JP3855159B2 - Incorrect wiring protection device and equipment equipped with erroneous wiring protection device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a device such as a bus drying fan, and more particularly to a device including actuators driven by two power sources having different voltages.
[0002]
[Prior art]
FIG. 7 is a circuit diagram showing a configuration of a conventional erroneous connection protection circuit described in, for example, Japanese Patent Laid-Open No. 4-127835.
In FIG. 7, reference numeral 216 denotes a constant voltage diode which is a voltage detecting means whose one end is connected to one side of the secondary terminal 204b of the transformer 204 and through which a current flows when a voltage equal to or higher than a predetermined voltage is applied. The constant voltage Vz of the constant voltage diode 216 exceeds (√2) E with respect to the voltage E appearing at the secondary terminal of the transformer 204 when an AC 100 V power supply is applied, and is less than 2 (√2) E. It is set.
A diode 217 has an anode connected to the anode of the constant voltage diode 216, and 218 is connected between the anode of the constant voltage diode 216 and the other end of the secondary terminal 204b of the transformer 204 via the diode 217. Current detection means for detecting a current from the voltage diode 216.
[0003]
This current detection means 218 is constituted by a photocoupler, and a diode 218a constituting the photocoupler is connected between the cathode of the diode 217 and the other end of the secondary side terminal 204b of the transformer 204, and a transistor 218b constituting the photocoupler. Is connected between the output terminal of the microcomputer 209 and the ground.
Reference numeral 219 denotes a light emitting diode which is an alarm means that is turned on when the current detection means 218 detects a current. The anode of the light emitting diode 219 is connected to one DC terminal of the rectifying means 205, and the cathode is connected to the output terminal of the microcomputer 209 via the driver 220, and is also connected to the collector of the photocoupler transistor 218b. Is.
[0004]
Next, the operation of the conventional dual power supply erroneous connection protection circuit will be described.
First, when a commercial power supply of 100 V is applied to the terminals 201a and 201b, a voltage E appears on the secondary side terminal 204b of the transformer 204, and its peak value is (√2). Since the voltage is lower than the constant voltage value Vz of the diode 216, no current flows through the constant voltage diode 216, no current flows through the diode 218a of the current detection means 218, and the transistor 218b is in an off state. As a result, no current flows through the light emitting diode 219 serving as an alarm means, and the light emitting diode 219 remains off.
[0005]
In addition, when the contractor accidentally applies the 200V commercial power supply to the power supply terminals 201a and 201b, a voltage 2E and a peak value 2 (√2) E appear between the secondary terminals 204b of the transformer 204. . Then, a voltage equal to or higher than the constant voltage Vz is applied to the cathode of the constant voltage diode 216, current flows through the constant voltage diode 216, current also flows through the diode 218a of the current detection means 218, and the transistor 218b Turn on. As a result, a current flows through the light emitting diode 219 serving as an alarm means to emit light.
Therefore, the installer can know that the 200V commercial power supply is erroneously connected to the power supply terminals 201a and 201b.
In this case, since the operation of the device is prevented from starting by the microcomputer 209, the device is not damaged.
[0006]
The conventional erroneous connection protection circuit as described above is a countermeasure against miswiring when the power supply of the device is one power supply, and the AC200V power supply is accidentally connected to the place where the AC100V power supply should be applied. This is a countermeasure against incorrect wiring.
However, the transformer 204 has a circuit configuration in which the secondary voltage is doubled when the input voltage is 100V AC and 200V AC. In general, transformers designed for 100V AC are generally input. From around 130VAC, the core of the transformer 204 is magnetically saturated, and when a voltage higher than that is applied, an excessive current flows through the primary winding, generating heat internally, resulting in a break in the winding. .
Therefore, in order to maintain the function without causing the transformer 204 to generate heat even with AC200V, it must be designed as a transformer for AC200V in spite of the AC100V input, and only for the protection of the initial construction. However, increasing the core size has a problem in that it has a large cost disadvantage.
[0007]
In recent years, with the increase in capacity of home appliances, devices operating at 200 VAC have been increasing. Up to now, the power supply of the main body of equipment has been changed to the AC 200V main body power supply as the capacity of the heater has increased due to the increased capacity of the heater.
This bath drying fan has a built-in heater and circulation fan, and is often manufactured by combining a fan for ventilation with a commercially available ventilation fan. With the wiring work, AC100V and AC200V will be mixed, and troubles for that will be assumed.
Therefore, when two different power supplies are connected to the same equipment, it is required to notice the miswiring when the AC100V and AC200V power supplies are mistakenly wired during the initial construction, and to prevent damage to the equipment due to miswiring. Is done.
[0008]
[Problems to be solved by the invention]
The present invention was made to solve such a problem. When two different power sources are connected to the same device, an incorrect wiring is noticed when AC100V and AC200V power sources are mistakenly wired at the time of initial construction. An object of the present invention is to provide an erroneous wiring protection device capable of preventing damage to the device and an apparatus equipped with the erroneous wiring protection device.
