JP2008105613A - Electrostatic atomizer for vehicle - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To effectively generate nano-size mist, while using blowing air of an on-vehicle air conditioner. <P>SOLUTION: This electrostatic atomizer has a cooling means for generating water based on moisture in air by cooling a discharge electrode, and a blowoff port for blowing off mist provided by electrostatic atomization of the water by discharge in the discharge electrode, and introduces the mist into a cabin by carrying the mist on wind delivered from a blowout port of the on-vehicle air conditioner, and has an introducing pipe arranged outside an air blowing passage reaching the blowout port of the on-vehicle air conditioner and introducing the mist to the air blowing passage, and a ventilation passage for introducing cabin inside air to the vicinity of the discharge electrode from a suction port opening in a cabin. For generating the moisture from the cabin inside air taken in via the ventilation passage, the nano-size mist is generated by generating condensation water without receiving influence of adjusted air flowing in the air blowing passage, and the nano-size mist can be efficiently carried on the wind blowing off into the cabin from the blowout port by flowing in the air blowing passage. <P>COPYRIGHT: (C)2008,JPO&INPIT

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 (see Patent Document 1) that generates atomized water (nanosize mist) by atomizing water has attracted attention. The nano-sized mist generated by this electrostatic atomizer contains radicals such as superoxide radicals and hydroxy radicals, and has recently been used for deodorizing, suppressing viruses and molds, and inactivating alleles. Attention has been paid. For this purpose, by sending the nano-size mist 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. Allele sources such as pollen that are attached to clothes and brought into the passenger compartment can also be suppressed.

In this case, it is most preferable to place the nano-sized mist on the wind output from the air conditioner provided in the vehicle from the viewpoint of spreading the nano-sized mist in the vehicle interior. When water is supplied to the discharge electrode to which voltage is applied by cooling the discharge electrode to condense moisture in the air, electrostatic atomization is performed in the airflow path after the evaporator or heater of the air conditioner When the apparatus is arranged, it takes a very long time to generate nano-size mist when air of high temperature or low humidity is blown in the air conditioner. In addition, when it is placed in the air passage before the evaporator, it may be placed in an environmental condition of less than zero degrees when outside air introduction is selected in the air conditioner. Since no condensation can occur, nano-sized mist cannot be generated.
Japanese Patent No. 3260150

  The present invention has been invented in view of the above-described conventional problems, and is an electrostatic atomization for vehicles that can achieve both the effective generation of nano-size mist and the use of air blow from an on-vehicle air conditioner. It is an object to provide an apparatus.

  In order to solve the above problems, an electrostatic atomizer according to the present invention includes a discharge electrode, a counter electrode facing the discharge electrode and a high voltage applied between the discharge electrode, and the discharge electrode by cooling the discharge electrode. And a cooling means for generating water for electrostatic atomization based on moisture in the air in the part, and the mist generated by electrostatic atomization in the wind discharged from the air outlet of the on-vehicle air conditioner An electrostatic atomizing device that is mounted and led to the vehicle interior, and is provided outside the air passage leading to the air outlet of the in-vehicle air conditioner and includes an introduction pipe that guides the mist to the air passage. It has a feature that an air passage that guides vehicle interior air to the vicinity of the discharge electrode from a suction port that opens to the inside of the vehicle is provided, and the moisture is generated from the vehicle interior air taken in through the air passage.

  Condensed water can be generated from the air in the passenger compartment without being affected by the regulated air flowing through the air passage, and nano-sized mist can be generated. The nano-sized mist can be efficiently put on the blowing wind.

  When the suction port is located in front of the driver's seat of the vehicle, it is easy to obtain air with high humidity due to the expiration of the driver.

  If an air filter is provided in the air passage, it is possible to prevent the electrostatic atomization operation from being hindered due to dust and dirt in the passenger compartment.

  In the introduction pipe that guides the mist to the air passage, if there is a blowing means that sends the air at a speed substantially the same as the speed of the air flowing in the air passage, turbulent flow in the part where the nano-size mist is placed on the air flowing in the air passage Is less likely to occur and the nano-sized mist can be efficiently dispersed indoors.

