JP2940297B2 - High voltage application device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a high voltage applying apparatus, and more particularly to a high voltage applying apparatus having a plurality of high voltage applying sections for applying a high voltage to an object to be applied.

[0002]

2. Description of the Related Art Generally, in an air purifier, an ozone deodorizer and the like, a dust collecting element for collecting dust in the air,
And a high voltage application device for applying a high voltage to the dust collection element. In recent years, in air purifiers, ozone deodorizers, and the like, a plurality of dust collecting elements are provided in order to improve performance. Therefore, the high voltage application device is provided with a plurality of high voltage application units for applying a high voltage to the dust collection element. An example of such a high voltage application device is shown in FIGS. 3 and 4 are block diagrams showing a schematic configuration of a conventional high voltage application device.

[0003] The above-mentioned high voltage application device is shown in Figs.
The high voltage applying units 3 and 4 for discharging the dust collecting elements 1 and 2 respectively, and the control unit 5 for controlling the driving of the high voltage applying units 3 and 4 are provided. It is built into the main unit side control unit such as an air purifier and an ozone deodorizer. And in the high voltage application device shown in FIG.
In the control unit 5, one interface circuit IF is provided for exchanging information signals between the high-voltage applying units 3, 4 and the control unit 5, and the interface circuit IF includes a signal line SL and a power supply. The high voltage applying units 3 and 4 are connected via the line V _cc L.

On the other hand, in the high voltage application device shown in FIG.
The high voltage applying unit 3 is connected to the interface circuit IF1 via the signal line SL1 and the power supply line _Vcc L1, and the interface circuit IF2 is connected to the signal line SL2,
The high voltage applying units 4 are connected to each other via the power supply line _Vcc L2. That is, the high voltage applying units 3 and 4 are connected to the control unit 5 in parallel.

[0005]

However, FIG.
The high voltage application device of 4 cannot easily cope with an increase in the number of high voltage application units. That is, in the high-voltage application device of FIG. 3, only one interface circuit in the control unit is required, but routing of the power supply line is complicated. Also, since the signal line is relayed into two via the adapter 6 and connected to each high-voltage application unit, the specifications of the adapter must be changed each time the number of connected high-voltage application units increases. And the adapter cannot be used in common. Therefore,
Manufacturing costs are high.

On the other hand, in the high voltage application device shown in FIG.
As compared with the high-voltage application device shown in FIG. 3, the power supply line can be easily routed and an adapter is not required. However, since the high-voltage application unit is connected in parallel with the control unit, the number of high-voltage application units to be connected increases Each time, the number of interface circuits in the control unit must be increased, and the control unit cannot be commonly used. Therefore, the manufacturing cost is high.

SUMMARY OF THE INVENTION In view of the above, it is an object of the present invention to provide a high voltage applying device which can easily cope with an increase in the number of high voltage applying sections.

[0008]

Means for solving the problems of the present invention are as follows. A plurality of objects to be applied are connected to each other, and a plurality of high voltage applying sections for applying a high voltage to each object are provided. A high-voltage application device including a control unit for controlling driving of the high-voltage application unit, wherein the plurality of high-voltage application units are connected in series, and a series-connected body of the high-voltage application units is connected to the control unit The high voltage application unit includes a high voltage application unit that applies a high voltage to the object based on an operation signal from the control unit, an abnormality detection unit that detects an abnormality of the object, and a high voltage application. When the means receives the operation signal from the control unit, the operation signal is transmitted to the adjacent high-voltage application unit in the subsequent stage, and the abnormality is detected by the abnormality detection unit. Signals are passed through the adjacent previous high voltage application section. The control unit includes an operation signal transmission unit that transmits an operation signal to the foremost high voltage application unit, and receives an abnormality signal from the foremost high voltage application unit. Then, the operation signal transmission stopping means for stopping the transmission of the operation signal from the operation signal transmission means is included.

[0009]

In the above-mentioned means for solving the above problems, a plurality of high voltage applying sections are connected in series, and a series connection of the high voltage applying sections is connected to the control section, so that it is not only easy to route the power supply line. Therefore, there is no need to relay the adapter and branch the signal line in accordance with the number of high-voltage applying sections.

