JP2009172491A - Electrostatic spraying equipment - Google Patents

Abstract

[PROBLEMS] To prevent air bubbles from entering a nozzle.
SOLUTION: A housing 41, a container 11 accommodated in the housing 41 and filled with a liquid, and a nozzle attached to the container 11, having a front end opened to the outside of the container and a rear end opened to the inside of the container. A main body 21, a pressurizing mechanism that compresses the container 11 and supplies a liquid to the tip of the nozzle main body 21, and a conductive member 12 that applies a predetermined voltage to the liquid in the container 11 are provided. The target is an electrostatic spraying device in which the liquid is sprayed from the tip of the nozzle body 21 in an atomized state. The nozzle body 21 is formed with a nozzle extension 61 that is extended so that the rear end of the nozzle body 21 is opened at the center in the container 11.
[Selection] Figure 5

Description

    The present invention relates to an electrostatic spraying device, and particularly relates to measures for preventing bubbles from entering a nozzle.

    Conventionally, as a liquid spraying device for spraying a liquid stored in a container, an electrostatic spraying device for spraying a liquid sent to a nozzle serving as an outlet of the container from the tip of the nozzle by an 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 formed 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. In this state, by forming an electric field at the tip of the nozzle, the liquid in the pouch is sprayed from the tip of the nozzle.

As an electrostatic spraying device of the same type as the electrostatic spraying device, for example, an electrostatic spraying device (a) as shown in FIG. 10 or FIG. 11 is known. In this type of electrostatic spraying device (a), the container (b) storing the liquid is pressurized by the pressurizing member (c), so that the container (b) is compressed and the liquid in the container (b) is discharged. The nozzle (d) is supplied.
Japanese Patent Laid-Open No. 05-138081

    However, in the electrostatic spraying device (a), when the liquid is filled in the container (b), air is filled in the container (b) together with the liquid. Therefore, when the container (b) is pressurized and the liquid is supplied into the nozzle (d), air bubbles (e) simultaneously enter the nozzle (d) at the same time as the liquid, and as shown in FIG. Air bubbles are clogged in the flow path. In this state, even if the container (b) is pressed, the liquid cannot be supplied to the tip of the nozzle (d), and as a result, the liquid cannot be sprayed from the tip of the nozzle (d). there were.

    The present invention has been made in view of such a point, and an object thereof is to prevent bubbles from entering the inside of a nozzle.

    The first invention includes a housing (41), a container (11) housed in the housing (41) and filled with a liquid, and attached to the container (11), the tip of the container (11) being outside the container (11). A nozzle (20) having a rear end opened inside the container (11), a pressurizing means (50) for compressing the container (11) and supplying liquid to the tip of the nozzle (20), Voltage applying means (12) for applying a predetermined voltage to the liquid in the container (11), and the liquid to which the predetermined voltage is applied by the voltage applying means (12) is fogged from the tip of the nozzle (20). It is an electrostatic spraying device sprayed in a liquefied state, and is provided with a restricting means (60) for restricting bubbles contained in the liquid in the container (11) from entering the nozzle (20).

    In the first aspect of the invention, the liquid in the container (11) is charged by the voltage applying means (12). When the container (11) is pressed in this state, the liquid and bubbles in the container (11) flow toward the inside of the nozzle (20). Here, the regulation means (60) regulates the bubbles contained in the container (11) from entering the nozzle (20). Only the charged liquid flows into the nozzle (20) and blows out as a fine liquid from the tip of the nozzle (20).

    In a second aspect based on the first aspect, the regulating means (60) is configured such that the rear end of the nozzle (20) is located inside the container (11) rather than bubbles accumulated on the inner wall of the container (11). The nozzle extension (61) is formed by extending the nozzle (20) so as to open.

    In the said 2nd invention, the bubble contained with a liquid in a container (11) stays in the inner wall part of a container (11). The nozzle (20) is opened to extend inside the container (11) rather than the bubbles remaining on the inner wall of the container (11). When the container (11) is pressed, only the liquid in the container (11) flows into the nozzle (20) and blows out as a fine liquid from the tip of the nozzle (20).

    In a third aspect based on the second aspect, the nozzle extension (61) is formed so as to protrude inside the container (11) from the inner wall surface of the container (11) into which the nozzle (20) is inserted. Has been.

