JP4840460B2 - Heating blower - Google Patents

Description

  The present invention relates to a heated air blower such as a dryer or a fan heater.

  2. Description of the Related Art Conventionally, heating includes a main body case having a suction port and a discharge port, including a blower that discharges air sucked from the suction port from the discharge port and a heating unit that heats air downstream of the blower. A blower is provided. Examples of this type of heated air blower include a hair dryer and a fan heater. In recent years, however, a negative ion generator that discharges negative ions is provided to moisturize hair and the like with mist adhering to the negative ions. A structure is provided (see Patent Document 1). However, the mist adhering to the negative ions has a particle size of about 1 nm, and therefore, evaporation is easily caused by the heat generated from the heating unit of the heating air blower, so that it is difficult to deliver a sufficient amount of mist to the object. There was a problem.

JP 2002-191426 A

  This invention is invented in view of the said problem, Comprising: Discharging the mist which does not produce easily with the heat | fever which a heating part emits, and provides the heating air blower which can deliver a sufficient quantity of mist to a target object It is an object to do.

In order to solve the above-mentioned problems, a heating air blower according to the present invention includes a blower unit 4 for discharging air sucked from the suction port 1 into the main body case 3 having the suction port 1 and the discharge port 2; The heating unit 5 that heats air on the downstream side of the blower unit 4, the hot air outlet 2 a that discharges the air heated and sent by the heating unit 5 to the outside, and the heating unit 5 are sent in And a cool air discharge port 2b for discharging the air to the outside, and the downstream portion of the flow path in the main body case 3 has a double cylinder structure including the inner cylinder portion 9 and the outer cylinder portion 10, and the inner side A main body block in which the discharge port of the inner cylinder part 9 in which the heating unit 3 is arranged is the hot air discharge port 2a and the discharge port of the outer cylinder part 10 not having the heating unit 3 is the cold air discharge port 2b. a hot air blower having a 40, the main body block 40 includes a discharge electrode 12, the discharge electrode Electrostatic mist that has a supply means for supplying liquid to 2 and that atomizes the liquid by applying a high voltage to the liquid held by the discharge electrode 12 and discharges ion mist from the mist discharge port 17 to the outside. includes a block 50, the pre-Symbol cold air discharge port 2b, is positioned between the mist discharge port 17 of the hot air discharge port 2a and the electrostatic atomization block 50, the mist discharge port 17 from the electrostatic atomization block 50 The discharge direction of the ion mist discharged to the outside via the cold air discharge port 2b from the main body block 40 is provided substantially parallel to the discharge direction of the cold air discharged to the outside.

By doing in this way, nanometer-sized ion mist with a particle size of about 3 to 100 nm can be discharged from the mist discharge port 17 of the electrostatic atomization block 50, and this ion mist adheres to negative ions. Compared with a mist with a particle size of about 1 nm, it is less likely to cause evaporation due to the heat of hot air. Therefore, a sufficient amount of mist is required as compared with a hot air blower equipped with a conventional negative ion generator. It becomes possible to deliver to. Moreover, since the discharge direction of the ion mist on the electrostatic atomization block 50 side and the discharge direction of the air on the main body block 40 side are provided substantially parallel, the discharged ion mist is discharged from the main body block 40 side. It will be delivered quickly and in large quantities to the target object.
The discharge direction of the ion mist is preferably inclined so that the ion mist flow merges with the air flow from the main body block 40 at a predetermined downstream position. The ion mist is preferably nanometer size.

  Then, the cold air discharged from the cold air discharge port 2 b of the outer cylinder part 10 is discharged from the hot air discharge port 2 a of the inner cylinder part 9 as ion mist discharged from the mist discharge port 17 of the electrostatic atomization block 50. Protects against the heat of warm air. Therefore, evaporation before the ion mist reaches the object is prevented.

  In the heating blower, the mist discharge port 17 of the electrostatic atomization block 50 is preferably opened to the outside of the main body case 3 of the main body block 40. This further prevents the ion mist generated in the electrostatic atomization block 50 from being exposed to the heat generated by the heating unit 5 in the main body case 3 and causing evaporation.

