JP2013105601A - Ion generation device and ion generation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an ion generation device and an ion generation system in which replacement work can be efficiently carried out.SOLUTION: PCI control circuits 51 to 54 measure the aggregate operating time of a plurality of ion generation units 41 to 44. When the aggregate operating time of any of the ion generation units is equal to or greater than a time T1, a microcomputer 50 determines whether the aggregate operating time of the other ion generation units than the ion generation unit concerned is equal to or greater than a time T2(<T1). When the microcomputer 50 determines that the aggregate operating time of the other ion generation units than the ion generation unit whose aggregate operating time is equal to or greater than the time T1 is equal to or greater than the time T2(<T1), it notifies, in addition to the ion generation unit whose aggregate operating time is equal to or greater than the time T1, an ion generation unit whose aggregate operating time is equal to or greater than the time T2 and is less than the time T1 as the subject of notification.

Description

  The present invention relates to an ion generator and an ion generation system that generate ions.

  Conventionally, it is possible to deodorize and disinfect indoor wall surfaces by generating mist from a liquid having a deodorizing action and a sterilizing action and diffusing the mist into the room by an air flow generated using a fan. Air purifiers are in practical use.

  For example, an ion generator is disclosed that sucks air from an air suction port and blows out air containing ions generated by an ion generator from a plurality of air outlets (see Patent Document 1).

  In such an ion generator, an ion generating part, an ion sensor, etc. are provided in each of a plurality of air outlets. Then, the total operation period of the ion generation unit is recorded, and when the total operation time of the ion generation unit exceeds a predetermined lifetime, a warning lamp or the like is lit to urge replacement of the ion generation unit.

JP 2010-29553 A

  However, in an ion generation device including a plurality of ion generation units as in Patent Document 1, each ion generation unit can be individually replaced, and therefore the point in time for replacement differs for each ion generation unit. For example, although the warning light is on and one ion generator is replaced, the total operation time of another ion generator is approaching the life time. When the number of days (hours) has not elapsed, there may occur a situation where another ion generator must be replaced. For this reason, the ion generator which can perform exchange work efficiently was desired.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide an ion generation apparatus and an ion generation system capable of efficiently performing replacement work.

  An ion generation apparatus according to the present invention includes an ion generation apparatus that discharges ions generated by a plurality of ion generation units from a plurality of outlets, and a time measuring unit that measures the total operation time of each of the plurality of ion generation units. A determination unit that determines whether the total operation time of the ion generation units other than the ion generation unit is equal to or greater than the time T2 (<T1) when the total operation time of the ion generation units is equal to or greater than the time T1; An ion generation unit having a total operation time of time T2 or more and a notification unit that notifies any one of the ion generation units as a notification target.

  In the present invention, the timer unit counts the total operation time of each of the plurality of ion generation units. When the total operation time of any of the ion generation units is equal to or greater than time T1, the determination unit determines whether the total operation time of the ion generation units other than the ion generation unit is equal to or greater than time T2 (<T1) To do. The time T1 is a predetermined lifetime, for example, 19000 hours. The time T2 is shorter than the time T1, and is, for example, a time close to the life time although the life time has not been reached. For example, if the time T1 is 19000 hours, the time T2 can be shorter than the time T1 by 500 hours. Times T1 and T2 are appropriately determined according to the ion generation unit.

  When the determination unit determines that the total operation time of the ion generation units other than the ion generation unit is equal to or longer than the time T2 (<T1), the notification unit adds to the ion generation unit whose total operation time is the time T1 or more, An ion generation unit having a total operation time of time T2 or more (more precisely, a total operation time of time T2 or more and less than time T1) is notified as a notification target. As a result, when there is an ion generation unit that has reached the end of its life, if there is also an ion generation unit that will be at the end of its life, both ion generation units are notified as objects to be replaced. That is, when there is an ion generation unit that has reached the end of its life, if there is also an ion generation unit that is near the end of its life, it is notified that it is time to replace it. As a result, it is possible to prevent the situation where another ion generation unit has to be replaced at a time when not many days (hours) have passed since the replacement of one ion generation unit, and to perform the replacement work efficiently. Can do.

  In the ion generator according to the present invention, the determination unit determines whether or not the total operation time of any of the plurality of ion generation units is equal to or longer than a time T3 (≦ T2). And when the total operation time is determined to be equal to or greater than time T3, a notification unit for notification and an acquisition unit for acquiring a notification request signal for notifying the ion generation unit to be notified from the external device In addition, the notification unit is configured to notify the ion generation unit to be notified when the acquisition unit acquires the notification request signal.

