RU2390385C2 - Hot blast air blower - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: inventions relate to hot blast air blowers, such as hair drier, having electrostatic sprayer that creates charged water particles. Invention objective is improved efficiency of nanofog output and amount that comes out of electronic sprayer. For this purpose in hot blast air blower, electrostatic sprayer comprises discharge electrode, counter electrode, circuit of high voltage generation, facility of water supply. Counter electrode is located opposite to discharge electrode. Circuit of generation serves for application of high voltage to discharge electrode and to counter electrode. Facility for water supply serves for supply of water to discharge electrode, besides water is electrostatically sprayed as it arrives to discharge electrode. Circuit of generation is arranged by connection of high-frequency low-impedance element between primary input clamp that receives inlet voltage and secondary output clamp of low voltage. Output clamp is connected to counter electrode and is coupled with secondary output clamp of high voltage, which produces high voltage generated by increase of input voltage received by primary input clamp and then applied to discharge electrode.

EFFECT: provides for the possibility to create stable charged particles and their emission in large amount.

4 cl, 6 dwg

Description

Cross reference to related applications

This application is based on and claims to benefit from Japanese Patent Application No. TOKUGAN 2007-197644 of July 30, 2007, the entire contents of which are incorporated herein by reference.

Technical field

The invention relates to a hot blast blower, such as a hairdryer, having an electrostatic atomizer generating charged water particles.

State of the art

Conventional electrostatic atomizers are known, one of which is described in Japanese Patent Laid-Open No. 2006-239632. According to the method described in it, a high voltage is applied to the discharge electrode to which water enters and to the counter electrode located opposite the discharge electrode, as a result of which an electric discharge is created between them. In this case, the water held on the discharge electrode is repelled to the counter electrode and forms a form called the “Taylor cone”; moreover, at the end of the Taylor cone Rayleigh decay occurs, as a result of which charged nanoparticles of water (nano-fog) are formed, and their sputtering occurs.

In this conventional electrostatic atomizer, the counter electrode is grounded at a predetermined distance from one end of the discharge electrode, and during discharge a negative high voltage, for example, about -4.6 kV, is applied to the discharge electrode, resulting in a strong electric field between the discharge electrode and the counter electrode . When the nano-fog created in this strong electric field is pushed out and moves from the discharge electrode to the counter electrode, this nano-fog is easily attracted to the counter electrode, since the counter electrode is grounded and therefore its electric potential is stable. As a result of this, an undesirable decrease in the amount of nano-fog emanating from the electrostatic atomizer occurs. For this reason, it is desirable to increase the output efficiency and the amount of nano-fog emanating from the electronic atomizer.

This invention was developed taking into account the above circumstance, and it is aimed at providing a hot blast blower in which the amount of outgoing nano-fog will be increased.

SUMMARY OF THE INVENTION

According to a first aspect of the invention, there is provided a hot air blower with an electrostatic atomizer emitting charged particles of water and blowing warm air. An electrostatic atomizer creates charged particles of water by electrostatic atomization of water and contains: a discharge electrode; a counter electrode located opposite the discharge electrode; a high voltage generation circuit that applies high voltage to the discharge electrode and to the counter electrode; and a water supply means that supplies water to the discharge electrode, wherein the water is electrostatically sprayed when it enters the discharge electrode. The high voltage generation circuit is made by connecting a high frequency low impedance element between the primary input terminal receiving the input voltage and the secondary low voltage output terminal connected to the counter electrode and paired with the secondary high voltage output terminal, which outputs the high voltage received by increasing the input voltage received by the primary input clamp and then applied to the discharge electrode.

According to a second aspect of the invention, there is provided a hot air blower with an electrostatic atomizer emitting charged particles of water and blowing warm air. An electrostatic atomizer creates charged particles of water by electrostatic spraying of water and contains: a discharge electrode; a counter electrode located opposite the discharge electrode; a high voltage generation circuit that applies high voltage to the discharge electrode and to the counter electrode; and water supply means that delivers water to the discharge electrode, wherein water is electrostatically sprayed when it enters the discharge electrode. The high voltage generation circuit is made by connecting a high frequency low impedance element between a primary input terminal receiving an input voltage and a secondary high voltage output terminal that outputs a high voltage obtained by increasing the input voltage received by the primary input terminal and then applied to the discharge electrode.

