JP2010279864A - Electrostatic sprayer - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an electrostatic sprayer including a nozzle, wherein spray performance is stabilized. <P>SOLUTION: The electrostatic sprayer includes a container in which a liquid is filled and the nozzle attached to the container and having a liquid passage, wherein the liquid is sprayed from the distal end of the nozzle by applying a prescribed voltage to the liquid in the container and pressurizing the inside of the container. The nozzle of the electrostatic sprayer is provided with a distal end member 21a in which an spray opening 24 is formed and which is constituted to be deformable so as to expand the spray opening outward, and an adjusting mechanism 60 for deforming the distal end member 21a so as to expand the spray opening 24 outward accompanying the decrease of the spray flow rate. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to an electrostatic spraying device for spraying liquid, and particularly relates to measures for preventing clogging of sprayed liquid.

  Conventionally, for example, in order to spray a liquid containing a substance useful for the human body into a room, a nozzle is provided at the tip of a container filled with the liquid, a voltage is applied to the liquid in the container, and the inside of the container is pressurized to apply the liquid. An electrostatic spraying device is known in which liquid is sprayed by an electric field formed at the tip of the nozzle and supplied to the tip of the nozzle (see, for example, Patent Document 1 below).

  By the way, when spraying a liquid using the above-mentioned electrostatic spraying apparatus using a fine needle-like nozzle, the particle diameter of the liquid is stabilized and the spraying property is improved. Therefore, an electrostatic spraying device using a thin needle-like nozzle has been used.

Japanese Patent Laid-Open No. 5-13881

  By the way, in the said electrostatic spraying apparatus, the solution, emulsion, suspension, etc. containing various chemical | medical agents etc. are used as the liquid to spray, and the viscosity changes with evaporation of a water | moisture content. In particular, since the spray liquid tends to dry near the spray port, the viscosity of the spray liquid tends to increase locally. Further, as the viscosity of the spray liquid increases, the surface tension also increases. Therefore, even during spraying, the viscosity locally increases near the spray port, the surface tension of the spray liquid may exceed the spray liquid transport capability, and high viscosity spray liquid may accumulate. As a result, there is a possibility that the spray port becomes constricted and the spray liquid is not sprayed normally.

  This invention is made | formed in view of this point, The objective is to stabilize the spraying property in an electrostatic spraying apparatus.

  The first invention includes a container (11) filled with a liquid and a nozzle (21) attached to the container (11) and having a liquid passage, and a predetermined voltage is applied to the liquid in the container (11). Is applied to the container (11) to spray the liquid from the tip of the nozzle (21), the nozzle (21) forming a spray port (24) A tip member (21a) configured to be deformable so that the spray port (24) is expanded outward, and the spray port (24) is expanded outward as the spray flow rate decreases. Spray nozzle adjusting means (60) for deforming the tip member (21a) is provided.

  In the first invention, when a predetermined voltage is applied to the liquid in the container (11) to compress the container (11), the charged liquid flows into the nozzle (21), and the nozzle (21) Blows out as a fine liquid from the tip.

  By the way, the viscosity of the spray liquid changes due to evaporation of moisture or the like. In particular, since the spray liquid tends to dry near the spray port (24), the viscosity of the spray liquid tends to increase locally. Further, as the viscosity of the spray liquid increases, the surface tension also increases. Therefore, even during spraying, the viscosity locally increases in the vicinity of the spray port (24), the surface tension of the spray liquid exceeds the ability to transport the spray liquid, and high-viscosity spray liquid may accumulate. . As a result, there is a possibility that the spray port (24) becomes narrowed and the spray liquid is not normally sprayed.

  However, in the first invention, when the spray flow rate of the spray liquid decreases, the tip member (21a) of the nozzle (21) is deformed by the spray port adjusting means (60) and the spray port (24) is expanded outward. The Therefore, even if a high-viscosity spray liquid accumulates in the vicinity of the spray port (24), the spray port (24) is expanded, so that the effective opening area does not decrease. Therefore, the spray liquid is normally sprayed from the nozzle.