In addition, an operation signal from the control unit is sequentially transmitted to an adjacent high voltage application unit at a subsequent stage, so that a high voltage can be applied to all the objects to be applied. When an abnormality occurs, the abnormality signal can be sequentially transmitted to the control unit via the adjacent high-voltage application unit in the preceding stage, and the application of the high voltage to all the objects can be stopped. Therefore, only one circuit is required to transmit and receive information of the control unit, regardless of the number of high voltage application units.

[0011]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below in detail with reference to FIGS. A configuration of a high voltage application device according to one embodiment of the present invention will be described with reference to FIG. FIG. 1 is a block diagram showing a schematic configuration of a high voltage application device according to one embodiment of the present invention.

The high-voltage applying apparatus according to the present embodiment is used for an air purifier, an ozone deodorizer, and the like. As shown in FIG. 1, a plurality of dust collecting elements 1 for collecting dust in the air are provided.
10N are connected to each other, and each dust collecting element 101, 102, 103... 1
20N for applying a high voltage to 0N, and control for controlling the driving of each of the high voltage applying units 201, 202, 203,. And a unit 30.

The control section 30 is incorporated in a main body side control unit such as an air purifier or an ozone deodorizer, and the number of dust collecting elements is at least two if necessary.
It is only necessary to provide at least two. And the high voltage application unit 2
01, 202, 203... 20N are signal lines SL
1, SL2, SL3 ... SLN, power supply line _Vcc L
1, _Vcc L2, _Vcc L3,... _Vcc LN are connected in series.
03... 20N, the foremost high voltage application unit 201 is connected to the control unit 30 via the signal line SLM.
Are connected to a power supply 40 via a power supply line V _cc LM. The “signal line SL” is a general term for an operation signal line DL, an abnormal signal line EL, and a ground line GL described later.

The electrical configuration of the high voltage application device will be described with reference to FIG. FIG. 2 is an electric circuit diagram of the high voltage application device.
Only 01 and 202 are shown. High voltage applying section 201,
2, an operation signal receiving circuit 501, which outputs a drive signal when an operation signal is received from the control unit 30, as shown in FIG.
High voltage application circuits 511 and 51 for applying and discharging a high voltage to the dust collection elements 101 and 102 based on the drive signals from the operation signal reception circuits 501 and 502 and the operation signal reception circuits 501 and 502.
2, abnormality detection circuits 521 and 522 for detecting abnormal discharge of the dust collection elements 101 and 102, and an abnormality detection circuit 52
When the operation signal receiving circuits 501 and 502 and the operation signal receiving circuits 501 and 502 receive the operation signals from the control unit 30 based on the abnormality detection signals from the control units 30 and 522, the operation signals are adjacent to each other. Based on the operation signal transmission circuits 541 and 542 for transmitting to the subsequent high voltage application unit and the abnormal signal from the abnormal signal output circuits 531 and 532, the control unit 30 transmits the abnormal signal to the adjacent high voltage application unit via the adjacent high voltage application unit. Signal transmission circuits 551 and 552 for transmitting to the
Operation signal receiving circuits 501 and 502, high voltage application circuit 51
1, 512, abnormality detection circuits 521, 522, abnormality signal output circuits 531, 532, operation signal transmission circuits 541, 54
2 and power supply circuits 561 and 562 for supplying power to the abnormal signal transmission circuits 551 and 552.

The input terminals of the operation signal receiving circuits 501 and 502 are connected to a connector 7 via photocouplers 601 and 602, respectively.
01, 702, the first output terminal is connected to the input terminals of the high voltage application circuits 511, 512, and the second output terminal is connected to the input terminals of the operation signal transmission circuits 541, 542, respectively. . High voltage application circuits 511, 51
2 are connected to the connectors 711 and 71, respectively.
2 and the third output terminal is connected to the input terminals of the abnormality detection circuits 521 and 522, respectively.

Output terminals of the abnormality detection circuits 521 and 522 are connected to first input terminals of abnormality signal output circuits 531 and 532, respectively. The second input terminals of the abnormal signal output circuits 531 and 532 are output terminals of the abnormal signal transmission circuits 551 and 552, and the output terminals are photocouplers 611 and 612.
Are connected to abnormal signal output terminals of connectors 701 and 702, respectively.

