JP2011050149A - Load control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a load control device capable of performing advanced load control such as dimming control by correctly controlling an opening-closing timing, while suppressing heat generation of a switch element and miniaturizing the control device. <P>SOLUTION: In the load control device, a control unit 13 sets a main opening-closing conduction time to be counted so as to conduct a main opening-closing unit 11 of a transistor structure of 1/2 period in response to an operation input into an operation unit 28, and a voltage detection unit 18 conducts the main opening-closing unit 11 to control dimming only during the time when the first predetermined time counted from the time point when a voltage input into a third power supply unit 16 overlaps the main opening-closing conduction time. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a two-wire load control device connected in series between a load such as an AC power source and a lighting device.

  Conventionally, load control devices for lighting devices using contactless switching elements such as triacs and thyristors have been put into practical use. These load control devices generally have a two-wire connection from the viewpoint of reduced wiring, and are connected in series between a commercial AC power source and a load. Thus, in a load control device connected in series between an AC power supply and a load, how to secure its own circuit power supply becomes a problem.

  A load control device 50 of the first conventional example shown in FIG. 19 is connected in series between the AC power source 2 and the load 3, and includes a main opening / closing unit 51, a rectifying unit 52, a control unit 53, and a control unit 53. A first power supply unit 54 for supplying stable power, a second power supply unit 55 for supplying power to the first power supply unit 54 when power to the load 3 is stopped, and power supply to the load 3 are performed. The third power source unit 56 supplies power to the first power source unit 54 when it is connected, and an auxiliary opening / closing unit 57 that energizes a minute current in the load current. The switch element 51a of the main opening / closing part 51 is configured by a triac.

  In the off state of the load control device 50 in which no power is supplied to the load 3, the voltage applied from the AC power supply 2 to the load control device 50 is supplied to the second power supply unit 55 via the rectification unit 52. The second power supply unit 55 is a constant voltage circuit composed of a resistor and a Zener diode. The current flowing through the load 3 at this time is a minute current that does not cause the load 3 to malfunction, the current consumption of the control unit 53 is small, and the impedance of the second power supply unit 55 is set to be kept high.

  On the other hand, in the ON state of the load control device 50 in which power is supplied to the load 3, the third power supply unit 56 is turned on by the control signal from the control unit 53, and the impedance of the load control device 50 is lowered to reduce the load 3 As the amount of current flowing through the first power supply unit 56 increases, the current flowing through the third power supply unit 56 also flows through the first power supply unit 54 and starts charging the buffer capacitor 59. When the charging voltage of the buffer capacitor 59 becomes higher than a predetermined threshold value, the Zener diode 56a constituting the third power supply unit 56 breaks down and current starts to flow, current flows into the gate of the auxiliary switching unit 57, and the auxiliary switching unit 57 conducts (closed state). As a result, the current flowing from the rectifying unit 52 to the third power supply unit 56 is commutated to the auxiliary switching unit 57 and further flows into the gate of the switch element 51a of the main switching unit 51, and the main switching unit 51 becomes conductive (closed state). ). Therefore, almost all the electric power is supplied to the load 61. Once the main opening / closing part 51 becomes conductive (closed state), the current continues to flow. However, when the alternating current reaches the zero cross point, the switch element 51a self-extinguishes and the main opening / closing part 51 becomes non-conductive (open state). become. When the main opening / closing part 51 becomes non-conductive (open state), a current flows again from the rectifying part 52 through the third power supply part 56 to the first power supply part 54, and the operation for securing the self-circuit power supply of the load control device 50 is performed. . In other words, the self-circuit power supply securing of the load control device 50, the conduction of the auxiliary opening / closing part 57, and the conduction operation of the main opening / closing part 51 are repeated every half cycle of the alternating current.

  A load control device 60 of the second conventional example shown in FIG. 20 is connected in series between the AC power source 2 and the load 3, and includes a main opening / closing unit 61, a rectifying unit 62, a control unit 63, and a control unit 63. The first power supply unit 64 for supplying stable power, the second power supply unit 65 for supplying power to the first power supply unit 64 when the power to the load 3 is stopped, and the power supply to the load 3 are performed. The third power source unit 66 supplies power to the first power source unit 64 when the power source is disconnected, and the zero cross detection unit 67 detects the zero cross point of the load current. A MOSFET is used as the switch element 61a of the main opening / closing part 61, and an incandescent lamp is used as a load to be controlled.

  When power is supplied to the load 3, the switch element 61a is turned on at the timing when the zero-cross detector 67 detects the voltage zero-cross point (closed state), and the switch element 61a is turned off (open state) after the above period. . While the main opening / closing part 61 is non-conductive (open state), the self-circuit power supply of the load control device 60 is secured as in the first conventional example. When the main opening / closing part 61 is made non-conductive (open state), the zero cross detection part 67 again detects the zero cross point and repeats the operation of making the switch element 61a conductive (closed state) every half cycle of AC. .

  When the switch element of the main switching unit 51 is a triac or thyristor as in the load control device 50 of the first conventional example, to reduce noise generated when power is supplied to the load 3, and to supply power to the load 3. In order to prevent malfunction caused by noise propagated from the power supply 2 when stopping the operation, it is necessary to provide a filter. However, the size of the coil 58 constituting the filter and the heat generated by the coil become problems, and the load control device is downsized. Is difficult.

  In order to reduce noise caused by the load control device without using a filter, for example, in the load control device described in Patent Document 1 (third conventional example), in addition to the switch element of the main switching unit, The second switch unit having a larger on-resistance than the first switch unit is provided, and the first switch unit is turned on after the second switch unit is turned on. However, in the third conventional example, the number of switch elements increases, the circuit configuration becomes complicated, and the control of switch-on timing becomes complicated.

  Further, in the case where the switch element 61a of the main switching unit 61 has a transistor structure as in the load control device 60 of the second conventional example, an anti-phase control in which a current flows from the zero cross point and the current is cut off at a phase angle corresponding to dimming. It is said. In this case, the noise increases due to the need to cut off the energized current, but the noise is reduced by slowing down the cutoff speed by controlling the transistor. However, there is a problem that heat generation of the switch element is increased due to the switching loss generated at the time of the interruption.

  When the switch element 51a of the main switching unit 51 has a thyristor structure as in the load control device 50 of the first conventional example, the dimming control of the lighting device is performed by delaying the conduction of the switch element 51a using a variable resistor. be able to. However, the triac used as this switch element is made of Si, and a vertical type in which current flows in the vertical direction of the element is generally used. Since a PN junction exists in the energization path, a loss occurs due to overcoming this barrier during energization. Will occur. Due to this loss, the switch element itself generates a large amount of heat and requires a large heat sink, which hinders an increase in capacity and size of the load control device.

  In general, such a load control device is used by being housed in a metal box or the like provided on a wall surface. However, since there is a limit to downsizing of a conventional load control device, it is currently generally used. Depending on the size of the box used, the load control device cannot be used in combination with other sensors or switches. Therefore, further reduction in size of the load control device is required in order to allow the load control device and other sensors, switches, and the like to be provided in a box having a general size.

JP 2006-92859 A

  The present invention has been made in order to solve the above-described problems of the conventional example, and while controlling the heat generation of the switch element and reducing the size, the opening / closing timing is accurately controlled to provide advanced dimming control and the like. An object of the present invention is to provide a load control device capable of performing load control.