  In the present invention, the determination unit determines whether or not the total operation time of any of the plurality of ion generation units is equal to or longer than time T3 (≦ T2). The time T3 is a time for specifying the execution time of the inspection or cleaning of the ion generation unit, or a time for specifying the notification time point informing that the replacement time of the ion generation unit is near. It is a time shorter than the time (time T1, T2). When the determination unit determines that the total operation time is equal to or greater than time T3, the notification unit notifies that fact. The notification unit can use, for example, an LED lamp. And, in order to specify the ion generation unit to be inspected or cleaned by maintenance personnel, for example, when transmitting a notification request signal for notifying the ion generation unit to be notified from an external device such as a remote control, The acquisition unit acquires the notification request signal. The acquisition unit is, for example, a light receiving unit such as a remote control.

  A notification part notifies the ion generation unit used as information object, when a notice demand signal is acquired in an acquisition part. As a result, even if any of the ion generation units reaches the time of inspection or cleaning, the operation of the ion generation unit and the operation of the ion generation device should be continued until maintenance personnel perform inspection or cleaning work. Can do. Moreover, since it can be easily confirmed which ion generation unit should be inspected or cleaned at the time of inspection or cleaning work by maintenance personnel or the like, the efficiency of work such as inspection or cleaning can be improved.

  The ion generator according to the present invention is provided with a wind direction adjusting plate that adjusts a wind direction at each of the plurality of outlets, and the notification unit is configured to release the ions from the ion generation unit to be notified. The adjustment plate is configured to be notified in a predetermined open / close state.

  In the present invention, a wind direction adjusting plate for adjusting the wind direction is provided at each of the plurality of outlets. The notification unit notifies the airflow direction adjusting plate of the outlet from which ions from the ion generation unit to be notified are released in a predetermined open / close state. For example, the wind direction adjusting plate corresponding to the ion generation unit to be notified can be closed, and the wind direction adjusting plate corresponding to the ion generation unit other than the notification target can be opened. For example, it is possible to stop the operation of only the ion generation unit that is the replacement target due to the life and continue the operation of the ion generation unit that is not the replacement target. In addition, when there is an ion generation unit to be exchanged, when stopping the operation of the ion generation device, the air direction adjustment plate corresponding to the ion generation unit to be notified is opened or the state in which the opening / closing operation is repeated, and other than the notification target The wind direction adjusting plate corresponding to the ion generation unit can be closed. According to the open / closed state of the wind direction adjusting plate, it is possible to easily confirm the one to be replaced among the plurality of ion generating units.

  In the ion generator according to the present invention, each of the plurality of air outlets is provided with a display unit, and the notification unit displays a predetermined part of the air outlet display unit from which ions from the ion generation unit to be notified are released. It is configured to notify in a state.

  In this invention, the display part is provided in each of several outlet. The notification unit notifies the display unit of the air outlet from which ions from the ion generation unit to be notified are released in a predetermined display state. For example, the display unit corresponding to the ion generation unit to be notified can be turned on or blinked, and the display unit corresponding to the ion generation unit other than the notification target can be turned off. Depending on the display state of the display unit, it is possible to easily check the object to be inspected or cleaned or replaced from among a plurality of ion generating units.

  The ion generation system according to the present invention includes an ion generation system including a plurality of ion generation devices that discharge ions generated by a plurality of ion generation units from a plurality of outlets, and each ion generation device includes the plurality of ions of its own device. A timekeeping unit that counts the total operation time of each generation unit, and a transmission unit that transmits information to that effect to another ion generation device when the total operation time of any of the ion generation units of the device is equal to or greater than time T1 And a notification unit that notifies an ion generation unit whose total operation time is equal to or longer than time T1 as a notification target, wherein the other ion generation device receives the information, and a reception unit that receives the information. A determination unit that determines whether or not the total operation time of the plurality of ion generation units of the device is equal to or greater than time T2 (<T1), and the total operation time There characterized in that it comprises a notifying unit for notifying the ion generating unit of the above time T2 as a notification target.

  In the present invention, the time measuring unit of each ion generating device measures the total operation time of each of the plurality of ion generating units. When the total operation time of one of the ion generation units of the self-device is equal to or longer than time T1, each ion generation device transmits information to that effect to the other ion generation devices by the transmission unit, and the total operation time is time. A notification unit notifies an ion generation unit of T1 or more as a notification target. The other ion generation device receives the information to that effect by the reception unit, and determines whether or not the total operation time of the plurality of ion generation units of its own device is equal to or longer than time T2 (<T1). Then, the other ion generation device notifies the notification unit of the ion generation unit whose total operation time is the time T2 or more (more precisely, the total operation time is the time T2 or more and less than the time T1). The time T1 is a predetermined lifetime, for example, 19000 hours. The time T2 is shorter than the time T1, and is, for example, a time close to the life time although the life time has not been reached. For example, if the time T1 is 19000 hours, the time T2 can be shorter than the time T1 by 500 hours. Times T1 and T2 are appropriately determined according to the ion generation unit.

