board is inserted and removed to perform the above sequence operation. In other words, the power supply with the longer pin is first turned on and turned on, and when it is pulled out, it is turned off later to realize the sequence operation.

[0004]

However, in such a conventional power supply device, when it is desired to turn off the power switch, it is necessary to remove the printed board in advance,
If the printed circuit board is still inserted, turn off the power switch.
When the value is set to F, there is a possibility that an element such as a gallium / arsenic LSI that requires a power supply sequence may be damaged.

The present invention was devised in view of the above problems, and it is a sequence operation formula capable of realizing a desired sequence operation required for two outputs by only ON / OFF operation of a power switch. An object is to provide a power supply device.

[0006]

FIG. 1 is a block diagram showing the principle of the first invention according to claim 1. In FIG.
Reference numeral 0 denotes an interlocking switch, and the interlocking switch 10 has a pair of switch parts 10a and 10b which are connected in parallel to the power supply line and operate in conjunction with each other.

Reference numeral 11 is a first relay switch, and the first relay switch 11 is connected in parallel with the interlock switch 10. Reference numeral 12 is a second relay switch, and the second relay switch 12 is connected in series to one switch portion 10a of the interlocking switch 10.

Reference numeral 13 is a first power source section, and the first power source section 13 is connected in series to the other switch section 10b of the interlocking switch 10 and the first relay switch 11. Reference numeral 14 denotes a second power supply unit, and this second power supply unit 14
Are connected in series to the second relay switch 12.

Reference numeral 15 is a first relay switch control section,
The first relay switch control unit 15 includes the second power supply unit 14
It is provided on the output side of and controls the opening and closing of the first relay switch 11.

Reference numeral 16 is a second relay switch control section,
The second relay switch control unit 16 includes the first power supply unit 13
It is provided on the output side of and controls the opening and closing of the second relay switch 12.

FIG. 2 is a block diagram of the principle of the second aspect of the present invention. In FIG. 2, reference numeral 20 is a switch, and the switch 20 is connected to a power supply line.
Reference numeral 21 is a first relay switch, 22 is a second relay switch, and these first relay switch 21 and second relay switch 22 are connected in parallel with the switch 20, respectively.

Reference numeral 23 is a first power supply section, and this first power supply section 23 is connected in series to the first relay switch 21. Reference numeral 24 denotes a second power supply section, and the second power supply section 24 is connected to the second relay switch 22 in series.

25 is a coil, and this coil 25 is
The switch 20 is connected in series to smooth the rise and fall of the current. Reference numeral 26 is a first relay switch control unit, and this first relay switch control unit 26
Is connected in series to the coil 25 and controls the opening and closing of the first relay switch 21.

Reference numeral 27 is a shunt circuit.
Are connected in series to the first relay switch control unit 26. Reference numeral 28 denotes a second relay switch control unit, and the second relay switch control unit 28 is connected in series to the branch flow path of the diversion circuit 27 and controls opening / closing of the second relay switch 22.

FIG. 3 is a principle block diagram of a third invention according to claim 3, and in FIG. 3, reference numeral 30 is a switch, and the switch 30 is connected to a power supply line.
Reference numeral 31 is a first relay switch, 32 is a second relay switch, and these first relay switch 31 and second relay switch
The relay switches 32 are each connected in parallel with the switch 30.

Reference numeral 33 is a first power source section, 34 is a second power source section, and these first power source section 33 and second power source section 34 are connected in series to a first relay switch 31 and a second relay switch 32, respectively. ing.

Reference numeral 35 is an integrating circuit, and this integrating circuit 35
Is connected in series with the switch 30 to smooth the rise and fall of the voltage. A voltage dividing circuit 36 is provided on the output side of the integrating circuit 35 to divide the voltage into a high voltage output and a low voltage output.

Reference numeral 37 denotes a first relay switch control section,
The first relay switch control unit 37 is connected to the high voltage output side of the voltage dividing circuit 36 and controls opening / closing of the first relay switch 31.

Reference numeral 38 is a second relay switch control section,
The second relay switch control unit 38 is connected to the low voltage output side of the voltage dividing circuit 36 and controls the opening / closing of the second relay switch 32.

[0020]

In the sequence operation type power supply device of the first invention shown in FIG. 1 (claim 1), when the interlock switch 10 is turned on, the output immediately rises through the first power supply section 13 and turns on. Then, the output is turned on, the second relay switch control unit 16 is driven,
The second relay switch 12 is closed and turned on, and the output rises through the second power supply unit 14 to be turned on. After the output is turned on, the first relay switch control unit 15 is driven and the first relay switch 11 is closed and turned on.
Has become.