  In order to achieve the above object, the invention of claim 1 is a two-wire load control device connected in series between an AC power source and a load, comprising a switch element having a transistor structure, A main switching unit for controlling power supply; a switch element having a thyristor structure; an auxiliary switching unit for controlling power supply to a load when the main switching unit is non-conductive; and the main switching unit And a control unit that controls opening and closing of the auxiliary switching unit, a first power supply unit that is supplied with power from both ends of the main switching unit via a rectifying unit and supplies a stable voltage to the control unit, and the main switching unit A second power supply unit that supplies power to the first power supply unit when power is supplied from both ends of the power supply via the rectification unit and power supply to the load is stopped, and the main switching unit or the auxiliary switching unit Section is closed and supplying power to the load A third power source for supplying power to the first power source; a voltage detector for detecting a voltage input to the third power source; and an operation operated by a user to adjust a current flowing through the load. The controller sets a main opening / closing part conduction time that is counted to make the main opening / closing part conductive every half cycle of the AC power supply according to an operation input to the operation part. In addition, the voltage detection unit is the time when the first predetermined time counted from when the voltage input to the third power supply unit reaches a predetermined threshold and the main switching unit conduction time overlap each other. The main opening / closing part is electrically connected.

  The invention according to claim 2 is the load control device according to claim 1, further comprising a zero-cross detection unit that detects a zero-cross point of the load current, the control unit, after the zero-cross detection unit detects the zero-cross point, The main opening / closing part conduction time is counted after counting the main opening / closing part non-conduction time in which the main opening / closing part is non-conducting according to the operation input to the operation part.

  According to a third aspect of the present invention, in the load control device according to the first or second aspect, the control unit sets the auxiliary opening / closing part to a second predetermined opening when the main opening / closing part is switched from conduction to non-conduction. It is characterized by conducting for only time.

  According to a fourth aspect of the present invention, in the load control device according to the third aspect of the present invention, the load control device further includes a current detection unit that detects a current flowing through the auxiliary switching unit, and the control unit has a current equal to or greater than a predetermined threshold. The main opening / closing part is once brought into a conducting state when flowing into the part, and then the auxiliary opening / closing part is brought into conduction when the main opening / closing part becomes non-conducting.

  According to a fifth aspect of the present invention, in the load control device according to any one of the first to fourth aspects of the present invention, the load control device further includes a drive circuit that drives the main open / close section, and the main open / close section includes the AC power supply and It has a main switch element of a horizontal dual gate transistor structure which is connected in series to the load, has one gate to which a control voltage is applied to each connection point, and has a withstand voltage portion at one place. Features.

  According to a sixth aspect of the present invention, in the load control device according to the fifth aspect, the drive circuit is based on potentials at points connected to the AC power supply and the load, respectively, in accordance with a drive signal from the control unit. Then, the power electrically insulated from the control unit is supplied to the gate unit of the main switch element to drive the main switch element.

  A seventh aspect of the present invention is the load control device according to the sixth aspect, wherein the drive circuit is provided in two sets corresponding to the dual gate of the main switch element, and has a light emitting portion and a light receiving portion. The light emitting unit is connected to the control unit and a drive signal is input, and the light receiving unit performs photoelectric conversion when light output from the light emitting unit is incident, and is generated by the light receiving unit. The power is connected such that a positive potential is applied to the gate terminal of the main switch element with respect to the point where the AC power supply and the load are connected.

  The invention according to claim 8 is the load control device according to claim 6, wherein the drive circuit is provided in two sets corresponding to the primary side coil connected to the control unit and the dual gate of the main switch element. A transformer having two sets of secondary coils connected to the gate electrode of the main switch element through a rectifier circuit, and an AC current is supplied to the primary coil in accordance with a drive signal from the control unit. When a positive potential is applied to the gate terminal of the main switch element with reference to the point where the AC power supply and the load are connected by the power obtained by rectifying the electromotive force generated in the secondary coil. It is characterized by being applied.

  According to a ninth aspect of the present invention, in the load control device according to the fifth aspect, two sets of the drive circuits are provided corresponding to the dual gates of the main switch elements, respectively, and a diode connected to the first power supply unit and , One end connected to each power line, the other end connected between the capacitor connected to the diode, the connection point of the diode and the capacitor, and each gate terminal of the main switch element of the main switching unit A drive switch element is provided, and drive power is supplied to the main opening / closing section by making the drive switch element conductive by a signal from the control section.

  According to a tenth aspect of the present invention, in the load control device according to the ninth aspect, the drive switch element in the drive circuit includes a light emitting unit that outputs light according to a drive signal from the control unit, and a light output from the light emitting unit. Is a light-insulating semiconductor switch element configured to receive light and conduct, and when the light-receiving part conducts, the driving power is supplied to the main switching part using the power of the first power supply. It is characterized by.

  According to an eleventh aspect of the present invention, in the load control device according to the seventh or tenth aspect, the light emitting portions of the two optically insulated semiconductor switch elements in the drive circuit are connected in series.

  According to a twelfth aspect of the present invention, in the load control device according to any one of the ninth to eleventh aspects, the drive circuit is a connection point where the gate electrode of the main switch element and the drive switch element are connected. And a capacitor connected between the gate electrode and a power line serving as a reference of the gate electrode.

  A thirteenth aspect of the present invention is the load control device according to any one of the fifth or ninth to twelfth aspects, wherein the AC line of the rectifying unit is connected to the negative output point. It has a synchronous switch element connected between, and synchronizes with the operation | movement which the said main opening-and-closing part closes, The operation | movement which the said synchronous switch element closes is performed.

  According to a fourteenth aspect of the present invention, in the load control device according to the thirteenth aspect, the drive switch element has a thyristor or triac structure, and the drive switch element is a power source unit of the load control apparatus. It is driven by an isolated signal.

  According to the first aspect of the present invention, when the voltage detection unit detects that the voltage input to the third power supply unit has reached a predetermined threshold, the control unit causes the main opening / closing unit to conduct (close). Therefore, power is supplied from the main switching unit to the load for most of the half period of the AC power supply. In addition, since the continuity of the main opening / closing part is intermittently controlled in accordance with the operation input to the operation part, the load can be operated in a desired manner using a two-wire load control device to reduce power consumption. It becomes possible to plan. For example, when the load is a lighting device, the user can adjust the light to a desired brightness by operating the operation unit. Further, since the switch element of the main opening / closing part has a transistor structure, the load control device can be downsized with little heat generation.

  According to the invention of claim 2, by appropriately setting the main switching part non-conduction time, the time until the voltage input to the third power supply part reaches a predetermined threshold and the main switching part conduction time do not overlap. It can be. Thereby, intermittent conduction control of a load can be accurately performed according to a user's operation.

  According to the invention of claim 3, when the main opening / closing part is switched from conducting to non-conducting, the auxiliary opening / closing part is made to conduct for a predetermined time. After power is supplied from the unit to the load, power is supplied to the load from the auxiliary opening / closing unit after the energization current decreases. As a result, even if a transistor-type switching element is used for the main switching part, phase control that does not require current interruption is possible, the level of noise generated during operation of the load control device can be kept low, and switching loss is also reduced. Therefore, a small device can be realized.