  Accordingly, in an ion generation system including a plurality of ion generation devices, when there is an ion generation unit that has reached the end of its lifetime, not only the one ion generation device but also other ion generation devices will soon When there is an ion generation unit that has a lifetime, the corresponding ion generation unit in both ion generation apparatuses is notified as an object to be replaced. In other words, when an ion generation unit that has reached the end of its life exists in one ion generation apparatus, if there is an ion generation unit that is near the end of its life in another ion generation apparatus, it is simultaneously notified that it is time for replacement. This prevents a situation in which the ion generation unit of another ion generation device must be replaced at a time when not many days (hours) have passed since the replacement of the ion generation unit of one ion generation device, Exchange work can be performed efficiently.

  According to the present invention, it is possible to prevent a situation in which another ion generation unit must be replaced at a time when not many days (hours) have elapsed since the time when one ion generation unit was replaced, thereby efficiently performing the replacement work. Can be done.

It is an external appearance perspective view which shows an example of a structure of the state which closed the louver of the ion generator of this Embodiment. It is an external appearance perspective view which shows an example of the structure of the state which opened the louver of the ion generator of this Embodiment. It is a perspective view which shows an example of an internal structure of the ion generator of this Embodiment. It is an external appearance perspective view which shows an example of the ion generation unit of this Embodiment. It is a block diagram which shows an example of a structure of the ion generator of this Embodiment. It is explanatory drawing which shows an example of determination of the total operation time of the ion generation unit by the ion generator of this Embodiment. It is explanatory drawing which shows the other example of determination of the total operation time of the ion generation unit by the ion generator of this Embodiment. It is a top view which shows an example of the mode at the time of replacement | exchange of the ion generation unit of the ion generator of this Embodiment. It is a flowchart which shows an example of the process sequence of the ion generator of this Embodiment. It is a flowchart which shows an example of the process sequence of the ion generator of this Embodiment. It is a flowchart which shows an example of the process sequence of the ion generator of this Embodiment. It is a block diagram which shows an example of a structure of the ion generation system of this Embodiment.

  Hereinafter, the present invention will be described with reference to the drawings illustrating embodiments thereof. FIG. 1 is an external perspective view showing an example of a configuration in which the louver of the ion generator 100 of the present embodiment is closed, and FIG. 2 is a configuration of the ion generator 100 of the present embodiment in a state where the louver is opened. FIG. 3 is a perspective view showing an example of the internal configuration of the ion generator 100 according to the present embodiment. The ion generator 100 includes a box-shaped case 1 having an open surface, a rectangular panel 2 attached to the opening surface of the case 1, and the like.

  By housing the case 1 in an opening provided on a mounting surface such as a ceiling surface, the panel 2 is mounted on the mounting surface. When the ion generator 100 is installed on the ceiling, the panel 2 is exposed from the mounting surface, and the ion generator 100 is a so-called ceiling-embedded ion generator.

  The panel 2 is provided with a rectangular air intake 10 at the center, and the height dimension (thickness dimension) of the portion where the intake 10 is provided is large, and the height from the center of the panel 2 toward the periphery increases. The surface (front surface) of the panel 2 is inclined with respect to the surface of the inlet 10 so as to reduce the size.

  Rectangular air outlets 11, 12, 13, and 14 are provided at the peripheral edge of the panel 2. In addition, louvers 21, 22, 23, and 24, which are wind direction adjusting plates, are provided at the respective outlets 11 to 14.

  The louvers 21 to 24 have a rectangular shape having substantially the same dimensions as the air outlets 11 to 14. The louvers 21 to 24 are provided so as to be rotatable around an axis along the edge of the air outlets 11 to 14 on the side opposite to the peripheral edge of the panel 2. The rotating operation of the louvers 21 to 24 is controlled by a louver control circuit 58 described later. By closing the louvers 21 to 24, the air outlets 11 to 14 are covered with the louvers 21 to 24. In addition, by opening the louvers 21 to 24 at an appropriate angle (for example, an angle with respect to the surface of the intake port 10), the air containing ions blown from the blowout ports 11 to 14 hits the inner side surfaces of the louvers 21 to 24 and the wind direction. Can be adjusted. Moreover, the air containing the ion which blows off from the blower outlets 11-14 can be blown off in the direction which goes to the peripheral part from the center part of the panel 2. FIG.

  LED31, 32, 33, 34 as a display part is provided in the vicinity of the blower outlets 11-14 corresponding to each blower outlets 11-14. LED31-34 can be provided between the peripheral part of the inlet 10, and the edge part of each blower outlet 11-14, for example.

