JP2010116161A - Electrostatic atomizing device for vehicle - Google Patents

Abstract

PROBLEM TO BE SOLVED: To deodorize or inactivate allergens when a user gets into a vehicle to drive.
SOLUTION: A moisture supply means 13 for supplying moisture to the discharge electrode 11, a discharge port 17 for electrostatically atomizing the moisture by applying a high voltage to the discharge electrode 11 and discharging mist into the vehicle interior, and the high voltage And a control means C for controlling the electrostatic atomization operation by the application, and is connected to the vehicle power source V without passing through an ignition key switch. An operation time setting unit 5 for inputting an operation start time is provided, and the control means starts the electrostatic atomization operation at the set operation start time and terminates the electrostatic atomization operation after a predetermined time has elapsed, If the remaining capacity detected by the detecting means for detecting the remaining capacity is equal to or less than the threshold value, the electrostatic atomization operation is terminated without waiting for the elapse of the predetermined time.
[Selection] Figure 1

Description

  The present invention relates to an electrostatic atomizer for a vehicle.

  In the case of a vehicle such as a passenger car, there is a problem that a smell such as cigarette is trapped in the passenger compartment because the passenger compartment is a sealed space. For this reason, various types of filtration-type air purification apparatuses are provided, but it is impossible to remove odorous components adhering to the wall surface of the passenger compartment.

  Here, an electrostatic atomizer that atomizes water to generate nanometer-sized charged fine particle water (nano-size mist) has attracted attention. Since the nano-size mist generated by this electrostatic atomizer contains radicals such as superoxide radicals and hydroxy radicals, in addition to the deodorizing effect, it also has the effect of suppressing viruses and fungi, the effect of inactivating allele substances, etc. Therefore, if the nano-size mist is sent out into the passenger compartment, not only the odorous components in the air in the passenger compartment, but also the odorous components adhering to the walls and sheets in the passenger compartment can be deodorized. It also suppresses allergens such as pollen, etc., which are attached to seats, floor carpets, cushions, etc., and pollen that are brought into the passenger compartment and attached to the clothes of passengers when doors are opened and closed outdoors. be able to. For this purpose, Japanese Unexamined Patent Application Publication No. 2006-151046 (Patent Document 1) discloses an electrostatic fog for a vehicle that discharges nano-size mist into the vehicle interior by placing the nano-size mist on the wind output from the air conditioner provided in the vehicle. A device has been proposed.

  In the above, the conventional air purifying device provided in the vehicle turns on the switch (including the accessory switch) by inserting a key into the ignition key switch from the viewpoint of preventing the consumption of the battery as the power source for the vehicle. As a result, power is supplied, and in practice, the air is purified only when the engine is started.

  On the other hand, the user feels the strongest smell in the vehicle when the door of the vehicle is opened or when the air conditioner installed in the vehicle is operated. When getting in, allergens in the passenger compartment are active. However, this point cannot be dealt with in an electrostatic atomizer that is operable when the ignition key switch is turned on, as in the air purification device.

  Further, when a person is sitting on the sheet, the nano-sized mist M cannot touch the odor that has soaked into the sheet or the allergen that has entered the sheet, so there is no opportunity to deodorize or inactivate them.

JP 2006-151046 A

  The present invention has been made in view of the above points, and when a user gets into the vehicle to drive, the vehicle is capable of deodorizing or allergen inactivated. It is an object to provide a computer apparatus.

  The present invention relates to a discharge electrode to which a high voltage is applied, a water supply means for supplying water to the discharge electrode, and a mist generated by electrostatic atomization of the water by applying a high voltage to the discharge electrode. Is a vehicle electrostatic atomizer having a discharge port for discharging to the vehicle and a control means for controlling the electrostatic atomization operation by applying the high voltage, and is connected to the vehicle power supply without going through an ignition key switch. The controller is operable even when the ignition key switch is turned off, and has an operation time setting unit for inputting an operation start time, and the control means performs the electrostatic atomization at the operation start time set by the operation time setting unit. When the operation is started and the electrostatic atomization operation is terminated after a predetermined time has elapsed, and the remaining capacity detected by the detecting means for detecting the remaining capacity of the vehicle power source is equal to or less than a threshold value, the predetermined time It is characterized in that without waiting for the lapse in which to terminate the electrostatic atomization operation. Even if the ignition key switch is turned off, the electrostatic atomization operation is started when the set operation start time is reached, and the electrostatic atomization operation is ended when the set operation end time is reached. The time for performing the electrostatic atomization operation can be set according to the dirt in the room.

  If the control unit is provided with a display unit that calculates the electrostatic atomization operation possible time from the detected remaining capacity and the power consumption of the electrostatic atomizer and displays it, the user can use the remaining power of the vehicle. An operation in consideration of the capacity can be performed.

  In addition, the control unit determines whether there is a remaining capacity necessary for the next electrostatic atomization operation from the detected remaining capacity and the power consumption of the electrostatic atomizer, and if not, a warning unit that warns this With this, it is possible to perform an operation in which the remaining capacity of the vehicle power source is not excessively reduced.