[0009]
[Means for Solving the Problems]
  The erroneous wiring protection device according to claim 1 of the present invention includes a high voltage terminal block to which a high voltage power supply is connected, a power supply circuit that is connected to the high voltage terminal block, converts alternating current into a DC voltage, and outputs it. A low voltage terminal block to which a low voltage power source is connected, a first actuator connected to the high voltage terminal block via first normally open switch means, and a terminal block to which the second actuator is connected And a normally open second switch means provided between the terminal block and the low voltage terminal block, and a control circuit for receiving power from the power supply circuit and controlling opening and closing of the first and second switch means. A miswiring protection device used in equipment, connected to the low-voltage terminal block, and a voltage determination circuit that outputs a detection signal when only a high voltage is detected;A power connection determination circuit connected to a terminal block to which the second actuator is connected and outputting a power connection signal when a voltage is detected;When the second switch means is kept open at least upon receiving a detection signal from the voltage determination circuit, and no detection signal is received from the voltage determination circuitReceiving the power connection signal from the power connection determination circuit, maintaining the second switch means open, and closing the first and second switch means when not receiving the power connection signal. Circuit andIt consists of
[0010]
According to a second aspect of the present invention, there is provided the miswiring protection device according to the present invention, wherein the voltage determination circuit is connected in parallel to at least two resistors connected in series to the low voltage terminal block and both ends of the resistor where the divided voltage is generated. And a series circuit of a constant voltage diode and a current detection element.
[0011]
  The miswiring protection device according to claim 3 of the present invention isThe power connection determination circuit includes a resistor and a current detection element connected in series to a terminal block to which the second actuator is connected.
[0012]
  The erroneous wiring protection device according to claim 4 of the present invention isA high-voltage terminal block to which a high-voltage power supply is connected; a power supply circuit connected to the high-voltage terminal block that converts AC to DC voltage and outputs; a low-voltage terminal block to which a low-voltage power supply is connected; Provided between the first actuator connected to the high voltage terminal block via the normally open first switch means, the terminal block connected to the second actuator, and the terminal block and the low voltage terminal block An erroneous wiring protection device for use in a device comprising the normally-switched second switch means and a control circuit that receives power from the power supply circuit and controls opening and closing of the first and second switch means, Connected to the terminal block for connecting to the terminal block to which the second actuator is connected, and a voltage determination circuit for outputting a detection signal when only a high voltage is detected, and a power connection signal when detecting the voltage First power connection judgment time to output A second power connection determination circuit connected to the low voltage terminal block and outputting a power connection signal when a voltage is detected, and at least the second switch means receiving the detection signal from the voltage determination circuit When the detection signal is not received from the voltage determination circuit, the second switch means is maintained at least when the power connection signal is received from the first power connection determination circuit. The control circuit for closing the first and second switch means when receiving no power connection signal from the first power connection determination circuit and receiving a power connection signal from the second power connection determination circuitIt consists of
[0013]
  An erroneous wiring protection device according to claim 5 of the present invention isThe device includes a display unit, and includes a remote controller that outputs an operation / stop command to the control circuit. The control circuit receives a detection signal from the voltage determination circuit and receives the detection signal from the first and second switch units. While maintaining the open state, the display means of the remote controller is made to display an abnormal wiring error.
[0014]
  In the erroneous wiring protection device according to claim 6 of the present invention, the device has a display means.SaidA remote controller that outputs a command for operation / stop to the control circuit;Power connection signal from the power connection determination circuitIn response to this, at least the second switch means is kept open, and the display means of the remote controller is made to display an abnormal wiring error.
[0015]
  In the erroneous wiring protection device according to claim 7 of the present invention, the device has a display means.SaidA remote controller that outputs a command for operation / stop to the control circuit;When a power connection signal is received from the first power connection determination circuit and a power connection signal is not received from the second power connection determination circuitAt least, the second switch means is kept open, and the display means of the remote controller is made to display an abnormal wiring error.
[0016]
  An erroneous wiring protection device according to claim 8 of the present invention isThe first actuator is a heater, and the second actuator is a ventilation fan.is doing.
[0017]
  The erroneous wiring protection device according to claim 9 according to the present invention.The equipment equipped with the bus drying fanIt is said.
[0019]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
1 is a circuit diagram of normal wiring according to the bus drying fan of Embodiment 1 of the present invention, FIG. 2 is a circuit diagram of an erroneous wiring pattern 1 according to the bus drying fan, and FIG. 3 is an erroneous wiring according to the bus drying fan. FIG. 4 is a flowchart showing the operation of the bus drying fan.
In the figure, reference numeral 1 denotes a bus drying fan main body of a bus drying fan which is a home electric appliance using two power sources having different voltages. Reference numeral 2 denotes a remote controller for operating the bus drying fan main body 1. It shall be powered. 3 is a power supply for AC200V, 4 is a power supply for AC100V, and 5 is a ventilation fan for AC100V installed outside the bus drying fan main body 1.
6 is an AC200V connection terminal block to which an AC200V power supply 3 is connected via a breaker 17, 7 is an AC100V connection terminal block to which an AC100V power supply 4 is connected via a breaker 1, and 8 is an AC100V ventilation fan 5 A ventilation fan connecting terminal block to be connected, 9 is a circulation fan provided in the bath drying fan main body 1, and 10 is a heater provided in the bus drying fan main body 1.