    In the said 3rd invention, the bubble contained with a liquid in a container (11) accumulates on the inner wall face of a container (11). The nozzle (20) protrudes inside the container (11) from the inner wall surface of the container (11). When the container (11) is pressed, only the liquid in the container (11) flows into the nozzle (20) and blows out as a fine liquid from the tip of the nozzle (20).

    In a fourth aspect based on the third aspect, the nozzle extension (61) extends so that the rear end of the nozzle (20) opens at a central portion inside the container (11).

    In the fourth aspect of the invention, the rear end of the nozzle (20) extends so as to open at the center in the container (11). When the container (11) is pressed, only the liquid in the container (11) flows into the nozzle (20) and blows out as a fine liquid from the tip of the nozzle (20).

    In a fifth aspect based on the first aspect, the restricting means (60) includes a filter (62) attached to the rear end of the nozzle (20).

    In the fifth aspect, when the container (11) is compressed, bubbles flow into the nozzle (20) together with the liquid in the container (11). A filter (62) attached to the rear end of the nozzle (20) captures bubbles contained in the liquid in the container (11). Only the liquid in the container (11) flows into the nozzle (20) and blows out as a fine liquid from the tip of the nozzle (20).

    In a sixth aspect based on the first aspect, the regulating means (60) is formed in the container (11), and bubbles in the container (11) are located above the rear end of the nozzle (20). It consists of an air reservoir (63) that collects in the air.

    In the sixth aspect of the invention, the bubbles contained in the container (11) together with the liquid accumulate in the air reservoir (63) at the upper part of the container (11). The rear end of the nozzle (20) is formed below the air reservoir (63). When the container (11) is pressed, only the liquid in the container (11) flows into the nozzle (20) and blows out as a fine liquid from the tip of the nozzle (20).

    In a seventh aspect based on the sixth aspect, the container (11) is formed in a rectangular shape, and the nozzle (20) is attached to the center of the upper surface of the container (11), while the air reservoir ( 63) is formed at the upper corner of the container (11), and the inner upper surface of the container (11) is formed as a tapered surface that rises toward the air reservoir (63).

    In the seventh aspect of the invention, the bubbles contained together with the liquid in the container (11) accumulate in the air reservoir (63) at the upper corner of the container (11) along the tapered surface. The rear end of the nozzle (20) is formed below the air reservoir (63). When the container (11) is pressed, only the liquid in the container (11) flows into the nozzle (20) and blows out as a fine liquid from the tip of the nozzle (20).

According to an eighth invention, in the sixth or seventh invention, the inner wall of the container (11) is constituted by a member having affinity for the liquid filled in the container (11). .

In the eighth aspect of the invention, air bubbles adhere to the inner wall surface of the container (11) by coating the inner wall surface of the container (11) with a material having a high affinity for the liquid filled in the container (11). To prevent .

    According to the present invention, since the restricting means (60) for restricting the entry of bubbles is provided inside the nozzle (20), it is possible to reliably prevent the bubbles from entering the nozzle (20). Thereby, even if the container (11) is pressed, bubbles are not clogged in the liquid flow path inside the nozzle (20). As a result, the liquid can be reliably sprayed from the tip of the nozzle (20).

    According to the second aspect of the present invention, the nozzle extension (61) is formed in the nozzle (20), and the rear end of the nozzle (20) is placed on the inner wall of the container (11) rather than the bubbles accumulated in the container (11). Since the opening is made inside, it is possible to surely prevent the bubbles accumulated on the inner wall portion of the container (11) from entering the nozzle (20). Thereby, even if the container (11) is pressed, bubbles are not clogged in the liquid flow path inside the nozzle (20). As a result, the liquid can be reliably sprayed from the tip of the nozzle (20).

    According to the third aspect of the invention, since the nozzle extension (61) is protruded inside the container (11) from the inner wall surface of the container (11), the inner wall surface of the container (11) is placed inside the nozzle (20). It is possible to reliably prevent the bubbles accumulated in the intrusion. Thereby, even if the container (11) is pressed, bubbles are not clogged in the liquid flow path inside the nozzle (20). As a result, the liquid can be reliably sprayed from the tip of the nozzle (20).

    According to the fourth aspect of the invention, the nozzle extension (61) is formed so that the rear end of the nozzle (20) is opened at the center in the container (11). It is possible to reliably prevent the air bubbles accumulated on the inner wall portion of the container (11) from entering. Thereby, even if the container (11) is pressed, bubbles are not clogged in the liquid flow path inside the nozzle (20). As a result, the liquid can be reliably sprayed from the tip of the nozzle (20).