  The LEDs 31 to 34 may be provided with a light guide member (not shown) so that, for example, a desired region on the outer surface of the louvers 21 to 24 can be illuminated with light at the time of lighting. Thereby, irrespective of the open / closed state of the louvers 21-24, the desired area | region of the outer surface of the louvers 21-24 can be made to shine, and the visibility from the outside can be improved.

  A display provided on the front of the panel 2 includes an LED lamp (warning light) as a notification unit for notifying the timing of inspection or cleaning, a light receiving unit as an acquisition unit for acquiring a predetermined signal from an external device such as a remote control, etc. A panel 25 is provided.

  For example, the display panel 25 includes a plurality of LED lamps, an LED lamp (operation lamp) indicating that the ion generating apparatus 100 is in an operating state, and an LED lamp (notification) for inspecting or cleaning the ion generation unit ( Warning light) lamps are provided.

  Further, as shown in FIG. 3, a fan 3 is provided at the center of the case 1. The fan 3 is a so-called turbo fan, and includes a plurality of slats erected in the rotation axis direction. The slats are inclined along the circumferential direction of the fan 3. That is, the distance along the radial direction from the rotation axis of the fan 3 to both ends of the slats is different, and the slats push air out by rotating the fan 3. Thereby, when the fan 3 rotates, air is taken in from an inlet, and the air taken in by rotation of the fan 3 is discharged | emitted in the state containing ion from each blower outlet 11-14.

  As shown in FIG. 2 or FIG. 3, ion generation units 41, 42, 43, and 44 are mounted inside the respective outlets 11 to 14.

  FIG. 4 is an external perspective view showing an example of the ion generation unit 41 of the present embodiment. In addition, since the other ion generation units 42-44 are also equivalent to the ion generation unit 41, the ion generation unit 41 is demonstrated below.

  The ion generation unit 41 includes a box-shaped storage unit 411. The storage unit 411 stores an ion generation unit including electrode units 413 and 412 that generate positive ions and negative ions, an ion sensor 414, and the like. .

  The ion generating part is a rectangular plate-like body, provided with an electrode part 412 that generates negative ions in the vicinity of one end part, and provided with an electrode part 413 that generates positive ions in the vicinity of the other end part. is there.

  A connector 415 for mechanically and electrically connecting the ion generating unit 41 is provided at one end of the accommodating portion 411. In addition, a threaded portion 416 for fixing the ion generating unit 41 to the case 1 is provided at one end of the accommodating portion 411.

The ion generation unit 41 ionizes water vapor in the air by plasma discharge, so that H ⁺ (H ₂ O) _n (n is an arbitrary natural number) as positive ions and O ₂ ⁻ (H ₂ as negative ions). O) _m (m is an arbitrary natural number). These chemically react to generate hydrogen peroxide (H ₂ O ₂ ) and / or hydroxyl radicals (OH), which are active species, and remove airborne bacteria and airborne viruses.

  Thereby, each blower outlet 11-14 can blow out the air containing a positive ion and the air containing a negative ion independently, and the positive ion and negative ion in the air which blown out from the ion generator 100 are immediately. It can prevent neutralization. And ion diffusibility can be improved by preventing neutralization of ions.

  FIG. 5 is a block diagram showing an example of the configuration of the ion generator 100 of the present embodiment. The ion generator 100 includes a microcomputer 50, ion generation units 41 to 44, PCI control circuits 51 to 54, a remote control light receiving unit 55, a memory 56 that stores predetermined data, the fan 3, the operation / stop of the fan 3, and the rotation speed. The fan control circuit 57 that controls the louvers, the louvers 21 to 24, the louver control circuit 58 that drives the opening and closing of the louvers 21 to 24, the display units 31 to 34, and the display unit that controls the lighting, blinking and extinguishing of the display units 31 to 34 A control circuit 59 and the like are provided.

  The PCI control circuits 51 to 54 receive instructions from the microcomputer 50 and control the driving and stopping of the ion generation units 41 to 44. For example, the ion generation units 41 to 44 are continuously driven (ion is generated continuously), or the ion generation units 41 to 44 are intermittently driven (on / off is repeated at predetermined intervals, thereby intermittently generating ions. To generate).

  Moreover, the PCI control circuits 51-54 have a function as a time measuring part which measures the total operation time of the ion generation units 41-44. In addition, the structure which the microcomputer 50 performs the function of the said time measuring part may be sufficient.

  The PCI control circuits 51 to 54 can also determine whether or not the operations of the ion generation units 41 to 44 are normal. Whether or not the operation is normal is, for example, whether or not the ion concentration generated in the ion generation units 41 to 44 is within a normal value range, and whether or not the ion generation units 41 to 44 are normally attached. Then, it is determined whether or not there is an error in the data (for example, the total operation time, the number of abnormal ion generations, etc.) in the memory built in the ion generation units 41 to 44. The microcomputer 50 can also determine whether the ion generation units 41 to 44 are normal or abnormal.

