JP2009011958A - Electrostatic spraying apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent the leakage of a liquid or the like after the stoppage of the operation of an electrostatic spraying apparatus. <P>SOLUTION: The electrostatic spraying apparatus is provided with a container part (31), a nozzle part (32) communicating with the container (31), a pressing mechanism (23) for pressing the container part (31), a cartridge side electrode (16) forming an electric field in the nozzle part (32), a power source part (24) for applying voltage to the cartridge side electrode (16) and a control part (28) for controlling so as to form the electric fields on the distal end of the nozzle part (32) even after the stoppage of the pressing of the container part (31) by the pressing mechanism 23. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

    The present invention relates to an electrostatic spraying device, and particularly relates to measures against liquid leakage when spraying is stopped.

Conventionally, as a liquid spraying device for spraying a liquid stored in a container, an electrostatic spraying device that sprays liquid fed to a nozzle serving as an outlet of the container from the tip of the nozzle by electric field strength is known. Yes. Such an electrostatic spraying apparatus is shown in Patent Document 1. The electrostatic spraying device shown in Patent Document 1 includes a housing composed of a pair of cases whose one ends are connected by a hinge. Each case is provided with a pad of an elastically deformable material. In this electrostatic spraying device, when the housing is closed, the pad contracts while sandwiching a small bag that is a container for storing liquid. The pouch is compressed by the pad and the liquid in the pouch is supplied to the nozzle. Next, the liquid in the pouch is sprayed by forming an electric field at the nozzle.
Japanese Patent Laid-Open No. 05-138081

    As shown in FIG. 6A, the conventional electrostatic spraying device includes a resistor (c) inside the nozzle (a). The resistor (c) is configured so that a predetermined amount of liquid (b) is supplied to the nozzle (a) even when the compressive force of the pad against the pouch is increased. For this reason, as shown in FIG. 7, even if the operation of the electrostatic spraying device is stopped, the residual pressure acts on the liquid inside the pouch. Thereby, even after the operation is stopped, the liquid is sent to the tip of the nozzle (a), so that the liquid is accumulated at the tip of the nozzle (a) as shown in FIG. (d) is formed. When the liquid pool (d) is formed, there is a problem that when the operation is stopped, liquid leaks from the tip of the nozzle (a), so-called liquid leakage occurs. Further, at the start of the next operation, there is a problem that a liquid clogging, that is, a so-called liquid clogging is formed at the tip of the nozzle (a).

    This invention is made | formed in view of such a point, and it aims at preventing the liquid leak etc. after the operation | movement stop of an electrostatic spraying apparatus.

    According to a first aspect of the present invention, there is provided a container (31) for storing a liquid, a nozzle part (32) communicating with the inside of the container (31), and the liquid inside the container (31) to the nozzle part (32). A liquid conveying means (15) for supplying to the tip of the nozzle, and an electric field forming means (16) for forming an electric field at the tip of the nozzle part (32) by being supplied with electric power from the power supply part (24). It is premised on an electrostatic spraying device that sprays liquid in an atomized state from the tip of the nozzle section (32) by forming an electric field of the means (16). And a control means (28) for controlling the electric field forming means (16) to spray the liquid at the tip of the nozzle portion (32) after the liquid transportation of the liquid transport means (15) is stopped. Yes.

    In the first aspect of the invention, when the liquid inside the container (31) is fed to the tip of the nozzle part (32), an electric field is formed at the tip of the nozzle part (32). The liquid at the tip of the nozzle part (32) is pulled outside by this electric field strength. And it becomes a fine droplet and is sprayed from the front-end | tip of a nozzle part (32).

    Here, even if the operation of the electrostatic spraying device is stopped, the residual pressure acts on the liquid inside the container (31). When the residual pressure acts, the liquid moves to the tip of the nozzle portion (32) to form a liquid pool. As a result, liquid leakage occurs from the tip of the nozzle part (32) after the operation is stopped, and problems such as liquid clogging occur at the tip of the nozzle part (32) during the next operation. However, in the present invention, since the control means (28) for controlling the electric field forming means (16) is provided so that the liquid is sprayed from the tip of the nozzle portion (32) even after the liquid conveyance is stopped, the nozzle is stopped after the operation is stopped. The liquid sent to the tip of the section (32) is sprayed.