According to a third aspect of the invention, in a hot air blower according to the first and second aspects of the invention, a high-frequency low-impedance element is located inside the hot air blower in a position in which it is almost not affected by an electrically charged discharge electrode.

According to the hot blast blower according to the first aspect of the invention, the electric potential of the secondary low voltage output terminal is set to be stable and slightly higher than the ground potential, as a result of which charged water particles can be generated stably and therefore emit them in a larger amount than before.

According to the hot blast blower according to the second aspect of the invention, the electric potential of the secondary low voltage output terminal is set to be stable and slightly higher than the ground potential, as a result of which charged water particles can be generated stably and therefore emit them in a larger quantity than before.

According to a hot blast blower according to a third aspect of the invention, the electric potential of the secondary output terminal can be stabilized to provide a stable discharge.

Brief Description of the Drawings

Cited as an example embodiment of the invention, the data are explained in the description below and in the attached claims, in conjunction with the accompanying drawings. It is intended that these drawings show only exemplary embodiments, and therefore should not be construed as limiting the scope of the invention; and cited as an example embodiment of the invention more specifically and in more detail are described with reference to the accompanying drawings, in which:

1 is a diagram showing a configuration of an electrostatic atomizer with which a hot blast blower is equipped in accordance with a first embodiment of the invention;

FIG. 2 is a diagram showing a structure of a hot blast blower having an electrostatic atomizer according to a first embodiment of the invention; FIG.

Figure 3 is a diagram showing the construction of an insulating tube for a capacitor;

4 is a diagram showing a change in the electric potential of the secondary terminal, when the capacitor is not connected; and

5 is a diagram showing a change in the electrical potential of the secondary terminal, with a capacitor connected; and

6 is a diagram showing a configuration of an electrostatic atomizer in a hot blast blower according to a second embodiment of the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS

Preferred embodiments of the invention are set forth below with reference to the accompanying drawings.

1 is a diagram showing a configuration of an electrostatic atomizer with which a hot blast blower is equipped in accordance with a first embodiment of the invention; and FIG. 2 is a diagram showing a hairdryer as an example of a hot blast blower with an electrostatic atomizer, which is shown in FIG. 1.

Turning to FIG. 1: the electrostatic atomizer comprises a voltage control circuit 1, a high voltage generation circuit 2, a discharge device 3, a water supply unit 4, a capacitor 5 (5a, 5b) and a resistor 6 (6a, 6b).

The voltage control circuit 1 receives electricity with a voltage of 100 V or 200 V from the AC power source 7, and if the received voltage exceeds 100 V, the voltage control circuit 1 transforms it to 100 V, and supplies a voltage of 100 V to the high voltage control circuit 21 circuit 2 generating high voltage. Therefore, even if the AC power source 7, the voltage of which may be different in different countries, is used to receive electricity from it, the unified power supply voltage can be supplied to the high voltage regulation circuit 21 in the high voltage generation circuit 2.

The high voltage generation circuit 2 consists of a high voltage control circuit 21, a step-up transformer 22, and a smoothing / rectifying circuit 23 and generates high voltage by increasing the voltage supplied from the voltage control circuit 1.

The high voltage control circuit 21 is connected to the voltage control circuit 1 through a primary input terminal 24 of the high voltage generation circuit 2. The high voltage control circuit 21 receives electrical energy through the primary input terminal 24, the voltage of which is regulated by the voltage control circuit 1, and controls the power supply of the primary winding of the step-up transformer 22.

The step-up transformer 22 has a primary winding connected to the high voltage control circuit 21, and a secondary winding connected to the smoothing / rectifying circuit 23. The step-up transformer 22 boosts the voltage coming from the high-voltage control circuit 21, generates a positive or negative high voltage set in advance secondary winding, for example, approximately -4 kV, and supplies the generated high voltage to the smoothing / rectifying circuit 23.