  The microcomputer 50 has a function as a determination unit that determines whether the total operation time is equal to or longer than a predetermined time. Hereinafter, the determination process by the microcomputer 50 will be described.

  FIG. 6 is an explanatory diagram showing an example of determination of the total operation time of the ion generation unit by the ion generation apparatus 100 of the present embodiment. In the example of FIG. 6, it is assumed that four ion generation units A to D are mounted on the ion generation apparatus.

  The microcomputer 50 determines whether or not the total operation time of any of the plurality of ion generation units A to D is equal to or longer than a third time T3 (a second time T2 or less described later). The third time T3 is, for example, a time for specifying the execution time of inspection or cleaning of the ion generation unit, or a time for specifying a notification time point informing that the replacement time of the ion generation unit is near. The time is shorter than the replacement period (first time T1 and second time T2 described later) due to the lifetime.

  When the microcomputer 50 determines that there is an ion generation unit having a total operation time of the third time T3 or more (in the example of FIG. 6, the ion generation unit A corresponds), the warning light on the display panel 25 is turned on or blinked. Let

  Then, in order to identify an ion generation unit (in the example of FIG. 6, the ion generation unit A corresponds) that is to be inspected or cleaned, or to be replaced soon, maintenance personnel or the like can notify from an external device such as a remote control. When the notification request signal for notifying the target ion generation unit is transmitted, the remote control light receiving unit 55 of the display panel 25 acquires the notification request signal.

  When the notification request signal is acquired by the remote control light receiving unit 55, the microcomputer 50 turns on or blinks an LED as a display unit corresponding to an ion generation unit to be inspected or cleaned or whose replacement time is near. As a result, if any ion generation unit reaches the time of inspection or cleaning, or if it is almost time for replacement, the operation of the ion generation unit will be continued until maintenance personnel perform inspection, cleaning, or replacement. And the operation of the ion generator 100 can be continued. In addition, it is possible to easily check which ion generation unit should be checked, cleaned, or replaced at the time of inspection or cleaning work by maintenance personnel, etc., or at the time of replacement. The work efficiency can be increased.

  FIG. 7 is an explanatory view showing another example of determination of the total operation time of the ion generation unit by the ion generation apparatus 100 of the present embodiment. In the example of FIG. 7, it is assumed that four ion generation units A to D are mounted on the ion generation apparatus.

  The microcomputer 50 determines whether or not the total operation time of any of the plurality of ion generation units A to D is equal to or greater than the first time T1, and the total operation time of any of the ion generation units is the first time T1. In the case of the above (in the example of FIG. 7, the ion generation unit A corresponds), it is determined whether or not the total operation time of the ion generation units other than the ion generation unit is equal to or longer than the second time T2 (<T1). .

  The first time T1 is a predetermined lifetime, for example, 19000 hours. The second time T2 is shorter than the first time T1, and is, for example, a time close to the life time although the life time has not been reached. For example, if the first time T1 is 19000 hours, the second time T2 can be shorter than the first time T1 by 500 hours. The first time T1 and the second time T2 can be appropriately determined according to the type or performance of the ion generation unit.

  When there is an ion generation unit whose total operation time is equal to or longer than the first time T1 (in the example of FIG. 7, the ion generation unit A corresponds), the total operation time is the second time T2 in the ion generation units other than the ion generation unit. When it is determined that there is something that is greater than (<T1), the microcomputer 50 adds to the ion generation unit (the ion generation unit A in the example of FIG. 7) whose total operation time is the first time T1 or more, An ion generating unit (the ion generating unit C in the example of FIG. 7) having a total operation time of the second time T2 or more (more precisely, the total operation time is the second time T2 or more and less than the first time T1). Target for notification.

  In other words, the microcomputer 50 closes the louvers corresponding to the ion generation units A and C that have been replaced due to their lifetimes, and opens the louvers corresponding to the ion generation units B and D that have not reached their lifetimes. Thereby, operation | movement of the ion generation unit which is not a replacement | exchange object can be continued.

  Moreover, the microcomputer 50 lights or blinks the display part (LED) corresponding to the ion generation units A and C which became exchange object by lifetime, and the display part corresponding to the ion generation units B and D which has not reached lifetime. (LED) can be turned off.

  The replacement time is notified by the open / closed state of the louver corresponding to the ion generation unit to be replaced and / or the lighting state of the display unit (LED). If there is an ion generation unit that has reached the end of its life and there is also an ion generation unit that will have an end of life, it is notified that both ion generation units are to be replaced. That is, when there is an ion generation unit that has reached the end of its life, if there is also an ion generation unit that is near the end of its life, it is notified that it is time to replace it. As a result, it is possible to prevent the situation where another ion generation unit has to be replaced at a time when not many days (hours) have passed since the replacement of one ion generation unit, and to perform the replacement work efficiently. Can do.