    In a second aspect based on the first aspect, the control means (28) continues the electric field formation of the electric field forming means (16) even after the liquid transport means (15) stops transporting the liquid. Thus, the electric field forming means (16) is controlled.

    In the second aspect of the invention, the electric field forming means (16) continues to form the electric field even after the liquid transport is stopped. Even after the transfer of the liquid is stopped, the residual pressure acts on the liquid inside the container (31), so that the liquid moves to the tip of the nozzle part (32) to form a liquid pool. However, in the present invention, since the electric field is continuously formed even when the transport of the liquid is stopped, the liquid sent to the tip of the nozzle portion (32) can be sprayed after the operation is stopped.

    In a third aspect based on the second aspect, the container (31) is constituted by a flexible member, while the liquid transporting means (15) presses the container (31) to supply liquid. A pressurizing means (23) for supplying the tip of the nozzle part (32) is provided.

    In the said 3rd invention, the said pressurization means (23) presses the container (31) comprised by the flexible member. When the container (31) is compressed, the internal pressure of the container (31) increases. The liquid inside the container (31) is pushed to the internal pressure and moves to the tip of the nozzle part (32).

    In a fourth aspect based on the third aspect, the control means (28) is configured to form the electric field until a predetermined time elapses after the pressurization of the pressurization means (23) to the container (31) is stopped. The electric field forming means (16) is controlled so that the means (16) forms an electric field.

    In the fourth aspect of the invention, after the pressurizing means (23) stops pressurizing the container (31), a predetermined voltage is applied to the electric field forming means (16). That is, even after the pressurization to the container (31) is stopped, the residual pressure acts on the liquid inside the container (31), so the liquid moves to the tip of the nozzle part (32). A liquid pool is formed. However, in the present invention, the electric field is continuously formed for a predetermined time even after the pressurizing means (23) stops pressurizing the container (31). The liquid sent to the tip can be sprayed.

    According to a fifth aspect of the present invention, in the second aspect of the invention, the control means (28) has a capacitor that accumulates electrification by supplying power from the power supply unit (24), while the control means (28) The electric field forming means (16) is controlled so that the electric field forming means (16) forms an electric field.

    In the fifth invention, the electric field forming means (16) continuously forms the electric field by the electric charge accumulated in the capacitor of the power supply section (24) after the liquid transport is stopped. When the power supply from the power supply unit (24) is stopped, the electric field strength of the electric field forming means (16) decreases instantaneously. However, in the present invention, the power supply unit (24) has a capacitor for accumulating charges. For this reason, even if the electric field forming means (16) stops forming the electric field, the electric field can be continuously formed by the electric charge accumulated in the capacitor. As a result, since the electric field is continuously formed even when the transport of the liquid is stopped, the liquid sent to the tip of the nozzle part (32) can be sprayed after the operation is stopped.

    According to the present invention, the control means (28) capable of controlling the electric field forming means (16) for forming an electric field at the tip of the nozzle portion (32) is provided. The control means (28) can form an electric field at the tip of the nozzle section (32) even after the liquid transport is stopped. Thereby, the liquid sent to the tip of the nozzle part (32) by the action of the residual pressure after the operation is stopped can be surely sprayed. As a result, no liquid pool is formed at the tip of the nozzle part (32) after the operation is stopped, so that liquid leakage from the tip of the nozzle part (32) can be reliably prevented.

    According to the second aspect of the invention, the electric field is continuously formed at the tip of the nozzle portion (32) after the liquid conveyance is stopped. Thereby, the liquid sent to the tip of the nozzle part (32) by the action of the residual pressure after the operation is stopped can be surely sprayed. As a result, no liquid pool is formed at the tip of the nozzle part (32) after the operation is stopped, so that liquid leakage from the tip of the nozzle part (32) can be reliably prevented.

    According to the third aspect of the invention, since the liquid is moved to the tip of the nozzle part (32) by pressurizing the container (31), the liquid is moved to the tip of the nozzle part (32) with a simple configuration. Can be transported.

