JP2010142102A - Device for switching power supply - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power supply switching device capable of safely and simply switching a commercial power supply line and a generator power supply line. <P>SOLUTION: The device for switching the power supply includes a line switch 23 interposed to the commercial power supply line and the switch 29 for delay, and a line switch 37 interposed to the generator power supply line and an electromagnetic type switch 43 for delay. The line switch interposed on one power supply line side is opened by the supplied power between the line switch for the power supply line on the other side and the switch for delay. The switch for delay is closed by the supplied power between the line switch for its own interposed power supply line and the switch for delay. The switches 23 and 29 are automatically opened and the switches 37 and 43 are closed by only starting a generator power supply 11 when restoring a commercial power supply 3. The switches 23 and 29 are automatically closed and the switches 37 and 43 are opened by stopping the generator power supply 11 when restoring the commercial power supply 3. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a power supply switching device that switches between a commercial power supply line and a generator power supply line.

  In the event of an emergency such as an earthquake, the commercial power supply supplied by the power company may stop, making it impossible to use electricity. In such an emergency, it is conceivable to use a generator power supply, but when connecting the generator power supply to the building power supply line, the commercial power supply line and the power It is necessary to switch to the machine power supply line.

  In that case, an operation error is likely to occur in a system in which the switch connected to the commercial power supply line and the generator power supply line is simply mechanically switched manually. Moreover, if the generator power supply operates accidentally after the commercial power supply is restored, the power supplied to the load interferes. On the other hand, if all the switches are controlled by a control device or the like, the configuration of the entire device becomes complicated.

  The present invention has been made paying attention to the above-mentioned conventional problems, and provides a power switching device that can be switched safely and easily with a simple configuration between a commercial power supply line and a generator power supply line. And its purpose.

  The present invention has been made to solve the above problems, and the invention of claim 1 includes a commercial power supply line, a generator power supply line, and a line switch inserted in the commercial power supply line. A power switch comprising a line switch interposed in the generator power supply line and display means for displaying the power supply to the line switch.

  The invention of claim 2 is the switching device according to claim 1, wherein an electromagnetic line switch is inserted in the generator power supply line, and when power is supplied to the commercial power supply line, The line switch of the generator power supply line is automatically opened, and is a power switching device.

  According to a third aspect of the present invention, in the power supply switching device according to the first or second aspect, the generator power supply line is provided with delay means for delaying the power supply to the load. It is.

  According to a fourth aspect of the present invention, in the power supply switching apparatus according to the third aspect, the delay means is provided on the power source side from the delay switch, an electromagnetic delay switch interposed in the generator power supply line. Timer circuit and an electromagnetic timer switch connected in series to the coil of the delay switch, the timer circuit for the timer after a predetermined delay time has elapsed since receiving power supply A power supply switching device characterized by closing a switch and closing a delay switch.

  According to a fifth aspect of the present invention, in the power supply switching device according to any one of the first to fourth aspects, a display means for displaying a power supply state is provided.

  According to a sixth aspect of the present invention, in the power supply switching device according to any one of the first to fifth aspects, when the generator capacity is determined to be abnormal when inserted in the generator power supply line, the line switch is shut off. A power supply switching device characterized in that means is provided.

  The power supply switching device of the present invention can safely and easily switch between a commercial power supply line and a generator power supply line with a simple configuration.

It is an installation figure of the power supply switching device concerning Embodiment 1 of the present invention. It is a figure explaining the power supply state of a commercial power supply in the power supply switching apparatus of FIG. It is a figure explaining the power supply state of a generator power supply in the power supply switching device of FIG. It is a front view of the state which opened the door of the cabinet for panels of the power supply switching device of FIG. It is a front view of the state which closed the door of the cabinet for panels of the power supply switching device of FIG. It is a front view of the power supply switching apparatus provided with the some display means of another example. It is an electrical block diagram of the power supply switching apparatus concerning Embodiment 2 of this invention. It is an electrical block diagram of the power supply switching apparatus concerning Embodiment 2 of this invention. It is an electrical block diagram of the power supply switching apparatus concerning Embodiment 2 of this invention. It is an electrical block diagram of the power supply switching apparatus concerning Embodiment 2 of this invention. It is an electrical block diagram of the power supply switching apparatus concerning Embodiment 2 of this invention. It is an electrical block diagram of the power supply switching apparatus concerning Embodiment 3 of this invention. It is an electrical block diagram of the power supply switching apparatus concerning Embodiment 4 of this invention. It is an electrical block diagram of the power supply switching apparatus concerning Embodiment 5 of this invention.

A power supply switching device 1 according to an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 1, the power supply switching device 1 is installed in a building such as a shelter or a house. The input side of the power switching device 1 is connected to the commercial power input line from the commercial power source 3 via the breaker box 5 and the generator power input line from the generator power source 11, and the output side is connected to the load collectively. Has been.
As shown in FIG. 2, the breaker box 5 is normally installed in a building, and in the breaker box 5, a contract breaker 7 and an earth leakage breaker 9 are provided.

Next, the configuration of the power supply switching device 1 will be described with reference to FIG.
Each power supply line is composed of a single-phase three-wire R phase, S phase, and T phase. The S phase is grounded, AC 100V between the R phase and S phase and between the T phase and S phase, and AC 200V between the R phase and T phase.