  In addition, an induction flow path R3 that sends air from the blower 4 in the main body block 40 toward the discharge electrode 12 in the electrostatic atomization block 50 and attracts ion mist to the outside is provided avoiding the heating unit 5. It is also preferable. In such a case, since the generated ion mist is prevented from drifting around the discharge electrode 12 for a long time, a large amount of ion mist can be continuously generated and this large amount is generated. Ion mist can be quickly delivered to the target. Moreover, since the attracting flow path R3 is formed avoiding the heating unit 5, the ion mist is prevented from being evaporated by the heat of the air passing through the attracting flow path R3.

  And the rectification | straightening part which rectifies | straightens the air sent into the electrostatic atomization block 50 from the main body block 40 side in this induction flow path R3 in the direction substantially parallel to the axial center of this discharge electrode 12 in the discharge electrode 12 vicinity. 27, and in this way, the air flow is stabilized particularly in the vicinity of the tip portion of the discharge electrode 12, so that the electrostatic atomization phenomenon occurs stably, and the ion mist having a stable particle diameter. Is generated in large quantities.

Moreover, it is also preferable to provide the partition 30 between the main body block 40 and the electrostatic atomization block 50, and to provide the branch port 24 connected to the induction flow path R3 in this partition 30 . In such a case, after sufficiently generating an electrostatic atomization phenomenon in the electrostatic atomization block 50 to form an ion mist with a high degree of completion, the ion mist can be discharged to the outside. Is.

  Further, when the control unit 8 that controls the heating by the heating unit 5 of the main body block 40 and the voltage application to the liquid held by the discharge electrode 12 of the electrostatic atomization block 50 is heated by the heating unit 5. It is also preferable to provide for stopping the voltage application to the liquid held in the discharge electrode 12. By doing in this way, it is prevented more reliably that ion mist evaporates.

  It is also preferable to provide an electrode 13 for applying a high voltage to the liquid held on the discharge electrode 12.

  It is also preferable that an electrode 13 is provided and the ion mist is ejected from the discharge electrode 12 toward the electrode 13 side.

  At this time, a protective cover 22 is preferably fixed to the outside of the electrode 13. Thereby, it can prevent that a hand touches and can ensure safety.

  The present invention produces an effect that a sufficient amount of mist can be delivered to an object by discharging mist that is unlikely to be evaporated by heat generated by the heating unit.

It is explanatory drawing which shows the structure of the heating air blower of an example in embodiment of this invention. It is explanatory drawing which shows the structure of the electrostatic atomization block with which a heating air blower same as the above is equipped. It is explanatory drawing which shows the rectification | straightening part in an electrostatic atomization block same as the above, and the flow of air, (a) When not providing a rectification part, (b) When providing the rectification part of another form, (c) Is a case where a further form of rectification unit is provided. It is explanatory drawing which shows the example of control of a heating air blower same as the above. It is explanatory drawing which shows the case where many electrostatic atomization blocks of a heating air blower same as the above are arranged, (a) is arranged three pieces, (b) is arranged four pieces, (c) is arranged eight pieces. This is the case. It is explanatory drawing which shows the structure of the heating air blower of the other example in embodiment of this invention.

  Hereinafter, the present invention will be described based on embodiments shown in the accompanying drawings. FIG. 1 shows the entire heating blower as an example in the embodiment of the present invention. This heating blower is a hair dryer, and a wind tunnel type main body case 3 having a suction port 1 and a discharge port 2 is provided with a blower unit 4 made of a fan and a heating unit 5 made of a heater in the main body case 3. In the flow path from the suction port 1 to the discharge port 2, the heating unit 5 is provided on the downstream side of the blower unit 4. Further, in the flow path from the suction port 1 to the discharge port 2 in the main body case 3, the downstream portion where the heating unit 5 and the discharge port 2 are located is an inner tube portion that is a cylindrical member that is open at both ends. 9 and the outer cylinder part 10 are formed in a two-layered cylinder structure coaxially arranged, and the heating part 5 is arranged only in the inner cylinder part 9 so that the flow path in the inner cylinder part 9 (hereinafter referred to as the inner cylinder part 9). The air passing through the hot air flow path R1 is heated to become hot air and passes through the flow path in the gap between the inner cylinder portion 9 and the outer cylinder portion 10 (hereinafter referred to as the cold air flow path R2). The air is not heated by the heating unit 5 and is kept in a cold air state. The discharge port 2 is divided into a hot air discharge port 2a which is a discharge port on the warm air flow channel R1 side and a cold air discharge port 2b which is a discharge port on the cold air flow channel R2 side via the inner cylinder portion 9, and the center side The hot air is discharged outward from the hot air discharge port 2a formed on the outer side and the outer side from the cold air discharge port 2b formed with the inner cylinder portion 9 as a partition wall around the hot air discharge port 2a. Cold air is discharged. A power switch 7 is provided on the handle portion 6 protruding from the main body case 3, and power to the blower unit 4, the heating unit 5, and a high voltage applying unit 15 described later based on the operation of the power switch 7 is provided. A control unit 8 for controlling supply is incorporated.