[0020]
Reference numeral 11 denotes a power supply circuit that is connected to a terminal block 6 for AC200V connection via a pair of connection wires 12 and outputs alternating current to direct current. The control described later is performed regardless of whether the power supply connected to the terminal block 6 is AC100V or AC200V. It is assumed that a predetermined voltage for operating the circuit is obtained. 11a is a switching transformer in the power supply circuit 11, and 13 is a control circuit to which DC power is supplied from the power supply circuit 11.
Reference numeral 14 a denotes an operation coil of a ventilating fan relay that performs on / off control of energization to the ventilating fan 5 controlled by the control circuit 13. 14b is a normally open twin contact of the ventilating fan relay, one terminal of which is connected to the AC100V connecting terminal block 7 and the other terminal is connected to the ventilating fan connecting terminal block 8.
[0021]
Reference numeral 15a denotes an operation coil of a circulation fan relay that performs on / off control of energization to the circulation fan 9 controlled by the control circuit 13. Reference numeral 15b denotes a normally open contact of the circulation fan relay. It is connected to the connection terminal block 6.
Reference numeral 16a denotes an operation coil of a heater relay that performs on / off control of energization to the heater 10 controlled by the control circuit 13. Reference numeral 16b denotes a normally open contact of the heater relay, which is a terminal for connecting 200V AC in series with the heater 10. It is connected to the base 6.
[0022]
20 is connected to the AC100V terminal block 7 and the input side is connected to the AC200V power supply 3 and the AC100V power supply 4 to determine the voltage, and 21 is connected to the ventilator fan terminal block 8 and the input side is connected to check the presence or absence of voltage. A power connection determination circuit for determining, 22 is a communication line for connecting the output side of the voltage determination circuit 20 and the control circuit 13, 23 is a communication line for connecting the output side of the power connection determination circuit 21 and the control circuit 13, and 24 is A communication line connecting the control circuit 13 of the bus drying fan main body 1 and the remote controller 2
[0023]
The voltage determination circuit 20 includes a diode 101 and resistors 102 and 103 connected in series to the AC 100 V connection terminal block 7, a constant voltage diode 104 connected in parallel to the resistor 103, and a photodiode of a photocoupler 105 that is a current detection element. It is composed of a series circuit and a series circuit of a phototransistor 105 and a resistor 106 of the photocoupler 105 connected to the power supply circuit 11.
[0024]
In this voltage determination circuit 20, when the AC100V power supply 4 is connected to the AC100V connection terminal block 7, the AC100V power supply 4 causes the current to flow through the diode 101, the resistor 102, and the resistor 103 every half wave. Since the voltage divided by the resistors 102 and 103 at this time is equal to or lower than the constant voltage of the constant voltage diode 104, no current is divided into the constant voltage diode 104 and no current flows through the photodiode of the photocoupler 105. Therefore, the transistor of the photocoupler 105 remains off, and the connection line 22 transmits the same voltage value as the output voltage of the power supply circuit 11 (hereinafter referred to as H level) to the control circuit 13.
[0025]
However, if the AC200V power supply 3 is erroneously connected to the AC100V connection terminal block 7, the voltage divided by the resistors 102 and 103 becomes equal to or higher than the constant voltage of the constant voltage diode 104. Since the current is shunted and the current flows through the photodiode of the photocoupler 105, the transistor of the photocoupler 105 is turned on. As a result, the communication line 22 becomes a pulse signal in which an H level and a voltage close to circuit ground (hereinafter referred to as L level) are repeated every half wave, and is transmitted to the control circuit 13.
[0026]
The power connection determination circuit 21 includes a diode 107 connected in series to the ventilating fan connection terminal block 8, a resistor 108, and a photodiode series of a photocoupler 109 as a current detection element, and a photocoupler 109 connected to the power supply circuit 11. And a series circuit of a resistor 110.
In the power supply connection determination circuit 21, when an AC voltage is generated in the ventilating fan connection terminal block 8, current flows through the photodiode 107, the resistor 108, and the photodiode of the photocoupler 109 every half wave, so that the transistor of the photocoupler 109 is turned on. To do. As a result, the connection line 23 becomes a pulse signal in which the H level and the L level are repeated every half wave and is transmitted to the control circuit 13.
[0027]
Next, the operation of the bus drying fan according to the first embodiment of the present invention will be described with reference to the flowcharts of FIGS.
2 shows a miswiring pattern 1 when the AC 200V power source 3 and the AC 100V power source 4 are alternately wired with respect to the normal circuit diagram shown in FIG. 1, and FIG. 3 is different from FIG. Connected to AC 100V power source 4 connected to AC 100V connection terminal block 7 in series with ventilating fan 5, where wiring pattern 2 is wrong and only ventilation fan 5 should be connected to vent fan connecting terminal block 8 Shows the case. 4 is described only for the operation of the ventilation fan 5, and does not refer to the operation of stopping the ventilation fan 5 by the operation of the remote controller 2.