  In the present invention, it is necessary to replenish water in order to cool the discharge electrode and generate water for electrostatic atomization in the discharge electrode portion based on the moisture in the air and to atomize this water. In addition, the generation of condensed water and generation of nano-size mist can be performed without being affected by the regulated air flowing through the air passage. In particular, in order to take in and condense the air in the passenger compartment where the temperature is relatively stable, it is possible to stably supply moisture by condensation. In addition, the generated nanosize mist can be reliably put on the wind flowing through the air passage and spread from the outlet to the vehicle interior.

  Hereinafter, the present invention will be described based on an embodiment shown in the accompanying drawings. In FIG. 3, reference numeral 2 denotes an air conditioner installed in the vehicle, which includes an air passage 20 including an air conditioning duct, and one end. The other end of the air passage 20 that is the suction port 21 is branched into a plurality of outlets 22. The suction port 21 is selectively communicated with either the vehicle exterior or the vehicle interior by a switching means (not shown).

  A blower fan 23, an air filter 24, an evaporator 25, and a heater 26 are disposed in the air passage 20. By the operation of the blower fan 23, the air outside the vehicle or the air inside the vehicle compartment is sucked from the suction port 21 through the air filter 24 and is sent out to the air passage 20, and the wind blows out from the air outlet 22 toward the vehicle compartment. The evaporator 25 is in a cooling refrigerant circuit including a compressor and a condenser (not shown) and forms a refrigeration cycle. When the liquid refrigerant exchanges heat with the air in the air passage 20 in the evaporator 25. The air sent out into the passenger compartment is cooled and dehumidified. The heater 26 includes an electric pump in a heat medium circulation path through which engine cooling water flows, and the heat medium (cooling water) heated by the engine by the electric pump exchanges heat with the air in the blower path 20. When doing so, the air sent into the passenger compartment is warmed.

  On the other hand, an electrostatic atomizer 1 that generates nanometer-sized charged fine particle water (nanosize mist M) has a discharge electrode 11 and a cylindrical body 16 made of an insulating material surrounding the discharge electrode 11, as shown in FIG. A ring-shaped counter electrode 12 which is disposed at the tip opening of the electrode and faces the discharge electrode 11, and a cooling means 13 for condensing moisture in the air on the discharge electrode 11 by cooling the discharge electrode 11. The high-voltage power supply unit 15 that applies a high voltage between the discharge electrode 11 and the counter electrode 12 includes the Peltier element and the discharge electrode 11 is thermally connected to the cooling side. The cooling means 13 includes heat radiating fins 14 on the heat radiating side.

  In the electrostatic atomizer 1, the discharge electrode 11 is cooled by the cooling means 13 to condense moisture in the air to generate condensed water on the discharge electrode 11, and a high voltage is applied between the electrodes 11 and 12. When the water is applied, the condensed water collects at the tip of the discharge electrode 11 and repeats a Rayleigh split by discharge with the counter electrode 12 to become a nano-sized mist M, which rides on the wind by the motor fan 14 and releases the discharge. It is discharged from the outlet 17 to the outside.

  Here, as shown in FIG. 1, the electrostatic atomizer 1 is installed outside the air passage 20 in the air conditioner 2, and the introduction pipe 18 connected to the discharge port 17 has an air passage 20. In the vicinity of the air outlet 22, the air enters the air passage 20, and the leading end opening of the introduction pipe 20 is directed in the direction of the wind flow in the air passage 20.

  In addition, the electrostatic atomizer 1 is connected to a vent passage 3 having a suction port 30 opened in the vehicle interior at one end, and a motor fan that sends cooling air to the radiating fins 14 in the vent passage 3. 18 and an air filter 31 are installed, and the air cooled by the cooling means 13 is air in the vehicle compartment taken in through the air passage 3 by the operation of the motor fan 14. A part of the wind sent from the motor fan 14 to the electrostatic atomizer 1 enters the cylindrical body 16 from the side opening of the cylindrical body 16, and the introduction pipe from the discharge port 17 which is the distal end opening of the cylindrical body 16. 18 through the air passage 20.