  According to the invention of claim 4, when the current detection unit detects that the current exceeding the allowable value flows in the auxiliary opening / closing unit, the main opening / closing unit is once turned on (closed). The switch element can be constructed with a small switch element, and the load control device can be miniaturized. improves.

  According to the fifth aspect of the present invention, the structure of the main switch element of the main opening / closing section of the two-wire load control device is a dual which has a semiconductor chip configuration that is efficient for low loss (low resistance) in AC control. Due to the gate transistor structure, the load control device can be reduced in size and capacity.

  According to the sixth aspect of the present invention, it is possible to easily input a drive signal to the gate electrode of the main switching element of the main opening / closing part having a different reference potential, and to make the main switching element of the main opening / closing part conductive. .

  According to the invention of claim 7, the simple power source based on the potential of the power line can be configured with small and inexpensive components. Furthermore, the power to drive the main switch element can be sent with high efficiency without changing the power through the opto-isolated semiconductor switch element in which the light emitting part and the light receiving part are electrically insulated, so the dual gate transistor configuration The main switch element can be easily driven.

  According to the invention of claim 8, even when the main switching element of the main switching part is an element that needs to pass a current to the gate part when driving the main switching part, it is insulated from the internal power supply of the load control device. The generated power can be stably supplied to the gate portion. Therefore, it is possible to realize a small-sized and high-capacity two-wire load control device equipped with a low-loss dual gate switch element.

  According to the ninth aspect of the present invention, the simple power source based on the potential of the power line can be configured with small and inexpensive components. Furthermore, since the power for driving the main switch element can be sent with high efficiency without changing the power, it becomes possible to easily drive the main switch element having a dual gate transistor configuration.

  According to the invention of claim 10, the timing for driving the main opening / closing portion can be transmitted by the optically isolated semiconductor switching element, and the main switching element having the dual gate transistor configuration can be easily driven. It becomes possible.

  According to the eleventh aspect of the present invention, since the current consumption in the light emitting part of the optically insulated semiconductor switch element in the drive circuit can be reduced to about half, the power that must be secured when supplying power to the load can be reduced. , Stable operation can be realized.

  According to the twelfth aspect of the present invention, the noise generated by the operation of the main opening / closing section can be kept low, and the noise filter can be eliminated, so that it is inexpensive and small, and maintains a high impedance when the load control device is off. Is possible.

  According to the thirteenth aspect of the present invention, when the main opening / closing part is driven, even if the main switching element of the main opening / closing part requires an electric current to flow to the gate part, power is stably supplied to the gate part. can do. Therefore, it is possible to realize a small-sized and high-capacity two-wire load control device equipped with a low-loss dual gate switch element.

  According to the fourteenth aspect of the present invention, it is possible to suppress the power for driving the drive switch element for sending the drive power to the gate part of the main switch element of the main opening / closing part.

The circuit diagram which shows the structure of the load control apparatus which concerns on 1st Embodiment of this invention. The circuit diagram which shows the structure of the main opening / closing part applied to the apparatus. The time chart which shows the signal waveform of each part at the time of normal operation of the load control apparatus which concerns on 1st Embodiment. The time chart which shows the signal waveform of each part at the time of the light control operation | movement of the load control apparatus which concerns on 1st Embodiment. The circuit diagram which shows the structure of the load control apparatus which concerns on 2nd Embodiment of this invention. The time chart which shows the signal waveform of each part at the time of normal operation of the load control apparatus which concerns on 2nd Embodiment. The time chart which shows the signal waveform of each part at the time of the light control operation | movement of the load control apparatus which concerns on 2nd Embodiment. (A) is a circuit diagram of a main switch element of a horizontal dual gate transistor structure having one withstand voltage portion applied to the load control device according to the third embodiment of the present invention, and (b) is a reference example. The circuit diagram at the time of connecting two MOSFET type transistor elements in the reverse direction. The longitudinal cross-sectional view of the main switch element of a horizontal type dual gate transistor structure. The circuit diagram which shows the structure of the drive circuit applied to the load control apparatus which concerns on 3rd Embodiment of this invention. The circuit diagram which shows the modification of the drive circuit applied to the load control apparatus which concerns on 3rd Embodiment of this invention. The circuit diagram which shows the structure of the drive circuit applied to the load control apparatus which concerns on 4th Embodiment of this invention. The circuit diagram which shows schematic structure of the drive circuit applied to the load control apparatus which concerns on 5th Embodiment of this invention. The circuit diagram which shows the specific structural example of the drive circuit applied to the load control apparatus which concerns on 5th Embodiment of this invention. The circuit diagram which shows the modification of the drive circuit applied to the load control apparatus which concerns on 5th Embodiment of this invention. The circuit diagram which shows the other modification of the drive circuit applied to the load control apparatus which concerns on 5th Embodiment of this invention. The circuit diagram which shows the structure of the load control apparatus which concerns on 6th Embodiment of this invention. The circuit diagram which shows the structure of the drive circuit applied to the load control apparatus which concerns on 7th Embodiment of this invention. The circuit diagram which shows the structure of the load control apparatus which concerns on a 1st prior art example. The circuit diagram which shows the structure of the load control apparatus which concerns on a 2nd prior art example.

(First embodiment)
A load control device according to a first embodiment of the present invention will be described. FIG. 1 is a circuit diagram showing a configuration of a load control device 1A according to the first embodiment. FIG. 2 is a circuit diagram showing an example of the configuration of the main switching unit 11 applied to the load control device 1A. FIGS. 3 and 4 are time charts showing signal waveforms in each part of the load control device 1A.

  A load control device 1 </ b> A according to the first embodiment shown in FIG. 1 is connected in series between an AC power supply 2 and a load 3. , The rectifying unit 12, the control unit 13 for controlling the entire load control device 1A, the first power supply unit 14 for supplying stable power to the control unit 13, and the power supply to the load 3 when the power is stopped. A second power supply unit 15 for supplying power to the first power supply unit 14; a third power supply unit 16 for supplying power to the first power supply unit 14 when power is supplied to the load 3; The auxiliary opening / closing unit 17 for energizing a minute current, an AND circuit 27, and an operation unit 28 operated by a user are included. The drive circuit 10 drives the main opening / closing unit 11 according to the pulse signal output from the control unit 13. The third power supply unit 16 includes a voltage detection unit 18 that detects a voltage input to the third power supply unit 16 and a zero-cross detection unit 19 that detects a zero-cross point of the load current. The main opening / closing part 11 has a main switch element 11a having a single gate transistor structure (see FIG. 2), and the auxiliary opening / closing part 17 has an auxiliary switch element 17a having a thyristor structure. In addition, the control unit 13 is provided with a main control unit 20 including a CPU, a first pulse output unit 21, a second pulse output unit 22, and a dimming control pulse output unit 24.

  The main control unit 20 sets a main opening / closing part conduction time for conducting the main opening / closing part 11 in a half cycle of the AC power supply according to an operation input to the operation unit 28, and a dimming control pulse output unit The current flowing through the load 3 is intermittently controlled by controlling the drive circuit 10 by counting to 24. After receiving the charge completion signal for the buffer capacitor 29 from the voltage detection unit 18, the first pulse output unit 21 outputs a first pulse so that the main switching unit 11 is turned on for a first predetermined time. That is, the first pulse rises in response to a charge completion signal from the voltage detector 18 and falls after the first predetermined time has elapsed.