  FIG. 8 is a plan view showing an example of a state when the ion generation unit of the ion generation apparatus 100 of the present embodiment is replaced. In the example of FIG. 8, the total operation time of the ion generation unit 41 corresponding to the louver 21 (air outlet 11) is equal to or longer than the first time T1, and the total operation time of the ion generation unit 43 corresponding to the louver 23 (air outlet 13). Is not less than the second time T2 and less than the first time T1.

  In this case, the louvers 21 and 23 corresponding to the ion generation units 41 and 43 to be exchanged are closed, and the louvers 22 and 24 corresponding to the ion generation units 42 and 44 not being exchanged are opened. Further, the LEDs 31 and 33 are turned on so that the regions indicated by the reference symbol S of the louvers 21 and 23 corresponding to the ion generation units 41 and 43 to be exchanged are lit, and the louvers 22 to the ion generation units 42 and 44 that are not exchange targets are provided. The LEDs 32 and 34 corresponding to 24 are turned off. Accordingly, it is possible to easily determine which ion generation unit should be replaced as well as whether or not the replacement is performed from the outside. The mode at the time of replacement is not limited to the example of FIG.

  By closing the louver corresponding to the ion generation unit to be replaced and opening the louver corresponding to the ion generation unit other than the replacement target, only the ion generation unit that is the replacement target due to its life is stopped. In addition, the operation of the ion generation unit that is not the replacement target can be continued.

  In addition, when it is determined that there is an ion generation unit to be exchanged, when the operation of the ion generation apparatus 100 is stopped, for example, a state where the louver corresponding to the ion generation unit to be exchanged is opened or an opening / closing operation is repeated. The louver corresponding to the ion generation unit other than the exchange target can be closed. Depending on the open / closed state of the louver, it is possible to easily confirm the one to be replaced from among a plurality of ion generating units.

  In addition to the replacement object, the display unit (LED) corresponding to the louver for the ion generation unit that has been inspected or cleaned, or the ion generation unit that is approaching the replacement time is lit or blinked to be inspected or cleaned. Or the display part (LED) corresponding to the louver with respect to the ion generation unit which is not a replacement | exchange object can also be made into a light extinction state. Thereby, according to the display state of a display part (LED31-34), the thing of inspection or cleaning object or the object of exchange can be easily checked from a plurality of ion generation units.

  Next, the operation of the ion generator 100 of the present embodiment will be described. FIG. 9, FIG. 10 and FIG. 11 are flowcharts showing an example of the processing procedure of the ion generator 100 of the present embodiment. In the following processing procedure, the main body will be described as the microcomputer 50 for convenience.

  The microcomputer 50 determines whether or not an operation start signal has been received (S11). If the operation start signal has not been received (NO in S11), the microcomputer 50 continues the process of step S11. The operation start signal is transmitted from the remote control to the ion generator 100, for example.

  When the operation start signal is received (YES in S11), the microcomputer 50 starts the operation of the fan and the ion generation unit, turns on the operation lamp, and opens the louver (S12). The microcomputer 50 measures the total operation time of each ion generation unit (S13).

  The microcomputer 50 determines whether or not the total operation time of any of the ion generation units is equal to or greater than the third time T3 (S14). If the total operation time is not equal to or greater than the third time T3 (NO in S14), It is determined whether an operation stop signal has been received (S15). The operation stop signal is transmitted from the remote control to the ion generator 100, for example.

  If the operation stop signal has not been received (NO in S15), the microcomputer 50 performs the processes in and after step S13. If the microcomputer 50 receives the operation stop signal (YES in S15), the microcomputer 50 stops the operation of the fan and the ion generation unit. Then, the operation lamp is turned off, the louver is closed (S16), and the process is terminated.

  If the total operation time of any of the ion generation units is equal to or longer than the third time T3 (YES in S14), the microcomputer 50 turns on or blinks the warning lamp on the display panel 25 (S17). By turning on or blinking the warning lamp, for example, it is possible to notify maintenance personnel that any ion generation unit in the ion generator 100 is in the inspection or cleaning time.

  The microcomputer 50 determines whether a notification request signal has been received (S18). The notification request signal is transmitted from the remote control to the ion generator 100 by, for example, maintenance personnel. When the notification request signal is received (YES in S18), the microcomputer 50 lights or blinks the display unit (LED) corresponding to the ion generation unit whose total operation time is the third time T3 or more (S19). It should be noted that the ion generation unit can continue to operate without problems at the time of inspection or cleaning, or the time of replacement, so that it is time for inspection or cleaning only with the display (LED), or at the time of replacement. It is not necessary to notify that the vehicle is approaching and to notify when the louver is opened or closed.