The smoothing / rectifying circuit 23 is connected to the secondary winding of the step-up transformer 22. The smoothing / rectifying circuit 23 receives an alternating high voltage from the step-up transformer 22, smooths and rectifies the alternating high voltage and outputs a constant high voltage obtained by smoothing and rectification through the secondary output terminal 25a of the high voltage circuit 2 generating high voltage.

The discharge device 3 consists of a discharge electrode 31 and a counter electrode 32. The discharge electrode 31 is connected to the secondary high voltage output terminal 25 a of the high voltage generation circuit 2, and high voltage is supplied from the smoothing / rectifying circuit 23 through the secondary high voltage output circuit 25 a. The counter electrode 32 is located opposite the discharge electrode at a predetermined distance from it and is connected to the secondary low voltage output terminal 25b of the high voltage generation circuit 2.

The water supply unit 4 supplies to the discharge electrode 31 water used for electrostatic spraying performed by the discharge device 3. The water supply unit 4 has, for example, a container for water supplied to the discharge electrode 31; or has, for example, a Peltier module as cooling means for cooling the discharge electrode 31 below the dew point in order to obtain water condensate on the discharge electrode 31.

Capacitor 5 consists of two capacitors 5a and 5b connected in series between the primary input terminal 24 and the secondary low voltage output terminal 25b. The capacitor 5 serves as a high-frequency low-impedance element and connects these clamps to each other, and sets the electric potential value of the secondary low voltage output terminal 25b approximately equal to the electric potential value of the primary input terminal 24.

The capacitor 5 may consist of only one capacitor, but preferably it consists of two capacitors connected in series. If two capacitors are used and a short circuit occurs on one of them, then it is possible to provide a connection between the primary input terminal 24 and the secondary output terminal 25b of the low voltage through a low-impedance element, thereby eliminating the possibility of breaking the low-impedance state: by using a capacitor to connect both clamps together.

In addition, according to FIG. 3, by closing the capacitor 5 with an insulator such as an insulating tube 33, it is possible to insulate the capacitor 5 in order to prevent a short circuit due to physical contact with other components.

Turning to FIG. 2: a description is given of the principle construction of a hairdryer, which is an example of a hot air blower with an electrostatic atomizer shown in FIG. 1.

According to FIG. 2, the hair dryer has a housing 81 forming a main unit and a handle 82 integrally formed with the housing 81 on the lower wall of the housing 81 and protruding in a downward direction. A fan 84 is installed in the housing 81, which draws air from the air inlet 87, and an electric motor 83 that rotates the fan 84. A heating device 85 is installed downstream of the electric motor 83, on which the heater 86 is located, to selectively heat the air coming from the fan 84 , and providing warm air when the heater 86 is selectively energized; moreover, warm air passes through the blow hole 88 to the outside.

A switch 89 is located in the handle 82 to turn on / off the motor 83, heater 86 and electrostatic atomizer, and also to turn on other functions of the hairdryer.

On the front of the upper wall of the housing 81 are located: a high voltage generation circuit 2, a discharge device 3, a water supply unit 4 including an electrostatic atomizer shown in FIG. 1 and a voltage control circuit 1 (not shown). The nano-fog created by the discharge device 3 goes in the same direction as the air blown out from the blow hole 88, and then is introduced into the inlet channel 90 by the air flow from the fan 84.

On the upper wall in the housing 81, between the air inlet 87 and the fan 84, there is a capacitor 5 connected to a high voltage generating circuit 2 through a wire (not shown).

In this design: when electricity is supplied from the AC power source 7 and the power supply voltage exceeds 100 V, then this voltage is regulated by the voltage control circuit 1 to a value of 100 V and then supplied to the high voltage generation circuit 2. The voltage from the high voltage generation circuit 2 is boosted by step-up transformer 22 to provide high voltage alternating current. This high voltage alternating current is smoothed and rectified by a smoothing / rectifying circuit 23 to generate a high voltage direct current. This generated constant voltage is applied to the discharge electrode 31 of the discharge device 3 through a secondary high voltage output terminal 25 a, and then a strong electric field is generated between the discharge electrode 31 and the counter electrode 32.