  The main body block 40 of the heating air blower of the present example has the above-described configuration. On the outer surface of the outer cylinder portion 10 that forms the downstream outer shell portion of the main body case 3 of the main body block 40, A pair of electrostatic atomizing blocks 50 are fixed at locations that are equally spaced in the circumferential direction. As shown in FIG. 2, the electrostatic atomization block 50 has a tank 11 for storing water for atomization, a sharp conical tip portion 12a, and a base opposite to the tip portion 12a. A rod-shaped discharge electrode 12 made of a porous water-absorbing body arranged so that the end 12b side contacts the water in the tank 11, and a ring-shaped counter electrode 13 positioned facing the tip 12a of the discharge electrode 12. And a high voltage application unit 15 that applies a high voltage between the counter electrode 13 and the discharge electrode 12.

  In the electrostatic atomization block 50, when a high voltage is applied by the high voltage application unit 15 so that the discharge electrode 12 side becomes a negative electrode between the counter electrode 13 and the discharge electrode 12, charges are concentrated on the tip 12a. A high voltage is applied between the water transported from the tank 11 side into the discharge electrode 12 and the counter electrode 13. Then, the water transported to the distal end portion 12a of the discharge electrode 12 jumps toward the counter electrode 13 with a negative charge, and repeatedly undergoes Rayleigh splitting while drifting in a high electric field in the air, finally resulting in a nanometer. An electrostatic atomization phenomenon that causes ion mist of a size (hereinafter referred to as nano ion mist M) occurs, and the nano ion mist M is discharged to the outside through the mist discharge port 17.

  Each member of the electrostatic atomization block 50 is fixed to a cylindrical electrostatic atomization case 18 that forms an outer shell of the electrostatic atomization block 50. A fitting hole 19 is provided in the bottom of one end side in the axial direction of the electrostatic atomizing case 18, and the distal end 12 a side is located in the electrostatic atomizing case 18 in the fitting hole 19, and the base end. The discharge electrode 12 is fitted so that the portion 12b side protrudes to the outside, and the base end portion 12b protruding to the outside of the discharge electrode 12 is watertight by a tank 11 that is detachably connected to the outer surface of the electrostatic atomizing case 18. It is supposed to cover. An O-ring 20 is interposed between the fitting hole 19 of the electrostatic atomizing case 18 and the discharge electrode 12 and between the electrostatic atomizing case 18 and the tank 11. The inside water is prevented from leaking outside. The tank 11 is provided with a fine air hole 21 that allows air to pass therethrough but does not allow water to leak due to the action of surface tension. Even if the water in the tank 11 is transported, the pressure in the tank 11 is prevented from decreasing.

  The mist discharge port 17 for discharging the nano ion mist M generated in the electrostatic atomization case 18 to the outside is opened at the end of the electrostatic atomization case 18 opposite to the side where the fitting hole 19 is provided. ing. The counter electrode 13 is fixed in the mist discharge port 17, and a protective cover 22 is further fixed outside the counter electrode 13. The protective cover 22 is provided with a hole that does not allow a human fingertip to pass therethrough to prevent the hand from touching the counter electrode 13 and the discharge electrode 12 to ensure safety.