First, the commercial power supply line side connected to the commercial power supply 3 will be described.
The code | symbol 23 shows an electromagnetic type line switch, and this line switch 23 is inserted in the power supply side of the commercial power supply line. The line switch 23 includes a contact portion 25 and a coil 27. The contact portion 25 is always urged to be closed. When the power is supplied to the coil 27, the line switch 23 is excited to switch from closed to open. Reference numeral 29 denotes an electromagnetic delay switch, which is inserted on the load side of the commercial power supply line. The delay switch 29 is composed of a contact portion 31 and a coil 33. The contact portion 31 is always urged to open, and is energized and switched from open to closed when power is supplied to the coil 33.
The output end of the contact portion 25 of the line switch 23 is connected to the input end of the contact portion 31 of the delay switch 29.

Next, the generator power supply line side connected to the generator power supply 11 will be described.
Reference numeral 35 denotes an earth leakage breaker, and this earth leakage breaker 35 is inserted as a countermeasure against earth leakage in the generator power supply line.
The code | symbol 37 shows an electromagnetic type line switch, and this line switch 37 is inserted in the power supply side of the generator power supply line. The line switch 37 includes a contact portion 39 and a coil 41. The contact portion 39 is always urged to be closed, and is energized to switch from closed to open when power is supplied to the coil 41. Reference numeral 43 denotes an electromagnetic delay switch, and this delay switch 43 is inserted on the load side of the generator power supply line. The delay switch 43 includes a contact portion 45 and a coil 47. The contact portion 45 is always urged to open, and is energized to switch from open to closed when power is supplied to the coil 47.
The output end of the contact point 39 of the line switch 37 is connected to the input end of the contact point 45 of the delay switch 43.

The coil 27 of the line switch 23 of the commercial power supply line is connected between the R phase and the S phase between the line switch 37 and the delay switch 43 of the generator power supply line. On the other hand, the coil 33 of the delay switch 29 is connected between the R phase and the S phase between the line switch 23 of the commercial power supply line and the delay switch 29.
On the other hand, the coil 41 of the line switch 37 of the generator power supply line is connected between the R phase and the S phase between the line switch 23 and the delay switch 29 of the commercial power supply line. On the other hand, the coil 47 of the delay switch 43 is connected between the R phase and the S phase between the line switch 37 of the generator power supply line and the delay switch 43.

  Reference numerals 57 and 67 denote indicator lamps. The indicator lamp 57 is connected between the R phase and the S phase between the line switch 23 and the delay switch 29 of the commercial power supply line, and the indicator lamp 67 is a generator. It is connected between the R phase and the S phase between the line switch 37 and the delay switch 43 of the power supply line.

Reference numerals 49 and 59 denote timer control units as delay means. The timer control unit 49 is inserted on the commercial power supply line side, and the timer control unit 59 is inserted on the generator power supply line side.
The timer control unit 49 includes a timer circuit 51 having a timer and two timer switches 53 and 55. The timer circuit 51 is connected between the R phase and the S phase between the line switch 23 and the delay switch 29 of the commercial power supply line. The electromagnetic timer switch 53 is connected in series with the coil 33, and the electromagnetic timer switch 55 is connected in series with the indicator lamp 57. The timer switches 53 and 55 are always urged to open, and are switched from open to closed in response to an output signal from the timer circuit 51 of the timer control unit 49.
The timer control unit 59 includes a timer circuit 61 having a timer and two switches 63 and 65. The timer circuit 61 is connected between the R phase and the S phase between the line switch 37 and the delay switch 43 of the generator power supply line. The electromagnetic switch 63 is connected in series with the coil 47, and the electromagnetic timer switch 65 is connected in series with the indicator lamp 67. The timer switches 63 and 65 are always urged to open, and are switched from open to closed in response to an output signal from the timer circuit 61 of the timer control unit 59.

  As shown in FIG. 4, the power supply switching device 1 having an electrical configuration as shown in FIG. 2 is connected to a panel cabinet 68 using a terminal block 69, and as shown in FIG. 57 and 67 are arranged.

Next, the operation of the power supply switching device 1 will be described.
In normal times, power is supplied from the commercial power source 3 and the generator power source 11 is stopped. Power is supplied from the commercial power source 3 to the power source switching device 1 via the contract breaker 7 and the leakage breaker 9 of the breaker box 5. The operation at this time will be described with reference to FIG. The supplied power is supplied to the line switch 23. At this time, no power is supplied to the generator power supply line, and no power is supplied to the coil 27. Therefore, the contact portion 25 is closed, and the power is supplied before the line switch 23 and supplied to the delay switch 29.

  Further, power is supplied to the timer circuit 51 of the timer control unit 49, and the timer circuit 51 is started. When the set delay time has elapsed since the timer circuit 51 was started, the timer switches 53 and 55 are switched from open to closed by the timer circuit 51. As a result, power is supplied to the coil 33 of the delay switch 29, and the contact portion 31 is excited and switched from open to closed. When the contact 31 of the delay switch 29 is closed, the power is supplied to a load (not shown). Further, power is supplied to the indicator lamp 57, and the indicator lamp 57 is lit in green.