  In a second aspect based on the first aspect, the tip member (21a) extends in the spraying direction and faces each other, the liquid passage is formed between the opposing surfaces, and the spray port (24) is formed at the tip. A pair of plate-like members (25) formed and configured to be displaceable so that the distance between the tips is variable is provided.

  In 2nd invention, if a pair of opposing plate-shaped member (25) is displaced so that the distance between the front-end | tips may increase, a spraying opening (24) will be expanded outside. Therefore, when high-viscosity spray liquid accumulates near the spray port (24) and the spray flow rate decreases, the effective opening of the spray port (24) is increased by increasing the distance between the tips of the pair of plate-like members (25). By suppressing the reduction of the area, the spray liquid is normally sprayed.

  According to a third aspect, in the second aspect, the tip member (21a) is a shielding plate (27) that covers both sides of the liquid passage formed between the opposing surfaces of the pair of plate-like members (25). It has.

  In the third invention, the side of the liquid passage formed between the opposing surfaces of the pair of plate-like members (25) is covered with the shielding plate (27). Therefore, the water in the spray liquid in the liquid passage hardly evaporates, and drying of the spray liquid is suppressed.

  According to a fourth aspect of the present invention, in any one of the first to third aspects, the spray port adjusting means (60) causes the tip member (21a) to close the spray port (24) when spraying is stopped. It is configured to be deformed.

  If the spray stop time becomes long, the water in the spray liquid near the spray port (24) evaporates and dries, and the spray liquid may solidify. However, in the fourth aspect of the invention, when spraying is stopped, the spray port (24) is closed by the spray port adjusting means (60), so that drying of the spray liquid in the vicinity of the spray port (24) is suppressed.

  According to the present invention, as the spray flow rate of the spray liquid decreases, the spray port adjusting means (60) deforms the tip member (21a) of the nozzle (21), thereby expanding the spray port (24) to the outside. The Therefore, even when a high-viscosity spray liquid accumulates in the vicinity of the spray port (24), the spray liquid can be normally sprayed without clogging. Accordingly, the spray properties can be constantly stabilized.

  Further, according to the second invention, the tip member (21a) that can be deformed so that the spray port (24) is expanded outward can be easily formed.

  According to the third invention, evaporation of moisture in the spray liquid in the liquid passage formed by the pair of plate-like members (25) can be suppressed. Therefore, by suppressing the drying of the spray liquid, it is possible to prevent clogging near the spray port (24) and to stabilize the spray properties.

  According to the fourth invention, drying of the spray liquid in the vicinity of the spray port (24) when spraying is stopped can be suppressed, and solidification of the spray liquid is prevented to prevent clogging of the spray port (24). be able to. Therefore, spraying can be normally performed when the operation is resumed.

FIG. 1 is a perspective view showing the configuration of the electrostatic spraying apparatus according to Embodiment 1 as viewed from the first cover side. FIG. 2 is a perspective view showing the configuration of the electrostatic spraying apparatus according to the first embodiment when viewed from the second cover side. FIG. 3 is a front view illustrating the configuration of the electrostatic spraying apparatus according to the first embodiment. FIG. 4 is a longitudinal sectional view showing the configuration of the electrostatic spraying apparatus according to the first embodiment. FIG. 5 is a perspective view illustrating a configuration of the pressurizing unit according to the first embodiment. FIG. 6 is a diagram illustrating a schematic configuration of an adjustment mechanism that adjusts the opening area of the nozzle tip member and the spray port according to the first embodiment. 7A and 7B are diagrams illustrating the operation of the tip member of the nozzle according to the first embodiment, in which FIG. 7A illustrates a state where the spray port is expanded, and FIG. 7B illustrates a state where the spray port is closed. FIG. 8A is a side view showing a tip member of a nozzle according to the second embodiment, and FIG. 8B is a cross-sectional view thereof. FIG. 9 is a diagram illustrating the operation of the tip member of the nozzle according to the second embodiment, where (A) shows a state where the spray port is expanded, and (B) shows a state where the spray port is closed.