In this case, water from the water supply unit 4 is supplied to the discharge electrode 31, and the water supplied to the discharge electrode 31 is electrostatically sprayed by a strong electric field created between the discharge electrode 31 and the counter electrode 32, and a nano-fog is created in accordance with the above description . Since the nano-fog thus created is electrically charged, it moves from the discharge electrode 31 to the counter electrode 32 due to the strong electric field created between them and then goes outside with the air stream created by the fan 84.

If a capacitor 5 is not installed between the primary input terminal 24 and the secondary low voltage output terminal 25b, and therefore the secondary low voltage output terminal 25b is in a low impedance state, then the electric potentials of the secondary low voltage output terminal 25b and the secondary high voltage output terminal 25a are changed according to FIG. 4A and 4B, respectively, during the creation and exit of the nano-fog, as described above.

1 кВ, и изменение потенциала вторичного выходного зажима 25b низкого напряжения становится значительным по отношению к напряжению, прикладываемому к разрядному электроду 31. Поэтому, когда изменение потенциала вторичного выходного зажима 25b низкого напряжения становится значительным и нестабильным, то создаваемый нано-туман притягивается к разрядному электроду 31 или к противоэлектроду 32, и поэтому его выход наружу затрудняется.For example, when a high voltage is applied to the discharge electrode 31 of about -4 kV, the amplitude V1 of the potential change is in the approximate range

1 kV, and the potential change of the secondary low voltage output terminal 25b becomes significant with respect to the voltage applied to the discharge electrode 31. Therefore, when the potential change of the secondary low voltage output terminal 25b becomes significant and unstable, the generated nano-fog is attracted to the discharge electrode 31 or to the counter electrode 32, and therefore its exit to the outside is difficult.

In contrast, when the capacitor 5 is installed according to the first embodiment and therefore the secondary low voltage output terminal 25b is in a low impedance state, then the electric potentials of the secondary low voltage output terminal 25b and the secondary high voltage output terminal 25a are changed according to FIGS. 5A and 5B, respectively.

100 В, и изменение потенциала вторичного выходного зажима 25b низкого напряжения становится существенно меньшим по отношению к напряжению, прикладываемому к разрядному электроду 31. То есть изменение потенциала вторичного выходного зажима 25b низкого напряжения и небольшое, и стабильное, и его электрический потенциал стабильно задан в значении, превышающем значение потенциала заземления, в результате чего можно исключить ситуации, когда созданный нано-туман притягивается к разрядному электроду 31 или к противоэлектроду 32. Вследствие этого созданный нано-туман легко выходит наружу с создаваемым вентилятором 84 потоком воздуха, в результате чего увеличивается количество исходящего нано-тумана - по сравнению с конструкциями известного уровня техники, в которых электрический потенциал противоэлектрода 32 задан в значении потенциала заземления.Similarly, as in the previous example, when the high voltage applied to the discharge electrode 31 is approximately −4 kV, the potential change amplitude V2 changes around

100 V, and the potential change of the secondary low voltage output terminal 25b becomes substantially smaller with respect to the voltage applied to the discharge electrode 31. That is, the potential change of the secondary low voltage output terminal 25b is both small and stable, and its electric potential is stably set to exceeding the value of the grounding potential, as a result of which it is possible to exclude situations when the created nano-fog is attracted to the discharge electrode 31 or to the counter electrode 32. As a result, with The created nano-fog easily exits with the air flow created by the fan 84, resulting in an increase in the amount of outgoing nano-fog compared to prior art designs in which the electric potential of counter electrode 32 is set to the ground potential.

[Second exercise]

6 is a diagram showing a configuration of an electrostatic atomizer in a hot blast blower according to a second embodiment of the invention. The second embodiment, as shown in FIG. 2, is characterized in that one of the two capacitors of the capacitor 5 is connected to the secondary output terminal 25a of the high voltage instead of the secondary output terminal 25b of the low voltage, as opposed to the first embodiment according to FIG. 1, to provide a connection between the primary the input terminal 24 and the secondary output terminal 25a of the high voltage through the capacitor 5. The other components are the same as in the first embodiment.