    According to the fifth aspect, since the filter (62) is attached to the rear end of the nozzle (20), before the bubbles contained in the liquid in the container (11) enter the inside of the nozzle (20), It can be captured by a filter (62). For this reason, it is possible to reliably prevent bubbles from entering the nozzle (20). Thereby, even if the container (11) is pressed, bubbles are not clogged in the liquid flow path inside the nozzle (20). As a result, the liquid can be reliably sprayed from the tip of the nozzle (20).

    According to the sixth aspect of the invention, since the air reservoir (63) is formed in the container (11) to accumulate the bubbles above the rear end of the nozzle (20), the bubbles enter the nozzle (20). Can be reliably prevented. Thereby, even if the container (11) is pressed, bubbles are not clogged in the liquid flow path inside the nozzle (20). As a result, the liquid can be reliably sprayed from the tip of the nozzle (20).

    According to the seventh aspect of the invention, the air reservoir (63) is formed in the upper corner of the container (11) above the rear end of the nozzle (20), and the inner upper surface of the container (11) Since it was formed in the taper surface which goes up toward a reservoir (63), the bubble in a container (11) can be guide | induced to an air reservoir (63). For this reason, it is possible to reliably prevent bubbles from entering the nozzle (20). Thereby, even if the container (11) is pressed, bubbles are not clogged in the liquid flow path inside the nozzle (20). As a result, the liquid can be reliably sprayed from the tip of the nozzle (20).

According to the eighth aspect of the invention, by coating the inner wall surface of the container (11) with a material having a high affinity with the liquid filled in the container (11), bubbles are formed on the inner wall surface of the container (11). It is possible to prevent adhesion.

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

<Embodiment 1>
In the first embodiment, the present invention is applied to an electrostatic spraying apparatus.

    As shown in FIGS. 1-6, the electrostatic spraying apparatus (1) which concerns on this Embodiment 1 is installed and used on a desktop etc. As shown in FIG. The electrostatic spraying device (1) includes a housing (41) and a spray cartridge (10). In the electrostatic spraying device (1), the spray cartridge (10) is detachable from the housing (41).

    The spray cartridge (10) includes a container (11) configured as a flat bag-like container, a conductive member (12) and a nozzle (20) inserted into the container (11), and the nozzle (20 And a nozzle cap (23) for preventing drying of the liquid in the inside. Details of the spray cartridge (10) will be described later.

    The housing (41) includes a housing body (41a) and a pair of cover members (41b, 41c) that respectively cover both ends of the housing body (41a). Cover (42) is attached. Inside the housing (41), a pressurizing mechanism (50) which is a pressurizing means and a power source (not shown) are accommodated.

    The housing body (41a) is formed in a cylindrical shape, and a support portion (43) for supporting the housing body (41a) is provided at the lower portion, while a shroud (48) for protecting the nozzle (20) is provided at the upper portion. ) Is formed. The shroud (48) is formed to bulge out from the housing body (41a), and has a recess at a substantially central portion. The shroud (48) is formed with a hole for mounting the spray cartridge (10). Moreover, LED (46) is attached to the lower side of the hole of the upper part of a housing main body (41a) (2 pieces in FIG. 1). This LED (46) is irradiated from the tip of the nozzle (20) toward the liquid to be sprayed so that the user of the electrostatic spraying device (1) can check the spray state. is there. Although not shown, one end of a constant load spring (51) to be described later is attached to the inside of the housing main body (41a).

    The cover member (41b, 41c) includes a first cover (41b) and a second cover (41c) that form a pair. First, the first cover (41b) is formed in a circular shape having substantially the same outer shape as one end surface of the housing body (41a), and is attached so as to cover one end surface of the housing body (41a). The first cover (41b) is attached so that the user can turn it in the circumferential direction of the housing body (41a). The surface of the first cover (41b) is provided with a strip-like counter electrode (44) for the charged liquid, while the back surface of the first cover (41b) is not shown, but the first cover (41b) A cylindrical winding upper portion having a smaller diameter is formed. A notch that is spirally cut along the circumferential direction of the upper part is formed in the upper part of the winding, and the movement of the pressurizing stage (52) described later is restricted. Next, the second cover (41c) is formed in a circular shape having substantially the same outer shape as the other end surface of the housing body (41a), and is attached so as to cover the other end surface of the housing body (41a). On the surface of the second cover (41c), a band-like counter electrode (44) for a charged liquid is provided, and a volume knob (45) that is interlocked with an output adjustment volume of a power supply unit described later is provided. .