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

Embodiment 1 of the Invention
As shown in FIGS. 1-5, the electrostatic spraying apparatus (1) of this embodiment is installed and used on a desktop etc. As shown in FIG. The electrostatic spraying device (1) includes a main body (40), a base cover (42), and a support (43).

  The main body (40) includes a housing (41), a spray cartridge (10) detachably attached to the housing (41), and a pressurizing means (8).

  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).

  The housing body (41a) is formed in a cylindrical shape. A support portion (43) for supporting the housing body (41a) is provided at a lower portion of the housing body (41a). On the other hand, a shroud portion (31) for protecting a nozzle (21) of a spray cartridge (10) described later is formed on the upper portion of the housing body (41a). As for this shroud part (31), a part of circumferential direction of the housing main body (41a) bulges outside. A recess (32) is formed at the center of the shroud portion (31) so as to cover the periphery of the nozzle (21).

  Further, LED lights (46) are attached to the outer peripheral surface of the housing body (41a) below the shroud portion (31) (two in FIG. 1). This LED light (46) is irradiated toward the liquid to be sprayed from the tip of the nozzle (21) of the spray cartridge (10), so that the user can confirm the spray state.

  The cover member (41b, 41c) includes a first cover (41b) and a second cover (41c) that form a pair.

  As shown in FIG. 1, the first cover (41b) is formed in a circular shape having substantially the same outer shape as one end face of the housing body (41a), and is attached so as to cover one end face 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 cutout spirally cut along the circumferential direction of the upper part is formed in the upper part of the winding, and the movement of the pressure stage (52) described later is restricted.

  On the other hand, as shown in FIG. 2, 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). ing. On the surface of the second cover (41c), a strip-shaped counter electrode (44) for the charged liquid is provided, while a volume knob (45) interlocking with the output adjustment volume (not shown) of the power supply unit is provided. It has been. By rotating the volume knob (45), the output voltage from the power supply unit is appropriately adjusted. In addition, the power supply part should just be comprised so that a voltage may be converted into the value of 0 kV or more and 12 kV or less.

  The pedestal cover (42) is formed in a bowl shape along the cylindrical side surface of the housing body (41a). The pedestal cover (42) is attached to the support portion (43) and used as a pedestal during use (see FIG. 1 and FIG. 2). The pedestal cover (42) is attached so as to cover the shroud portion (31) of the main body (40) when not in use (during storage) to protect the nozzle (21). In addition, this electrostatic spraying device (1) can adjust the height of the electrostatic spraying device (1) in two steps by using the base cover (42) after removing it from the support part (43). it can.

  The pressurizing means (8) 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 (21). As shown in FIG. 5, the pressurizing means (8) includes the first cover (41b), two constant load springs (51), a pressurizing stage (52), and a partition plate (53). ing.

  The pressurizing stage (52) has a bottomed cylindrical main body (52a) and two mainspring support portions (52b). The bottomed cylindrical main body (52a) is disposed such that the bottom faces the second cover (41c). On the other hand, the two mainspring support portions (52b) are formed at positions that are inverted by 180 ° about the axis of the main body portion (52a), and are parallel to the outer peripheral surface of the main body portion (52a) in the radial direction. And a pair of plate-like members (25) projecting from each other. The pair of plate members (25) are formed with notches that are rotatably engaged with both ends of the shaft (51a) of the two constant load springs (51).