  During the engine operation of the vehicle, the electrostatic atomization operation may be performed regardless of the setting of the operation time setting unit. In this case, the electrostatic atomization operation is performed in conjunction with the air conditioning operation of the vehicle. The electrostatic atomization operation may be performed according to the output of the odor sensor or the allergen sensor, or the electrostatic atomization operation may be performed at all times during the engine operation of the vehicle.

  You may provide the counter electrode to which a high voltage is applied between a discharge electrode while facing a discharge electrode.

  In the present invention, since the electrostatic atomization operation is started at the set operation start time regardless of whether the ignition key switch is on or off, the electrostatic atomization operation is performed even when no one is on board. Therefore, the next time a vehicle user gets into the car and starts driving, the odor can be removed and the allergen can be deactivated, so that the comfortable space The vehicle can be used in In addition, the electrostatic atomization operation is completed after a lapse of a predetermined time, and if the remaining capacity of the vehicle power source becomes a threshold value or less, the electrostatic atomization operation is terminated without waiting for the lapse of the predetermined time. Power consumption can be reduced.

It is a block circuit diagram of an example of an embodiment of the invention. It is sectional drawing of an electrostatic atomization unit part same as the above. It is the schematic which shows a vehicle-mounted state same as the above. It is a schematic front view of an example of an operation time setting part same as the above. It is a time chart which shows operation | movement of the reference example same as the above. It is a time chart which shows operation | movement of this invention.

  Hereinafter, the present invention will be described based on an embodiment shown in the accompanying drawings. FIG. 2 shows an atomization unit portion of an electrostatic atomizer 1 that generates nanometer-size charged fine particle water (nanosize mist). A ring-shaped counter electrode 12 that is disposed at the tip opening of a cylindrical body 16 made of an insulating material surrounding the discharge electrode 11 and faces the discharge electrode 11, and water in the air by cooling the discharge electrode 11. It comprises a cooling means 13 for condensation on the discharge electrode 11 and a high-voltage power supply unit 15 for applying a high voltage between the discharge electrode 11 and the counter electrode 12, which is composed of a Peltier element and is arranged on the cooling side. The cooling means 13 to which the discharge electrode 11 is thermally connected is provided with heat radiation fins 14 on the heat radiation side.

  In addition, the electrostatic atomizer 1 includes a motor fan (not shown) that sends cooling air to the radiating fins 14, and a part of the air sent from the motor fan is opened on the side surface of the cylindrical body 16. From the discharge port 17, which is the front end opening of the cylindrical body 16.

  In this electrostatic atomizer 1, the cooling means 13 cools the discharge electrode 11 to condense moisture in the air to generate condensed water on the discharge electrode 11. Therefore, the cooling means 13 is used as the discharge electrode. A water supply means for supplying water to the water is configured. In a state where the condensed water is attached to the discharge electrode 11, if a high voltage is applied between the electrodes 11 and 12, the condensed water collects at the tip of the discharge electrode 11 and discharges between the counter electrode 12. As a result, the Rayleigh splitting is repeated to form a nano-sized mist M, which is discharged from the discharge port 17 to the outside by the wind generated by the motor fan. The electrostatic atomizer 1 includes a discharge voltage detection circuit and a discharge current detection circuit, and adjusts the amount of condensed water generated by adjusting the cooling degree of the cooling means 13 based on the detected discharge voltage and discharge current. The control part C which performs is provided, the appropriate amount of dew condensation water is always ensured on the discharge electrode 11, and generation | occurrence | production of the nanosize mist M is reliably performed without being influenced by temperature and humidity.

  The electrostatic atomizer 1 configured as described above has a nano-size mist M, which is installed in the vicinity of a blow-out port of a vehicle compartment, which is an automobile, and discharged from the discharge port 17 in the vehicle interior. Supply, deodorize and inactivate allergens. In view of efficiently supplying the nano-sized mist M to the entire vehicle interior, it is preferable that the nano-sized mist M discharged from the discharge port 17 can be put on the wind discharged from the air outlet of the air conditioner. FIG. 3 shows an example of this case, and the discharge port 26 in the air conditioner comprising the suction port 21, the blower 22, the filter 23, the evaporator 24, and a plurality of discharge ports 26 provided through the air passage 25. The electrostatic atomizer 1 is installed in the vicinity, and the discharge port 17 communicates with the vicinity of the discharge port 26 of the air passage 25. As will be described later, since the nano-sized mist M is generated and discharged into the room even when the air conditioner is not operating, the discharge port 17 is provided at a position that also takes this point into consideration.

  An operation time setting unit 5 is connected to the control unit C as shown in FIG. This operation time setting unit 5 is used for setting input of time for operating the electrostatic atomizer 1. For example, as shown in FIG. 4, the operation time setting unit 5 includes a start time input unit 51 and an end time input unit 52. If the operation start time and the end time are input by the time input by the up / down key in the start time input unit 51 and the end time input unit 52, the control unit C calculates the set time and the time of the built-in clock. In comparison, when the operation start time is reached, the electrostatic atomizer 1 is operated to generate the nano-size mist M, and when the end time is reached, the electrostatic atomizer 1 is stopped. The operation time setting unit 5 is preferably capable of setting a plurality of operation start times and operation end times. Instead of the operation end time, a time during which the operation is to be performed may be input.