    The pedestal cover (42) protects the nozzle (20) when the electrostatic spraying device (1) is stopped (during storage), while being used as a pedestal for supporting the housing (41). The base cover (42) is formed in a bowl shape along the cylindrical side surface of the housing body (41a). As shown in FIG. 4, the pedestal cover (42) is attached to the housing (41) so as to cover the hole on the upper side surface of the housing body (41a) when stopped (during storage). , Removed from the housing (41) and attached to the lower support portion (43) of the housing body (41a). In this electrostatic spraying device (1), the base cover (42) is attached to the lower part of the support part (43), and the housing (41) is supported by the base cover (42) from below. And the housing (41) can be adjusted to a two-stage height including a state in which the housing (41) is supported only from the lower side.

    The pressurizing mechanism (50) is for compressing the container (11) of the spray cartridge (10) and transporting the liquid in the container (11) to the tip of the nozzle (20). The pressure mechanism (50) includes a constant load spring (51), a pressure stage (52), and a partition plate (53). Specifically, the pressurizing mechanism (50) is configured so that the constant load spring (51) moves the pressurizing stage (52) toward the second cover (41c) inside the housing (41), and the pressurizing stage. The container (11) is sandwiched between (52) and the partition plate (53) and pressed.

    The pressurizing stage (52) is formed in a bottomed cylindrical shape, and spring holding portions (52a) to which constant load springs (51) are respectively attached are formed at both end portions. Further, although not shown, a convex portion that protrudes toward the center of the pressure stage (52) is formed on the inner surface of the pressure stage (52). When the first cover (41b) is rotated in the circumferential direction of the housing main body (41a) by making the convex part abut on a notch formed in the upper part of the first cover (41b), the convex part is spiraled. It guides to the 1st cover (41b) side along a notch. Along with this, the pressure stage (52) moves to the first cover (41b) side, whereby the pressure stage (52) is held by the first cover (41b). In this state, the container (11) of the spray cartridge (10) is separated from the pressure stage (52). And if a 1st cover (41b) is reversely rotated and a convex part is guided to a 2nd cover (41c) side along a spiral notch, a convex part will remove | deviate from a winding part. At this time, the pressure stage (52) is movable with respect to the first cover (41b). That is, the first cover (41b) is rotated to switch between holding and releasing the pressure stage (52).

    The constant load spring (51) 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 (51) has a characteristic that when the stroke exceeds a predetermined value, the restoring force becomes constant even if the stroke is further increased. The main body of the constant load spring (51) is attached to the spring holding portion (52a) of the pressure stage (52), and one end of the spirally wound metal plate is attached to the inside of the housing body (41a). Yes.

    The partition plate (53) is formed of a flat plate member, and faces the pressure stage (52) with the container (11) of the spray cartridge (10) interposed therebetween in the housing (41). Installed. The partition plate (53) is attached to the housing body (41a).

    Although not shown, the power supply unit is provided closer to the second cover (41c) than the partition plate. A power supply part converts the output voltage from the battery accommodated in the housing (41) into a high voltage of 6 kV, for example. The converted high voltage is applied to the liquid in the container (11) of the spray cartridge (10) through the conductive member (12). That is, the conductive member (12) constitutes a voltage applying unit. The power supply section is provided with an output adjustment volume for adjusting the output voltage, and this output adjustment volume rotates in conjunction with a volume knob (45) attached to the second cover (41c). It is configured as follows. That is, the output voltage from the power supply unit can be adjusted as appropriate by rotating the volume knob (45). In addition, the power supply part should just be comprised so that a voltage may be converted into the value below 0 kV and below 12 kV.

    As shown in FIGS. 5 to 7, the spray cartridge (10) includes a container (11) configured as a flat bag-like container, a conductive member (12) and a nozzle ( 20) and a nozzle cap (23) for preventing the liquid in the nozzle (20) from drying. The spray cartridge (10) is housed in the housing (41) with a nozzle base (30) protecting the nozzle (20) attached. Then, when the spray cartridge (10) is housed in the housing (41), the tip of the nozzle (20) is adjusted to face obliquely upward. The spray cartridge (10) is configured such that the liquid in the container (11) is supplied to the nozzle (20) when the container (11) is compressed. The spray cartridge (10) is replaced when the liquid in the container (11) is low.