[0028]
When the power is connected to the terminal blocks 6 and 7 and the AC fan 100V is connected to the terminal block 8, the control circuit 13 waits for an instruction for operating the ventilation fan 5 from the remote controller 2. (Step S1). At this time, it is assumed that the breaker 17 and the breaker 18 are already turned on before the operation instruction is given.
When the operation instruction for the ventilation fan 5 is received from the remote controller 2, the control circuit 13 determines whether or not the AC200V power source 3 is applied to the terminal block 7 from the voltage determination circuit 20 (step S2).
[0029]
As shown in FIG. 1, when the AC 100V power supply 4 is correctly connected to the terminal block 7, the voltage determination circuit 20 does not output a determination signal indicating that the AC 200V power supply 3 is applied. It is determined that the power supply 4 for AC100V is connected to the terminal block 7, and the process proceeds to step S3.
As shown in FIG. 2, when the AC 200V power source 3 is connected to the terminal block 7, the voltage determination circuit 20 outputs a determination signal indicating that the AC 200V power source 3 is applied. Determines that the AC power supply 3 for AC 200V is connected to the terminal block 7, and proceeds to step S5 described later.
[0030]
  In step S3, the twin contact 14b of the ventilating fan relay that performs on / off control of energization to the ventilating fan 5 is opened (that is, the opening of the ventilating fan 5 is started when the ventilating fan 5 starts operating, and after the start of the operation, the process proceeds to step S4). This is an opening when the twin contact 14b of the ventilating fan relay is closed, and then the wrong wiring is detected and the twin contact 14b of the ventilating fan relay is opened in step S6, and the operation is stopped by the operation of the remote controller 2. The control circuit 13 is a power connection determination circuit.21It is determined whether any one of the power supply 4 for AC100V or the power supply 3 for AC200V is applied to the terminal block 8 depending on whether there is a pulse signal from.
[0031]
When the operation is started, the twin contact 14b of the ventilating fan relay is in an open state, and the power connection determination circuit 21 does not output a pulse signal when the terminal block 8 is not connected to supply power. 13 determines that only the ventilation fan 5 is connected to the terminal block 8 as shown in FIG. 1, and proceeds to step S4.
When the terminal block 8 is connected so that power is supplied, the power connection determination circuit 21 outputs a pulse signal, so that the control circuit 13 not only supplies the ventilation fan 5 to the terminal block 8 as shown in FIG. Then, it is determined that the AC 100V power source 4 connected to the terminal block 7 is connected, and the process proceeds to step S5 described later.
[0032]
  In step S4, the control circuit 13 energizes the operation coil 14a of the ventilating fan relay to provide a twin contact.14bThe AC100V power supply 4 connected to the terminal block 7 is twin contact.14bIs relayed to feed power to the ventilating fan 5, and the operation of the ventilating fan 5 is started.
  Simultaneously with the start of the operation of the ventilation fan 5, the control circuit 13 energizes the operation coil 15a of the circulation fan relay and the operation coil 16a of the heater relay as necessary to close the contacts 15b and 16b. Contact the connected AC200V power supply 315bAnd 16b are relayed to supply power to the circulation fan 9 and the heater 10, and the operation of the circulation fan 9 and the heater 10 is started. Then, it returns to step S1.
  Thereafter, the same flow processing is performed, but in the determination in step S3, since the twin contact 14b of the ventilating fan relay is closed this time, even if the power connection signal from the power connection determination circuit 10 is generated, the step is performed. The process proceeds to S4.
[0033]
As described above, when the AC 200V power source 3 is erroneously connected to the terminal block 7, the voltage determination circuit 20 outputs a determination signal indicating that the AC 200V power source 3 is applied and proceeds to step S5. The pulse signal that the power connection determination circuit 21 is connected to the terminal block 8 because the AC power supply 4 for AC 100V connected to the terminal block 7 is connected to the terminal block 8 in addition to the ventilation fan 5. In step S5, the control circuit 13 is connected to the terminal block 7 with the AC 200V power source 3 or to the terminal block 8 with not only the ventilation fan 5 but also the power source. Is transmitted to the remote controller 2, and the remote controller 2 displays the incorrect wiring abnormality and proceeds to step S6.
[0034]
In step S6, the twin contact 14b of the ventilation fan relay is opened, and the operation of the ventilation fan 5 is stopped. However, since the twin contact 14b of the ventilating fan relay is not closed on the flow, the twin contact 14b is only kept open. Then, it returns to step S1.
In addition, even if the AC200V power supply 3 is applied to the AC200V connection terminal block 6 after the AC100V power supply 4 is applied to the AC100V connection terminal block 7 with the correct wiring shown in FIG. 4 is applied, both the AC100V power supply 4 and the AC200V power supply 3 are applied at the timing at which the flowchart shown in FIG. 4 operates. That is, the breaker 17 and the breaker 18 are already turned on. It works under the condition.