The output terminals of the operation signal transmission circuits 541 and 542 are connected to resistors R11 and R12 and a PNP transistor Q1.
1, 72 through the base-collector of Q12
1, 722 are connected to the operation signal output terminals. The input terminals of the abnormal signal transmission circuits 551 and 552 are connected to the connector 7
21 and 722 are connected to abnormal signal output terminals.

The first input terminals of the power supply circuits 561 and 562 are connected to the connector 731 via fuses F1 and F2.
The first input terminal 732 is connected to the second input terminal of the connector 731, and the second input terminal is connected to the second input terminal of the connector 732. Further, the power supply circuits 561 and 562 have a ground terminal GND and a power output terminal _Vcc , and the ground terminal GND is grounded to the ground and the power output terminal _Vcc.
cc is the operation signal receiving circuit 5 via the resistors R21 and R22.
An abnormal signal transmission circuit 55 via a connection midpoint between the photocouplers 01 and 502 and the photocouplers 601 and 602, the emitters of the transistors Q11 and Q12, and the resistors R31 and R32.
1, 552 and connectors 721, 722 respectively.

Photocouplers 601, 602 and 61
Reference numerals 1 and 612 denote light emitting diodes D11, D12 and D21 and D22 for temporarily converting an input signal into an optical signal, and a phototransistor for receiving an optical signal from the light emitting diodes D11 and D12 and D21 and D22 and converting the signal again into an electric signal. It is composed of PT11, PT12 and PT21, PT22.

The anodes of the light emitting diodes D11 and D12 are connected to the connector 70 via resistors R41 and R42.
1, 702 are connected to the operation signal input terminals, and the cathodes are connected to the ground terminals of the connectors 701, 702, respectively. On the other hand, the collectors of the phototransistors PT11 and PT12 are connected to the operation signal receiving circuits 501 and 502, and the emitters are grounded.

The anodes of the light emitting diodes D21 and D22 are connected to abnormal signal output circuits 531 and 532 via resistors R51 and R52, and the cathodes are grounded. On the other hand, the phototransistor PT2
1, the collectors of PT22 are connected to abnormal signal output terminals of connectors 701 and 702, and the emitters are connected to connectors 701 and 7
02 and the light emitting diodes D11 and D12
Are connected to the connection intermediate points.

The connector 721 is connected to the operation signal line DL
1, the connector 702 via the abnormal signal line EL1 and the ground line GL1, the connector 722 includes the operation signal line DL2, the abnormal signal line EL2, and the ground line G
Each is connected to a connector (not shown) connected to an operation signal receiving circuit in the high voltage application unit 203 via L2. The ground terminals of the connectors 721 and 722 are grounded in the high-voltage application units 201 and 202.

The first input terminal of the connector 731 is connected to the power supply 40 via the door switch 80, and the second input terminal is connected to the power supply 40. Power supply circuit 56
Smoothing capacitors C1 and C2 are connected between lines connecting the connectors 1562 and the connectors 731 and 732, respectively. Among the lines, the line to which the fuses F1 and F2 are connected is connected to the first output terminals of the connectors 741 and 742, and the other line is connected to the second output terminals of the connectors 741 and 742, respectively. .

The connector 741 is connected to a connector 732 via a power supply line V _cc L1, and the connector 742 is connected to a power supply circuit in the high voltage application section 203 via a power supply line V _cc L2 (not shown). )). The control unit 30 includes a control circuit 90 including a microcomputer having a CPU, a data RAM, a program ROM, and the like.
Has a function of transmitting an operation signal to the foremost high voltage application unit 201 and a function of stopping transmission of the operation signal when an abnormal signal is received from the foremost high voltage application unit 201.

The first output terminal of the control circuit 90 is connected to the operation signal output terminal of the connector 100M via the resistor R1M and the base-collector of the PNP transistor QM, and the second output terminal is connected to the abnormal signal input of the connector 100M. The terminal, the third output terminal is connected to the ground terminal of the connector 100M, and the input terminal is connected to the operation switch 110 via the connector 101M. Note that one terminal of the connector 101M is grounded in the control unit 30.

The resistors R2M and R3M are connected to the intermediate point between the second output terminal of the control circuit 90 and the abnormal signal input terminal of the connector 100M and the intermediate point of the connection between the input terminal of the control circuit 90 and the connector 101M. Are connected to each other, and a third output terminal of the control circuit 90 is connected to the connector 10.
The midpoint of connection with the 0M ground terminal is grounded.