  The microcomputer 50 determines whether an operation stop signal has been received (S20). The operation stop signal is transmitted from the remote control to the ion generation device 100 by a maintenance person, for example, for inspection or cleaning of the ion generation unit.

  When the operation stop signal is received (YES in S20), the microcomputer 50 stops the operation of the fan and the ion generation unit, turns off the operation lamp, closes the louver (S21), and ends the process.

  If the operation stop signal is not received (NO in S20), the microcomputer 50 determines whether or not the total operation time of any of the ion generation units is equal to or greater than the first time T1 (S22), and the total operation time. If it is not the first time T1 or more (NO in S22), the process of step S20 is performed.

  When the total operation time of any of the ion generation units is equal to or longer than the first time T1 (YES in S22), the microcomputer 50 performs a process of step S24 described later.

  When the notification request signal has not been received (NO in S18), the microcomputer 50 determines whether or not the total operation time of any of the ion generation units is equal to or longer than the first time T1 (S23). If the time is not equal to or longer than the first time T1 (NO in S23), the process of step S18 is performed. When the total operation time is equal to or longer than the first time T1 (YES in S23), the microcomputer 50 performs a process of step S24 described later.

  The microcomputer 50 determines whether or not the total operation time of the other ion generation units is equal to or longer than the second time T2 (S24), and the total operation time of the other ion generation units is equal to or longer than the second time T2 (YES in S24), stop the operation of the ion generation unit whose total operation time is the first time T1 or more and the ion generation unit whose total operation time is the second time T2 or more (and less than the first time T1) Then, the louver corresponding to the ion generation unit is closed, and the display unit (LED) is turned on or blinked (S25). As a result, not only the ion generation unit that has reached the end of life but also the ion generation unit that has a near end of life can be replaced at the same time. In this case, the operation of the ion generation unit that is not a replacement target can be continuously performed without stopping.

  When the total operation time of the other ion generation units is not equal to or longer than the second time T2 (NO in S24), the operation of the ion generation unit whose total operation time is equal to or longer than the first time T1 is stopped, and the ion generation unit corresponds to the ion generation unit. The louver is closed, and the display unit (LED) is turned on or blinked (S26).

  The microcomputer 50 determines whether an operation stop signal has been received (S27). The operation stop signal is transmitted from the remote control to the ion generation apparatus 100 by a maintenance person, for example, for replacement of the ion generation unit.

  When the operation stop signal is received (YES in S27), the microcomputer 50 stops the operation of the ion generation unit other than the ion generation unit to be replaced, stops the fan, turns off the operation lamp, and turns off the display unit. Then, all the louvers are closed (S28), and the process is terminated. When the operation stop signal is not received (NO in S27), the microcomputer 50 continues the processing from step S13.

  In the above-described embodiment, the determination process for determining whether or not the total operation time is equal to or longer than the third time T3 is not essential, and the configuration for notifying the timing of inspection or cleaning may not be provided.

  According to the present embodiment, among the plurality of ion generating units, those that are close to the replacement time notify the replacement time at the same time, so the situation where the ion generating unit is replaced many times during a short period (date and time). Therefore, the replacement work can be performed efficiently.

  In the above example, one ion generation device has been described. However, the present invention is not limited to the above example, and the contents of the above embodiment are applied to an ion generation system including a plurality of ion generation devices. be able to. Hereinafter, the ion generation system will be described.

  FIG. 12 is a block diagram showing an example of the configuration of the ion generation system of this embodiment. In the ion generation system, a plurality of ion generation devices 150 are connected via a communication line 80. The ion generator 150 further includes a communication unit 151 as a transmitter and a receiver in addition to the configuration of the ion generator 100 illustrated in FIG. That is, the difference between the ion generator 150 and the ion generator 100 is that the ion generator 150 includes a communication unit 151. In addition, since structures other than the communication part 151 of the ion generator 150 are the same as that of the ion generator 100, illustration and description are abbreviate | omitted for convenience.

  In the ion generation system according to the present embodiment, the PCI control circuits (51 to 54) of the respective ion generation devices 150 measure the total operation time of each of the plurality of ion generation units (41 to 44). When the total operation time of any of the ion generation units (41 to 44) of each of the ion generation devices 150 is equal to or longer than the first time T1, the information to that effect is communicated to the other ion generation devices 150 by the communication unit 151. In addition, the notification unit notifies the ion generation unit whose total operation time is equal to or longer than the first time T1 as a notification target. Specifically, the replacement time is notified by the open / close state of the louver corresponding to the ion generation unit to be replaced and / or the lighting state of the display unit (LED).