  In addition, an air inlet 23 is provided on the outer surface of the end of the electrostatic atomizing case 18 opposite to the side where the mist outlet 17 is opened (that is, the side where the fitting hole 19 is provided). When the electrostatic atomizing block 50 is fixed to the outer cylinder portion 10 of the main body block 40, the branch port 24 opened to the outer cylinder portion 10 and the air intake port 23 are communicated with each other. ing. From the opening edge of the air inlet 23 of the electrostatic atomization case 18, the electrostatic atomization block 50 is inserted into the branch port 24 of the outer cylinder 10 when the electrostatic atomization block 50 is fixed to the outer cylinder 10 of the main body block 40. The projecting piece 25 is projected, and after the air passing through the cold air flow path R2 in the main body block 40 hits the projecting piece 25, the direction is changed in a direction substantially orthogonal to the central axis of the discharge electrode 12, and the branch port 24 The air is diverted from the cold air flow path R2 through the air and is drawn into the electrostatic atomizing case 18 through the air inlet 23. The air drawn into the electrostatic atomizing case 18 communicates with the inlet 23 on the upstream side and covers the periphery of the root portion 12c in the electrostatic atomizing case 18 of the discharge electrode 12 on the downstream side. The center of the counter electrode 13 that forms a ring shape after changing its direction in a direction substantially parallel to the axis of the discharge electrode 12 by passing through the discharge electrode 12 and the vicinity of the discharge electrode 12 by the flow path forming portion 26 formed. It passes through the hole and the hole of the protective cover 22 and is discharged from the mist discharge port 17 to the outside. At this time, the nano ion mist M generated from the distal end portion 12 a of the discharge electrode 12 is attracted to the outside through the mist discharge port 17. That is, by each of the above-described configurations, a flow path (hereinafter referred to as this) that sends air from the blower 4 in the main body block 40 toward the discharge electrode 12 in the electrostatic atomization block 50 to attract the nanoion mist M to the outside. Is referred to as an induction flow path R3) and is branched from the cold air flow path R2.

  Reference numeral 27 in the figure denotes a rectifying unit arranged in the induction flow path R3, and this is fitted to the root portion 12c surrounded by the flow path forming part 26 of the discharge electrode 12, and between the flow path forming part 26 By positioning so as to form a plurality of rectifying holes 28 at equal intervals in the circumferential direction, the air sent into the electrostatic atomization block 50 from the main body block 40 side is discharged through the rectifying holes 28 to the discharge electrode 12. The current is rectified in a direction substantially parallel to the axis. This makes it possible to equalize and stabilize the air flow particularly in the vicinity of the distal end portion 12a of the discharge electrode 12, and to stably generate an electrostatic atomization phenomenon and to produce a large amount of nano ion mist M having a stable particle size. Can be generated. FIG. 3A shows a case where the rectifying unit 27 is not provided as in this example. In this case, air drawn into the electrostatic atomization block 50 is discharged as shown in the figure. It can be seen that it passes through the vicinity of the distal end portion 12a of the discharge electrode 12 in a state in which it is in direct contact with 12 and is distorted.

  Further, in the rectifying unit 27 of the present example, the upstream half 27a of the outer peripheral surface that forms the rectifying hole 28 with the inner peripheral surface of the flow path forming unit 26 is parallel to the axis of the discharge electrode 12. In addition, since the downstream half 27b is formed so as to approach the discharge electrode 12 as it goes downstream, the air passing through the rectifying hole 28 and in the vicinity of the tip 12a of the discharge electrode 12 is released. Although it is substantially parallel to the axial center of the electrode 12, it is slightly inclined closer to the discharge electrode 12 toward the downstream side so as to be concentrated and hit the tip 12 a of the discharge electrode 12. In FIG. 3B, as another form of the rectifying unit 27, the outer peripheral surface that forms the rectifying hole 28 with the inner peripheral surface of the flow path forming unit 26 is extended to the axial center of the discharge electrode 12. FIG. 3C shows an outer peripheral surface in which a rectifying hole 28 is formed with the inner peripheral surface of the flow path forming portion 26 as yet another form of the rectifying portion 27 in FIG. Is formed so as to approach the discharge electrode 12 toward the downstream side in the entire axial direction, but the air drawn into the electrostatic atomization block 50 is released also by the above-described another form. It can be applied to the tip 12a of the electrode 12 in a concentrated manner. The air concentratedly applied to the tip portion 12a from each rectifying hole 28 is then flowed in a direction substantially parallel to the axial center of the discharge electrode 12, and the nano ion mist M is placed on the outside from the mist discharge port 17 to the outside. Will be discharged.