The collector of the PNP transistor QM and one terminal of the resistors R2M and R3M are connected to a power source (not shown). The connector 100M is connected to the connector 701 via an operation signal line DLM, an abnormal signal line ELM, and a ground line GLM. In the above configuration, when the operation switch 110 is turned on, the control circuit 90 in the control unit 30 outputs an operation signal. Then, the transistor QM is turned on, and the operation signal is input to the photocoupler 601 of the high voltage application unit 201 via the operation signal line DLM.

When an operation signal is input to the photocoupler 601, the light emitting diode D11 temporarily converts the input signal into an optical signal, and the phototransistor PT11 receives the optical signal from the light emitting diode D11 and converts it into an electric signal again. ,
Output to the operation signal receiving circuit 501. When the operation signal receiving circuit 501 receives the operation signal, the high voltage application circuit 511
, A high voltage application circuit 511 applies a high voltage to the dust collecting element 101 and discharges it based on the driving signal. At this time, at the same time, the operation signal receiving circuit 501 outputs an operation signal to the operation signal transmission circuit 541.

When an operation signal is input to the operation signal transmission circuit 541, the transistor Q11 is turned on, and the operation signal is
The signal is transmitted from the operation signal transmission circuit 541 to the photocoupler 602 of the high voltage application unit 202 via the operation signal line DL1. When an operation signal is input to the photocoupler 602,
The light emitting diode D12 temporarily converts the input signal into an optical signal, and the phototransistor PT12 converts the input signal into the light emitting diode D1.
2 is converted into an electric signal again and output to the operation signal receiving circuit 502.

When the operation signal receiving circuit 502 receives the operation signal, it outputs a drive signal to the high voltage application circuit 512. Based on the drive signal, the high voltage application circuit 512
A high voltage is applied to the dust collecting element 102 to cause discharge. At this time, the operation signal receiving circuit 502 outputs an operation signal to the operation signal transmission circuit 542 at the same time. When the operation signal is input to the operation signal transmission circuit 542, the transistor Q12 is turned on, and the operation signal is transmitted from the operation signal transmission circuit 542 to the high voltage application unit 203 via the operation signal line DL2. Therefore, a high voltage is applied to the dust collection element 103 connected to the high voltage application unit 203.

Thereafter, similarly, the operation signals are sequentially transmitted to the adjacent high-voltage application section at the subsequent stage, and finally the dust collection element 10 connected to the high-voltage application section 20N at the rearmost stage.
A high voltage is applied to N. Further, for example, the dust collection element 103 connected to the high voltage application unit 203
When an abnormality such as arc discharge occurs, an abnormal signal is transmitted through an abnormality detection circuit, an abnormal signal output circuit, and a photocoupler (not shown) in the high-voltage applying unit 203, and a high-voltage signal is transmitted through the abnormal signal line EL2. The signal is output to the abnormal signal transmission circuit 552 of the application unit 202.

When an abnormal signal is input to the abnormal signal transmission circuit 552, the abnormal signal is transmitted to the abnormal signal output circuit 552, and the abnormal signal output circuit 552 outputs an abnormal signal to the photocoupler 612. When an abnormal signal is input to the photocoupler 612, the light emitting diode D22 temporarily converts the input signal into an optical signal, and
Receives the optical signal from the light emitting diode D22, converts it into an electric signal again, and outputs it to the abnormal signal transmission circuit 551 of the high voltage applying unit 201 via the abnormal signal line EL1.

When an abnormal signal is input to the abnormal signal transmission circuit 551, the abnormal signal is transmitted to the abnormal signal output circuit 551, and the abnormal signal is output from the abnormal signal output circuit 551 to the photocoupler 611. When an abnormal signal is input to the photocoupler 611, the light emitting diode D21 temporarily converts the input signal into an optical signal, and
Receives the optical signal from the light emitting diode D21, converts it into an electric signal again, and outputs it to the control circuit 90 of the control unit 30 via the abnormal signal line ELM.

When the control circuit 90 receives the abnormal signal, the transmission of the operation signal is stopped and the transistor QM is turned off.
F. Then, no operation signal is input to the high voltage application unit 201, and all the high voltage application units 201, 202, 2
03 ... 20N is not driven, and all dust collection elements 1
, 10N, no high voltage is applied.