  A convex portion (52c) that protrudes in the axial direction is formed on the inner surface of the end portion on the first cover (41b) side of the main body portion (52a) of the pressure stage (52). When the protrusion (52c) is engaged with a notch formed in the upper part of the first cover (41b) and the first cover (41b) is rotated in the circumferential direction of the housing body (41a), the protrusion The part (52c) is guided to the first cover (41b) side along the spiral cutout. Accordingly, the pressure stage (52) moves to the first cover (41b) side and 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). On the other hand, when the first cover (41b) is rotated in the reverse direction, the convex portion (52c) is guided to the second cover (41c) side along the spiral notch at the upper part of the winding, and the convex portion (52c) is eventually wound. Detach from the top. 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) includes a shaft (51a) and a belt-shaped metal plate (51b) wound around the shaft (51a) with a constant curvature. The constant load spring (51) generates a restoring force (load) when pulling out the metal plate (51b), and if the pulling amount (stroke) of the metal plate (51b) exceeds a predetermined length, the restoring force (Load) is configured to be constant regardless of the stroke. The shaft (51a) is rotatably engaged with the notch of the mainspring support portion (52b) of the pressure stage (52). On the other hand, the metal plate (51b) is partially pulled out to the second cover (41c) side, and its end (51c) is fixed to the housing body (41a).

  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). is set up. The partition plate (53) is attached to the housing body (41a).

  The elements other than the first cover (41b) of the pressurizing means (8) are arranged in order from the first cover (41b) to the second cover (41c) in the housing body (41a). 52) (the constant load spring (51) is engaged), the container (11) of the spray cartridge (10), and the partition plate (53) are arranged in this order.

  With the above configuration, in the pressurizing unit (8), the first cover (41b) is rotated in a predetermined direction to release the pressurization stage (52) held on the first cover (41b). Then, the pressure stage (52) moves while being pressed toward the second cover (41c) by the restoring force of the constant load spring (51). As a result, the container (11) of the spray cartridge (10) is pressed toward the second cover (41c) by the main body (52a) of the pressure stage (52), and is compressed between the partition plate (53). Pressure. On the other hand, when the first cover (41b) is rotated in the direction opposite to the predetermined direction, the pressure stage (52) is re-engaged with the first cover (41b) and moved to the first cover (41b) side. And held by the first cover (41b). Thereby, a pressurization stage (52) separates from a container (11), and pressurization is cancelled | released.

  The housing (41) is provided with a voltage switch (47), and the pressure stage (52) is provided with a pusher (49) for turning on and off the voltage switch (47). The pusher (49) contacts the voltage switch (47) when the first cover (41b) rotates relative to the housing body (41a) and the pressure stage (52) moves. It is like that. When the pressurizing means (8) is in the pressurizing operation, the pusher (49) continues to contact the voltage switch (47), and the voltage switch (47) is maintained in the ON state. Thereby, a high voltage is applied to the liquid in the container (11). When the pressurizing operation of the pressurizing means (8) is released, the pusher (49) is separated from the voltage switch (47) and the voltage switch (47) is turned off. Thereby, the voltage application to the liquid in the container (11) is released.

  Thus, in this embodiment, the pressurization operation to the container (11) and the on / off of the voltage switch (47) are performed simultaneously by rotating the first cover (41b).

  As shown in FIG. 4, the spray cartridge (10) includes a container (11), a conductive member (12), a nozzle portion (20), and a nozzle base (33). The container (11), the conductive member (12), the nozzle portion (20), and the nozzle base (33) are assembled together.

The container (11) is formed in a flat bag shape. Specifically, the container (11) is formed by overlapping two rectangular sheets made of a relatively soft material that does not allow liquid to permeate. These two sheets are bonded to each other on the four sides, and an opening (11a) is formed on one side on the short side so as to project outward. The container (11) is filled with a cosmetic liquid containing a moisturizing component and an antioxidant component (for example, a solution containing hyaluronic acid). The concentration of this liquid is adjusted so that the electric resistivity is 1.0 × 10 ⁴ Ωcm or more and 1.0 × 10 ⁷ Ωcm or less.