On the other hand, when power is supplied before the line switch 23 on the commercial power supply line side, power is supplied to the coil 41 of the line switch 37 on the generator power supply line side, and the contact 39 is excited and closed. Switch from open to open. Further, since no power is supplied to the generator power supply line, the delay switch 43 is opened and the indicator lamp 67 is turned off.
As described above, the commercial power supply line continues to supply power to the load while the contact part 25 of the line switch 23 and the contact part 31 of the delay switch 29 are both kept closed. A thick line in FIG. 2 indicates that power from the commercial power source 3 is supplied. On the other hand, when the generator power supply line continues to supply power to the load from the commercial power supply line, the contact part 39 of the line switch 37 and the contact part 45 of the delay switch 43 are both kept open. The machine power supply line is completely cut off. Therefore, even if the generator power supply 11 is operated by mistake, the power supplied to the load does not interfere and is safe.

  Next, in an emergency, the commercial power source 3 is stopped and power is supplied from the generator power source 11. The operation at this time will be described with reference to FIG. Since no power is supplied to the commercial power supply line, no power is supplied to the coil 41 as well. Therefore, the contact part 39 is closed. Therefore, when the generator power supply 11 is operated, the power is supplied before the line switch 37 of the generator power supply line and is supplied to the delay switch 43.

  Further, power is supplied to the timer circuit 61 of the timer control unit 59, and the timer circuit 61 is started. When the set delay time has elapsed since the timer circuit 61 was started, the timer switches 63 and 65 are switched from open to closed by the timer circuit 61. As a result, power is supplied to the coil 47 of the delay switch 43, and the contact portion 45 is excited and switched from open to closed. When the contact 45 of the delay switch 43 is closed, the power is supplied to a load (not shown). Further, power is supplied to the indicator lamp 67, and the indicator lamp 67 is lit in green.

On the other hand, when power is supplied before the line switch 37 on the generator power supply line side, power is supplied to the coil 27 of the line switch 23 on the commercial power supply line side, and the contact 25 is excited and closed. Switch from open to open.
As described above, the generator power supply line continues to supply power to the load while the contact part 39 of the line switch 37 and the contact part 45 of the delay switch 43 are both kept closed. A thick line in FIG. 3 indicates that power from the generator power supply 11 is supplied. On the other hand, in the commercial power supply line, when power is continuously supplied from the generator power supply line to the load, the contact part 25 of the line switch 23 and the contact part 31 of the delay switch 29 are both kept open. The power supply line is completely shut off. Therefore, even if the commercial power supply 3 is suddenly restored, the power supplied to the load does not interfere and is safe.

  When the commercial power source 3 is restored, the power source is supplied from the commercial power source 3 to the power source switching device 1 via the contract breaker 7 and the earth leakage breaker 9 of the breaker box 5. The supplied power is supplied to the line switch 23. At this time, power is supplied to the generator power supply line, and power is also supplied to the coil 27. Therefore, the contact portion 25 is open, and power is not supplied before the line switch 23.

Here, when the generator power supply 11 is stopped, the power supplied to the generator power supply line is stopped, so the power supplied to the coil 27 of the line switch 23 is stopped and the contact portion 25 is always closed. Because it is energized, it switches from open to closed. When the contact portion 25 of the line switch 23 is switched to the closed state, the power is supplied before the line switch 23 and supplied to the delay switch 29. Thereafter, in the same manner as described above, the delay switch 29 is switched to the closed state and supplied from the commercial power source 3 to a load (not shown). Further, power is supplied to the indicator lamp 57, and the indicator lamp 57 is lit in green.
On the other hand, when power is supplied before the line switch 23 on the commercial power supply line side, power is supplied to the coil 41 of the line switch 37 on the generator power supply line side, and the contact 39 is excited and closed. Switch from open to open. Therefore, the generator power supply line is completely cut off.

As described above, in the power supply switching device 1, when the commercial power supply 3 stops in an emergency, the switches 23 and 29 on the commercial power supply line side are opened by simply starting the generator power supply 11, and The switches 37 and 43 on the generator power supply line side are automatically switched to the closed state, and the power supply line to the load is switched from the commercial power supply line to the generator power supply line. Thereafter, when the commercial power supply 3 is restored, the commercial power supply line side switches 23 and 29 are closed and the commercial power supply line side switches 37 and 43 are simply stopped by simply stopping the generator power supply 11. Is automatically switched to the open state, and the power supply line to the load is switched from the generator power supply line to the commercial power supply line. Therefore, according to the power supply switching device 1, the commercial power supply line and the generator power supply line can be switched safely and easily with a simple configuration.
In addition, since the delay means is provided, it is possible to reliably prevent interference between the generator power supply line and the commercial power supply line.

As described above, the first embodiment has been described in detail. However, the specific configuration is not limited to this embodiment, and even if there is a design change or the like without departing from the gist of the present invention, it is included in the invention. .
In the above embodiment, the coil of the electromagnetic switch, the timer circuit of the timer control unit, and the indicator lamp are connected between the R phase and the S phase, but may be connected between the T phase and the S phase or between the R phase and the T phase. .
Moreover, although the said embodiment was provided in each of the commercial power supply line and the generator power supply line by using the display means as an indicator lamp, it may be provided in either one of the power supply lines.

  Furthermore, in order to make it easier to visually check the power supply state in the apparatus, for example, display means may be added as shown in FIG. In the figure, reference numerals 71 and 73 denote indicator lamps. The indicator lamp 71 is connected to light up in white when the commercial power supply 3 is restored, and the indicator lamp 73 lights up in red when the generator capacity is abnormal. To be connected. Reference numeral 75 denotes a generator ammeter as display means, and this generator ammeter 75 is connected to measure the current value supplied from the generator power supply 11. Reference numeral 77 denotes a usable home appliance display section as a display means, and this usable home appliance display section 77 is composed of six indicator lights. These six indicator lamps are allocated corresponding to each home appliance, and are connected to light the indicator lamps corresponding to usable home appliances.