  As shown in FIGS. 4 and 5, the suction port 30 is preferably located in an instrument panel portion arranged on the front side of the passenger compartment, particularly in front of the driver's seat. It is desirable to be at a height that does not allow garbage to enter. Furthermore, in order to avoid the influence of the wind discharged from the air outlet 22 of the air conditioner 2, it is desirable that the air outlet 22 is located at least 10 cm, preferably 15 cm or more away from the air outlet 22.

  In this, since the electrostatic atomizer 1 is outside the air passage 20, the condensed water is generated without being affected by the adjusted air flowing through the air passage 20 to generate the nano-size mist M. In particular, in order to condense by taking in high-humidity air in the vicinity of the driver's seat where the driver is present from the suction port 30 and cooling it, moisture can be supplied reliably. It does not take time until the mist M is generated.

  Then, the nano-sized mist M that has entered the air passage 20 from the discharge port 17 through the introduction pipe 18 is diffused from the air outlet 22 into the vehicle compartment by riding on the wind flowing through the air passage 20. At this time, since the front end opening of the introduction pipe 18 is directed in the direction of the blowout port 22 in the wind flow in the air passage 20, the wind flow is generated from the nanosize mist M from the front end opening of the introduction pipe 18. There is no such thing as preventing the discharge.

  The introduction pipe 18 is made of a material that is difficult to be charged, and has a flexibility made of a soft material and a smooth inner surface, for example, a pipe made of PVC, for the convenience of installation in a vehicle and airflow. Turbulence is prevented from occurring in the flow of the nano-size mist M, and the amount of the nano-size mist M discharged from the tip opening of the introduction tube 18 is prevented from being greatly reduced.

  The air filter 31 disposed in the air passage 3 is used to block dust having a large size that affects electrostatic atomization. For example, a lattice-like one having an interval of 0.5 to 1.0 mm is preferably used. Can be used. Of course, a finer grid may be used, but in this case, clogging is likely to occur.

  As the motor fan 14, a motor fan whose amount of air flow is variable is used, and the motor fan 14 is adjusted in accordance with the output of the means for detecting the speed of the wind flowing in the air passage 20 or the rotational speed of the blower fan 23. It is preferable that a wind at a speed substantially equal to the wind speed in the air passage 20 is obtained in the introduction pipe 18 by providing a control unit for controlling the air flow rate. The nano-sized mist M discharged from the introduction pipe 18 can easily get on the wind flowing through the air blowing path 20, and the spraying efficiency into the passenger compartment is increased.

It is a schematic sectional drawing of an example of embodiment of this invention. It is sectional drawing of an electrostatic atomization unit part same as the above. It is a schematic sectional drawing which shows the whole structure of an air conditioner same as the above. It is a perspective view of a vehicle interior same as the above. It is a schematic sectional drawing same as the above.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Electrostatic atomizer 2 Air conditioner 3 Ventilation path 18 Introducing pipe 20 Blower path 30 Inlet

Claims (4)

  A discharge electrode and a counter electrode facing the discharge electrode and a high voltage applied between the discharge electrode and water for cooling the discharge electrode and electrostatically atomizing the discharge electrode portion based on the moisture in the air. An electrostatic atomizer that includes a cooling means to be generated and carries mist generated by electrostatic atomization to a wind discharged from an air outlet of the vehicle-mounted air conditioner and guides the mist into the vehicle interior. An air passage that is installed outside the air passage leading to the air outlet of the device and includes an introduction pipe that guides the mist to the air passage, and that guides the air in the vehicle interior from the suction opening that opens into the vehicle interior to the vicinity of the discharge electrode. An electrostatic atomizer for a vehicle comprising: the vehicle interior air taken in through the air passage and generating the moisture.   2. The electrostatic atomizer for a vehicle according to claim 1, wherein the suction port is located in front of a driver's seat of the vehicle.   The electrostatic atomizer for vehicles according to claim 1, wherein an air filter is provided in the air passage.   4. The blower according to claim 1, further comprising a blowing unit configured to flow a wind at a speed substantially the same as a speed of the wind flowing in the blowing path in the introduction pipe that guides the mist to the blowing path. Electrostatic atomizer for vehicles.

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