  The conductive member (12) is formed of a conductive resin, and constitutes a voltage applying means for applying a charge (applying a high voltage) to the liquid in the container (11). The conductive member (12) is inserted into the opening (11a) of the container (11), and is integrally formed with the insertion part (12a) that contacts the liquid in the container (11) and the outer end of the insertion part (12a). The flange (12b) is formed with a larger diameter than the mouth (11a) of the container (11). The conductive member (12) has a flange (12b) electrically connected to a power supply unit (not shown), and applies a high voltage to the liquid in the container (11) via the insertion unit (12a). It is configured.

  The nozzle part (20) includes a nozzle (21) and a nozzle holding part (22) for holding the nozzle (21). The nozzle (21) is inserted into the nozzle holding part (22) and held by the nozzle holding part (22).

  The nozzle (21) is formed of a metal material in the present embodiment. The nozzle (21) includes a tip member (21a) on the tip side of the nozzle holding portion (22), and a main body member (21b) inserted from the nozzle holding portion (22) to the conductive member (12). It has.

  As shown in FIG. 6, the tip member (21a) includes a pair of plate members (25) formed in a folded plate shape. The pair of plate-like members (25) are provided so as to face each other, and a liquid passage through which the spray liquid flows is formed between the facing surfaces. That is, the pair of plate-like members (25) are arranged with an interval such that a liquid passage is formed between the opposing surfaces using surface tension. The pair of plate-like members (25) are formed in a folded plate shape so that each of them extends in a direction away from each other from the base end side toward the tip end side, and then bends and extends in a direction approaching each other. . A spray port (24) is formed between the tips of the pair of plate-like members (25).

  Similar to the tip member (21a), the main body member (21b) is constituted by a pair of plate-like members facing each other, and the pair of plate-like members uses a surface tension to spray liquid between the opposed surfaces. The liquid passages that circulate are formed so as to be spaced apart from each other. The liquid passage in the tip member (21a) communicates with the liquid passage in the main body member (21b).

  A connecting member (26) is connected to each base end portion of the pair of plate-like members (25) so as not to be relatively rotatable. Each connecting member (26) is rotatably connected to one end of a pair of plate-like members constituting the main body member (21b). With such a configuration, the connecting member (26) rotatably supports the pair of plate members (25) constituting the tip member (21a) with respect to the main body member (21b). Further, the motor (63) is connected to the connecting member (26) and is driven to rotate by the motor (63). In FIG. 6, the motor (63) is connected to only one connecting member (26), not shown, but the motor (63) is also connected to the other connecting member (26).

  On the other hand, as shown in FIG. 4, the nozzle holding portion (22) is formed of a resin material, and has a cylindrical portion having a diameter larger than that of the nozzle (21) and three circles through which the nozzle (21) passes. And plate-like legs. The three leg portions are provided in parallel to both end portions and the central portion in the axial direction of the cylindrical portion, and are formed integrally with the cylindrical portion. That is, the nozzle holding part (22) supports the main body member (21b) of the nozzle (21) at three locations. The nozzle holding portion (22) is provided such that the inner end portion on the container (11) side engages with a recess formed on the outer end surface of the flange (12b) of the conductive member (12).

  In addition, a nozzle cap (23) is detachably attached to the nozzle portion (20) in order to suppress drying of the liquid in the nozzle (21) when not in use. The spray cartridge (10) is detachable in the housing (41) so that the tip member (21a) of the nozzle (21) faces obliquely upward and is exposed in the recess (32) of the shroud portion (31). Arranged.

  The said nozzle base (33) is being fixed to the container (11) and the electrically-conductive member (12), as shown in FIG. A mounting recess (36) in which the conductive member (12) is accommodated is formed at the inner end of the nozzle base (33). A nozzle recess (34) in which the tip member (21a) of the nozzle (21) is accommodated is provided at the outer end of the nozzle base (33). The tip member (21a) of the nozzle (21) is provided so as not to protrude from the nozzle recess (34). A through hole (35) communicating with the mounting recess (36) is formed at the bottom of the nozzle recess (34), and the nozzle holding part (22) of the nozzle part (20) is accommodated in the through hole (35). Yes.