The container (11) is formed by superposing two rectangular sheets made of a relatively soft material that does not allow liquid to permeate. In the two rectangular sheets, a hollow container is formed by bonding the four sides of each other. At the center of the upper surface of the container (11), a container tip (11a) that communicates the inside and the outside of the container (11) is formed protruding toward the outside of the container (11). The container tip (11a) is formed in a hollow cylindrical shape, and a conductive member (12) and a nozzle (20) described later are inserted therein. The container (11) is filled with a liquid containing a moisturizing component and an antioxidant component. The concentration of this liquid is adjusted so that the electric resistivity is in the range of 1.0 × 10 ⁴ Ωcm to 1.0 × 10 ⁷ . Further, the container (11) is held in an inclined state together with the nozzle (20) in the housing (41).

    The conductive member (12) is for imparting electric charges to the liquid filled in the container (11). The conductive member (12) is formed of a conductive resin and is in contact with the liquid in the container (11) while being connected to the power supply unit. Specifically, the conductive member (12) includes an insertion portion (12a) to be inserted into the container front end portion (11a), and a flange (12b) formed at one end of the insertion portion (12a). .

    The said insertion part (12a) is formed in a cylindrical shape, and the nozzle (20) has penetrated substantially the center part. The insertion part (12a) is inserted into the container front end part (11a), and the lower end is in contact with the liquid inside the container (11).

    The flange (12b) is formed in a large-diameter circular shape and is attached to the upper end of the insertion portion (12a). A recess that engages the lower end of a nozzle holding portion (22), which will be described later, is formed in the substantially central portion of the upper end surface of the flange (12b), while the nozzle (20) It penetrates. That is, the nozzle (20) is inserted through the conductive member (12) from the lower end of the insertion portion (12a) to the upper end of the flange (12b). Further, in the conductive member (12), the insertion portion (12a) is inserted into the container front end portion (11a), while the lower end surface of the flange (12b) closes the opening at the front end of the container front end portion (11a). Therefore, the liquid is sealed in the container (11).

The nozzle base (30) constitutes a part of the shroud (48). The nozzle base (30) is formed in a horizontally long substantially rectangular parallelepiped shape, and a through hole (34) from which the tip of the nozzle (20) protrudes is formed at the center. At both ends in the longitudinal direction of the nozzle base (30), a wall portion (31) extending upward is formed, and a leg portion (33) extending downward is formed. When the nozzle base (30) is attached to the spray cartridge (10), the nozzle (20) is fixed in a state of protruding from the through hole (34). Here, the wall portion (31) is formed so that its height projects beyond the height of the tip of the nozzle (20). When the nozzle base (30) is attached to the housing (41) while being attached to the spray cartridge (10), the wall (31) forms both ends of the shroud (48) in the longitudinal direction. That is, the wall portion (31) of the nozzle base (30) and the inner surface (47) of the shroud (48) form a continuous wall surface and surround the protruding nozzle (20). The continuous wall surface is formed at a distance (1 cm or more in the first embodiment) that does not inhibit the electric field formed around the nozzle (20) from the tip of the nozzle (20). In addition, the height of the inner surface (47) of the shroud (48) is formed to be equal to the height of the wall portion (31) of the nozzle base (30).

    The nozzle cap (23) seals the tip of the nozzle (20) to prevent the liquid remaining inside the nozzle (20) from drying when the electrostatic spraying device (1) is stopped (stored). Is for. The nozzle cap (23) includes a large portion that covers the nozzle holding portion (22) and a small portion that covers the tip of the nozzle body (21). The nozzle holding part (22) and the nozzle body (21) will be described later.

    The large portion is formed in a cylindrical shape slightly larger than the nozzle holding portion (22) and covers the nozzle holding portion (22). The small portion is formed in a cylindrical shape that is smaller than the large portion and slightly larger than the tip of the nozzle body (21), and covers the tip of the nozzle body (21). Further, the inner side surface of the small portion is formed in a tapered surface that becomes narrower from the proximal end toward the distal end. That is, when the nozzle (20) is inserted into the nozzle cap (23), the tip of the nozzle body (21) is guided from the base end to the tip along the tapered surface of the small portion of the nozzle cap (23). Then, the nozzle holding part (22) abuts against the upper end surface of the large part of the nozzle cap (23) and is fixed.