Next, when the interlock switch 10 is turned off, the output is immediately turned off. Then, as the output is turned off, the first relay switch control unit 15 is activated, and the first relay switch 11 is opened and O
It becomes FF and the output becomes OFF. The output is O
After becoming FF, the 2nd relay switch control part 16 act | operates and the 2nd relay switch 12 is opened and it is OFF.

4A to 4C are time charts in the sequence operation type power supply device of the present invention. When the power switch is ON, the output rises first and then the output turns ON. When the power switch is OFF,
It can be seen that the output drops first and then turns off.

In the sequence operation type power supply device of the second invention shown in FIG. 2 (claim 2), when the switch 20 is turned on, the current is smoothly raised by the action of the coil 25. At this time, the second relay switch control unit 28 causes the shunt circuit 27 to
The first relay switch control unit 26 is driven first, the first relay switch 21 is closed and turned on, and the output rises and is turned on through the first power supply unit 23. Subsequently, the second relay switch control unit 28 is driven later, the second relay switch 22 is closed, and O
N, the output rises through the second power supply section 24 and becomes ON.

When the switch 20 is turned off, the coil 2
The action of 5 causes the current to drop smoothly. At this time, since the second relay switch control unit 28 is shunted by the shunt circuit 27, the second relay switch control unit 28 operates first, the second relay switch 22 opens and turns OFF, and the output turns OFF first. Becomes Subsequently, the first relay switch control unit 26 operates, the first relay switch 21 is opened and turned off, and the output is turned off later.

Therefore, the sequence operation type power supply device of the second invention also has a time chart similar to that shown in FIGS. 4 (a) to 4 (c). In the sequence operation type power supply device (claim 3) of the third invention shown in FIG. 3, when the switch 30 is turned on, the voltage rises smoothly due to the action of the integrating circuit 35. At this time, since the first relay switch control unit 37 is connected to the high voltage output side of the voltage dividing circuit 36, the second relay switch control unit 38 on the low voltage side.
Drive first, and the first relay switch 31 closes
N, the output rises through the first power supply unit 33 and is turned ON first. Subsequently, the second relay switch control unit 38 on the low voltage output side is driven, and the second relay switch 3
2 is closed and turned on, and the output rises and is turned on through the second power supply section 34.

When the switch 30 is turned off, the voltage drops smoothly due to the action of the integrating circuit 35. At this time,
Since the second relay switch control unit 38 is connected to the low voltage output side of the voltage dividing circuit 36, it operates before the first relay switch control unit 37 on the high voltage output side, and the second relay switch 32 opens and turns off. Then the output is turned off first. Then, the first relay switch control unit 37 operates,
The first relay switch 31 is opened and turned off, and the output is turned off later.

Therefore, also in the sequence operation type power supply device of the third invention, a time chart similar to that shown in FIGS. 4 (a) to 4 (c) is obtained.

[0028]

Embodiments of the present invention will be described below with reference to the drawings. (A) Description of First Embodiment FIG. 5 is a block diagram showing a first embodiment of the present invention.
The sequence operation type power supply device shown in FIG. 5 includes an interlocking switch 50, a first relay switch 51, a second relay switch 52, and a DC / DC converter 5 as a first power supply unit.
3, DC / DC converter 54 as the second power supply unit, first relay coil 5 as the first relay switch control unit
5, and a second relay coil 56 serving as a second relay switch control unit.

Here, the interlock switch 50 has a pair of switch parts 50a and 50b which are connected in parallel to the power supply line and operate in conjunction with each other. The first relay switch 51 is connected in parallel with the interlocking switch 50, and the second relay switch 52 is connected in series to one switch portion 50a of the interlocking switch 50.

The DC / DC converter 53 as the first power supply section is connected in series to the other switch section 50b of the interlocking switch 50 and the first relay switch 51, and the DC / DC converter 54 as the second power supply section. Are connected in series to the second relay switch 52.

The first relay coil 55 is provided on the output side of the DC / DC converter 54 and is connected to the first relay switch 51.
The second relay coil 56 is a DC
It is provided on the output side of the / DC converter 53 and controls the opening and closing of the second relay switch 52.

With such a configuration, in the sequence operation type power supply device according to the first embodiment, the interlock switch 5
When 0 is turned on, the switch sections 50a and 50b are closed, so that the output immediately rises through the DC / DC converter 53 and becomes ON. Then the output is O
When it becomes N, the second relay coil 56 is driven, the second relay switch 52 is closed and turned on, and DC
The output rises through the / DC converter 54,
Turns on. In addition, after the output is turned on, the first relay coil 55 is driven, and the first relay switch 51 is closed and turned on.

Next, when the interlocking switch 50 is turned off, the switch parts 50a and 50b are opened, so that the output is immediately turned off. Then, as the output is turned off, the first relay coil 55 is activated and the first relay coil 55 is activated.
The relay switch 51 opens and turns off, and the output is O
Become FF. In addition, after the output is turned off, the second relay coil 56 is activated, and the second relay switch 52 is opened and turned off.