  The discharge direction of the nano ion mist M discharged to the outside from the mist discharge port 17 is parallel to the axial center direction of the discharge electrode 12 and is also parallel to the facing direction of the discharge electrode 12 and the counter electrode 13. In FIG. 5, the discharge direction of the nano ion mist M is set to be substantially parallel to the discharge direction of air from the discharge port 2 of the main body block 40. Thereby, the nano ion mist M discharged to the outside from the electrostatic atomization block 50 is put on the flow of air discharged to the outside from the main body block 40, and the nano ion mist M is quickly applied to the target object at a distance. It is possible to reach a large amount. Moreover, in the electrostatic atomization block 50 of this example, although the discharge direction of the nano ion mist M from the mist discharge port 17 is substantially parallel to the discharge direction from the discharge port 2 of the main body block 40, it goes downstream. The nano ion mist M is set to be inclined so that the flow of the nano ion mist M approaches the air flow from the main body block 40 and intersects at a predetermined location on the downstream side, so that the nano ion mist M is discharged from the main body block 40 to the outside. It can be more effectively put on the air flow. The predetermined portion where the flow of the nano ion mist M and the air flow from the main body block 40 intersect is preferably set at the position where the hair is located in the hair dryer as in this example. However, although not shown in this example, it is desirable that an angle adjusting mechanism capable of appropriately changing the discharge direction of the nano ion mist M is provided.

  Thus, in the heating and blowing device of the present example having the above-described configuration, when the air blowing unit 4 is driven by energization, the outside air is sucked from the suction port 1 and the sucked air passes through the flow path in the main body case 3. After being generated, the wind pressure discharged from the discharge port 2 is generated. The downstream portion of the main body case 3 has a double-cylinder structure in which the hot air flow path R1 with the heating unit 5 is positioned inside, and the cold air flow path R2 provided avoiding the heating unit 5 is positioned on the outer peripheral side. Since the flow paths R1 and R2 are formed by reliably branching from the middle of the flow path from the suction port 1 to the discharge port 2 through the inner cylinder portion 9 serving as a partition wall, heat generation from the heating unit 5 is caused by energization. When hot air is discharged from the hot air discharge port 2a formed on the center side in the discharge port 2 through the hot air flow path R1, the hot air discharge is performed using the inner tube portion 9 as a partition wall. Cold air will be discharged from the cold air discharge port 2b formed in the outer peripheral side of the exit 2a. In addition, when the air blowing unit 4 is driven without energizing the heating unit 5, cold air is discharged from both the hot air discharge port 2a and the cold air discharge port 2b (that is, the entire discharge port 2). Of course.

  Then, by driving the air blowing unit 4 of the main body block 40 as described above, the electrostatic atomization block 50 fixed to the outer peripheral surface of the main body case 3 having a wind tunnel shape is cooled in the main body block 40. Air is fed from the middle of the wind passage R2 through the induction passage R3 branched through the branch port 24, passes through the vicinity of the discharge electrode 12 and the counter electrode 13, and is discharged to the outside from the mist discharge port 17. In this case, if a high voltage is applied between the discharge electrode 12 and the counter electrode 13 to generate the nano ion mist M, the nano ion mist M can be strongly attracted to the outside. Since the nano ion mist M discharged from the electrostatic atomization block 50 has a particle size of about 3 to 100 nm, it is discharged toward the outside simultaneously with the hot air discharged from the hot air discharge port 2a of the main body block 40. Even so, it does not easily evaporate due to the heat of the hot air, and therefore, it can reach even a part separated by an external distance, and various effects such as moisturizing can be exhibited.