  Reference numeral 79 denotes a display tower as display means. The display tower 79 is mounted on the power supply switching device 1 and fixed. It consists of indicator lamps 81, 83, 85, 87 and an indicator lamp with sound 89. The indicator lamp 81 is interlocked with the indicator lamp 73 and is connected so as to be lit red when the generator capacity is abnormal. The indicator lamp 83 is interlocked with the indicator lamp 71, and is connected so that it lights in green when the commercial power source 3 is restored. The indicator lamp 85 is linked to the indicator lamp 57 and is connected so that it lights in yellow when the commercial power supply 3 is supplied. The indicator lamp 87 is interlocked with the indicator lamp 67 and is connected so as to be lit in blue when the generator power supply 11 is supplied. The indicator lamp with sound 89 is connected so as to be lit in white when switching between the commercial power source 3 and the generator power source 11 so that a melody flows.

A power supply switching apparatus 101 according to a second embodiment of the present invention will be described with reference to FIGS. In FIG. 7, the left side is the commercial power supply line and the right side is the generator power supply line, and the drawings showing the two power supply lines are the same in the third and subsequent embodiments.
Switches 109a, 109b, 109c, 111a, 111b, 123a, 125a, 127a, 135a, 147a, 147b, 147c, 151a, 153a, 155a, 163a, 167a, 173a, 181a, 185a and 193a are normally open, Each switch is switched from open to closed by operating by supplying power to a relay coil indicated by the same reference numeral.
The switches 111c, 111d, 127b, 127c, 131a, 131b, 155b, 155c, 159a, 159b, and 171a are normally closed, and the switches indicated by the same reference numerals are operated in the same manner, so that the switches are respectively closed. It is designed to switch to open.
The switch 187a is normally open, and is switched from open to closed when a reset button (not shown) is pressed.
The switch 189a is normally closed, and is switched from closed to open when an emergency stop button (not shown) is pressed.

The power supplied from the commercial power source 3 to the power switching device 101 is supplied to the switch 105 through the leakage breaker 103. When the power source passes through the earth leakage breaker 103, the indicator lamp 107 is turned on, and the relays 109 and 111 are operated. When power is supplied to the timer circuit 113 and the delay time elapses, the switches 113a, 113b, 113c are switched from open to closed.
When the switches 113a and 113b are switched, power is supplied to the PC 117 (PC is a programmable controller) via the noise filter 115. In addition, power is supplied to the stabilized power source 119, and power of DC voltage 24V (voltage between P phase and N phase) is supplied from the stabilized power source 119. Then, the power source of DC voltage 24 V supplied from the stabilized power source 119 passes through the leakage breaker 121.

As shown in FIG. 8, the PC 117 reads the state of the relay, switch, etc. as a signal, and outputs a signal as shown in FIG.
When the PC 117 determines that the commercial power source is operating, the relays 123 and 125 are operated, and the relay 127 is operated. The contact 127 of the switch 105 is excited by the coil of the relay 127 to switch from open to closed, and power is supplied to a load (not shown). Further, the relay 131 is activated.
If the PC 117 determines that power is supplied from the commercial power supply 3, the PC 117 turns on the indicator lamp 133 and activates the relay 135. Then, the indicator lamp 139 of the signal tower 137 is turned on.
When the PC 117 determines that power is supplied from the commercial power supply 3, the PC 117 operates the relay 173. Then, a signal is sent to the signal voice 169, and a melody corresponding to the signal flows from the signal voice 169 for a predetermined time.
As described above, the commercial power supply line continues to supply power to the load.

Next, when the commercial power supply 3 is stopped, the generator power supply 11 is operated to supply power from the generator power supply 11 to the power supply switching device 101.
The power supplied from the generator power supply 11 to the power supply switching device 101 is supplied to the switch 145 through the leakage breakers 141 and 143. When the power source passes through the earth leakage breaker 143, the relay 147 is activated. Then, power is supplied to the timer circuit 149. When the delay time elapses after the timer circuit 149 is started, the switches 149a, 149b, 149c are switched from open to closed.
When the switches 149a and 149b are switched, power is supplied to the PC 117 via the noise filter 115. In addition, power is supplied to the stabilized power source 119, and power of DC voltage 24V (voltage between P phase and N phase) is supplied from the stabilized power source 119. Then, the power source of DC voltage 24 V supplied from the stabilized power source 119 passes through the leakage breaker 121.

  When the PC 117 determines that power is supplied from the generator power supply 11, the PC 117 operates the relays 151 and 153, and the relay 155 operates. The contact 157 is excited by the coil of the relay 155 to switch from open to closed, and the power is supplied to a load (not shown). Also, the relay 159 is activated.

If the PC 117 determines that power is supplied from the generator power supply 11, the PC 117 turns on the indicator lamp 161 and operates the relay 163. Then, the indicator lamp 165 of the signal tower 137 is turned on.
When the PC 117 determines that power is supplied from the generator power supply 11, the PC 117 operates the relay 167. Then, a signal is sent to the signal voice 169, and a melody corresponding to the signal flows from the signal voice 169 for a predetermined time.
As described above, the generator power supply line continues to supply power to the load.

