JP5853148B2 - Two-wire load control device - Google Patents

Description

  The present invention relates to a two-wire load control device for controlling on and off of a load such as a lighting device.

  Conventionally, a load control device using a semiconductor switch element such as a triac is known. Among such load control devices using semiconductor switch elements, the two-wire load control device is connected in series between the AC power source and the load, and therefore wiring work is simple. On the other hand, it is necessary to secure a power source for driving the semiconductor switch element and the control circuit (CPU or the like) even when the load is turned off. For this purpose, a rectifier circuit is connected in parallel to the semiconductor switch element, and even when the load is off, a weak current that does not actually turn on or malfunction is allowed to flow, and the buffered capacitor is charged with the rectified current, A power supply (off power supply unit) is secured when is turned off. Even when the load is on, a current (on power supply unit) when the load is on is secured by using the current rectified by the rectifier circuit (see Patent Document 1).

  The off power supply unit is a constant voltage circuit (bootstrap circuit) composed of, for example, a resistor that limits current, a Zener diode (constant voltage diode) that clamps voltage, and a transistor, and is full-wave rectified by a rectifier circuit. The pulsating flow is input. Part of the current output from the off power supply circuit flows to the control unit and is used to drive the CPU and the like. The remaining current charges the buffer capacitor. When the voltage of the pulsating current rectified by the rectifier circuit is lower than the Zener voltage, the buffer capacitor is a power source, and therefore the buffer capacitor is repeatedly charged and discharged. Therefore, even if the load is originally off as described above, a weak current flows through the load via the Zener diode and the rectifier circuit. As a result, a weak current flows through the ON power supply circuit, and the buffer capacitor is charged.

  On the other hand, in order to turn on the load, for example, a drive signal is input from the control unit to the switch element, and the switch element is turned on. In addition to a semiconductor switch element such as a triac, a switch element having a mechanically driven contact, such as a latch relay, is applied to the switch element.

JP 2008-97535 A

  In such a two-wire load control device, when the load is switched from on to off, if the drive voltage input from the control unit to the switch element is insufficient, the switch element cannot operate properly, and the load malfunctions. May occur. In particular, in a load control device to which a latch-type relay that requires a large amount of power to operate as a switch element is applied, when a load with low power consumption such as an LED (Light Emitting Diode) bulb is connected, the load is turned on. There is a possibility that control from OFF to OFF cannot be performed appropriately. This is because when a load with low power consumption is connected, the power output from the on-power supply circuit also tends to decrease.

  The present invention has been made in order to solve the above-described problem, and even when a load with low power consumption is connected, a two-wire system capable of appropriately controlling the load from on to off. An object is to provide a load control device.

In order to achieve the above object, a two-wire load control device according to the present invention includes:
Two input terminals respectively connected to an AC power source and a load;
A series circuit of a switch element and a current transformer connected between the two input terminals;
When the switch element is connected in parallel to both ends of the switching element of the switch element and the switch element is in a non-conductive state using an alternating current flowing from the AC power source through the load when the switch element is in a non-conductive state. An off power supply unit that outputs DC power of
An on-power supply unit that is connected to the secondary side of the current transformer and outputs DC power when the switch element is in a conductive state using an alternating current that flows to the secondary side of the current transformer;
A controller that is driven by DC power output from the off-power supply unit and the on-power supply unit, and that controls conduction and non-conduction of the switch element based on operation information input from the outside;
The control unit monitors DC power output from the ON power supply unit, and does not control switching of the switch element from conduction to non-conduction when the DC power is less than a predetermined threshold. .

Another two-wire load control device according to the present invention is
Two input terminals respectively connected to an AC power source and a load;
A series circuit of a switch element and a current transformer connected between the two input terminals;
When the switch element is connected in parallel to both ends of the switching element of the switch element and the switch element is in a non-conductive state using an alternating current flowing from the AC power source through the load when the switch element is in a non-conductive state. An off power supply unit that outputs DC power of
An on-power supply unit that is connected to the secondary side of the current transformer and outputs DC power when the switch element is in a conductive state using an alternating current that flows to the secondary side of the current transformer;
A control unit that is driven by DC power output from the off power supply unit and the on power supply unit, and controls conduction and non-conduction of the switch element based on operation information input from the outside;
It has a counting unit that counts time,
The control unit monitors DC power output from the ON power supply unit, and executes predetermined power shortage handling processing when the DC power is less than a predetermined threshold, After switching from non-conduction to conduction, the DC power output from the on-power supply unit is not monitored while the counting unit counts a predetermined time .