    Next, the configuration of the nozzle (20), which is a feature of the present invention, will be described.

    As shown in FIG. 7, the nozzle (20) is for discharging the liquid filled in the container (11) to the outside. The nozzle (20) includes a nozzle body (21) that is a thin tube, a nozzle holding part (22) that is integrally formed with the nozzle body (21), and a nozzle extension part (61) that is a regulating means (60). I have.

The nozzle body (21) is formed in a tube shape having a uniform inner diameter from the rear end to the front end, and the rear end opens inside the container (11), while the front end opens outside the container (11). is doing. The nozzle body (21) has an outer diameter of, for example, 0.35 mm, and an inner diameter (diameter) of, for example, 0.1 mm. The nozzle body (21) is formed of a flexible resin material and is inserted into the conductive member (12). The nozzle body (21) is formed with a free end of 6 to 7 mm from the upper end surface of the nozzle holder (22) to the tip of the nozzle body (21).
The nozzle body (21) may be provided with a resistor that serves as a flow path resistance of the liquid toward the tip in order to adjust the liquid amount per unit time of the liquid fed from the container (11). .

    The nozzle holding part (22) is for fixing to the container (11) while holding the nozzle body (21) formed of a flexible resin material. The nozzle holding part (22) is formed of a substantially cylindrical resin member that is larger than the nozzle body (21), and the nozzle body (21) is inserted into the nozzle body (21) in the center. Insert molding. The nozzle holding portion (22) has leg portions that are in contact with the outer peripheral surface of the nozzle body (21) with a gap, and supports the nozzle body (21) at three points. And the lower end of the nozzle holding part (22) is engaged with the recessed part formed in the upper end surface of the flange (12b) of the said electrically-conductive member (12). That is, the nozzle holding part (22) forms the root part of the nozzle (20).

    The nozzle extension (61) is for preventing bubbles contained in the liquid from entering the nozzle body (21). The nozzle extension part (61) is formed by extending the rear end of the nozzle body (21) inserted into the conductive member (12) to the center part inside the container (11). That is, the rear end of the nozzle body (21) is opened on the inner side of the inner wall surface of the container (11) and below the bubbles accumulated on the inner wall of the container (11).

-Driving action-
Next, operation | movement of the electrostatic spraying apparatus (1) of this Embodiment 1 is demonstrated. In this electrostatic spraying device (1), so-called cone jet mode EHD spraying is performed.

    This electrostatic spraying device (1) becomes operable when the user inserts the spray cartridge (10) into the housing (41). At this time, a load generated by the constant load spring (51) is applied to the pressure stage (52).

    First, when the user manually turns the first cover (41b) in the circumferential direction of the housing body (41a), the restriction of the first cover (41b) with respect to the pressure stage (52) is released. When the restriction is released, the spring force of the constant load spring (51) is applied to the pressure stage (52), and the pressure stage (52) moves toward the partition plate (53). The container (11) filled with the liquid is pressed by the moved pressure stage (52) and the partition plate (53). The liquid in the compressed container (11) flows into the nozzle body (21). Here, since the nozzle extension (61) formed at the rear end of the nozzle body (21) extends to the center of the container (11), bubbles contained in the liquid in the container (11) Does not enter the body (21). Then, the liquid flowing into the nozzle body (21) moves to the tip of the nozzle body (21). On the other hand, since the electric power is applied to the liquid in the container (11) via the conductive member (12) from the power source, the charged liquid is polarized and the gas-liquid interface at the tip of the nozzle body (21) A liquid with a positive (+) charge collects in the vicinity of. At the tip of the nozzle body (21), the gas-liquid interface is elongated due to the potential difference with the counter electrode (44), resulting in a conical shape, and a part of the aqueous solution flows from the top of the conical gas-liquid interface. Torn into droplets. In addition, if the magnitude | size of the applied voltage of this embodiment and the electrical resistivity of a liquid are used, the magnitude | size of the droplet which splashes from the front-end | tip of a nozzle main body (21) will be a magnitude | size of the range of about 50 micrometers-200 micrometers in general. The liquid splashed from the nozzle body (21) reaches a distance of about 40 to 50 cm away from the tip of the nozzle body. When the user installs the electrostatic spraying device (1) with the tip of the nozzle body (21) facing the face approximately 50 cm forward, the scattered droplets adhere to the user's face.