  When the commercial power supply 3 is restored, the power supplied from the commercial power supply 3 to the power supply switching device 101 is supplied to the switch 105 through the leakage breaker 103 as described above. Also, the relays 109 and 111 are activated. When the relay 109 is activated, the relay 171 is activated, the timer circuit 149 is stopped, and the PC 117 stops the relays 151 and 153. As a result, the relay 155 is stopped, the contact portion 157 of the switch 145 is switched from closed to open, and the generator power supply line is completely cut off.

When the relays 109 and 111 are operated, power is supplied to the PC 117 as described above, and power is supplied to the stabilized power source 119, so that the commercial power supply line continues to supply power to the load.
Thus, when the commercial power supply 3 is restored, the power supply to the load is automatically switched from the generator power supply line to the commercial power supply line.

  In a state where power is supplied to the stabilized power source 119, power is supplied from the stabilized power source 119 to the meter relay 175. The meter relay 175 reads the current value of the generator power supply line by the current transformer 177 and displays the current value on the meter 179. When the current value exceeds a certain value, the relay 181 is activated, the PC 117 determines that the generator capacity is over, and the PC 117 stops the relays 151 and 153. As a result, the relay 155 is stopped, the contact portion 157 is switched from closed to open, and the generator power supply line is completely cut off.

  When the PC 117 determines that the generator capacity is over, the indicator lamp 183 is turned on and the relay 185 is operated. Then, a signal is sent to the signal voice 169, and a melody corresponding to the signal flows from the signal voice 169 for a predetermined time. And this generator capacity over state is maintained. When a reset button (not shown) is pressed in the generator capacity over state, the generator capacity over state is canceled.

  When the PC 117 determines that the magnets are abnormal by operating both the relays 127 and 155, the PC 117 stops the relays 123, 125, 151 and 153. Thereby, the contact parts 129 and 157 of the switches 105 and 145 are switched from closed to open, and the commercial power supply line and the generator power supply line are completely cut off. And this magnet abnormal state is maintained. Pressing the reset button in the magnet abnormal state cancels the magnet abnormal state.

When an unillustrated emergency stop button is pressed, the PC 117 determines that it is an emergency stop, and the PC 117 stops the relays 123, 125, 151, and 153. Thereby, the contact parts 129 and 157 of the switches 105 and 145 are switched from closed to open, and the commercial power supply line and the generator power supply line are completely cut off. If the PC 117 determines an emergency stop, the indicator lamp 191 is turned on. And this emergency stop state is maintained. When the emergency stop button is unlocked in the emergency stop state, the emergency stop state is released.
When the PC 117 determines that the predetermined state is set, the relay 193 is activated. Then, a signal is sent to the signal voice 169, and a melody corresponding to the signal flows from the signal voice 169 for a predetermined time.
In the second embodiment, the switch 145 of the generator power supply line serves as both a line switch and a delay switch. The same applies to the following embodiments.

A power supply switching device 201 (24V type) according to Embodiment 3 of the present invention will be described with reference to FIG.
Switches 207a, 207b, 207c, 209a, 209b, 211a, 211b, 219a, 219b, 223c, 236a, 236b, 236c, 236d, 239a, 239b, 243c, 259a, 259b, 266a, 266b, 273a, 275b and 275c are always Each switch is switched from open to closed when a relay indicated by the same reference numeral operates.
Switches 207d, 209c, 209d, 223a, 223b, 243a, 243b, 243c, 259c, 259d, 266c, 266d, 263a, 263b, 275a, 275d, 277a, 277b and 277c are normally closed, and each switch is the same The relays indicated by the reference numerals are operated to switch from closed to open.
The switches 281a and 281b are always open, and are switched from open to closed when a reset button (not shown) is pressed.
The switches 283a and 283b are normally open and the switches 283c and 283d are normally closed. When an emergency stop button (not shown) is pressed, the switches 283a and 283b are switched from open to closed, and the switches 283c and 283d are switched from closed to open. It is like that.

  The power supplied from the commercial power source 3 to the power switching device 201 is supplied to the delay switch 205 through the leakage breaker 203. When the power source passes through the leakage breaker 203, the relay 207 is activated and the relays 209 and 211 are activated. Then, power is supplied to the timer circuit 213. When the delay time elapses after the timer circuit 213 is started, the switches 213a, 213b, and 213c are switched from open to closed, and then the switch 213d is switched from closed to open.

When the switches 213a, 213b, and 213c are switched, power is supplied to the stabilized power source 215, and power of DC voltage 24V (voltage between P phase and N phase) is supplied from the stabilized power source 215. Then, the power source of DC voltage 24V supplied from the stabilized power source 215 passes through the leakage breaker 217, and the relay 219 is activated. The contact 221 of the delay switch 205 is excited by the coil of the relay 219 and switched from open to closed, and power is supplied to a load (not shown). Further, the relay 223 is activated and the indicator lamp 225 is turned on. Also, the buzzer 265 sounds.
When the switch 213d is switched, the buzzer 265 stops sounding. That is, the buzzer 265 continues to sound for a predetermined time after power is supplied from the commercial power supply 3 to the power supply switching device 201.
As described above, the commercial power supply line continues to supply power to the load.