  The second pulse output unit 22 detects that the main opening / closing unit 11 has become non-conducting (open state), and then causes the auxiliary opening / closing unit 17 to conduct for a second predetermined period of time. Output a signal. That is, the second pulse rises upon detecting that the main opening / closing part 11 is turned off (open state), and falls after the elapse of the second predetermined time. The dimming control pulse output unit 24 counts the main opening / closing unit conduction time set by the main control unit 20 and outputs the dimming control pulse to the AND circuit 27.

  The operation unit 28 is operated by the user in order to adjust the current flowing through the load 3. The operation unit 28 includes a volume switch for the user to adjust the current flowing through the load 3. For example, when a lighting device is connected as the load 3, the user can adjust the light by operating the operation unit 28. Similarly, when the drive motor of the ventilation fan is connected as the load 3, the user can adjust the air volume of the ventilation fan by operating the operation unit 28.

  Even in the off state of the load control device 1A in which power supply to the load 3 is not performed, a current flows from the power source 2 to the second power source unit 15 via the rectifying unit 12, and therefore a minute current also flows to the load 3. However, the current is kept low enough not to cause the load 3 to malfunction, and the impedance of the second power supply unit 15 is maintained at a high value.

  When power is supplied to the load 3, the impedance of the third power supply unit 16 is lowered, a current is supplied to the circuit side inside the load control device 1 </ b> A, and the buffer capacitor 29 is charged. As described above, the third power supply unit 16 is provided with the voltage detection unit (charge monitoring unit) 18 and detects the voltage input to the third power supply unit 16, that is, the charging voltage of the buffer capacitor 29. When the charging of the buffer capacitor 29 is completed, the third power supply unit 16 is temporarily turned off, and the impedance of the third power supply unit 16 is lowered again in synchronization with the operation of the main opening / closing unit 11 and turned on.

  The voltage detection unit 18 is configured by, for example, a Zener diode and a transistor. When the voltage input to the third power supply unit 16 exceeds the Zener voltage of the Zener diode, the transistor is turned on, and a detection signal to that effect is input to the control unit 13 (first pulse output unit 21). During the normal operation, when receiving the detection signal from the voltage detection unit 18, the control unit 13 causes the main opening / closing unit 11 to be turned on (closed) for a first predetermined time. In FIG. 1, the first pulse output unit 21 configured in hardware using a dedicated IC or the like is used to directly output the first pulse signal in response to the detection signal from the voltage detection unit 18. The example of a structure provided as a part of control part 13 is shown. Alternatively, the configuration is not limited to the illustrated configuration, and the output from the voltage detection unit 18 may be input to the main control unit 20 configured by a CPU or the like, and the first pulse signal may be output in software. . The first predetermined time for conducting the main opening / closing part 11 is preferably set to a time slightly shorter than a half cycle of the commercial frequency power supply.

Next, when the main opening / closing part 11 starts an operation of becoming non-conductive (open state) after the first predetermined time has elapsed, the control unit 13 opens the auxiliary opening / closing part 17 for the second predetermined time (for example, several hundred μm). For 2 seconds). This operation may be performed as long as the auxiliary opening / closing part 17 becomes non-conductive (open state) slightly later than the main opening / closing part 11. Alternatively, the main control unit 20 may output a pulse signal to the auxiliary opening / closing unit 17 that is longer than the first pulse signal output to the main opening / closing unit 11 by a second predetermined time. Alternatively, the delay circuit may be configured using a diode or a capacitor.

  With these operations, after charging of the buffer capacitor 29 is completed, power is supplied to the load 3 from the main switching unit 11 for most of the half cycle of the commercial AC power supply, and then the energization current decreases. Then, electric power is supplied from the auxiliary opening / closing unit 17 to the load 3. Since the auxiliary opening / closing section 17 includes the auxiliary switch element 17a having a thyristor structure, the auxiliary opening / closing section 17 becomes non-conductive (open state) when the current value becomes zero (zero cross point). When the auxiliary opening / closing part 17 becomes non-conductive (open state), since the current flows again into the third power supply part 16, the above operation is repeated every 1/2 cycle of the commercial power supply.

  FIG. 3 shows signal waveforms in each part of the load control device 1A during normal operation, and FIG. 4 shows signal waveforms in each part of the load control device 1A during dimming operation. During normal operation, that is, when the lighting device as the load 3 is not dimmed, a high signal is always output from the dimming control pulse output unit 24 as shown in FIG. After the completion, power is supplied from the main switching unit 11 to the load 3 for most of the half period of the commercial power supply. At this time, since the first predetermined time is set so that the main opening / closing part 11 is turned off before the time when the current value becomes zero (zero crossing point), the main opening / closing part 11 exceeds the zero crossing point. There is no conduction.

  After that, the second pulse output unit 22 that has received the first pulse signal sends a second pulse signal to the auxiliary opening / closing unit 17 that makes the auxiliary opening / closing unit 17 conductive only for a second predetermined time when the main opening / closing unit 11 becomes non-conductive. The power is output from the auxiliary opening / closing unit 17 to the load 3.

  On the other hand, when the operation unit 28 is operated during the dimming operation, that is, when the lighting device as the load 3 is dimmed, the dimming control pulse signal as shown in FIG. Is output. The dimming control pulse signal has a low signal output over the main opening / closing part non-conduction time and a high signal output over the main opening / closing part conduction time. The main opening / closing part non-conduction time is counted after the zero cross detection part 19 detects the zero cross point. The main opening / closing part conduction time is continuously counted after counting the main opening / closing part non-conduction time.

  The dimming control pulse signal output from the dimming control pulse output unit 24 is input to the AND circuit 27. The AND circuit 27 calculates the logical product of the first pulse signal output from the first pulse output unit 21 and the dimming control pulse signal output from the dimming control pulse output unit 24, thereby obtaining a main switching unit drive signal. And is output to the main opening / closing part 11 through the drive circuit 10. Thereby, the first predetermined time counted from when the voltage detection unit 18 detects that the voltage input to the third power supply unit 16 has reached a predetermined threshold, and when the zero cross detection unit 19 detects a zero cross. The main opening / closing part 11 is turned on only during the time when the main opening / closing part conduction time counted from the above overlaps, the current flowing through the load 3 is intermittently controlled, and the load 3 is dimmed. Since the subsequent operations of the second pulse output unit 22 and the auxiliary opening / closing unit 17 are the same as those in the normal operation shown in FIG. 3, the description thereof is omitted.

  According to the load control device 1A according to the first embodiment, during normal operation, when the voltage detection unit 18 detects that the voltage input to the third power supply unit 16 has reached a predetermined threshold value, the control unit 13 makes the main opening / closing part 11 conductive (closed) for a first predetermined time, so that power is supplied from the main opening / closing part 11 to the load for most of the half cycle of the AC power supply. . Further, during the dimming operation, the conduction of the main opening / closing unit 11 is intermittently controlled according to the operation input to the operation unit 28. Therefore, a desired load can be applied to the load using a two-wire load control device. It is possible to reduce power consumption by operating. For example, when the load 3 is a lighting device, the user can adjust the light to a desired brightness by operating the operation unit 28. In addition, after the zero-cross detection unit 19 detects the zero-cross point, the main opening / closing part non-conduction time is counted and then the main opening / closing part conduction time is counted. The time until the voltage input to the power supply unit 16 reaches a predetermined threshold and the main switching unit conduction time may not overlap. Thereby, intermittent conduction control of a load can be accurately performed according to a user's operation. Further, since the main switch element 11a of the main opening / closing part 11 has a transistor structure, the load control device with less noise and less heat generation can be downsized.