    According to the fourth aspect of the invention, after the pressurizing means (23) stops pressurizing the container (31), an electric field is continuously formed at the tip of the nozzle portion (32) for a predetermined time. I did it. Thereby, the liquid sent to the tip of the nozzle part (32) by the action of the residual pressure after the operation is stopped can be surely sprayed. As a result, no liquid pool is formed at the tip of the nozzle part (32) after the operation is stopped, so that liquid leakage from the tip of the nozzle part (32) can be reliably prevented.

    According to the fifth aspect, since the power supply unit (24) has the capacitor, the electric field forming means (16) continuously generates the electric field even if the power supply from the power supply unit (24) is stopped. Can be formed. For this reason, even after the conveyance of the liquid is stopped, an electric field can be formed at the tip of the nozzle portion (32) by the charge accumulated in the capacitor. Thereby, the liquid sent to the tip of the nozzle part (32) by the action of the residual pressure after the operation is stopped can be surely sprayed. As a result, since no liquid pool is formed at the tip of the nozzle part (32) after the operation is stopped, liquid leakage from the tip of the nozzle part (32) can be reliably prevented.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

    As shown in FIG.1 and FIG.2, the electrostatic spraying apparatus (10) based on this invention is equipped with the main-body part (20) and the spray cartridge (30). In this electrostatic spraying device (10), the spray cartridge (30) is detachable from the main body (20).

    The spray cartridge (30) includes a container part (31) configured as a flat bag-like container and a nozzle part (32) communicating with the inside of the container part (31). The spray cartridge (30) is configured such that when the container part (31) is compressed, the liquid inside the container part (31) is discharged through the nozzle part (32). The spray cartridge (30) is replaced when the liquid in the container part (31) is low.

Specifically, as shown in FIG. 3, the container part (31) is formed of a relatively flexible material that does not allow liquid to penetrate. The container part (31) is formed by overlapping two rectangular sheets (31a). In the two rectangular sheets (31a), three of the four sides are bonded together, and one side is connected via a rhombus-shaped seal member (31b). In the container part (31), a liquid containing a moisturizing component and an antioxidant component is stored in a state where air is not mixed. The concentration of the liquid is adjusted so that the electric resistivity is in the range of 1.0 × 10 ⁴ Ωcm to 1.0 × 10 ⁷ Ωcm.

    The nozzle part (32) is, for example, a resin nozzle. The nozzle portion (32) has an inner diameter that is uniform from the base end to the tip. The inner diameter (diameter) of the nozzle part (32) is, for example, 0.2 mm. The interior of the nozzle part (32) communicates with the interior of the container part (31). The nozzle section (32) may be provided with a resistor serving as a flow path resistance of the liquid toward the tip in order to adjust the amount of liquid fed per unit time. While the inner diameter of the nozzle part (32) is small, the flow path resistance of the nozzle part (32) is increased. For this reason, even if the pressing force against the container part (31) is increased, the liquid inside the container part (31) is gradually supplied to the tip of the nozzle part (32). Thereby, even if the pressure on the container part (31) is released, the residual pressure acts on the liquid inside the container part (31). Then, the liquid is fed into the tip of the nozzle part (32) until the residual pressure is eliminated. The nozzle part (32) is attached to the central part of the seal member (31b) of the container part (31). The nozzle part (32) is provided with a cartridge side electrode (16) that comes into contact with a main body side electrode described later. The cartridge side electrode (16) is exposed on the outer peripheral surface of the nozzle part (32) and is in contact with the liquid inside the nozzle part (32). The cartridge side electrode (16) constitutes an electric field forming means for forming an electric field at the tip of the nozzle part (32).

    The main body (20) includes a housing (21), a base member (22), a pressing mechanism (23), a power supply unit (24), and a control unit (28). The pressing mechanism (23) and the base member (22) form a liquid transport means (15) for supplying a liquid to the nozzle portion (32) of the spray cartridge (30).