Next, when the commercial power supply 3 is stopped, the generator power supply 11 is operated to supply power from the generator power supply 11 to the power supply switching device 201.
The power supplied from the generator power supply 11 to the power supply switching device 201 is supplied to the delay switch 235 through the leakage breakers 231 and 233. When the power source passes through the earth leakage breaker 233, the relay 236 is activated. Then, power is supplied to the timer circuit 237. When the delay time elapses after the timer circuit 237 is started, the switches 237a, 237b, and 237c are switched from open to closed, and then the switch 237d is switched from closed to open.

When the switches 237a, 237b, and 237c are switched, power is supplied to the stabilized power source 215, and power of DC voltage 24V (voltage between P phase and N phase) is supplied from the stabilized power source 215. Then, the power source of DC voltage 24V supplied from the stabilized power source 215 passes through the leakage breaker 217, and the relay 239 is activated. The contact 241 is excited by the coil of the relay 239 to switch from open to closed, and the power is supplied to a load (not shown). Further, the relay 243 is activated and the indicator lamp 245 is turned on. Also, the buzzer 279 sounds.
When the switch 237d is switched, the buzzer 279 stops sounding. That is, the buzzer 279 continues to sound for a predetermined time after power is supplied from the generator power supply 3 to the power supply switching device 201.
As described above, the generator power supply line continues to supply power to the load.

When the commercial power supply 3 is restored, the power supplied from the commercial power supply 3 to the power switching device 201 as described above is supplied to the delay switch 205 through the earth leakage breaker 203. Also, the relay 207 is activated. When the relay 207 is activated, the relay 236 is stopped. As a result, the timer circuit 237 and the relay 239 are stopped, the contact portion 241 is switched from closed to open, and the generator power supply line is completely cut off.
Further, when the relay 207 is activated, the relays 209 and 211 are activated as described above, and the commercial power supply line continues to supply power to the load.
Thus, when the commercial power supply 3 is restored, the power supply to the load is automatically switched from the generator power supply line to the commercial power supply line.

In a state where power is supplied from the commercial power supply 3 to the power supply switching device 201, the relay 207 operates as described above. In this state, when the relay 239 is activated due to a failure or the like, the relay 259 is activated. As a result, the timer circuit 213 and the relay 219 are stopped, the contact portion 221 is switched from closed to open, and the commercial power supply line is completely cut off. In addition, the indicator lamp 261 is turned on. And this magnet abnormal state is maintained.
When a reset button (not shown) is pressed in the magnet abnormal state, the relay 263 is activated to cancel the magnet abnormal state.

When an emergency stop button (not shown) is pressed, the timer circuit 213 is stopped. As a result, the relay 219 is stopped, the contact portion 221 is switched from closed to open, and the commercial power supply line is completely cut off. In addition, the indicator lamp 261 is turned on. And this emergency stop state is maintained.
When the emergency stop button is unlocked in the emergency stop state, the emergency stop state is released.

  Further, in a state where power is supplied from the generator power supply 11 to the power supply switching device 201, the relay 236 operates as described above. In this state, when the relay 219 is activated due to a failure or the like, the relay 266 is activated. As a result, the timer circuit 237 and the relay 239 are stopped, the contact portion 241 is switched from closed to open, and the generator power supply line is completely cut off. In addition, the indicator lamp 267 is turned on. And this magnet abnormal state is maintained.

In a state where power is supplied from the generator power supply 11 to the power supply switching device 201, power is supplied to the meter relay 268. The meter relay 268 reads the current value of the generator power supply line by the current transformer 269 and displays the current value on the meter 271. When the current value exceeds a certain value, the relay 273 is activated and the relay 275 is activated. As a result, the timer circuit 237 and the relay 239 are stopped, the contact portion 241 is switched from closed to open, and the generator power supply line is completely cut off. In addition, the indicator lamp 267 is turned on. And this generator capacity over state is maintained.
When the reset button is pressed in the generator capacity over state or the magnet abnormal state, the relay 277 is actuated to cancel the generator capacity over state or the magnet abnormal state.

When an emergency stop button (not shown) is pressed, the timer circuit 237 stops. As a result, the relay 239 is stopped, the contact portion 241 is switched from closed to open, and the generator power supply line is completely cut off. In addition, the indicator lamp 267 is turned on. And this emergency stop state is maintained.
When the emergency stop button is unlocked in the emergency stop state, the emergency stop state is released.

A power supply switching device 301 (100 V type) according to Embodiment 4 of the present invention will be described with reference to FIG.
Switches 307a, 307b, 309a, 309b, 315a, 337a, 337b, 337c, 337d, 343a, 351a, 351b, 361a, 361b, 373a, 375a and 375b are normally open, and each switch has the same number sign Each of the shown relays is switched from open to closed.
Switches 307c, 307d, 309c, 315b, 315c, 343b, 343c, 351c, 351d, 355a, 355b, 361c, 361d, 375c, 375d, 377a, 377b and 377c are normally closed, and each switch has the same number Each of the relays indicated by the reference sign is switched from closed to open.
The switches 381a and 381b are always open, and are switched from open to closed when a reset button (not shown) is pressed.
The switches 383a and 383b are normally open and the switches 383c and 383d are normally closed. When an emergency stop button (not shown) is pressed, the switches 383a and 383b are switched from open to closed, and the switches 383c and 383d are switched from closed to open. It is like that.