  Further, when the main opening / closing part 11 becomes non-conductive after the first predetermined time has elapsed, the auxiliary opening / closing part 17 is made conductive only for the third predetermined time to supply electric power from the auxiliary opening / closing part 17 to the load 3. Thereby, even if a transistor element is used as the main switch element 11a of the main opening / closing part 11, phase control that does not require interruption of current is possible, and the level of noise generated during operation of the load control device can be suppressed low. Since switching loss is also reduced, a small device can be realized.

(Second Embodiment)
A load control device according to a second embodiment of the present invention will be described. FIG. 5 is a circuit diagram showing a configuration of a load control device 1B according to the second embodiment. FIGS. 6 and 7 are time charts showing signal waveforms in each part of the load control device 1A. The load control device 1B is different from the load control device 1A according to the first embodiment in that it further includes a third pulse output unit 23, an AND circuit 25a, a current detection unit 26, and an OR circuit 25b. It is the same.

  When a low-capacity load such as a miniature bulb is connected as the load 3, it takes a lot of time to charge the buffer capacitor 29 because the load current is small. For this reason, the time from when the zero cross detection unit 19 detects the zero crossing until the voltage detection unit 18 detects the completion of charging becomes longer, and the rise of the first pulse is delayed. Since the first predetermined time is set on the assumption that the above-described high-capacity load is connected, if the rising edge of the first pulse is excessively delayed, the first current is exceeded after the load current exceeds the zero cross point. The pulse falls. Therefore, in the case of controlling the main switching unit 11 using only the first pulse and the dimming control pulse, the main switching unit 11 is turned on beyond the zero cross point at low load, and charging is performed every half cycle. Operation is not stable.

  Therefore, in the present embodiment, as shown in FIGS. 6 and 7, the third pulse output from the third pulse output unit 23 is used to limit the open state of the main opening / closing unit 11 in the third predetermined time. I am going to call. The third pulse output unit 23 outputs the third pulse so as to limit the open state of the main opening / closing unit 11 for a third predetermined time after the zero cross detection unit 19 detects the zero cross point of the power supply current. In other words, the third pulse rises in response to the zero-cross detection signal from the zero-cross detection unit 19 and falls after the elapse of a third predetermined time shorter than the half cycle of the load current. The AND circuit 25 a calculates the logical product of the first pulse signal output from the first pulse output unit 21 and the third pulse signal output from the third pulse output unit 23 and outputs the logical product to the AND circuit 27. The OR circuit 25 b generates a main opening / closing part drive signal by taking the logical sum of the signal output from the current detection part 26 and the signal output from the AND circuit 7, and supplies the main opening / closing part 11 to the main opening / closing part 11 via the drive circuit 10. Output.

  By these operations, the main switching unit 11 causes the first predetermined time for the first pulse to rise, the third predetermined time for the third pulse to rise, and the main switching unit conduction time for the dimming control pulse to rise. It closes only when it overlaps. As described above, the third pulse rises at the timing when the zero-cross detection unit 19 detects the zero-cross point, and falls in the third predetermined period shorter than the half cycle of the load current. Therefore, the completion of charging of the buffer capacitor 29 is detected. Even when the timing, i.e., the timing at which the first predetermined time starts later, shifts beyond the zero cross point of the power supply frequency, the main opening / closing part 11 is not closed. Thereby, it can charge reliably for every half cycle and the operation | movement stability is achieved.

  The auxiliary opening / closing part 17 is originally intended to detect a zero-cross point of the current, and is not intended to be energized, and is expected to be composed of a small switch element. However, if the frequency shifts in the commercial power supply or if the load control device is to be operated with both 50 Hz and 60 Hz, the time from when the main switching unit becomes non-conductive until the zero cross point of the current becomes long, the load Energization of the auxiliary opening / closing part is started before the current becomes sufficiently small. In addition, when an overload connection is made as a load, even if the energization time in the auxiliary opening / closing part is the same, the energization loss may increase, and the switch element constituting the auxiliary opening / closing part 17 may be damaged. Therefore, in the second embodiment, the current detection unit 26 detects the current value flowing through the auxiliary opening / closing unit 17, and when a current exceeding the allowable current value of the auxiliary opening / closing unit 17 flows again (for the fourth predetermined time). The main opening / closing part 11 is made conductive (closed) only for a period of time, and then the auxiliary opening / closing part 17 is made conductive again when the main opening / closing part 11 becomes non-conductive (open state).

  More specifically, the current detection unit 26 that has detected that the current exceeding the allowable current value of the auxiliary opening / closing unit 17 flows, outputs a signal to that effect to the OR circuit 25b. When receiving either the output signal from the AND circuit 25a or the output signal from the current detection unit 26, the OR circuit 25b makes the main switching unit 11 conductive for a short time to protect the auxiliary switching unit 17. To do. By repeatedly switching the main opening / closing part 11 and the auxiliary opening / closing part 17 in this way, the auxiliary switch element 17a of the auxiliary opening / closing part 17 is prevented from being damaged, and the compatibility with the type of commercial power source and the overload are improved. .

  According to the load control device 1B according to the second embodiment, when the third predetermined time has elapsed even within the first predetermined time, the control unit 13 makes the main opening / closing unit 11 non-conductive. Even if the timing at which the first predetermined time is started during the load is delayed, the main switching unit 11 is turned off before the load current becomes zero. As a result, the main switching unit 11 is not conducted beyond the zero cross of the load current, so that charging can be reliably performed during the half cycle of the AC power supply, and the operation for each half cycle can be stabilized. it can. Further, when the current detection unit 26 detects that a current exceeding the allowable value flows through the auxiliary opening / closing unit 17, the main opening / closing unit is temporarily turned on (closed), and then is turned off. As a result, the switch element of the auxiliary opening / closing part 17 can be prevented from being damaged, and the auxiliary opening / closing part 17 can be configured with a small switch element, so that the load control device can be miniaturized, and the compatibility with the type of commercial power supply And improved response to overload.

(Third embodiment)
A load control device according to a third embodiment of the present invention will be described. The load control device according to the third embodiment includes a dual-gate transistor main switch element (shown in FIG. 8) and the load control device 1A according to the first embodiment and the load control device 1B according to the second embodiment. The drive circuit 10 is applied.

  First, the main switch element used in the load control device described below will be described. This main switch element is different from the above-described conventional example in that it is a main switch element having a horizontal dual gate transistor structure having one withstand voltage portion. FIG. 8A shows a circuit diagram of a main switch element having a horizontal dual gate transistor structure with one withstand voltage portion, and FIG. 8B shows two reference examples as in the second conventional example. The circuit diagram at the time of reversely connecting a MOSFET type transistor element is shown. FIG. 9 shows a vertical cross-sectional configuration of a main switch element having a horizontal dual gate transistor structure.