  The other ion generator 150 receives the information to that effect by the communication unit 151, and is the total operation time of the plurality of ion generation units (41 to 44) of the own device equal to or longer than the second time T2 (<T1)? The microcomputer (50) determines whether or not. Then, the other ion generator 150 is notified of the ion generation unit whose total operation time is the second time T2 or more (more precisely, the total operation time is the second time T2 or more and less than the first time T1). As a notification unit. Specifically, the replacement time is notified by the open / close state of the louver corresponding to the ion generation unit to be replaced and / or the lighting state of the display unit (LED).

  In the case of the ion generation system, the first time T1 is a predetermined lifetime, for example, 19000 hours. The second time T2 is shorter than the first time T1, and is, for example, a time close to the life time although the life time has not been reached. For example, if the first time T1 is 19000 hours, the second time T2 can be shorter than the first time T1 by 500 hours. The first time T1 and the second time T2 are appropriately determined according to the ion generation unit.

  Accordingly, in an ion generation system including a plurality of ion generation devices, when there is an ion generation unit that has reached the end of its lifetime, not only the one ion generation device but also other ion generation devices will soon When there is an ion generation unit that has a lifetime, the corresponding ion generation unit in both ion generation apparatuses is notified as an object to be replaced. In other words, when an ion generation unit that has reached the end of its life exists in one ion generation apparatus, if there is an ion generation unit that is near the end of its life in another ion generation apparatus, it is simultaneously notified that it is time for replacement. This prevents a situation in which the ion generation unit of another ion generation device must be replaced at a time when not many days (hours) have passed since the replacement of the ion generation unit of one ion generation device, Exchange work can be performed efficiently.

  In the example of FIG. 12, the mutual ion generator 150 transmits and receives information via the communication line 80, but is not limited to wired communication, and the mutual ion generator 150 transmits information via wireless communication. It can also be set as the structure which transmits / receives.

DESCRIPTION OF SYMBOLS 1 Case 2 Panel 3 Fan 10 Inlet 11, 12, 13, 14 Air outlet 21, 22, 23, 24 Louver (wind direction adjustment board, notification part)
25 Display panel (notification unit, acquisition unit)
31, 32, 33, 34 LED (display unit, notification unit)
41, 42, 43, 44 Ion generation unit 50 Microcomputer (determination unit)
51, 52, 53, 54 PCI control circuit 55 Remote control light receiving unit (acquisition unit)
151 Communication unit (transmission unit, reception unit)

Claims (5)

In an ion generator that discharges ions generated by a plurality of ion generation units from a plurality of outlets,
A timekeeping unit for measuring the total operation time of each of the plurality of ion generation units;
A determination unit that determines whether or not the total operation time of any of the ion generation units is equal to or greater than time T1, and whether or not the total operation time of the ion generation units other than the ion generation unit is equal to or greater than time T2 (<T1); ,
An ion generation apparatus comprising: an ion generation unit having a total operation time of time T2 or more; and a notification unit that notifies any one of the ion generation units as a notification target. The determination unit
Whether or not the total operation time of any of the plurality of ion generation units is equal to or greater than time T3 (≦ T2);
An informing unit for informing when the determining unit determines that the total operation time is time T3 or more;
An acquisition unit for acquiring a notification request signal for notifying the ion generation unit to be notified from an external device;
The notification unit
The ion generator according to claim 1, wherein when the notification request signal is acquired by the acquisition unit, the ion generation unit to be notified is notified. A wind direction adjusting plate for adjusting the wind direction is provided at each of the plurality of outlets,
The notification unit
The ion according to claim 1 or 2, wherein a notification is made by setting a wind direction adjusting plate of a blower outlet from which ions from a target ion generation unit are released to a predetermined open / close state. Generator. A display section is provided for each of the plurality of outlets,
The notification unit
The ion generation according to claim 1 or 2, wherein the notification is performed by setting a display portion of a blower outlet from which ions from the ion generation unit to be notified are released to a predetermined display state. apparatus. In an ion generation system including a plurality of ion generation devices that discharge ions generated by a plurality of ion generation units from a plurality of outlets,
Each ion generator
A time measuring unit for measuring the total operation time of each of the plurality of ion generation units of the own device;
When the total operation time of any of the ion generation units of the own device is time T1 or more, a transmission unit that transmits information to that effect to another ion generation device;
A notification unit for notifying an ion generation unit having a total operation time of time T1 or more as a notification target,
The other ion generator is
A receiving unit for receiving the information;
A determination unit that determines whether or not the total operation time of the plurality of ion generation units of the device is equal to or greater than time T2 (<T1) when the reception unit receives the information;
An ion generation system comprising: a notification unit that notifies an ion generation unit having a total operation time of time T2 or more as a notification target.

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