  The power supplied from the commercial power source 3 to the power switching device 301 is supplied to the delay switch 305 through the leakage breaker 303. When the power source passes through the leakage breaker 303, the relay 307 is activated and the relay 309 is activated. When the relay 309 is activated, the buzzer 311 sounds and power is supplied to the timer circuit 313. When the delay time elapses after the timer circuit 313 is started, the switches 313a, 313b, and 313c are switched from open to closed, and the switch 313d is switched from closed to open.

When the switches 313a and 313b are switched, the relay 315 is activated. The contact 317 of the delay switch 305 is excited by the coil of the relay 315 and switched from open to closed, and power is supplied to a load (not shown).
When the switch 313c is switched, the indicator lamp 319 is turned on.
When the switch 313d is switched, the buzzer 311 stops sounding. That is, the buzzer 311 continues to sound for a predetermined time after power is supplied from the commercial power supply 3 to the power supply switching device 301.
As described above, the commercial power supply line continues to supply power to the load.

Next, when the commercial power supply 3 is stopped, the generator power supply 11 is operated to supply power from the generator power supply 11 to the power supply switching device 301.
The power supplied from the generator power supply 11 to the power supply switching device 301 is supplied to the delay switch 335 through the leakage breakers 331 and 333. When the power source passes through the earth leakage breaker 333, the relay 337 is activated. Then, the buzzer 339 sounds and the timer circuit 341 is supplied with power. When the delay time elapses after the timer circuit 341 is started, the switches 341a, 341b, and 341c are switched from open to closed, and the switch 341d is switched from closed to open.

When the switches 341a and 341b are switched, the relay 343 is activated. The contact 345 of the delay switch 335 is excited by the coil of the relay 343 and switched from open to closed, and the power is supplied to a load (not shown).
When the switch 341c is switched, the indicator lamp 347 is turned on.
When the switch 341d is switched, the buzzer 339 stops sounding. That is, the buzzer 339 continues to sound for a predetermined time after power is supplied from the generator power supply 11 to the power supply switching device 301.
As described above, the generator power supply line continues to supply power to the load.

When the commercial power source 3 is restored, the power supplied from the commercial power source 3 to the power source switching device 301 as described above is supplied to the delay switch 305 through the leakage breaker 303. Also, the relay 307 is activated. When the relay 307 operates, the relay 337 stops. As a result, the timer circuit 341 and the relay 343 are stopped, the contact portion 345 is switched from closed to open, and the generator power supply line is completely cut off.
When the relay 307 is activated, the relay 309 and the like are activated as described above, and the commercial power supply line continues to supply power to the load.
Thus, when the commercial power supply 3 is restored, the power supply to the load is automatically switched from the generator power supply line to the commercial power supply line.

In a state where power is supplied from the commercial power supply 3 to the power supply switching device 301, the relay 309 operates as described above. In this state, when the relay 343 is activated due to a failure or the like, the relay 351 is activated. As a result, the timer circuit 313 and the relay 315 are stopped, the contact portion 317 is switched from closed to open, and the commercial power supply line is completely cut off. In addition, the indicator lamp 353 is turned on. And this magnet abnormal state is maintained.
When a reset button (not shown) is pressed in the magnet abnormal state, the relay 355 is activated to cancel the magnet abnormal state.

When an emergency stop button (not shown) is pressed, the timer circuit 313 is stopped. As a result, the relay 315 is stopped, the contact portion 317 is switched from closed to open, and the commercial power supply line is completely cut off. In addition, the indicator lamp 353 is turned on. And this emergency stop state is maintained.
When the emergency stop button is unlocked in the emergency stop state, the emergency stop state is released.

  Further, in a state where power is supplied from the generator power supply 11 to the power supply switching device 301, the relay 337 operates as described above. In this state, when the relay 315 is activated due to a failure or the like, the relay 361 is activated. As a result, the timer circuit 341 and the relay 343 are stopped, the contact portion 345 is switched from closed to open, and the generator power supply line is completely cut off. In addition, the indicator lamp 363 is turned on. And this magnet abnormal state is maintained.

In a state where power is supplied from the generator power supply 11 to the power switching device 301, power is supplied to the meter relay 367. The meter relay 367 reads the current value of the generator power supply line by the current transformer 369 and displays the current value on the meter 371. When the current value exceeds a certain value, the relay 373 is activated and the relay 375 is activated. As a result, the timer circuit 341 and the relay 343 are stopped, the contact portion 345 is switched from closed to open, and the generator power supply line is completely cut off. In addition, the indicator lamp 363 is turned on. And this generator capacity over state is maintained.
When a reset button (not shown) is pressed in the generator capacity over state or the magnet abnormal state, the relay 377 is actuated to cancel the generator capacity over state or the magnet abnormal state.

When an emergency stop button (not shown) is pressed, the timer circuit 341 stops. As a result, the relay 343 stops and the contact portion 345 is switched from closed to open, and the generator power supply line is completely cut off. In addition, the indicator lamp 363 is turned on. And this emergency stop state is maintained.
When the emergency stop button is unlocked in the emergency stop state, the emergency stop state is released.

A power supply switching device 401 (completely manual type) according to Embodiment 5 of the present invention will be described with reference to FIG.
The switches 437a, 439a, and 439b are normally open, and each switch is switched from open to closed by the operation of the relay indicated by the same reference numeral.
The switches 409a and 439c are normally closed, and each switch is switched from closed to open when a relay indicated by the same reference numeral operates.
The switch 443a is normally closed, and is switched from closed to open when a reset button (not shown) is pressed.