In this second embodiment, the capacitor 5 serves as a high-frequency low-impedance element connecting the primary input terminal 24 and the secondary high voltage output terminal 25 a to each other. Moreover, the electric potential of the secondary output terminal 25a of the high voltage varies, as shown in FIG. 5B, and the electric potential of the secondary output terminal 25b of the low voltage, changing essentially the same as the potential of the secondary output terminal 25a of the high voltage, changes almost in accordance with FIG. .5A.

Accordingly, this second implementation can provide the same beneficial effect as in the first implementation.

[Third exercise]

The following is a description of an electrostatic atomizer in a hot air blower in accordance with a third embodiment of the invention. The third embodiment is characterized in that the capacitor 5 is installed as far as possible from the discharge electrode 31; and other components are the same as in the first and second implementations.

The discharge electrode 31 charges easily because a high voltage is applied to it and electrostatic atomization is performed. Therefore, when the capacitor 5 is located near the discharge electrode 31, the electrically charged discharge electrode 31 freely acts on the capacitor 5. Therefore, the change in the electric potentials of the secondary terminals of the high voltage generation circuit 2 occurs through the capacitor 5, and therefore, the high voltage supplied to the discharge electrode 31 , becomes unstable, as a result of which a stable discharge is difficult.

In the third embodiment, the capacitor 5 is located as far as possible, that is, it is in a position in which it is almost not affected by an electrically charged discharge electrode 31, for example, on the upper wall in the housing 81 between the air inlet 87 and the fan 84, according to FIG. . 2; and connected to a high voltage generating circuit 2 through a wire (not shown), thereby eliminating the drawback mentioned above. Therefore, it is possible to provide a stable discharge and stable formation of nano-fog.

Although developed by the authors of this invention is described with reference to its implementation, but the description and its constituent drawings do not limit the invention. That is, various alternative embodiments, examples, and working methods performed by a person skilled in the art, based on the foregoing, are, of course, within the scope of this invention.

Claims (4)

1. A hot blast blower having an electrostatic atomizer emitting charged particles of water and blowing warm air; moreover, the electrostatic atomizer creates charged particles of water by electrostatic spraying of water; wherein the electrostatic atomizer comprises: a discharge electrode (31); a counter electrode (32) located opposite the discharge electrode (31); a high voltage generation circuit (2) that applies high voltage to the discharge electrode (31) and to the counter electrode (32); and means (4) for supplying water for supplying water to the discharge electrode (31); moreover, water is electrostatically sprayed when it enters the discharge electrode (31); and in which the high voltage generation circuit (2) is made by connecting a high frequency low impedance element between the primary input terminal (24) receiving the input voltage and the secondary low voltage output terminal (25b) connected to the counter electrode (32) and paired with the secondary output terminal ( 25a) a high voltage that outputs a high voltage obtained by increasing the input voltage received by the primary input terminal (24) and then applied to the discharge electrode (31). 2. The hot blast blower according to claim 1, in which the high-frequency low-impedance element is located inside the hot blast blower in a position in which it is almost not affected by an electrically charged discharge electrode (31). 3. A hot blast blower having an electrostatic atomizer emitting charged particles of water and blowing warm air; moreover, the electrostatic atomizer creates charged particles of water by electrostatic spraying of water; wherein the electrostatic atomizer comprises: a discharge electrode (31); a counter electrode (32) located opposite the discharge electrode (31); a high voltage generation circuit (2) that applies high voltage to the discharge electrode (31) and to the counter electrode (32); and means (4) for supplying water for supplying water to the discharge electrode (31); moreover, water is electrostatically sprayed when it enters the discharge electrode (31); and in which the high voltage generation circuit (2) is made by connecting a high frequency low impedance element between a primary input terminal (24) receiving an input voltage and a secondary high voltage output terminal (25b) that outputs a high voltage obtained by increasing the input voltage received by the primary input clamp (24) and then applied to the discharge electrode (31). 4. A hot blast blower according to claim 3, in which a high-frequency low-impedance element is located inside the hot blast blower in a position in which it is almost not affected by an electrically charged discharge electrode (31).

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