[0035]
Further, in the erroneous wiring pattern 1 shown in FIG. 2 described above, it has been described that the breaker 17 and the breaker 18 are already turned on when the operation instruction of the remote controller 2 is given. However, by the insertion of the breaker 17 to the terminal block 6 There is also a possibility that the AC 200 V power source 3 is applied to the terminal block 7 by applying the breaker 18 after the AC 100 V power source 4 is applied.
In this case, in the processing flow in FIG. 4, when the breaker 18 of the AC 200V power supply 3 is not turned on, the processing is performed in the same flow as in normal wiring even when the operation of the ventilation fan 5 is started, and the twin contact 14b is closed. Although no voltage is generated in the ventilation fan terminal block 8, the voltage determination circuit 20 operates in step 2 when the AC200V power source 3 is input to the terminal block 7, and the process proceeds to step 5.
Further, the AC power supply 3 for AC200V is applied to the ventilation fan 5 for a short time until the twin contact 14b of the ventilation fan relay is opened in step 6, but generally the ventilation fan 5 is applied for a short time. Will not fail.
[0036]
On the contrary, when the AC100V power supply 4 is applied to the AC200V connection terminal block 6 by turning on the breaker 17 later, the AC200V power supply 3 previously input to the AC100V connection terminal block 7 by turning on the breaker 18 is used. Since the control circuit 13 does not operate, the ventilation fan relay does not operate, the twin contact 14b of the relay remains open, the device is stopped, and the device is not damaged.
[0037]
Further, in the erroneous wiring pattern 2 shown in FIG. 3, if the breaker 17 and the breaker 18 are already turned on when the remote controller 2 is instructed to operate, before the operation of the ventilation fan 5 is started in step S3, that is, the ventilation fan. When the twin contact 14b of the relay is opened, the power connection determination circuit 21 operates, and the process proceeds to step 5.
However, after the breaker 17 is turned on and the AC power supply 3 is applied to the terminal block 6, the remote controller 2 gives an instruction to operate the ventilation fan 5. After that, the breaker 18 is turned on and the AC power supply 4 is applied to the terminal block 7. In this case, since the twin contact 14b of the ventilating fan relay is closed, the AC 100V power source 4 of the terminal block 7 and the AC 100V power source 4 of the terminal block 8 cause an internal short circuit, and the device is caused by the internal short circuit. A situation occurs where the protection against the damage that occurs is not working.
Such a situation is dealt with in the second embodiment of the present invention shown in FIGS.
[0038]
As described above, according to the first embodiment of the present invention, the AC200V power supply terminal 3 and the AC100V connection terminal block 7 are alternately connected to the AC200V power supply 3 and the AC100V power supply 4 by mistake. When the breakers 17 and 18 are turned on before the operation command for the ventilation fan 5 from 2 is turned on, and when the breaker 17 is turned on before the operation command for the ventilation fan 5 is sent from the remote control 2 and then the breaker 18 is turned on The voltage determination circuit 20 connected to the terminal block 7 outputs a determination signal (that is, a 200V power supply input signal) indicating that the AC block power supply 3 is connected to the terminal block 7 to the control circuit 13, and the control circuit 13 2 is transmitted to the remote controller 2 via the communication line 24, the remote controller 2 displays the erroneous wiring abnormality, and the control circuit 13 is connected to the ventilator fan terminal block 8 to which the terminal block 7 and the ventilator fan 5 are connected. Connect between Since the operation of the ventilation fan 5 is stopped while the twin contact 14b is left open without energizing the operation coil 14a of the ventilation fan relay that drives the twin contact 14b, the device is in a stopped state. No damage will occur.
[0039]
In addition, AC200V power supply 3 and AC100V power supply 4 are correctly connected to AC200V connection terminal block 6 and AC100V connection terminal block 7, respectively. Ventilation fan 5 and AC100V power supply 4 are incorrectly connected to ventilation fan connection terminal block 8. When the breakers 17 and 18 are turned on before the operation command of the ventilation fan 5 is given from the remote controller 2, the power connection determination circuit 21 connected to the terminal block 8 is connected to the terminal block 8 and the AC 100V power supply 4 is connected. Is output to the control circuit 13, and the control circuit 13 transmits an error in the incorrect wiring to the remote control 2 via the communication line 24 to the remote control 2. The remote control 2 displays the error in the incorrect wiring and the control circuit. 13 opens the twin contact 14b so as not to energize the operation coil 14a of the ventilation fan relay that drives the twin contact 14b that connects the terminal block 7 and the ventilation fan connection terminal block 8 to which the ventilation fan 5 is connected. Since the ventilation fan 5 as mom was set as the non-energized state, the device is in a stopped state, equipment damage does not occur.
Further, the voltage determination circuit 20 is connected in parallel to both ends of the two resistors 102 and 103 for dividing the voltage connected in series to the AC100V connection terminal block 7 which is a low voltage terminal block and the resistor 103 where the divided voltage is generated. Since the constant voltage diode 104 and the photocoupler 105, which is a current detection element, are connected in series, the voltage determination is detected from the voltage of the supplied primary power supply without using a transformer. A high voltage determination circuit can be obtained.