  In the conventional configuration shown in FIG. 8B, the source electrodes S of the two transistor elements are connected to each other and grounded (lowest potential portion), and the withstand voltage is between the source electrode S and the gate electrodes G1 and G2. Is required, and a withstand voltage is required between the gate electrodes G1 and G2 and the drain electrodes D1 and D2, so two withstand voltage portions (for example, a withstand voltage distance are opened) are required. Since the two transistor elements operate with a gate signal based on the source electrode, they can be driven by inputting the same drive signal to the gate electrodes G1 and G2 of each transistor element. On the other hand, as shown in FIG. 9, the main switch element having a horizontal dual gate transistor structure has a structure that realizes a bidirectional element with a small loss, with only one part maintaining the withstand voltage. In such a configuration, the heat generation amount of the main switch element itself during energization of the load 3 can be reduced, and the load control device can be reduced in size and increased in capacity at the same time. On the other hand, the element having this configuration needs to be controlled with reference to the voltages of the drain electrodes D1 and D2, and it is necessary to input different drive signals to the two gate electrodes G1 and G2, respectively. Call).

  Next, the drive circuit 10 applied in the load control apparatus according to the third embodiment will be described with reference to FIG. The drive circuit 10 for driving the main opening / closing section 11 is composed of optically-insulating semiconductor switch elements 101 and 102 such as photocouplers provided corresponding to the dual gate of the main switch element 11a. Drive signals from the control unit 13 are input to the light emitting units 101a and 102a of the optically insulated semiconductor switch elements 101 and 102, respectively. When the drive signal is input, the light emitting units 101a and 102a of the optically insulated semiconductor switch elements 101 and 102 convert the power into light energy and output the light energy. When light from the light emitting portions 101a and 102a enters the light receiving portions 101b and 102b of the optically insulated semiconductor switch elements 101 and 102, photoelectric conversion is performed by the light receiving portions 101b and 102b to convert light energy into electric energy (that is, power generation). To do. The light receiving units 101b and 102b are configured so that the power generated by the light receiving units 101b and 102b is based on the point where the AC power source (commercial power source) and the load are connected to each other (see FIG. 8A). The gate portion is connected so that a positive potential is applied.

  By outputting a drive signal from the control unit 13 and causing the light emitting units 101a and 102a of the optically insulated semiconductor switch elements 101 and 102 to emit light, the gate electrode of the main switch element 11a of the main switching unit 11 having a different reference potential is easily driven. A signal can be input, and the main switch element 11a of the main opening / closing part 11 can be turned on (closed state). Since the light emitting units 101a and 102a and the light receiving units 101b and 102b of the optically insulated semiconductor switch elements 101 and 102 are electrically insulated, unless the light is output from the light emitting units 101a and 102a, the main switch element 11a No drive signal is input to the gate electrode. That is, the electrically insulated power from the control unit 13 (or the first power supply unit 14 of the load control device 1A) different from the drive signal output from the control unit 13 is supplied to the gate electrode of the main switch element 11a. Is done. Further, based on the drive signal from the control unit 13, the optically insulated semiconductor switch elements 101 and 102 connected to the gate electrode of the main switch element 11a can be turned on and off easily and reliably while maintaining insulation. it can.

  FIG. 11 shows a modification of the drive circuit 10 shown in FIG. In this modification, the light emitting portions 101a and 102a of the optically insulated semiconductor switch elements 101 and 102 such as photocouplers are connected in series. Thereby, the value of the current flowing through the drive circuit 10 can be reduced to about ½, and the power consumption in the drive circuit 10 can be reduced.

(Fourth embodiment)
Next, a load control device according to a fourth embodiment of the present invention will be described. The load control device according to the fourth embodiment is different from the load control device according to the third embodiment in that the drive circuit 10 shown in FIG. 12 is applied instead of the drive circuit 10 shown in FIG.

  In the fourth embodiment, the drive circuit 10 of the main switching unit 11 includes a transformer (electromagnetic coupling element) 103 that transmits electric power by electromagnetic coupling, such as a high-frequency insulating transformer, rectifier circuits 104a and 104b, an oscillation circuit 105, and the like. Yes. The primary coil 103 a of the transformer 103 is connected to the oscillation circuit 105, and the oscillation circuit 105 is further connected to the control unit 13. When the drive signal from the control unit 13 is input to the oscillation circuit 105, the oscillation circuit 105 oscillates and generates AC power only while the drive signal is applied. When an alternating current generated by the oscillation circuit 105 flows through the primary side coil 103a of the transformer 103, an electromotive force is generated in the secondary side coils 103b and 103c by electromagnetic induction. Since the electromotive force generated in the coils 103 b and 103 c on the secondary side of the transformer 103 is alternating current, it is rectified by the rectifier circuits 104 a and 104 b and then input to the gate electrode of the main switch element 11 a of the main switching unit 11. The rectifier circuits 104a and 104b are connected so that a positive potential is applied to the gate electrode of the main switch element 11a with reference to the point where the AC power supply and the load are connected. In addition, since the primary side coil 103a and the secondary side coils 103b and 103c of the transformer 103 are electrically insulated, the gate electrode of the main switch element 11a is used as long as no current flows through the primary side coil 103a of the transformer 103. No drive signal is input to. That is, the electrically insulated power from the control unit 13 different from the drive signal output from the control unit 13 is supplied to the gate electrode of the main switch element 11a.

  As described above, in the fourth embodiment, the AC power is generated by the oscillation circuit 105 using the drive signal output from the control unit 13 as a trigger. Therefore, the oscillation frequency and amplitude in the oscillation circuit 105, and the primary of the transformer 103 are generated. By appropriately setting the number of windings of the side coil 103a and the secondary side coils 103b and 103c, desired power can be generated in the secondary side coils 103b and 103c of the transformer 103. Therefore, even if the gate part of the main switch element 11a of the main opening / closing part 11 is a current type main switch element that requires a certain current value or more, it can be driven stably. Needless to say, the driving power of the oscillation circuit 105 is supplied from one of the power supply units of the load control device. Alternatively, although not shown, the oscillation circuit 105 may be omitted and a pulse signal having a predetermined frequency and a predetermined amplitude may be directly output from the control unit 13.

(Fifth embodiment)
Next, a load control device according to a fifth embodiment of the present invention will be described. The load control device according to the fifth embodiment is different from the load control device according to the third embodiment in that the drive circuit 10 shown in FIG. 13 is applied instead of the drive circuit 10 shown in FIG.

  As shown in FIG. 13, two sets of driving circuits 10 for driving the main switching unit 11 are provided corresponding to the dual gates of the main switch element 11a, and are connected to the first power supply unit 14 of the load control device. Diodes 201a and 201b, capacitors 202a and 202b having one ends connected to the respective power lines and the other ends connected to the diodes 201a and 201b, connection points of the diodes 201a and 201b and the capacitors 202a and 202b, and the main switching unit 11 The drive switch elements 203a and 203b are connected to each gate terminal of the main switch element 11a. The drive switch elements 203a and 203b are turned on / off by a signal from the control unit 13. Further, the drive switch elements 203a and 203b have a configuration in which the switch unit and the operation unit are insulated. The configuration of the drive switch elements 203a and 203b is not particularly limited, and various types can be used as described below.