  Here, in this example, the electrostatic atomization block 50 is positioned outside the main body case 3 of the main body block 40, and the mist discharge port 17 is opened outside the main body case 3 of the main body block 40. It is further reliably prevented that the nano ion mist M discharged to the outside from the outlet 17 is exposed to the heat generated by the heating unit 5 and evaporated. In addition, since the cold air discharge port 2b is positioned between the mist discharge port 17 and the hot air discharge port 2a, the cold air discharged from the cold air discharge port 2b is interposed between the nano ion mist M and the hot air. Therefore, the nano ion mist M discharged to the outside from the mist discharge port 17 is more reliably prevented from being exposed to the heat of the hot air discharged from the hot air discharge port 2a and evaporating.

  Moreover, since the induction flow path R3 of this example is formed so that air is sent from the blower unit 4 while avoiding the heating unit 5, the heating unit 5 is energized to discharge hot air from the hot air discharge port 2a. Even in this case, cold air is always sent into the attracting flow path R3, whereby the nano ion mist M is exposed to the hot air introduced through the attracting flow path R3 and evaporates. Is prevented.

  In FIG. 4, the example of the electricity supply control to the ventilation part 4, the heating part 5, and the high voltage application part 15 by the control part 8 is shown. The circles in the lower table in the figure indicate that the energization to the respective parts 4, 5, and 15 is in the on state, and the x marks that the energization to the respective parts 4, 5, and 15 are in the off state. As shown in the figure, when heating is performed by the heating unit 5 and hot air is discharged from the hot air discharge port 2a as shown in the drawing, the discharge electrode 12 and the counter electrode 13 formed by the high voltage application unit 15 Only when the energization control is performed such that the voltage application is stopped and the nano ion mist M is not discharged from the mist discharge port 17 and the cool air is discharged also from the hot air discharge port 2a without heating by the heating unit 5. When energization control is performed such that the nano ion mist M is discharged from the mist discharge port 17 by applying a voltage between the electrode 12 and the counter electrode 13, the nano ion mist M is exposed to the heat of hot air and evaporates. Can be more reliably prevented. To become. In other words, the energization control shown in the figure is suitable for a method of using a hair dryer such as this example in which warm air is first applied to dry the hair and then cold air with nano ion mist M is applied to moisturize the hair. Control.

  In addition, although the heating air blower of this example is provided with the two electrostatic atomization blocks 50, it may not be restricted to this but may be provided with the three or more electrostatic atomization blocks 50. Absent. FIGS. 5A, 5B, and 5C show the cases where three, four, and eight electrostatic atomization blocks 50 are provided, respectively. By positioning the block 50 at locations on the outer peripheral surface of the main body case 3 that are equidistantly spaced in the circumferential direction, the nano ion mist M can be stably supplied to the object regardless of the way of applying air. In this example, the discharge electrode 12 and the tank 11 made of a porous body are used as the supply means for supplying water to the tip end portion 12a of the discharge electrode 12. However, the present invention is not limited to this. Therefore, other means such as directly generating water in the discharge electrode 12 may be used. Furthermore, although water is used as the atomized liquid in this example, the present invention is not limited to this, and other liquids such as a treatment agent, a fragrance, and aroma oil may be used.

  Further, in this example, a hair dryer is shown as an embodiment of the heated air blowing device, but it is needless to say that the same effect can be obtained by applying the same configuration to other heated air blowing devices such as a fan heater. It is.

  Next, another example of the heated air blower according to the embodiment of the present invention will be described with reference to FIG. In addition, about the structure which matches the structure of an example among the structures of this example, the same code | symbol is attached | subjected and detailed description is abbreviate | omitted, only a characteristic structure different from an example is attached | subjected, and a detailed description is given below. To do.

  In the heating blower of this example, the air atomizing block 23 and the flow path forming part 26 as shown in the example are not provided in the electrostatic atomizing block 50, and therefore the induction flow path R3 is not formed, so the main body block 40 The air sent out from the air blowing section 4 does not flow into the electrostatic atomizing case 18 of the electrostatic atomizing block 50. That is, in this example, the air sent out from the blower 4 of the main body block 40 flows into the electrostatic atomization block 50 through the side walls of the electrostatic atomization case 18 and the outer cylinder portion 10 of the main body case 3. Is formed with a plurality of flow straightening holes 28 on the bottom surface of the electrostatic atomizing case 18 opposite to the side where the mist discharge port 17 is opened. Thus, the nano ion mist M is ejected from the mist ejection port 17 to the outside without any problem on an ion wind generated from the discharge electrode 12 toward the counter electrode 13.