Furthermore, still another two-wire load control device according to the present invention is:
Two input terminals respectively connected to an AC power source and a load;
A series circuit of a switch element and a current transformer connected between the two input terminals;
When the switch element is connected in parallel to both ends of the switching element of the switch element and the switch element is in a non-conductive state using an alternating current flowing from the AC power source through the load when the switch element is in a non-conductive state. An off power supply unit that outputs DC power of
An on-power supply unit that is connected to the secondary side of the current transformer and outputs DC power when the switch element is in a conductive state using an alternating current that flows to the secondary side of the current transformer;
A control unit that is driven by DC power output from the off power supply unit and the on power supply unit, and controls conduction and non-conduction of the switch element based on operation information input from the outside;
It has a counting unit that counts time,
The control unit monitors DC power output from the ON power supply unit, and executes predetermined power shortage handling processing when the DC power is less than a predetermined threshold, After the switching from non-conduction to conduction, the power shortage handling process is not executed while the counting unit counts a predetermined time .

In this invention, after switching the switch element from non-conduction to conduction, it is preferable that the switching of the switch element from conduction to non-conduction can be controlled while the counting unit counts a predetermined time .

  According to the two-wire load control device of the present invention, the control unit monitors the DC power output from the ON power supply unit, and performs the predetermined power shortage handling process when the DC power is less than the predetermined threshold. Run. As a result, even when low-power-consumption loads are connected, etc., even when the drive power input to the switch element is insufficient, the DC power is recovered by the power shortage handling process, and malfunctions of the load are suppressed. it can. Therefore, it is possible to appropriately control the load from on to off.

The figure which shows the block configuration of the 2-wire type load control apparatus which concerns on one Embodiment of this invention. The circuit diagram which shows the specific structure of the said 2-wire type load control apparatus. The figure which shows waveforms, such as a voltage of each part of a 2-wire type load control apparatus, when a load with big power consumption is connected to the said 2-wire type load control apparatus and a switch element is switched from a non-conduction state to a conduction | electrical_connection state. When a load with low power consumption is connected to the above-described two-wire load control device (no function limitation), and the waveform of the voltage of each part of the two-wire load control device when the switch element is switched from the non-conductive state to the conductive state FIG. When a load with low power consumption is connected to the above-described two-wire load control device (with function limitations) and the switch element is switched from a non-conductive state to a conductive state, the waveforms of voltages and the like of each part of the two-wire load control device FIG.

  A two-wire load control apparatus according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 shows a basic block configuration of a two-wire load control apparatus 1 according to this embodiment, and FIG. 2 shows a specific circuit configuration. The two-wire load control device 1 includes two input terminals 11a and 11b connected to an AC power supply 2 and a load 3, respectively, and a switch element 12 and a current transformer connected between the two input terminals 11a and 11b. 13 series circuits are provided. The switch element 12 may be a semiconductor switch element such as a triac, or may be a switch element having a mechanically driven contact such as a latch relay.

  An off-power supply unit 14 that outputs DC power when the switch element 12 is in a non-conducting state to both terminals 12a and 12b of the opening / closing unit of the switch element 12 using an AC current flowing from the AC power supply 2 via the load 3 Is connected. More specifically, both terminals 12a and 12b of the opening / closing portion of the switch element 12 are configured by diode bridges or the like, and convert an alternating current flowing from the alternating current power supply 2 through the load 3 into a direct current (pulsating flow). The first rectifier circuit 15 is connected in parallel. For example, a resistor that limits current, a Zener diode (constant voltage diode) that clamps a voltage, and a constant voltage circuit (bootstrap circuit) 16 that includes transistors are connected to the first rectifier circuit 15. . The first rectifier circuit 15 and the constant voltage circuit 16 constitute an off power supply unit 14. In the circuit configuration shown in FIG. 2, the off power supply unit 14 has two voltage systems, for example, a high voltage system with a drive voltage of 24V and a low voltage system with a drive voltage of 12V.