-Effect of Embodiment 1-
According to the first embodiment, since the nozzle extension portion (61) extending to the central portion in the container (11) is formed at the rear end of the nozzle body (21), the rear end of the nozzle body (21) is connected to the container. (11) It can be made to open below the bubbles accumulated on the inner upper surface. For this reason, it can prevent reliably that a bubble penetrate | invades into the inside of a nozzle main body (21). Thereby, even if it presses a container (11), an air bubble does not clog the inside of a nozzle main body (21). As a result, the liquid can be reliably sprayed from the tip of the nozzle body (21).

<Embodiment 2 of the invention>
Next, Embodiment 2 of the present invention will be described with reference to the drawings.

    As shown in FIG. 8, the second embodiment is different from the first embodiment in the configuration of the restricting means (60). The restricting means (60) according to the second embodiment is different from the restricting means (60) according to the first embodiment in that a nozzle extension (61) is formed at the rear end of the nozzle body (21). A filter (25) is provided at the rear end of the main body (21). Specifically, the filter (25) attached to the rear end of the nozzle body (21) is formed in a substantially circular shape and attached so as to cover the opening surface of the rear end of the nozzle body (21).

    When the user turns the first cover (41b), the pressure stage (52) moves toward the partition plate (53) and compresses the container (11). The liquid in the container (11) flows into the nozzle body (21) through the rear end of the nozzle body (21). Here, since the filter (25) attached to the rear end of the nozzle body (21) captures bubbles contained in the liquid in the container (11), the bubbles do not enter the nozzle body (21). .

    According to the second embodiment, since the filter (25) is attached to the rear end of the nozzle body (21), before the bubbles contained in the container enter the nozzle body (21), the filter (25 ). For this reason, it can prevent reliably that a bubble penetrate | invades into the inside of a nozzle main body (21). Thereby, even if it presses a container (11), an air bubble does not clog the inside of a nozzle main body (21). As a result, the liquid can be reliably sprayed from the tip of the nozzle body (21). Other configurations, operations, and effects are the same as those of the first embodiment.

Embodiment 3 of the Invention
Next, Embodiment 3 of the present invention will be described with reference to the drawings.

    As shown in FIG. 9, this Embodiment 3 differs in the structure of the control means (60) in the said Embodiment 1. FIG. The regulating means (60) according to Embodiment 3 is a container that replaces the regulating means (60) according to Embodiment 1 with the nozzle extension (61) formed at the rear end of the nozzle body (21). The bubble storage part (63) is formed on the upper surface inside (11), and the upper surface in the container (11) is tapered to rise toward the bubble storage part (63). Specifically, the bubble storage part (63) is formed to bulge upward from the upper corner of the container (11) in which the container tip (11a) is formed. Here, the container front end (11a) is formed at the center of the upper surface in the container (11), which is below the bubble storage section (63), and the rear end of the nozzle body (21) It opens in the front-end | tip part (11a). That is, the bubbles contained in the liquid in the container (11) are collected in the bubble storage part (13) along the upper surface in the container (11).

According to the third embodiment, since the bubble storage part (63) is formed in the upper corner part above the center part of the upper surface in the container (11) where the rear end of the nozzle body (21) opens, the container ( 11) Bubbles inside can be collected in the bubble reservoir (13). Moreover, since the formation of the upper surface of the container (11) a tapered surface which rises toward the bubble reservoir (63), can induce bubble in the container (11) to the bubble reservoir (63). Thus, it is possible to reliably prevent bubbles from entering the nozzle body (21), and even if the container (11) is compressed, the bubbles are not clogged inside the nozzle body (21). As a result, the liquid can be reliably sprayed from the tip of the nozzle body (21). Other configurations, operations, and effects are the same as those of the first embodiment. In the third embodiment, instead of the tapered surface formed on the upper surface in the container (11), a guide groove for guiding bubbles to the bubble storage part (63) is formed on the inner surface of the container (11). You may do it.

<Other embodiments>
This invention is good also as following structures about the said Embodiment 1-3.