  Moreover, the said nozzle base (33) comprises a part of shroud part (31) of a housing main body (41a), as shown in FIG.1 and FIG.2. That is, the nozzle recess (34) of the nozzle base (33) becomes a part of the recess (32) of the shroud portion (31). The nozzle base (33) is formed to extend in the circumferential direction of the shroud portion (31), and is fitted into the shroud portion (31). Extraction knobs (3a) are formed at both ends of the nozzle base (33).

  In the spray cartridge (10), when the container (11) is compressed by the pressurizing means (8), the liquid in the container (11) is supplied to the nozzle (21). On the other hand, when a high voltage is applied to the liquid in the container (11) via the conductive member (12), an electric field is formed at the tip of the nozzle (21) (tip of the tip member (21a)). Thereby, the liquid is continuously sprayed from the tip of the nozzle (21) in the form of a mist. The spray cartridge (10) is replaced when there is no more or less liquid in the container (11). When replacing the spray cartridge (10), the spray cartridge (10) including the nozzle base (33) is removed from the housing (41) by pulling the knob (3a) for removing the nozzle base (33). It is. Then, a new spray cartridge (10) including the nozzle base (33) is mounted.

  The electrostatic spraying device (1) is provided with an adjusting mechanism (60) for adjusting the opening area of the spraying port (24) according to the spraying flow rate of the spraying liquid sprayed from the nozzle (21). Yes. The adjusting mechanism (60) constitutes the spray port adjusting means according to the present invention.

  The adjustment mechanism (60) includes a flow rate detection means (61) for detecting the flow rate of the spray liquid sprayed from the spray port (24) of the nozzle (21), a control unit (62), and the control unit (62 ), And a motor (63) as drive means for deforming the tip member (21a) so as to increase or decrease the opening area of the spray port (24).

  In the present embodiment, the flow rate detection means (61) is constituted by an infrared sensor having a light emitter that emits scattered light and a light receiver that receives light emitted from the light emitter. The light emitter and the light receiver constituting the infrared sensor are provided in the vicinity of the spray port (24). The luminous body is provided at a position where it can irradiate scattered light toward the spray liquid in a yarn state immediately after being sprayed from the spray port (24), and the light receiving body is provided at a position where the light emitted from the luminous body can be received. It has been. The infrared sensor is configured to detect the thickness of the sprayed liquid immediately after spraying from the state of light received by the photoreceptor. The infrared sensor is connected to the control unit (62), and is configured to transmit detection data to the control unit (62).

  The control unit (62) is connected to the motor (63) and is configured to control the drive amount of the motor (63) based on the detection signal from the flow rate detection means (61). Specifically, the control unit (62) determines the presence / absence of the spray and the increase / decrease of the spray flow rate from the detection signal (the thickness of the spray liquid) from the flow rate detection means (61). When it is determined that spraying is being performed and the spray flow rate is decreasing, the motor (63) is rotated by a predetermined amount in a predetermined first direction, while when it is determined that spraying is not being performed, the motor (63) Is rotated in a second direction opposite to the first direction to a predetermined reference position. The predetermined reference position of the motor (63) means that the spray port (24) formed at the tip of the tip member (21a) is closed (the tips of the pair of plate members abut). Refers to the angular position of the motor (63).

  As described above, the motor (63) as the drive means is connected to the pair of plate-like members (25) constituting the tip member (21a) of the nozzle (21) according to the present invention via the connecting member (26). The tip member (21a) is deformed by being connected and rotationally driving the connecting member (26). Then, when the motor (63) is rotated by a predetermined amount in the first direction based on the command value from the control unit (62), the connecting member (26) so that the spray port (24) is expanded outward. Is driven to rotate (see arrow in FIG. 7A). On the other hand, when the motor (63) is rotated in the second direction to the predetermined reference position based on the command value from the control unit (62), the tips of the pair of plate-like members (25) come into contact with each other. The connecting member (26) is rotationally driven so that the spray port (24) is closed (see arrow in FIG. 7B).