  On the other hand, on the secondary side of the current transformer 13, an on power supply unit 17 that outputs DC power when the switch element 12 is in a conductive state is connected using an alternating current flowing in the secondary side of the current transformer 13. ing. More specifically, a second rectifier circuit 18 configured by a diode bridge or the like and converting an alternating current flowing from the alternating current power supply 2 via the load 3 into a direct current (pulsating flow) is connected. The second rectifier circuit 18 is connected to a constant voltage circuit 19 composed of a capacitor and a Zener diode. The on power supply unit 17 also has two voltage systems, for example, a high voltage system with a drive voltage of 24V and a low voltage system with a drive voltage of 12V. The output terminal of the high voltage system of the off power supply unit 14 and the output terminal of the high voltage system of the on power supply unit 17 are connected to each other via a backflow prevention diode. Similarly, the output terminal of the low voltage system of the off power supply unit 14 and the output terminal of the low voltage system of the on power supply unit 17 are connected to each other through a backflow preventing diode.

  The control unit 20 operates based on software or the like. For example, when the user operates the input unit 25 such as an operation handle or a remote control device provided on the wall surface, the switch element 12 is turned on and off according to the operation information. Control continuity. The control unit 20 includes, for example, a CPU and includes a first control unit 21 that is driven at a low voltage (for example, 3V) and a second control unit 22 that is driven at a high voltage (for example, 24V). The first control unit 21 is connected to output terminals of the low voltage system of the off power supply unit 14 and the on power supply unit 17 through a regulator. The regulator is for stepping down the drive voltage 12V of the low voltage system to a lower voltage of 3V. The second control unit 22 outputs large power for driving an electromagnet device or the like when the switch element 12 is, for example, a latch relay.

  Further, an auxiliary power supply unit 23 for operating the CPU is connected between the output terminals of the low voltage system of the off power supply unit 14 and the on power supply unit 17 and the first control unit 21 via a regulator. Further, an auxiliary power supply unit 24 for switching the contact of the switch element 12 is connected between the output terminals of the high voltage system of the off power supply unit 14 and the on power supply unit 17 and the second control unit 22. Each of the auxiliary power supply unit 23 for operating the CPU and the auxiliary power supply unit 24 for opening and closing the contacts is composed of a buffer capacitor or the like.

  The load control device 1 according to the present embodiment further includes a voltage detection circuit 30 that detects the output voltage of the constant voltage circuit 19 of the on-power supply unit 17. The voltage detection circuit 30 includes a voltage dividing resistor and a capacitor. The output voltage of the on power supply unit 17 detected by the voltage detection circuit 30 is input to the power monitoring unit 2 </ b> A of the control unit 20.

  The control unit 20 further includes a power monitoring unit 2A, a power shortage response unit 2B, a power shortage notification unit 2C, and a timer (counting unit) 2D. The power monitoring unit 2A is configured by an A / D conversion circuit or the like, and monitors the output power of the on-power supply unit 17 by comparing the voltage detected by the voltage detection circuit 30 with a predetermined threshold value. The power shortage handling unit 2B executes a predetermined power shortage handling process when the output voltage of the ON power supply unit 17 (that is, the voltage detected by the voltage detection circuit 30) becomes less than a predetermined threshold. Examples of the power shortage handling process include not switching control of the switch element from conduction to non-conduction, performing notification by the power shortage notifying unit 2C, and providing a restriction on the function of the load control device 1 described later. It is done. The power shortage notifying unit 2C notifies that the output power of the on-power supply unit 17 is insufficient by applying a drive voltage to the LED 40 for notification. In addition to the notification LED 40 or instead of the notification LED 40, a notification sound may be output by driving a speaker (not shown) separately connected to the power shortage notification unit 2C. The timer 2D counts time such as a mask period described later. The timer 2D may be provided outside the control unit.

  Next, the operation of the load control device 1 according to this embodiment will be described. First, it is assumed that the switch element 12 is non-conductive and the load 3 is in an off state. Since the first rectifier circuit 15 is connected to both terminals 12a and 12b of the opening / closing portion of the switch element 12, even if the switch element 12 is non-conductive, the AC power supply 2, the load 3, and the first rectifier circuit A weak current flows through the 15 series circuits. The current at this time is a minute current that does not cause the load 3 to malfunction, and is set so that the impedance of the off-power supply unit 14 becomes high. When a full-wave rectified pulsating current is input from the first rectifier circuit 15, the voltage waveform of the output from the off power supply unit 14 becomes substantially trapezoidal due to the Zener voltage of the Zener diode. Part of the current output from the off power supply unit 14 is stepped down by the regulator and supplied to the first control unit 21. In parallel with this, the buffer capacitor of the auxiliary power supply unit 23 is charged. When the voltage of the pulsating current rectified by the first rectifier circuit 15 is lower than the Zener voltage, the buffer capacitor of the auxiliary power supply unit 23 becomes a power source and supplies power to the first control unit 21 via the regulator. To do. Therefore, when the load 3 is in the off state, the buffer capacitor of the auxiliary power supply unit 23 is repeatedly charged and discharged. Similarly, a part of the current output from the off power supply unit 14 is supplied to the second control unit 22 and, in parallel, charges the buffer capacitor of the auxiliary power supply unit 24.