The power supplied from the commercial power supply 3 to the power supply switching device 401 is supplied to a load (not shown) through the earth leakage breaker 403, the contact portion 405 a of the manual switching switch 405. The manual switching switch 405 has a contact portion 405a closed and a contact portion 405b open. When the power source passes through the earth leakage breaker 403, the indicator lamp 407 is turned on and the relay 409 is activated.
As described above, the commercial power supply line continues to supply power to the load.

Next, when the commercial power supply 3 is stopped, the manual switching switch 405 is switched so that the contact portion 405a is opened and the contact portion 405b is closed. Then, the generator power supply 11 is operated to supply power from the generator power supply 11 to the power supply switching device 401.
The power supplied from the generator power supply 11 to the power supply switching device 401 is supplied to the delay switch 415 through the leakage breakers 411 and 413. When the power passes through the leakage breaker 413, the indicator lamp 417 is turned on and the power is supplied to the timer circuit 419. When a delay time elapses after the timer circuit 419 is started, the switch 419a is switched from open to closed.

When the switch 419a is switched, the relay 421 is activated. The contact 423 of the delay switch 415 is excited by the coil of the relay 421 to switch from open to closed, and power is supplied to a load (not shown) through the contact 405b.
As described above, the generator power supply line continues to supply power to the load.

When the commercial power supply 3 is restored, the power supplied from the commercial power supply 3 to the power supply switching device 401 as described above is supplied to the manual switching switch 405 through the leakage breaker 403. When the power source passes through the leakage breaker 403, the indicator lamp 407 is turned on as described above, and the relay 409 is activated. As a result, the timer circuit 419 and the relay 421 are stopped, the contact portion 423 is switched from closed to open, and the generator power supply line is completely cut off.
The manual switching switch 405 is switched so that the contact portion 405a is closed and the contact portion 405b is opened. As a result, power is supplied to a load (not shown) through the contact portion 405a.
Thus, when the commercial power supply 3 is restored, the power supply to the load is switched from the generator power supply line to the commercial power supply line simply by switching the manual switching switch 405.

In a state where power is supplied from the generator power supply 11 to the power supply switching device 401, power is supplied to the meter relay 431. The meter relay 431 reads the current value of the generator power supply line by the current transformer 433 and displays the current value on the meter 435. When the current value exceeds a certain value, the relay 437 is activated and the relay 439 is activated. As a result, the relay 421 stops, the contact portion 423 is switched from closed to open, and the generator power supply line is completely cut off. In addition, the indicator lamp 441 is turned on. And this generator capacity over state is maintained.
When a reset button (not shown) is pressed in the generator capacity over state, the relay 439 stops and the generator capacity over state is released.

  In addition, in the case of a mobile configuration with a simple configuration, the power supply line of the generator power source of the power supply switching device 401 is changed to two lines of R line and S line, and is returned to three lines before the manual type switching switch 405, A configuration corresponding to the relay 409 may not be provided on the commercial power supply line side.

  According to the power supply switching device of the present invention, it can be used for a building to which commercial power is supplied such as a shelter or a house in case of emergency.

DESCRIPTION OF SYMBOLS 1 ... Power supply switching device 3 ... Commercial power supply 5 ... Breaker box 7 ... Contract breaker 9 ... Earth leakage breaker 11 ... Generator power supply 23, 29 ... Commercial power supply line side switch 25, 31 ... Contact part 27, 33 ... Coil 35 ... (Generator power supply line side) Earth leakage breakers 37, 43 ... Generator power supply line side switches 39, 45 ... Contacts 41, 47 ... Coils 49, 59 ... Timer control units 51, 61 ... Timer circuits 53, 55, 63, 65 ... Switch 57, 67 ... Indicator lamp 68 ... Panel cabinet 69 ... Terminal block 71, 73 ... Indicator lamp 75 ... Generator ammeter 77 ... Usable home appliance display part 79 ... Display tower 81, 83, 85, 87… Indicator light 89… Indicator light with sound

Claims (6)

  A commercial power supply line; a generator power supply line; a line switch interposed in the commercial power supply line; a line switch interposed in the generator power supply line; and the line switch. A power supply switching device characterized in that display means for displaying power supply is provided.   The switching device according to claim 1, wherein an electromagnetic line switch is interposed in the generator power supply line, and when power is supplied to the commercial power supply line, the generator power supply line A line switch is a power switching device that is automatically opened.   3. The power switching device according to claim 1, wherein the generator power supply line is provided with delay means for delaying power supply to the load.   4. The power switching device according to claim 3, wherein the delay means includes an electromagnetic delay switch interposed in the generator power supply line, a timer circuit provided on the power supply side from the delay switch, and a delay circuit. The timer circuit is connected in series to the coil of the switch for the timer, and the timer circuit closes the timer switch for delay after a predetermined delay time has elapsed since receiving the power supply. A power supply switching device characterized by closing a switch.   5. The power switching device according to claim 1, further comprising display means for displaying a power supply state.   6. The power switching device according to claim 1, further comprising an abnormality handling means that is inserted into the generator power supply line and shuts off the line switch when the generator capacity is determined to be abnormal. A power switching device characterized by the above.

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