As described above, the plurality of high voltage applying units 201,
20N are connected in series, and the series connection of the high voltage applying units 201, 202, 203... 20N is connected to the control unit 30, so that the power supply lines can be easily routed. In addition, there is no need to relay the adapter and branch the signal line in accordance with the number of high-voltage applying units.

It is also possible to transmit the operation signal from the control unit 30 to the adjacent high voltage applying unit in the subsequent stage in order to apply a high voltage to all the dust collecting elements 101, 102, 103,. Also, when an abnormality occurs in each dust collection element, an abnormality signal is sequentially transmitted to the control unit 30 via the adjacent high voltage application unit in the preceding stage, and all the dust collection elements 101, 102, 103,. Since the application of the high voltage to 10N can be stopped, only one control circuit 90 for transmitting and receiving the information of the control unit 30 is required regardless of the number of the high voltage application units.

Therefore, even if the number of high voltage applying parts increases,
It will be easy to deal with. It should be noted that the present invention is not limited to the above-described embodiment, and it goes without saying that many modifications and changes can be made within the scope of the present invention.

[0038]

As is apparent from the above description, according to the present invention, a plurality of high voltage applying sections are connected in series, and a series connection of the high voltage applying sections is connected to the control section. In addition to simplifying the routing, there is no need to relay the adapter and branch the signal line in accordance with the number of high-voltage applying units.

Further, the operation signal from the control unit is sequentially transmitted to the adjacent high voltage application unit in the subsequent stage, so that a high voltage can be applied to all the objects to be applied. Even when an abnormality occurs, the abnormality signal is sequentially transmitted to the control unit via the adjacent high voltage application unit in the preceding stage, and the application of the high voltage to all the objects to be applied can be stopped.
Regardless of the number of high voltage application units, only one circuit is required to transmit and receive information of the control unit.

Therefore, even if the number of high voltage applying sections increases,
There is an excellent effect that it can be easily dealt with.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a schematic configuration of a high voltage application device according to one embodiment of the present invention.

FIG. 2 is an electric circuit diagram of the high voltage application device.

FIG. 3 is a block diagram showing a schematic configuration of a conventional high voltage application device.

FIG. 4 is a block diagram showing a schematic configuration of a conventional high voltage application device.

[Explanation of symbols]

 101, 102, 103... 10N Dust collection elements 201, 202, 203... 532 Abnormal signal output circuit 541, 542 Operation signal transmitting circuit 551, 552 Abnormal signal transmitting circuit 561, 562 Power supply circuit 90 Control circuit

Continuation of the front page (72) Inventor Seiji Watanabe 1-1, Nishiichitsuya, Settsu-shi, Osaka Daikin Industries, Ltd. Yodogawa Works (56) References JP-A-61-193221 (JP, A) JP-A-48- 9243 (JP, A) (58) Fields investigated (Int. Cl. ⁶ , DB name) H02J 1/00 304 H02J 1/00 310 B03C 3/68

Claims (1)

(57) [Claims] A plurality of objects (101, 102, 103... 10N) are connected to each other, and each of the objects (101, 102, 103... 10N) is connected.
Multiple high-voltage application units (2
01,202,203 ... 20N) and each high voltage application part (201,202,203
.. 20N) and a control unit (30) for controlling the driving of the plurality of high-voltage applying units (201, 202, 203... 20N) are connected in series. Applicator (201,202,203 ... 20N)
Are connected to the control unit (30), and the high-voltage applying units (201, 202, 203,..., 20N) are connected to the objects (101, 10) based on the operation signal from the control unit (30).
High voltage applying means for applying a high voltage to (2,103 ... 10N), abnormality detecting means for detecting an abnormality of the object to be applied (101,102,103 ... 10N), and high voltage applying means from the control unit (30). When receiving the operation signal, when the operation signal transmission means for transmitting the operation signal to the adjacent high voltage application unit of the subsequent stage, and abnormality of the applied object (101, 102, 103 ... 10N) is detected by the abnormality detection means, The abnormal signal is sent to the control unit (3
0), the control unit (30) includes an operation signal transmitting unit that transmits an operation signal to the foremost high voltage application unit (201), and a foreground high voltage application unit. (201) A high voltage application device comprising an operation signal transmission stopping means for stopping the transmission of the operation signal from the operation signal transmitting means when receiving an abnormal signal from the apparatus.