FIGS. 6A to 6E are time charts in this embodiment. When the power switch is ON, the output rises first and the output turns ON later.
When the power switch is OFF, the output drops first, and then the output turns OFF. Then, ON / O of the first relay switch 51 and the second relay switch 52
The FF operation is performed as shown in FIGS. 6 (c) and 6 (e),
It realizes the output and the sequence operation required for the output.

As described above, the power switch is turned on / off
If the power switch is ON, the output rises first and then the output turns ON only by operation. If the power switch is OFF, the output drops first and the output turns OFF later. It can be done automatically.

(B) Description of Second Embodiment FIG. 7 is a block diagram showing a second embodiment of the present invention.
The sequence operation type power supply device shown in FIG. 7 includes a switch 70, a first relay switch 71, and a second relay switch 7.
2, DC / DC converter 73 as the first power supply unit, DC / DC converter 74 as the second power supply unit, coil 7
5, a first relay coil 76 as a first relay switch control unit, a shunt circuit 27, and a second relay coil 78 as a second relay switch control unit.

Here, the switch 70 is connected to the power supply line, and the first relay switch 71 and the second relay switch 72 are connected in parallel with the switch 70, respectively. DC / DC converter 73 as the first power supply unit
Is connected in series to the first relay switch 71, and the DC / DC converter 74 as the second power supply unit is connected in series to the second relay switch 72.

The coil 75 is connected in series with the switch 70 to smooth the rising and falling of the current. The first relay coil 76 is connected to the coil 75 in series and controls opening / closing of the first relay switch 71.

The shunt circuit 27 is connected in series with the first relay coil 76 and is connected in parallel with the resistor 77-.
1 and 77-2. The second relay coil 78 is connected in series to the shunt flow path of the shunt circuit 27 and controls the opening and closing of the second relay switch 72.

With this structure, in the second embodiment, when the switch 70 is turned on, the current is smoothly raised by the action of the coil 75. At this time, since the second relay coil 78 is shunted by the shunt circuit 27, the first relay coil 76 is driven first, the first relay switch 71 is closed and turned ON, and the DC / DC converter 73 is turned on.
Through, the output rises and becomes ON. Continuing,
After that, the second relay coil 78 is driven, the second relay switch 72 is closed and turned on, and the DC / DC converter 7
The output rises through 4 and turns on.

Next, when the switch 70 is turned off,
The current is smoothly reduced by the action of the coil 75. At this time,
Since the second relay coil 78 is shunted by the shunt circuit 27, the second relay coil 78 operates first,
The relay switch 72 is opened and turned off, and the output is turned off first. Subsequently, the first relay coil 76 is activated, the first relay switch 71 is opened and turned off,
The output will be turned off later. Therefore, also in the second embodiment, similar time charts are obtained as shown in FIGS. 6A to 6E, and the same effects or advantages as those of the first embodiment described above can be obtained.

(C) Description of Third Embodiment FIG. 8 is a block diagram showing a third embodiment of the present invention.
The sequence operation type power supply device shown in FIG. 8 includes a switch 80, a first relay switch 81, and a second relay switch 8
2, a DC / DC converter 83 as a first power supply unit, a DC / DC converter 84 as a second power supply unit, an integrating circuit 35, a voltage dividing circuit 36, a first relay coil 87, and a second relay coil 88. Has been done.

Here, the switch 80 is connected to the power supply line, and the first relay switch 81 and the second relay switch 82 are connected in parallel with the switch 80.
The DC / DC converter 83 as the first power supply unit and the DC / DC converter 84 as the second power supply unit are respectively the first
The relay switch 81 and the second relay switch 82 are connected in series.

The integrator circuit 35 is connected in series with the switch 80 to smooth the rise and fall of the voltage, and comprises a resistor 85 and a capacitor 86.

The voltage dividing circuit 36 is provided on the output side of the integrating circuit 35 and divides the voltage into a high voltage output and a low voltage output.
The resistor 89 and the transistors 90 and 91 are provided.

The first relay coil 87 is connected to the high-voltage output side of the voltage dividing circuit 36 to control the opening / closing of the first relay switch 81, and the second relay coil 88 is used for the low voltage of the voltage dividing circuit 36. It is connected to the output side and controls the opening and closing of the second relay switch 82.

With this configuration, in the third embodiment, when the switch 80 is turned on, the voltage rises smoothly due to the action of the integrating circuit 35. At this time, since the first relay coil 87 is connected to the high voltage output side of the voltage dividing circuit 36, it is driven before the second relay coil 88 on the low voltage side, and the first relay switch 81 is closed and turned on,
The output is turned on first through the first power source unit 83. Subsequently, the second relay coil 88 on the low voltage output side is driven, the second relay switch 82 is closed and turned on,
The output rises and is turned on through the second power supply unit 84.