  When the operation information for turning on the load 3 is input from the input unit 25, the second control unit 22 outputs drive power in order to switch the switch element 12 from the non-conductive state to the conductive state. This driving power is provided, for example, by discharging the buffer capacitor of the auxiliary power supply unit 24.

  FIG. 3 shows waveforms such as voltages at various parts when a load with high power consumption such as an incandescent lamp is connected as the load 3 and the switch element 12 is switched from the non-conductive state to the conductive state. The horizontal axis shows the passage of time. The passage of time (time) is counted by the timer 2D. At time t0, the input unit 25 is operated, the output power of the on-power supply unit 17 increases, exceeds the threshold value, and then saturates before the mask period elapses (time t1). Here, the mask period is a period in which the power monitoring function by the power monitoring unit 2A of the control unit 20 is masked (invalidated), that is, the DC power output from the on power supply unit 17 by the power monitoring unit 2A. This is a period that is not monitored. When the switch element 12 is switched from the non-conductive state to the conductive state, the timer 2D starts counting the mask period. In the mask period, when the input unit 25 is operated by the user immediately after the switch element 12 is switched from the non-conductive state to the conductive state (that is, before the output power of the on-power supply unit 17 exceeds the threshold value), the control unit 20 Is set to accept the operation input. Here, as the predetermined power shortage handling process according to claim 1, the DC power output from the on-power supply unit 17 is not monitored until the mask period is counted by the timer 2D. In addition, by masking the power monitoring function by the power monitoring unit 2A, when the switch element 12 is driven before the output power of the on-power supply unit 17 exceeds the threshold, the power is stored in the buffer capacitor of the auxiliary power supply unit 24. Charge is used.

  Before time t0, power is supplied from the off power supply unit 14 to the control unit 20, and a control signal can be transmitted from the control unit 20 to the switch element 12 (a drive voltage is applied). The period from time t0 to time t1 corresponds to a mask period, and the control unit 20 does not monitor the DC power output from the on power source unit 17, so even before the output power of the on power source unit 17 exceeds the threshold value. The control signal can be transmitted from the second control unit 22 of the control unit 20 to the switch element 12. A control signal can be transmitted from the second control unit 22 to the switch element 12 after the output power of the on-power supply unit 17 exceeds the threshold (including after the time t1). Therefore, in the case shown in FIG. 3, the control signal can always be transmitted from the second control unit 22 to the switch element 12. Also, the power shortage notification unit 2C and the LED 40 are not notified of power shortage.

  FIG. 4 shows waveforms such as voltages at various parts when a load with low power consumption such as an LED bulb is connected as the load 3. In FIG. 4, even if the DC power output from the on-power supply unit 17 is less than a predetermined threshold, the control unit 20 does not limit the functions of the two-wire load control device 1. When a load with low power consumption is connected, the increase in DC power output from the on-power supply unit 17 is gradual and saturates before the threshold is exceeded. Therefore, the DC power output from the on-power supply unit 17 does not exceed the threshold value, but the control signal can be transmitted from the control unit 20 to the switch element 12 until time t1 when the mask period elapses. When the mask period elapses at time t1, the control unit 20 starts monitoring the DC power output from the ON power supply unit 17. Along with this, the control unit 20 detects that the DC power output from the ON power supply unit 17 is less than the threshold value, and the power shortage handling process is executed. That is, the control unit 20 enters a mode in which the switching of the switching element 12 from conduction to non-conduction is not controlled, and the control signal cannot be transmitted from the second control unit 22 of the control unit 20 to the switching element 12. Further, along with this, a power shortage notification is made via the power shortage notification unit 2 </ b> C and the LED 40. Here, as the predetermined power shortage response processing according to claim 1, the switching control of the switch element 12 from conduction to non-conduction is not performed, and the direct current output from the on power supply unit 17 via the power shortage notification unit or the like A notification that power is insufficient is executed. Only one of the processes may be executed.