    The housing (21) includes a first case (41) and a second case (42) as a pair. One end of the first case (41) and the second case (42) are connected by a hinge (46) so that the housing (21) can be opened and closed. The closed housing (21) is formed in an approximately elliptical shape in a cross-sectional view. The first case (41) and the second case (42) are formed in a bowl shape having substantially the same shape. The second case (42) is provided with a claw-like member (48) that is hooked to the first case (41) in order to close the housing (21). In this electrostatic spraying device (10), the second case (42) is installed below the first case (41). Further, although not shown, the second case (42) is provided with legs for supporting the housing (21). The housing (21) may be provided with an angle adjusting mechanism for adjusting the angle of the nozzle part (32) of the attached spray cartridge (30). Further, the leg portion may be configured such that the angle of the nozzle portion (32) can be adjusted.

    The pedestal member (22) is attached so as to cover the open surface of the second case (42). A container installation part (43) for installing the container part (31) is formed near the center of the base member (22). Further, a notch portion (44) is formed at a position facing the hinge (46) on the outer peripheral portion of the base member (22). The cutout portion (44) is provided with a nozzle holding member (45) for holding the nozzle portion (32). The nozzle holding member (45) holds the nozzle portion (32) by sandwiching the nozzle portion (32). The nozzle holding member (45) is provided with a main body side electrode that contacts the cartridge side electrode (16). The main body side electrode and the power source section (24) are electrically connected, and are configured to output a voltage from the power source section (24) to the main body side electrode.

    The pressing mechanism (23) is provided inside the first case (41). The pressing mechanism (23) includes a constant load spring (25), a pressing member (26), and a pair of guide members (27), and forms a pressing means for compressing the container portion (31). The pressing mechanism (23) moves the pressing member (26) downward by a load generated by the constant load spring (25). The pressing member (26) is formed in a flat plate shape, and both end portions are attached to the guide member (27) and configured to press the container portion (31) in a planar shape.

    Specifically, one end of the constant load spring (25) is attached to the first case (41), and the other end is attached to the column (26a) of the pressing member (26). The constant load spring (25) is a spring in which a strip-shaped metal plate formed with a constant curvature is wound in a spiral shape. The constant load spring (25) has a characteristic that when the stroke exceeds a predetermined value, the restoring force becomes constant even if the stroke is further increased.

    The guide member (27) supports the pressing member (26) when the housing (21) is closed. The guide member (27) is configured to move downward in a state in which the pressing member (26) is kept parallel to the bottom surface of the container installation portion (43). Further, the guide member (27) is configured to support and fix the pressing member (26) at a position when the operation is stopped when the user stops the operation of the electrostatic spraying device (10).

    The power supply unit (24) is provided inside the second case (42). The power supply unit (24) is configured to convert the output voltage from the battery housed in the second case (42) into a high voltage of, for example, 6 kV and output it to the main body side electrode. The voltage output to the main body side electrode is applied to the liquid inside the nozzle part (32) via the cartridge side electrode (16). In addition, the power supply part (24) should just be comprised so that a voltage may be converted into the value of 0 kV or more and 12 kV or less.

    Next, the control unit (28) which is a characteristic part of the present invention will be described.

    As shown in FIG. 2, the control unit (28) is provided inside the second case (42). The control unit (28) is electrically connected to the power supply unit (24). The control unit (28) is configured to control an applied voltage value and an application time of the voltage output from the power supply unit (24) to the body side electrode. In particular, in the control unit (28), the cartridge side electrode (16) forms an electric field at the tip of the nozzle unit (32) even after the pressing mechanism (23) stops pressurizing the container unit (23). In this way, the voltage applied to the cartridge side electrode (16) is controlled.

-Driving action-
Next, the operation of the electrostatic spray device (10) of this embodiment will be described. This electrostatic spraying device (10) performs so-called cone jet mode EHD spraying.

    The electrostatic spraying device (10) is ready for operation when the user installs the spray cartridge (30) in the container setting portion (43) of the housing (21) and then closes the housing (21). When the spray cartridge (30) is installed, the stroke of the constant load spring (25) becomes larger by the thickness of the container part (31) than before the spray cartridge (30) is installed. In this state, the load generated by the constant load spring (25) is applied to the pressing member (26).