The power connection determination circuit 21 includes a resistor 108 connected in series to the ventilating fan connection terminal block 8 and a photocoupler 109 that is a current detection element, and supplies voltage determination without passing through a transformer. Since the detection is performed from the voltage, a low-cost and highly reliable power connection determination circuit can be obtained.
In the first embodiment, the AC 200 V power source 3 and the AC 100 V power source 4 are used as examples of two different power sources, but it is sufficient that one power source has a higher voltage than the other power source as the two different power sources. Of course, the voltage value is not limited.
[0040]
Embodiment 2. FIG.
FIG. 5 is a circuit diagram of an erroneous wiring pattern related to the bus drying fan according to the second embodiment of the present invention, and FIG. 6 is a flowchart showing the operation of the bus drying fan.
5, the same components as those in FIGS. 1 to 3 are denoted by the same reference numerals, and the description of the overlapping components is omitted.
In the second embodiment, the same power supply connection determination circuit 20 of the first embodiment is connected to the AC100V connection terminal block 7 of the AC100V power supply 4, and the power supply connected to the ventilating fan connection terminal block 8 side. The connection determination circuit is the first power connection determination circuit 21a, the power connection determination circuit connected to the terminal block 7 side is the second power connection determination circuit 21b, and the connections to the control circuit 13 are 23a and 23b, respectively. Is.
FIG. 5 shows the case where only the ventilation fan 5 should be connected to the ventilation fan connection terminal block 8 as in FIG.
[0041]
Next, the operation of the bus drying fan according to the second embodiment of the present invention will be described with reference to the flowcharts of FIGS.
Since the steps S1 to S3 are the same as those in the first embodiment of the present invention after the start, description of the operation is omitted.
In the following description of the operation, it is assumed that the breaker 17 and the breaker 18 are already turned on before the operation instruction is given.
In step S3, the control circuit 13 determines whether the AC 100V power source 4 is applied to the ventilating fan terminal block 8 depending on whether there is a pulse signal from the first power source connection determination circuit 20a.
At the start of operation, the contact 14b of the relay 14 is in an open state, and the first power connection determination circuit 21a does not output a pulse signal when the terminal block 8 is not connected so that power is supplied. 13 determines that only the ventilation fan 5 is connected to the terminal block 8 as shown in FIG. 1, and proceeds to step S7.
When the terminal block 8 is connected to be supplied with power, the first power connection determination circuit 21a outputs a pulse signal, so that the control circuit 13 is connected to the terminal block 8 with the ventilation fan 5 as shown in FIG. In addition, it is determined that the AC 100V power source 4 connected to the terminal block 7 is connected, and the process proceeds to step S5 described later.
[0042]
In step S7, when the power supply 4 for AC100V is connected to the terminal block 7 via the breaker 18, and the determination in step S3 is NO, the second power connection determination circuit 21b outputs a pulse signal. The process proceeds to step S4 as in FIG.
In step S4, the control circuit 13 energizes the operation coil 14a of the ventilating fan relay, closes the twin contact 14b, feeds the AC100V power source 4 connected to the terminal block 7 to the ventilating fan 5 via the twin contact 14b, The operation of the ventilation fan 5 is started. Simultaneously with the start of the operation of the ventilation fan 5, the operation of the circulation fan 9 and the heater 10 is also started as necessary. Then, it returns to step S1.
[0043]
  Breaker 17 is closed when breaker 17 is closed18If is open, step S3 is NO and the process proceeds to step S7, but the AC power supply 4V for AC100V is not applied to the terminal block 7 in the second power connection determination circuit 21b connected to the terminal block 7. Therefore, no power connection signal is generated. Therefore, the process proceeds to step S5, and the control circuit 13 keeps the twin contact 14b open. Since the twin contact 14b has never been closed before, the device is protected.
  On the contrary, when the breaker 17 is open and the breaker 18 is closed, that is, when the AC200V power supply 3 is applied to the terminal block 6 later, the control circuit is not limited to the AC100V power supply 4 previously input to the terminal block 7. Since 13 does not operate, the device is in a stopped state and the device is not damaged.
[0044]
As described above, according to the second embodiment of the present invention, the AC200V power supply terminal 3 and the AC100V connection terminal block 7 are correctly connected to the AC200V power supply 3 and the AC100V power supply 4, respectively. Ventilation fan 5 and AC100V power supply 4 are mistakenly connected to terminal block 8, AC200V power supply 3 is applied to terminal block 6, then operation command for ventilation fan 5 is given from remote control 2, and AC100V power supply 4 is connected to terminal later. When applied to the base 7, the second power connection determination circuit 21 b connected to the terminal base 7 does not output a power connection signal indicating that the AC power supply 4 for AC 100 V is connected to the terminal base 8 to the control circuit 13. The control circuit 13 transmits the incorrect wiring abnormality to the remote control 2 to the remote control 2 via the communication line 24. The remote control 2 displays the erroneous wiring abnormality, and the control circuit 13 is connected to the terminal block 7 and the ventilation fan 5. With the ventilation fan connecting terminal block 8 Since the twin contact 14b is left open so that the operation coil 14a of the ventilation fan relay that drives the twin contact 14b is not opened, and the ventilation fan 5 is turned off, the device is in a stopped state. There is no equipment damage.