  FIG. 5 shows waveforms of voltage and the like of each part when a load with low power consumption such as an LED bulb is connected as the load 3. In FIG. 5, when the DC power output from the ON power supply unit 17 is less than a predetermined threshold, the control unit 20 temporarily limits some functions of the two-wire load control device 1. And The functions of the two-wire load control device 1 restricted here include, for example, a wireless transmission function or a wireless reception function performed with a wireless remote control device (not shown) or an external device. Any function that consumes power is not particularly limited.

  When the function of the two-wire load control device 1 as shown in FIG. 4 is not limited, if the shortage of DC power output from the on power supply unit 17 continues for a predetermined time or longer, depending on the specifications of the control unit 20 The operation by software may be reset / restarted. In such a case, in order to avoid an infinite loop of resetting and restarting operations by software, the two-wire load control device 1 of the present embodiment restricts some functions (temporarily. The power consumption of the two-wire load control device 1 is reduced. Here, as the predetermined power shortage handling process according to the first aspect, temporarily limiting some functions of the two-wire load control device 1 is executed.

  In FIG. 5, the operation until time t1 elapses is the same as in FIG. When the time t1 elapses, the function restriction is started, and a power shortage notification is made via the power shortage notification unit 2C and the LED 40. When the function restriction starts, the power consumed by the two-wire load control device 1 decreases, so that the voltage detected by the voltage detection circuit 30 rises and exceeds the threshold at time t2. As a result, the control signal can be transmitted from the control unit 20 to the switch element 12 again. In addition, the function restriction and power shortage notification are canceled. When the function restriction is released, power is consumed by the operation of the two-wire load control device 1, the voltage detected by the voltage detection circuit 30 decreases, and falls below the threshold at time t3. After time t3 when the voltage detected by the voltage detection circuit 30 becomes less than the threshold value, the function limitation of the two-wire load control device 1 and the power shortage notification are resumed, and the voltage detected by the voltage detection circuit 30 increases. . Thereafter, the same operation is repeated near the upper and lower threshold values.

  As described above, according to the two-wire load control device 1 of the present embodiment, the power monitoring unit 2A of the control unit 20 monitors the DC power output from the ON power supply unit 17, and the DC power is predetermined. When it becomes less than the threshold value, predetermined power shortage handling processing is executed. Thus, for example, when a low power consumption load 3 such as an LED bulb is connected, the DC power is recovered by the power shortage handling process even when the drive power input to the switch element 12 is insufficient. Thus, malfunction of the load 3 can be suppressed. Therefore, it is possible to appropriately control the load 3 from on to off according to the power status.

  As an example of the power shortage handling process, in the configuration in which the switching control of the switch element 12 from conduction to non-conduction is not performed, when the drive power input to the switch element 12 is insufficient, the drive power is not applied to the switch element 12. Therefore, malfunction of the switch element 12 due to power shortage is suppressed.

  In addition, after the switch element 12 is switched from non-conduction to conduction, the power monitoring unit 2A does not monitor the DC power output from the ON power supply unit 17 during the mask period counted by the timer 2D. As a result, even when the input unit 25 is operated when the output power from the on-power supply unit 17 takes a long time due to a delay in the response of the current transformer 13 or the load 3, the switch element 12 Open / close control is appropriately performed.

  Further, when the DC power output from the on power supply unit 17 is less than a predetermined threshold, the control unit 20 temporarily limits some functions of the two-wire load control device 1. As a result, the power consumption of the two-wire load control device 1 is reduced, and the voltage detected by the voltage detection circuit 30 increases. In addition, problems such as an infinite loop of resetting and restarting the operation of the control unit 20 can be avoided.

  Further, since the power shortage notifying unit 2C notifies that the DC power output from the on power supply unit 17 is insufficient via the LED 40, the administrator or the user has insufficient DC power output from the on power supply unit 17. You can know what you are doing. Thereby, it becomes possible for an administrator and a user to perform an appropriate response quickly, and to solve a power shortage.

  The present invention is not limited to the configuration of the above embodiment. At least an off power supply unit 14, an on power supply unit 17, and a control unit 20 are provided. When the control unit 20 monitors the DC power output from the on power supply unit 17 and falls below a predetermined threshold value, the control unit 20 What is necessary is just to be comprised so that a power shortage response process may be performed. Further, the predetermined power shortage handling process is not limited to the above-described switching control of the switch element 12 from conduction to non-conduction, and the like, and when the DC power output from the on power supply unit 17 is insufficient, the switch element Other processes effective for the 12 conduction control may be used.