    When the user operates the electrostatic spraying device (10), the pressing member (26) moves downward under the load of the constant load spring (25). The pressing member (26) moved downward contacts the container part (31) and presses the container part (31). The liquid inside the pressed container part (31) moves to the tip of the nozzle part (32). The inner diameter of the nozzle part (32) is small and the flow path resistance of the nozzle part (32) is large. For this reason, even if the pressing force against the container part (31) is increased, the liquid inside the container part (31) is gradually supplied to the tip of the nozzle part (32).

    On the other hand, when the user operates the electrostatic spraying device (10), the power supply unit (24) outputs a predetermined voltage to the cartridge side electrode (16) via the main body side electrode. When a voltage is output from the cartridge side electrode (16), an electric field is formed at the tip of the nozzle portion (32). At this time, for example, a voltage of 6 kV is applied to the tip of the nozzle portion (32). When an electric field is formed at the tip of the nozzle part (32), the liquid at the tip of the nozzle part (32) is polarized, and + (plus) charges are collected near the gas-liquid interface at the tip of the nozzle part (32). . Then, at the tip of the nozzle portion (32), the gas-liquid interface is extended into a conical shape, and a part of the aqueous solution is torn off from the top of the conical gas-liquid interface to form droplets.

    Note that, in the case of the magnitude of the applied voltage and the electrical resistivity of the liquid according to this embodiment, the size of the droplets scattered from the nozzle portion (32) is approximately in the range of 50 μm to 200 μm. The liquid splashed from the nozzle part (32) reaches a distance of about 40 to 50 cm from the tip of the nozzle part (32). When the user installs the electrostatic spraying device (10) with the nozzle part (32) facing the face approximately 50 cm forward, the scattered droplets adhere to the user's face.

    Next, the operation when the electrostatic spraying device (10) is stopped will be described.

    When the user stops the electrostatic spraying device (10), the guide member (27) fixes the pressing member (26) and restricts the downward movement. When the downward movement of the pressing member (26) is stopped, the pressing force on the container part (31) disappears. However, since the residual pressure acts on the liquid inside the container part (31), the liquid is sent to the tip of the nozzle part (32). In this state, the control unit (28) outputs a voltage from the power source unit (24) to the cartridge side electrode (16) through the main body side electrode over a predetermined time. The output voltage at this time is set to 6 kV. The applied voltage value and the voltage application time can be changed according to the amount of liquid fed to the tip of the nozzle section (32). For this reason, as shown in FIG. 4, since the electric field is formed at the tip of the nozzle part (32) for a predetermined time even after the operation is stopped, the electrostatic spraying device (10) causes the nozzle part ( Spray the liquid sent to the tip of 32).

-Effect of the embodiment-
As described above, according to the present embodiment, even after the pressing of the pressing member (26) against the container part (31) is stopped, the control unit (28) is connected from the power supply unit (24) to the cartridge side electrode (16). Was controlled to output an output voltage (6 kV) during steady spraying. For this reason, after the operation is stopped, the liquid sent to the tip of the nozzle portion (32) by the residual pressure can be sprayed. As a result, no liquid pool is formed at the tip of the nozzle part (32) after the operation is stopped, thus reliably preventing liquid leakage from the tip of the nozzle part (32) and clogging during the next operation. be able to.

<Modification of this embodiment>
Next, a modification of this embodiment will be described.

    In this modification, the control unit (28) of the above embodiment directly controls the output voltage from the power supply unit (24), but not shown, but the power supply unit (24) is provided with a capacitor, The applied voltage of the cartridge side electrode (16) is controlled. In other words, the capacitor constitutes the control unit (28) and is configured to form an electric field at the tip of the nozzle part (32) even after the pressurization of the container part (31) is stopped.

    Specifically, when the user stops the electrostatic spraying device (10), the guide member (27) fixes the pressing member (26) and restricts the downward movement. When the downward movement of the pressing member (26) is stopped, the pressing force on the container part (31) disappears. However, since the residual pressure acts on the liquid inside the container part (31), the liquid is sent to the tip of the nozzle part (32). On the other hand, when the electrostatic spraying device (10) stops, the power supply from the power supply unit (24) stops. However, electric charges are accumulated in the capacitor provided in the power supply unit (24) between the time when the operation starts and the time when the operation stops. Therefore, the capacitor outputs a voltage to the cartridge side electrode (16) through the main body side electrode even when the power supply of the power source unit (24) is stopped. The output voltage at this time is 6 kV, which is an applied voltage in a steady state, and gradually decreases from there. For this reason, as shown in FIG. 5, since the electric field is formed at the tip of the nozzle portion (32) for a predetermined time even after the operation is stopped, the electrostatic spraying device (10) causes the nozzle portion ( The liquid sent to the tip of 32) can be sprayed. Other configurations and operations are the same as those in the embodiment.