  According to this configuration, the first power supply unit 14 of the load control device is connected to the other ends of the capacitors 202a and 202b, one end of which is connected to the power line, via the diodes 201a and 201b. A simple power supply is configured by the capacitors 202a and 202b. Charging to the capacitors 202a and 202b is performed by connecting the current flowing from the high power supply voltage side of the power line to the low voltage power line via the internal power supply of the load control device to the low voltage side. This is done by charging a capacitor. At that time, since the capacitor connected to the higher voltage side is not charged, the capacitor is repeatedly charged every cycle of the power supply frequency. The capacitor on the opposite side is charged at a timing opposite to that described above in relation to the potential of the power line.

  When the main switch element 11a having the horizontal dual gate transistor structure is turned on from off, it is necessary to apply a voltage to the gate of the main switch element 11a on the basis of the point where the power line is connected (see FIG. 8). . Here, when the drive switch element 203a or 203b connected to the gate electrode of the main switch element 11a of the main switching unit 11 is turned on by a signal from the control unit 13, a power line is connected to each gate terminal of the main switch element 11a. Since the charged voltage is applied to the reference capacitor, the main switch element 11a becomes conductive (closed). Once the main switch element 11a is turned on, the voltage across the terminals of the main switch element 11a becomes very small and is applied from the power supply of the load control device via the diodes 201a and 201b and the drive switch elements 203a and 203b. Conductivity can be maintained with voltage.

  In this embodiment, since the drive circuit 10 is configured to be non-insulated from the first power supply unit 14, it is possible to supply drive power with high efficiency. Since the capacitors 202a and 202b only need to temporarily determine the potential of the gate electrode when the main switch element 11a is turned on from off, the shape and capacity of the capacitors 202a and 202b may be small. Note that power is supplied to the drive circuit 10 from a relatively stable power supply unit such as an input or output of the first power supply unit 14.

  FIG. 14 shows a specific configuration example of the drive circuit 10, and optically insulated semiconductor switch elements such as photocouplers and photorelays are used as the drive switch elements 203 a and 203 b. When a drive signal from the control unit 13 is input, an optical signal is output from the light emitting unit of the optically insulated semiconductor switch element. When the optical signal is incident on the light receiving unit, the light receiving unit conducts, and from the first power supply unit 14 Current (drive signal) flows. Since the light emitting unit and the light receiving unit are electrically insulated, no drive signal is input to the gate electrode of the main switch element 11a unless light is output from the light emitting unit. Therefore, based on the drive signal from the control unit 13, the drive switch elements 203a and 203b connected to the gate electrode of the main switch element 11a can be turned on / off easily and reliably while maintaining insulation.

  FIG. 15 shows a modification of the drive circuit 10 shown in FIG. In this modification, the light emitting portions of the drive switch elements 203a and 203b using photo-insulating semiconductor switch elements such as photocouplers and photorelays are connected in series. Thereby, the value of the current flowing through the drive circuit 10 can be reduced to about ½, and the power consumption in the drive circuit 10 can be reduced.

  FIG. 16 shows another modification of the drive circuit 10 shown in FIG. In this modification, the light emitting parts of the drive switch elements 203a and 203b using photo-insulating semiconductor switch elements such as photocouplers and photorelays are connected in series, and the gate electrode of the main switch element 11a of the main switching part 11 Capacitors 204a and 204b are connected between a connection point to which the drive switch elements 203a and 203b are connected and a power line serving as a reference for the gate electrode. Note that capacitors 204a and 204b may be added to the configuration example of the drive circuit 10 shown in FIG.

  As shown in this modification, when the drive switch elements 203a and 203b are turned on / off by adding the capacitors 204a and 204b, the capacitors 204a and 204b are applied to the gate electrode of the main switch element 11a. A sudden change in voltage can be mitigated, and the main switch element 11a can be prevented from turning on and off rapidly. As a result, noise generated when the main switch element 11a of the main opening / closing part 11 is turned on / off can be reduced, so that the noise filter can be reduced or omitted. That is, as compared with the configuration of the conventional example shown in FIG. 19 or FIG. 20, the coil and the capacitor that function as a noise filter can be omitted.

  Regarding the coil constituting the noise filter, as the rated current of the load control device increases, this coil also increases in size. Therefore, if the coil can be omitted, the load control device can be reduced in size. In addition, regarding the capacitor constituting the noise filter, there are few restrictions on the size of the load control device compared to the coil, but the presence of this capacitor reduces the impedance of the load control device when the load control device is off. This is not preferable as an off state of the load control device. Also, even when the load control device is off, an alternating current flows through the capacitor, which may cause the load to malfunction. Therefore, if the capacitor for the noise filter can be omitted from the load control device, it is a preferable form for the two-wire load control device.

(Sixth embodiment)
Next, a load control device according to a sixth embodiment of the present invention will be described. In the load control device according to the fifth embodiment, when a drive signal is applied to the main switch element 11a of the main switching unit 11, the current does not flow due to the diode of the rectifier unit 12, and therefore the main switch element 11a Only the voltage type whose gate part (gate terminal) does not require a certain current value or more can be handled. Therefore, in the sixth embodiment, even when the main switch element 11a of the main opening / closing part 11 is a current-type main switch element that requires a certain current value or more, it can be driven stably. is there.

  As shown in FIG. 17, in the load control device 1C according to the sixth embodiment, the synchronous switch elements 120a and 120b are connected between the AC line of the rectifying unit 12 and the negative side output of the rectifying unit serving as a circuit reference. In synchronization with the operation of closing the main opening / closing section 11, the operation of turning on the synchronous switch elements 120a and 120b is performed. When the synchronous switch elements 120a and 120b are closed in synchronization with the operation of closing the main opening / closing part 11, the first power supply part 14 in the load control device 1C is connected to the gate part of the main switching element 11a of the main opening / closing part 11. A path for passing current is formed. Therefore, even if the gate part of the main switch element 11a is a dual gate element that requires current, it can be driven stably. Other configurations and basic operations are the same as in the case of the fifth embodiment, and the configuration of the drive circuit 10 is not particularly limited, and the basic configuration and modifications of the fifth embodiment can be applied. .

(Seventh embodiment)
Next, a load control device according to a seventh embodiment of the present invention will be described. The load control device according to the seventh embodiment is different from the load control device according to the sixth embodiment in that the drive circuit 10 shown in FIG. 18 is applied instead of the drive circuit 10 shown in FIG.

  In the load control device according to the seventh embodiment, the drive circuit 10 of the main switching unit 11 includes high-breakdown-voltage diodes 201a and 201b connected to the first power supply unit 14 of the load control device, and one end connected to each power line. The other ends of the capacitors 202a and 202b connected to the diodes 201a and 201b, and the connection points between the diodes 201a and 201b and the capacitors 202a and 202b and the gate terminals of the main switch element 11a of the main switching unit 11 are connected. It is composed of self-extinguishing type drive switch elements 205a and 205b such as a photothyristor or a phototriac.