[0045]
【The invention's effect】
  As described above, according to the present invention, a high-voltage terminal block to which a high-voltage power supply is connected, a power supply circuit connected to the high-voltage terminal block, which converts AC to DC voltage and outputs, and a low-voltage terminal block A low-voltage terminal block to which a power supply is connected; a first actuator connected to the high-voltage terminal block via first-open switch means; a terminal block to which a second actuator is connected; In a device comprising a normally open second switch means provided between the base and the low voltage terminal block, and a control circuit that receives power from the power supply circuit and controls opening and closing of the first and second switch means, If a high voltage power supply and a low voltage power supply are mistakenly connected to the high voltage terminal block and the low voltage terminal block, the voltage judgment circuit connected to the low voltage terminal block will Is connected to the control circuit. Since the control circuit keeps the second switch means open and stops the operation of the second actuator at least, the second actuator is in a non-energized state and the equipment is not damaged. In addition, a high voltage power supply and a low voltage power supply are connected correctly to the high voltage terminal block and low voltage terminal block, respectively.When a low voltage power supply is connected in series to the second actuator, the power connection determination circuit connected to the second actuator is connected to the power supply indicating that the low voltage power supply is connected to the second actuator. Since the signal is output to the control circuit, and the control circuit keeps the second switch means open at least and puts the second actuator in a non-energized state, the device is in a stopped state,There is an effect that the equipment is not damaged.
[0047]
  AnotherAccording to the present invention, a high-voltage terminal block to which a high-voltage power supply is connected, a power supply circuit that is connected to the high-voltage terminal block, converts alternating current into a DC voltage, and is output, and a low-voltage power supply are connected. Low voltage terminal block, first actuator connected to high voltage terminal block via first switch means normally open, terminal block connected to second actuator, terminal block and low voltage terminal In a device provided with a normally open second switch means provided between the base and a control circuit that receives power from the power supply circuit and controls opening and closing of the first and second switch means,If a high voltage power supply and a low voltage power supply are mistakenly connected to the high voltage terminal block and the low voltage terminal block, the voltage judgment circuit connected to the low voltage terminal block will Is output to the control circuit, and the control circuit keeps the second switch means open and stops the operation of the second actuator. The power is on and there is no equipment damage.When a high voltage power supply and a low voltage power supply are correctly connected to the high voltage terminal block and the low voltage terminal block, respectively, and a low voltage power supply is connected in series to the second actuator, it is connected to the second actuator. The second power source connected to the low voltage terminal block and the first power source connection determination circuit outputs a power source connection signal indicating that the low voltage power source is connected in series to the second actuator. The connection determination circuit outputs a power connection signal indicating that a low voltage power source is connected to the low voltage terminal block to the control circuit, and the control circuit keeps the second switch means open at least, and the second actuator is operated. Since the device is in a non-energized state, the device is in a stopped state, and there is an effect that the device is not damaged.
  Further, when the second switch means is opened before closing, the control circuit may receive a power connection signal from the first power connection determination circuit and not receive a power connection signal from the second power connection determination circuit. Therefore, even if a low voltage power source is applied after the start of operation, the device can be protected from erroneous wiring in which the low voltage power source connected to the low voltage terminal block is short-circuited.
[0048]
  Also,The present inventionAccording to the present invention, the device has a display means, is equipped with a remote controller that outputs a command for operation / stop, and the control circuit receives a detection signal from the voltage determination circuit.1st andWe want to keep the second switch means open and let the display means on the remote control display an error in the incorrect wiring, so we will inform the contractor early about the incorrect wiring and quickly recover the initial work. There is an effect that can be performed.
[0049]
  In addition, according to the present invention, the device has a display means, and includes a remote controller that outputs an operation / stop command, and the control circuit is supplied from the power connection determination circuit.Power connection signalIn responseAt leastWe want to keep the second switch means open and let the display means on the remote control display an error in the incorrect wiring, so we will inform the contractor of the incorrect wiring at an early stage and quickly recover the initial work. There is an effect that can be performed.
[0050]
  Further, according to the present invention, the device includes a display unit, and includes a remote controller that outputs an operation / stop command, the control circuit receives a power connection signal from the first power connection determination circuit, and the second circuit When the power connection signal is not received from the power connection judgment circuitAt leastWe want to keep the second switch means open and let the display means on the remote control display an error in the incorrect wiring, so we will inform the contractor early about the incorrect wiring and quickly recover the initial work. There is an effect that can be performed.
[0051]
According to the present invention, the first actuator is a heater, the second actuator is a ventilation fan, and the device is a bath drying fan.
[0052]
Further, according to the present invention, the device equipped with the miswiring protection device is a bus drying fan, and when the low voltage power is relayed and supplied from the bus drying fan side to the external ventilation fan, Does not damage the equipment.
[Brief description of the drawings]
FIG. 1 is a circuit diagram of normal wiring according to a bus drying fan of a first embodiment of the present invention.
FIG. 2 is a circuit diagram of a miswiring pattern 1 related to the bus drying fan.