<Other embodiments>
The present invention may be configured as follows with respect to the above embodiment.

    About the said embodiment and modification, you may use the aqueous solution of theanine as a liquid to spray. Further, an aqueous solution of an antioxidant such as catechin or proanthocyanidin may be used. A liquid containing a substance having a function of suppressing the growth of microorganisms or a function of killing microorganisms may be used. Alternatively, a liquid containing a substance that does not bromide due to a chemical change such as neutralization of odor molecules in the air may be used. Alternatively, a liquid containing a substance that chemically changes the antigenic site of a protein serving as an allergen may be used. Further, a liquid containing a substance that renders harmful substances in the air harmless by chemical change may be used. Moreover, you may use the liquid containing various fragrance | flavor, a pest repellent, etc.

    Further, in the present embodiment and the modification, an electrostatic spraying device (10) having a liquid transporting device (15) constituted by a constant load spring (25), a pressing member (26), a spray cartridge (30), etc. However, the present invention can be applied to various electrostatic spraying apparatuses.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for preventing liquid leakage after the operation of the electrostatic spraying device is stopped.

It is a perspective view which shows the electrostatic spraying apparatus which concerns on embodiment of this invention. It is a schematic sectional drawing which shows the electrostatic spraying apparatus which concerns on embodiment of this invention. It is a perspective view which shows the spray cartridge which concerns on embodiment of this invention. It is a timing chart which shows the relationship between the pressing force which concerns on embodiment of this invention, a container part internal pressure, an applied voltage, and time. It is a timing chart which shows the relationship between the pressing force which concerns on the modification of embodiment of this invention, a container part internal pressure, and an applied voltage. (A) is a schematic cross-sectional view showing a nozzle portion, and (B) is a schematic cross-sectional view showing a nozzle portion where a liquid pool has occurred. It is a graph which shows the relationship between a container part internal pressure and time.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Electrostatic spray apparatus 15 Liquid conveyance apparatus 16 Cartridge side electrode 23 Press mechanism 24 Power supply part 28 Control part 31 Container part 32 Nozzle part

Claims (5)

A container (31) for storing liquid, a nozzle part (32) communicating with the inside of the container (31), and a liquid for supplying the liquid inside the container (31) to the tip of the nozzle part (32) Conveying means (15), a power supply section (24), and an electric field forming means (16) that is supplied with power from the power supply section (24) and forms an electric field at the tip of the nozzle section (32),
An electrostatic spraying device that sprays liquid in an atomized state from the tip of the nozzle portion (32) by forming an electric field of the electric field forming means (16),
Control means (28) for controlling the electric field forming means (16) to spray the liquid at the tip of the nozzle portion (32) after the liquid transport of the liquid transport means (15) is stopped. An electrostatic spraying device characterized by. In claim 1,
The control means (28) controls the electric field forming means (16) so that the electric field formation of the electric field forming means (16) continues even after the liquid transfer of the liquid transfer means (15) is stopped. An electrostatic spraying device characterized by. In claim 2,
While the container (31) is constituted by a flexible member,
The liquid spraying means (15) is provided with a pressurizing means (23) for compressing the container (31) and supplying the liquid to the tip of the nozzle part (32), . In claim 3,
The control means (28) stops the pressurization of the pressurizing means (23) against the container (31), and then the electric field forming means (16) forms the electric field until a predetermined time elapses. An electrostatic spraying device characterized by controlling the forming means (16). In claim 2,
The control means (28) is constituted by a capacitor that accumulates electric charges by supplying power from the power supply unit (24),
The control means (28) controls the electric field forming means (16) so that the electric field forming means (16) forms an electric field by the electric charge accumulated in the capacitor. .

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