  The present invention can be variously modified. For example, in the mask period counted by the timer 2D, the power shortage handling process may be invalidated as an alternative means for invalidating the power monitoring function by the power monitoring unit 2A. By disabling the power shortage handling process, the second control unit 22 can transmit a control signal to the switch element 12 during the mask period, and the notification operation by the power shortage notification unit 2C is avoided.

  Moreover, in the said embodiment, although the buffer capacitor (electric storage element) was used as the auxiliary power supply units 23 and 24, the auxiliary power supply units 23 and 24 are not limited to this, and a rechargeable secondary battery is used. Also good. In that case, it is not necessary to replace the battery as in the case of using a buffer capacitor.

DESCRIPTION OF SYMBOLS 1 2 wire type load control apparatus 2 AC power supply 3 Load 11a, 11b Input terminal 12 Switch element 13 Current transformer 14 Off power supply part 15 1st rectifier circuit 16 Constant voltage circuit 17 On power supply part 18 2nd rectifier circuit 19 Constant voltage circuit DESCRIPTION OF SYMBOLS 20 Control part 21 1st control part 22 2nd control part 23 Auxiliary power supply part for CPU operation 24 Auxiliary power supply part for contact opening / closing 2A Power monitoring part 2A
2B Power shortage response unit 2C Power shortage notification unit 2D Timer (counting unit)
30 Voltage detection circuit

Claims (4)

Two input terminals respectively connected to an AC power source and a load;
A series circuit of a switch element and a current transformer connected between the two input terminals;
When the switch element is connected in parallel to both ends of the switching element of the switch element and the switch element is in a non-conductive state using an alternating current flowing from the AC power source through the load when the switch element is in a non-conductive state. An off power supply unit that outputs DC power of
An on-power supply unit that is connected to the secondary side of the current transformer and outputs DC power when the switch element is in a conductive state using an alternating current that flows to the secondary side of the current transformer;
A controller that is driven by DC power output from the off-power supply unit and the on-power supply unit, and that controls conduction and non-conduction of the switch element based on operation information input from the outside;
The control unit monitors DC power output from the ON power supply unit, and does not control switching of the switch element from conduction to non-conduction when the DC power is less than a predetermined threshold. Two-wire load control device. Two input terminals respectively connected to an AC power source and a load;
A series circuit of a switch element and a current transformer connected between the two input terminals;
When the switch element is connected in parallel to both ends of the switching element of the switch element and the switch element is in a non-conductive state using an alternating current flowing from the AC power source through the load when the switch element is in a non-conductive state. An off power supply unit that outputs DC power of
An on-power supply unit that is connected to the secondary side of the current transformer and outputs DC power when the switch element is in a conductive state using an alternating current that flows to the secondary side of the current transformer;
A control unit that is driven by DC power output from the off power supply unit and the on power supply unit, and controls conduction and non-conduction of the switch element based on operation information input from the outside;
It has a counting unit that counts time,
The control unit monitors DC power output from the ON power supply unit, and executes predetermined power shortage handling processing when the DC power is less than a predetermined threshold, After switching from non-conduction to conduction, the DC power output from the ON power supply unit is not monitored while the counting unit counts a predetermined time . Two input terminals respectively connected to an AC power source and a load;
A series circuit of a switch element and a current transformer connected between the two input terminals;
When the switch element is connected in parallel to both ends of the switching element of the switch element and the switch element is in a non-conductive state using an alternating current flowing from the AC power source through the load when the switch element is in a non-conductive state. An off power supply unit that outputs DC power of
An on-power supply unit that is connected to the secondary side of the current transformer and outputs DC power when the switch element is in a conductive state using an alternating current that flows to the secondary side of the current transformer;
A control unit that is driven by DC power output from the off power supply unit and the on power supply unit, and controls conduction and non-conduction of the switch element based on operation information input from the outside;
It has a counting unit that counts time,
The control unit monitors DC power output from the ON power supply unit, and executes predetermined power shortage handling processing when the DC power is less than a predetermined threshold, After switching from non-conduction to conduction, the two-wire load control device does not execute the power shortage handling process while the counting unit counts a predetermined time . After switching to conduct the switching element from the non-conductive, while the counting unit counts the predetermined time, according to claim 3, characterized in that to enable switching control to switch from the connection of the switching element 2-wire load control device.

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