FIG. 3 is a circuit diagram of a miswiring pattern 2 according to the bus drying fan.
FIG. 4 is a flowchart showing the operation of the bus drying fan.
FIG. 5 is a circuit diagram of an erroneous wiring pattern according to the bus drying fan of Embodiment 2 of the present invention.
FIG. 6 is a flowchart showing the operation of the bus drying fan.
FIG. 7 is a circuit diagram showing a configuration of a conventional erroneous wiring protection circuit.
[Explanation of symbols]
1 Bus drying fan body 2 Remote control 3 AC200V power supply 4 AC100V power supply 5 AC100V ventilation fan 6 AC200V connection terminal block 7 AC100V connection terminal block 8 Ventilation fan connection terminal block 9 Circulating fan DESCRIPTION OF SYMBOLS 10 Heater, 11 Power supply circuit, 12 Connection line, 13 Control circuit, 14a Operation coil of ventilation fan relay, 14b twin contact, 15a Operation coil of circulation fan relay, 15b contact, 16a Operation coil of heater relay, 16b contact, 20 voltage determination circuit, 21 power connection determination circuit.

Claims (9)

A high-voltage terminal block to which a high-voltage power supply is connected; a power supply circuit connected to the high-voltage terminal block that converts AC to DC voltage and outputs; a low-voltage terminal block to which a low-voltage power supply is connected; Provided between the first actuator connected to the high voltage terminal block via the normally open first switch means, the terminal block connected to the second actuator, and the terminal block and the low voltage terminal block An erroneous wiring protection device used in a device having the normally-switched second switch means and a control circuit that receives power from a power supply circuit and controls opening and closing of the first and second switch means,
A voltage determination circuit that is connected to the low-voltage terminal block and outputs a detection signal when only a high voltage is detected;
A power connection determination circuit connected to a terminal block to which the second actuator is connected and outputting a power connection signal when a voltage is detected;
When the detection signal from the voltage determination circuit is received and at least the second switch means is maintained open, and the detection signal from the voltage determination circuit is not received , the power connection signal from the power connection determination circuit is received. And the control circuit for closing the first and second switch means when the power supply connection signal is not received. .   The voltage determination circuit includes at least two resistors connected in series to a low voltage terminal block, and a series circuit of a constant voltage diode and a current detection element connected in parallel at both ends of the resistor where the divided voltage is generated. The erroneous wiring protection device according to claim 1, wherein The power supply connection judging circuit, wherein said second actuator is faulty wiring protection device according to claim 1, characterized in that it consists of a series connected resistor and current detection device to the terminal block to be connected. A high-voltage terminal block to which a high-voltage power supply is connected; a power supply circuit connected to the high-voltage terminal block that converts AC to DC voltage and outputs; a low-voltage terminal block to which a low-voltage power supply is connected; Provided between the first actuator connected to the high voltage terminal block via the normally open first switch means, the terminal block connected to the second actuator, and the terminal block and the low voltage terminal block An erroneous wiring protection device used in a device having the normally-switched second switch means and a control circuit that receives power from a power supply circuit and controls opening and closing of the first and second switch means,
A voltage determination circuit that is connected to the low-voltage terminal block and outputs a detection signal when only a high voltage is detected;
A first power connection determination circuit connected to a terminal block to which the second actuator is connected and outputting a power connection signal when a voltage is detected;
A second power connection determination circuit connected to the low voltage terminal block and outputting a power connection signal when a voltage is detected;
At least when the detection signal from the voltage determination circuit is received, the second switch means is kept open, and when the detection signal from the voltage determination circuit is not received ,
When the power connection signal is received from the first power connection determination circuit , at least the second switch means is kept open, does not receive the power connection signal from the first power connection determination circuit, and the second And a control circuit for closing the first and second switch means when receiving a power connection signal from the power connection determination circuit. The device has a display means, comprising a remote controller for outputting a command of operation / stop to the control circuit,
The control circuit receives a detection signal from the voltage determination circuit, maintains the opening of the first and second switch means, and causes the display means of the remote control to display an abnormal wiring abnormality. Item 3. An erroneous wiring protection device according to any one of Items 1 and 2. The device has a display means, comprising a remote controller for outputting a command of operation / stop to the control circuit,
The control circuit maintains the open of the second switch means and at the same time causes the display means of the remote controller to display an abnormal wiring abnormality even if it receives at least a power connection signal from the power connection determination circuit. Item 4. An erroneous wiring protection device according to any one of Items 1 and 3 . The device has a display means, comprising a remote controller for outputting a command of operation / stop to the control circuit,
When the control circuit receives a power connection signal from the first power connection determination circuit and does not receive a power connection signal from the second power connection determination circuit, the control circuit keeps the second switch means open at least. 5. The miswiring protection device according to claim 4 , wherein an error display of miswiring is displayed on the display means of the remote controller.   The erroneous wiring protection device according to claim 1, wherein the first actuator is a heater, and the second actuator is a ventilation fan.   A device equipped with the erroneous wiring protection device according to any one of claims 1 to 9, wherein the device equipped with the erroneous wiring protection device is a bus drying fan.

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