  That is, in the heating and blowing device of this example, air is not forcedly introduced into the electrostatic atomization block 50 but is placed on ion wind to discharge the nano ion mist M, so that the tip of the discharge electrode 12 It becomes possible to cause the Rayleigh splitting to sufficiently repeat while the water particles that have jumped out from the portion 12a toward the counter electrode 13 drift in a high electric field, and to discharge to the outside after the nano ion mist M having a high degree of completion. Yes.

DESCRIPTION OF SYMBOLS 1 Suction port 2 Discharge port 2a Hot air discharge port 2b Cold air discharge port 3 Main body case 4 Blower part 5 Heating part 8 Control part 12 Discharge electrode 13 Opposite electrode 17 Mist discharge port 27 Rectifier 30 Bulkhead 40 Main body block 50 Electrostatic atomization Block R1 Hot air flow path R2 Cold air flow path R3 Induction flow path

Claims (11)

In the main body case having the suction port and the discharge port, a blower that discharges air sucked from the suction port from the discharge port, a heating unit that heats air on the downstream side of the blower, and a heating unit It has a hot air outlet that discharges the air that has been sent to the outside, and a cold air outlet that discharges the air that has been sent to the outside while avoiding the heating section,
The downstream part of the flow path in the main body case has a double cylinder structure consisting of an inner cylinder part and an outer cylinder part, and the outlet of the inner cylinder part in which the heating part is arranged on the inside is the hot air outlet, A heating air blower provided with a main body block in which the discharge port of the outer cylinder portion not provided with a heating unit is the cold air discharge port ,
The main body block has a discharge electrode and supply means for supplying a liquid to the discharge electrode, and applies a high voltage to the liquid held by the discharge electrode to atomize the liquid from the mist discharge port to the outside. Equipped with an electrostatic atomization block that discharges ion mist ,
The pre-Symbol cool air discharge ports, is positioned between the hot air discharge port and the mist ejection port of the electrostatic atomization block, the discharge direction of the ion mist discharged to the outside through a mist discharge port from the electrostatic atomization block Is provided in parallel with the discharge direction of the cold air discharged to the outside from the main body block through the cold air discharge port. The heating air blower according to claim 1, wherein the discharge direction of the ion mist is inclined so that the flow of the ion mist merges with the flow of air from the main body block at a predetermined position on the downstream side. The heating air blower according to claim 1 or 2, wherein the ion mist has a nanometer size. The heating air blower according to any one of claims 1 to 3, wherein a mist discharge port of the electrostatic atomization block is opened outside the main body case of the main body block. 2. An induction flow path for sending air from a blower section in the main body block toward a discharge electrode in the electrostatic atomization block and attracting ion mist to the outside is provided avoiding the heating section. The heating air blower as described in any one of -4. A rectification unit is provided in the induction flow path for rectifying the air sent from the main body block side into the electrostatic atomization block in a direction substantially parallel to the axis of the discharge electrode in the vicinity of the discharge electrode. Item 6. The heating air blower according to Item 5. The heating air blower according to claim 5 or 6, wherein a partition wall is provided between the main body block and the electrostatic atomization block, and a branch port communicating with the induction channel is provided in the partition wall. When controlling the heating by the heating unit of the main body block and the voltage application to the liquid held in the discharge electrode of the electrostatic atomization block, when heating by the heating unit, the control unit controls the liquid held in the discharge electrode. The heating blower according to any one of claims 1 to 7, wherein the heating blower is provided to stop voltage application. The heating blower according to any one of claims 1 to 8, further comprising an electrode for applying a high voltage to the liquid held on the discharge electrode. The heating air blower according to claim 1, further comprising an electrode, wherein the ion mist is ejected from the discharge electrode toward the electrode. The heating blower according to claim 9 or 10, wherein a protective cover is fixed to the outside of the electrode.

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