After that, when the switch 80 is turned off,
The voltage drops smoothly due to the action of the integrating circuit 35. At this time, since the second relay coil 88 is connected to the low voltage output side of the voltage dividing circuit 36, the second relay coil 88 operates before the first relay switch control unit 87 on the high voltage output side, and the second relay switch 82 opens. , Is turned off, and the output is turned off first. Then, the first relay coil 87 is activated, the first relay switch 81 is opened and turned off, and the output is turned off later.

Therefore, also in the case of the third embodiment, similar time charts are obtained as shown in FIGS. 6A to 6E, and the same effects and advantages as those of the first and second embodiments described above. Is obtained.

[0050]

As described above in detail, according to the sequence operation type power supply device (claims 1 to 3) of the present invention, it is desired that the two outputs are obtained only by the ON / OFF operation of the power switch. Since the sequence operation of can be realized,
There is no fear of destroying the element, and the labor of inserting and removing the printed board can be saved.

[Brief description of drawings]

FIG. 1 is a principle block diagram of a first invention.

FIG. 2 is a principle block diagram of a second invention.

FIG. 3 is a principle block diagram of a third invention.

FIG. 4 is a time chart for explaining the operation of the sequence operation type power supply device of the present invention.

FIG. 5 is a block diagram showing a first embodiment of the present invention.

FIG. 6 is a time chart for explaining the operation of the embodiment of the present invention.

FIG. 7 is a block diagram showing a second embodiment of the present invention.

FIG. 8 is a block diagram showing a third embodiment of the present invention.

[Explanation of symbols]

10 interlocking switch, 10a, 10b switch part 11,21,31,51,71,81 first relay switch 12,22,32,52,72,82 second relay switch 13,23,33 first power supply part 14, 24,34 2nd power supply part 15,26,37 1st relay switch control part 16,28,38 2nd relay switch control part 20,30,70,80 switch 25,75 coil 27 shunt circuit 35 integrating circuit 36 partial pressure Circuit 50 Interlocking switch 50a, 50b Switch part 53,54,73,74,83,84 DC / DC converter 55,76,87 1st relay coil 56,78,88 2nd relay coil 77-1,77-2, 85,89 resistor 86 capacitor 90,91 transistor

Claims (3)

[Claims] 1. An interlocking switch (10) having a pair of switch parts (10a, 10b) connected in parallel to a power supply line and operating in conjunction with each other, and connected in parallel to the interlocking switch (10). A first relay switch (11) and one switch portion (10a) of the interlocking switch (10)
Second relay switch (12) connected in series to the switch, and the other switch section (10b) of the interlock switch (10)
And a first power source section (13) connected in series to the first relay switch (11) and a second power supply section connected in series to the second relay switch (12).
A power supply unit (14), a first relay switch control unit (15) provided on the output side of the second power supply unit (14) for controlling opening and closing of the first relay switch (11), and the first power supply A sequence operation type power supply, characterized in that it is provided with a second relay switch control section (16) provided on the output side of the section (13) and controlling the opening and closing of the second relay switch (12). apparatus. 2. A switch (2) connected to a power line.
0), a first relay switch (21) and a second relay switch (22) connected in parallel with the switch (20), and a first relay switch (21) connected in series with the first relay switch (21).
A power supply section (23) and a second relay switch (22) connected in series to the second relay switch (22).
Power supply unit (24) and coil (25) connected in series with the switch (20)
A first relay switch controller (26) connected to the coil (25) in series to control opening and closing of the first relay switch (21), and connected to the first relay switch controller (26). A shunt circuit (27) and a second shunt circuit connected in series to a shunt channel of the shunt circuit (27).
A sequence operation type power supply device comprising a second relay switch control section (28) for controlling opening / closing of a relay switch (22). 3. A switch (3) connected to a power line.
0), a first relay switch (31) and a second relay switch (32) connected in parallel with the switch (30), and a first relay switch (31) connected in series with the first relay switch (31).
A power supply unit (33) and a second relay switch (32) connected in series to the second relay switch (32).
A power supply section (34), an integrating circuit (35) connected to the switch (30), and a voltage dividing circuit (3 provided on the output side of the integrating circuit (35).
6), a first relay switch controller (37) connected to the high-voltage output side of the voltage dividing circuit (36) to control opening / closing of the first relay switch (31), and the voltage dividing circuit (36) And a second relay switch control section (38) for controlling opening and closing of the second relay switch (32) connected to the low voltage output side of the sequence operation type power supply device.