  Here, the electrostatic atomizer 1 including the control unit C directly receives power supply from a battery V as a vehicle power source as shown in FIG. 1, and for this reason, when the ignition key switch is off. The electrostatic atomization operation is also possible. For this reason, regardless of whether the engine is in operation or not, the electrostatic atomizer 1 performs electrostatic atomization operation, that is, the cooling means 13 cools the discharge electrode 11 at the set operation time. Securing condensed water and starting generation of nano-size mist M by applying high pressure to discharge, releasing nano-size mist M into the passenger compartment, and electrostatic atomization operation when set end time is reached To stop.

  For this reason, if the operation start time is set to a time when no person is riding, the electrostatic atomizer 1 emits the nano-size mist M into the unmanned vehicle interior. The seat of the driver's seat that is always covered by the person can also be exposed to the nano-size mist M, and therefore, the deodorization and allergen inactivation by the nano-size mist M can be performed in a wider range.

  The electrostatic atomization operation when the engine is not started is provided with a detection unit for detecting the capacity (voltage) of the battery V in order to avoid the consumption of the battery V, and if the detected voltage falls below a threshold value. As shown in FIG. 5, the control unit C desirably finishes the electrostatic atomization operation without waiting for the end time. Also, the remaining battery capacity at the set end time is calculated from the power consumption of the electrostatic atomizer and the remaining battery capacity. When this value falls below the threshold, a warning such as a buzzer or light emitting means is issued. You may make it give a warning using a means. Further, as shown in FIG. 4, the operable time that can be estimated from the current remaining capacity of the electrostatic atomizing atomizer 1 is calculated from the remaining capacity of the battery V, the power consumption, and the threshold value, and displayed. An operable time display unit 53 may be provided.

  The operation time setting unit 5 can input both the start time and the end time. However, only the start time may be input. In this case, the control unit C performs the electrostatic atomization operation for a predetermined time T as shown in FIG. However, when the remaining capacity of the battery V becomes equal to or less than the threshold value, the electrostatic atomization operation is terminated without waiting for the elapse of the predetermined time T.

  During engine operation, regardless of the setting of the operation time setting unit 5, an electrostatic atomization operation is performed in conjunction with the air conditioning operation, or depending on the output of an odor sensor or allergen sensor installed in the passenger compartment. You may perform an electroatomization operation | movement or always perform an electrostatic atomization operation | movement.

DESCRIPTION OF SYMBOLS 1 Electrostatic atomizer 5 Operation time setting part V Battery C Control part

Claims (8)

  A discharge electrode to which a high voltage is applied, a moisture supply means for supplying moisture to the discharge electrode, and a discharge for releasing mist generated by electrostatic atomization of the moisture by applying a high voltage to the discharge electrode into the vehicle interior. An electrostatic atomization device for a vehicle comprising an outlet and a control means for controlling the electrostatic atomization operation by the application of the high voltage, and connected to the vehicle power supply without passing through the ignition key switch. An operation time setting unit for inputting an operation start time is provided, and the control means starts the electrostatic atomization operation at the operation start time set by the operation time setting unit. In addition, the electrostatic atomization operation is terminated after a lapse of a predetermined time, and if the remaining capacity detected by the detecting means for detecting the remaining capacity of the vehicle power source becomes equal to or less than a threshold value, the lapse of the predetermined time is waited. Vehicle electrostatic atomization apparatus characterized in that to terminate the electrostatic atomization work without.   2. The control unit according to claim 1, further comprising a display unit that calculates the electrostatic atomization operation possible time from the detected remaining capacity and the power consumption of the electrostatic atomizer and displays the calculated time. Electrostatic atomizer for vehicles.   The control unit is equipped with a warning unit that determines whether there is a remaining capacity necessary for the next electrostatic atomization operation from the detected remaining capacity and the power consumption of the electrostatic atomizer, and warns if there is no remaining capacity. The electrostatic atomizer for vehicles according to claim 1 or 2 characterized by things.   The electrostatic atomizing device for a vehicle according to any one of claims 1 to 3, wherein the electrostatic atomizing operation is performed during the engine operation of the vehicle regardless of the setting of the operation time setting unit. .   The electrostatic atomizing device for a vehicle according to claim 4, wherein the electrostatic atomizing operation is performed in conjunction with an air conditioning operation of the vehicle.   5. The vehicle electrostatic atomizer according to claim 4, wherein the electrostatic atomization operation is performed in accordance with an output of an odor sensor or an allergen sensor.   5. The electrostatic atomizing device for a vehicle according to claim 4, wherein the electrostatic atomizing operation is always performed during engine operation of the vehicle.   The electrostatic atomizer for a vehicle according to claim 1, further comprising a counter electrode facing the discharge electrode and to which a high voltage is applied between the discharge electrode and the discharge electrode.

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