  When charging completion is detected by the voltage detection unit 18 provided in the third power supply unit 16, the operation moves to the operation of closing the main opening / closing unit 11. At that time, a signal is inputted to make the drive switch elements 205a and 205b connected to the gate electrode of the main switch element 11a of the main opening / closing part 11 conductive, and these drive switch elements 205a and 205b have a thyristor or triac structure. Therefore, the drive switch elements 205a and 205b need only be driven by the trigger signal. Therefore, the drive power of the drive switch elements 205a and 205b can be made smaller than those of the above embodiments. Further, in order to make the drive switch elements 205a and 205b non-conductive, it is only necessary to open the synchronous switch elements 120a and 120b provided in the rectifying unit 12, and the drive power for opening and closing the main switching unit 11 is reduced. It becomes possible. For a two-wire load control device, how to enable load control while ensuring a stable power supply is an important issue, so that the drive power of the load control device is small for stable operation of the load. desirable.

  Note that the present invention is not limited to the configuration of the above-described embodiment, and is counted in order to make the main switching unit 11 conductive in a half cycle of the AC power supply in accordance with at least an operation input to the operation unit 28. The main opening / closing portion conduction time is set, and the first predetermined time counted from when the voltage input to the third power supply portion 16 reaches a predetermined threshold by the voltage detection unit 18 overlaps with the main opening / closing portion conduction time. It is sufficient that the dimmer control is performed by causing the main opening / closing part 11 to conduct only during the time during which the main opening / closing part 11 is conducted. The present invention can be modified in various ways. For example, the second pulse is input to the main control unit 20 constituted by a CPU or the like as the output from the zero-cross detection unit 19 and is output as software. It may be configured.

1A, 1B, 1C Load control device 2 Power supply 3 Load 11 Main switching unit 11a Main switch element 12 Rectifier 13 Control unit 14 First power supply unit 15 Second power supply unit 16 Third power supply unit 17 Auxiliary switching unit 17a Auxiliary switch element 18 Voltage detection unit 19 Zero cross detection unit 20 Main control unit (control unit)
21 First pulse output unit (control unit)
22 Second pulse output unit (control unit)
23 Third pulse output unit (control unit)
24 Dimming pulse output unit (control unit)
26 Current detection unit 28 Operation unit

Claims (14)

A two-wire load control device connected in series between an AC power source and a load,
A main switching unit having a transistor-structure switch element and controlling supply of power to a load;
An auxiliary opening / closing part that has a switch element of a thyristor structure and controls supply of power to a load when the main opening / closing part is non-conductive;
A control unit that controls opening and closing of the main opening and closing unit and the auxiliary opening and closing unit;
A first power supply unit that is supplied with power from both ends of the main switching unit via a rectification unit and supplies a stable voltage to the control unit;
A second power supply unit that supplies power to the first power supply unit when power is supplied from both ends of the main opening / closing unit via the rectification unit and power supply to the load is stopped;
A third power supply for supplying power to the first power supply when the main switch or the auxiliary switch is in a closed state and supplying power to a load;
A voltage detection unit for detecting a voltage input to the third power supply unit;
An operation unit operated by a user to adjust the current flowing through the load;
The controller is
In accordance with an operation input to the operation unit, a main switching unit conduction time that is counted to conduct the main switching unit every half cycle of the AC power supply is set,
The main detector is only in a time during which the first predetermined time counted from when the voltage input to the third power source reaches a predetermined threshold and the main opening / closing portion conduction time overlap. A load control device characterized in that an opening / closing part is conducted. It further includes a zero cross detection unit that detects the zero cross point of the load current,
The control unit, after the zero cross detection unit has detected a zero cross point, in accordance with an operation input to the operation unit, after counting the main opening and closing unit non-conduction time to make the main opening and closing unit non-conductive, The load control device according to claim 1, wherein the main opening / closing portion conduction time is counted.   3. The load control device according to claim 1, wherein the control unit causes the auxiliary opening / closing part to conduct for a second predetermined time when the main opening / closing part is switched from conduction to non-conduction. . A current detection unit for detecting a current flowing through the auxiliary opening / closing unit;
When a current of a predetermined threshold value or more flows through the auxiliary opening / closing part, the control unit temporarily turns the main opening / closing part on, and then turns on the auxiliary opening / closing part when the main opening / closing part becomes non-conductive. The load control device according to claim 3, wherein: A drive circuit for driving the main opening and closing unit;
The main switching part is connected in series to the AC power supply and the load, has a single gate to which a control voltage is applied to each connection point, and a horizontal dual gate having a withstand voltage part. 5. The load control device according to claim 1, further comprising a main switch element having a transistor structure. 6.   In response to a drive signal from the control unit, the drive circuit uses, as a reference, a potential at a point connected to each of the AC power supply and the load, and the power electrically isolated from the control unit, The load control device according to claim 5, wherein the main switch element is driven by supplying the gate part of the main switch element.   Two sets of the drive circuits are provided corresponding to the dual gates of the main switch elements, and are constituted by optically insulated semiconductor switch elements having a light emitting part and a light receiving part, and the light emitting part is connected to the control part to drive signals. When the light output from the light emitting unit is incident, the light receiving unit performs photoelectric conversion, and the electric power generated by the light receiving unit is based on the point where the AC power supply and the load are connected, respectively. The load control device according to claim 6, wherein the load control device is connected so that a positive potential is applied to a gate terminal of the main switch element.   The drive circuit is provided in two sets corresponding to the primary side coil connected to the control unit and the dual gate of the main switch element, and is connected to the gate electrode of the main switch element via a rectifier circuit. Consists of a transformer having two sets of secondary coils, and rectifies the electromotive force generated in the secondary coil when an alternating current flows through the primary coil in response to a drive signal from the controller. The load control device according to claim 6, wherein a positive potential is applied to the gate terminal of the main switch element with reference to a point at which the AC power supply and the load are connected as a reference.   Two sets of the drive circuits are provided corresponding to the dual gates of the main switch element, the diode connected to the first power supply unit, one end connected to each power line, and the other end connected to the diode. And a drive switch element connected between a connection point of the diode and the capacitor and each gate terminal of the main switch element of the main switching unit, and the drive switch element is a signal from the control unit. The load control device according to claim 5, wherein driving electric power is supplied to the main opening and closing unit by conducting the electric power to the main opening / closing portion. The drive switch element in the drive circuit is an optically isolated semiconductor switch element configured by a light emitting unit that outputs light according to a drive signal from the control unit and a light receiving unit that receives and conducts light output from the light emitting unit. Yes,
10. The load control device according to claim 9, wherein when the light receiving unit is turned on, driving power is supplied to the main switching unit using power of the first power source.   11. The load control device according to claim 7, wherein the light emitting units of the two optically isolated semiconductor switch elements in the drive circuit are connected in series.   The drive circuit further includes a capacitor connected between a connection point where the gate electrode of the main switch element and the drive switch element are connected, and a power line serving as a reference of the gate electrode. The load control device according to any one of claims 9 to 11.   The synchronous switch element is connected between the point where the AC line of the rectifying unit is connected and the negative output point thereof, and the synchronous switch element is synchronized with the operation of closing the main opening / closing unit. The load control device according to any one of claims 5 or 9 to 12, wherein a closing operation is performed.   The drive switch element has a thyristor or triac structure, and the drive switch element is driven by a signal insulated from any power supply unit of the load control device. Load control device.

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