    About the said Embodiment 1-3, it is made to make the bubble diameter in a container (11) small by making the liquid with which a container (11) is filled contain the additive which increases the surface tension of a liquid. Good. In addition, by coating the inner wall surface of the container (11) with a material having a high affinity with the liquid filled in the container (11), it is possible to prevent bubbles from adhering to the inner wall surface of the container (11). It may be. Alternatively, an aqueous solution containing hyaluronic acid or an aqueous solution of theanine may be used as the liquid to be sprayed. In addition, an aqueous solution of an antioxidant such as catechin or proanthocyanidin may be used. In addition, a liquid containing a substance having a function of suppressing the growth of microorganisms or a function of killing microorganisms, or a liquid containing a substance that does not bromide by a chemical change due to neutralization of odor molecules in the air may be used. . Moreover, you may use the liquid containing various fragrance | flavor, a pest repellent, etc.

    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 measures for preventing bubbles from entering the nozzle.

It is a perspective view which shows the electrostatic spraying apparatus seen from the 1st cover side which concerns on this Embodiment 1. FIG. It is a perspective view which shows the electrostatic spraying apparatus seen from the 2nd cover side which concerns on this Embodiment 1. FIG. It is a front view which shows the electrostatic spraying apparatus which concerns on this Embodiment 1. FIG. It is a front view which shows the electrostatic spraying apparatus at the time of the stop (storage) concerning this Embodiment 1. FIG. It is a schematic longitudinal cross-sectional view which shows the electrostatic spraying apparatus which concerns on this Embodiment 1. It is a schematic longitudinal cross-sectional view which shows the electrostatic spraying apparatus which concerns on this Embodiment 1. It is a schematic sectional drawing which shows the spray cartridge and nozzle base which concern on this Embodiment 1. It is a perspective view which shows the control means concerning this Embodiment 2. It is a schematic longitudinal cross-sectional view which shows the electrostatic spraying apparatus which concerns on this Embodiment 3. It is a schematic sectional drawing which shows the conventional electrostatic spraying apparatus. It is a schematic diagram which shows the conventional electrostatic spraying apparatus. It is an expanded sectional view which shows the nozzle of the electrostatic spraying apparatus which concerns on FIG.

DESCRIPTION OF SYMBOLS 1 Electrostatic spray apparatus 11 Container 12 Conductive member 20 Nozzle 21 Nozzle main body 41 Housing 50 Pressurization mechanism 60 Control means 61 Nozzle extension part 62 Filter 63 Bubble storage part

Claims (7)

A housing (41), a container (11) housed in the housing (41) and filled with a liquid, and attached to the container (11), the tip opening to the outside of the container (11); A nozzle (20) whose end opens into the container (11), a pressurizing means (50) for compressing the container (11) and supplying liquid to the tip of the nozzle (20), and a predetermined voltage for the container (11) a voltage applying means (12) for applying to the liquid in,
An electrostatic spray device in which a liquid to which a predetermined voltage is applied by the voltage applying means (12) is sprayed in an atomized state from the tip of the nozzle (20),
An electrostatic spraying device comprising a regulating means (60) for regulating bubbles contained in the liquid in the container (11) from entering the nozzle (20). In claim 1,
The regulating means (60) extends the nozzle (20) so that the rear end of the nozzle (20) opens more inside the container (11) than the air bubbles accumulated on the inner wall of the container (11). An electrostatic spraying device comprising the formed nozzle extension (61). In claim 2,
The electrostatic spraying device, wherein the nozzle extension (61) is formed so as to protrude from the inner wall surface of the container (11) into which the nozzle (20) is inserted into the container (11). In claim 3,
The electrostatic spraying device, wherein the nozzle extension (61) extends so that a rear end of the nozzle (20) opens at a central portion inside the container (11). In claim 1,
The electrostatic spraying device characterized in that the regulating means (60) includes a filter (62) attached to a rear end of the nozzle (20). In claim 1,
The regulating means (60) is formed in the container (11),
An electrostatic spraying device comprising an air reservoir (63) in which bubbles in the container (11) accumulate above the rear end of the nozzle (20). In claim 6,
The container (11) is formed in a rectangular shape,
While the nozzle (20) is attached to the center of the upper surface of the container (11),
The air reservoir is formed at the upper corner of the container (11),
The electrostatic spraying device, wherein the inner upper surface of the container (11) is formed in a tapered surface rising toward the air reservoir (63).

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