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

  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) on the pressure stage (52) is released. When the restriction is released, a force directed toward the second cover (41c) by the restoring force of the constant load spring (51) acts on the pressure stage (52), and the pressure stage (52) is moved to the partition plate (53). ) The container (11) is pressed by the moved pressure stage (52) and partition plate (53). The liquid in the compressed container (11) flows into a liquid passage formed inside the nozzle (21). The liquid that has flowed into the liquid passage moves to the tip of the nozzle (21). Specifically, it flows between the opposed surfaces of the pair of plate-like members (25) constituting the tip member (21a) of the nozzle (21).

  On the other hand, when the first cover (41b) is turned to one side in the circumferential direction, the voltage switch (47) is turned on, and a high voltage is applied to the liquid in the container (11) from the power source via the conductive member (12). Applied. The liquid charged with the high voltage is polarized, and the liquid charged with + (plus) is collected in the vicinity of the gas-liquid interface at the tip of the tip member (21a) of the nozzle (21). In the tip member (21a), the gas-liquid interface is stretched by a potential difference with the counter electrode (44) to be conical (conical), and partly from the top of the conical gas-liquid interface. The water liquid is torn off 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 a front-end | tip member (21a) will be a magnitude | size of the range of about 50 micrometers-200 micrometers. The liquid splashed from the nozzle (21) reaches a distance of about 40 to 50 cm away from the tip member (21a). When the user installs the electrostatic spraying device (1) with the tip member (21a) of the nozzle (21) facing the face approximately 50 cm forward, the scattered droplets adhere to the user's face. When the user manually turns the first cover (41b) to the other side in the circumferential direction, the pressure stage (52) is regulated by the first cover (41b) and the voltage from the power supply unit stops. Spraying stops. Finally, the user attaches the nozzle cap (23) to the nozzle (21).

-Operation of nozzle tip member-
By the way, the viscosity of the spray liquid changes due to evaporation of moisture or the like. In particular, since the spray liquid tends to dry near the spray port (24), the viscosity of the spray liquid tends to increase locally. Further, as the viscosity of the spray liquid increases, the surface tension also increases. Therefore, even during spraying, the viscosity locally increases in the vicinity of the spray port (24), the surface tension of the spray liquid exceeds the ability to transport the spray liquid, and high-viscosity spray liquid may accumulate. . As a result, there is a possibility that the spray port (24) becomes narrowed and the spray liquid is not sprayed normally.

  However, in the electrostatic spray device (1) of the present embodiment, when the spray flow rate is reduced, the tip member (21a) of the nozzle (21) is deformed and the spray port (24) is expanded outward.

  Specifically, when the control unit (62) determines that the spray is performed and the spray flow rate is decreasing based on the detection signal from the infrared sensor that constitutes the flow rate detection means (61), the control unit (62) Drives the motor (63) by a predetermined amount in the first direction. Accordingly, the connecting member (26) is rotationally driven in a predetermined direction by the motor (63) (see the arrow in FIG. 7A). Specifically, each connecting member (26) that rotatably supports the pair of plate members (25) with respect to the main body member (21b) is rotated in different directions. More specifically, in FIG. 7A, the upper connecting member (26) is rotated counterclockwise, and the lower connecting member (26) is rotated clockwise. As a result, the tips of the pair of plate-like members (25) are separated from each other, and the spray port (24) is expanded outward (see FIG. 7A).

  As a result of this operation, the spray port (24) is expanded even if high-viscosity spray liquid accumulates in the vicinity of the spray port (24), so the effective opening area does not decrease, and the spray liquid from the nozzle (21) Is sprayed normally.

  On the other hand, when spraying is stopped, the tip member (21a) of the nozzle (21) is deformed and the spray port (24) is closed.

  Specifically, when the control unit (62) determines that the spraying is stopped based on the detection signal from the infrared sensor that constitutes the flow rate detection means (61), the control unit (62) Drive to the reference position in the second direction. Thereby, the connecting member (26) is rotationally driven in a predetermined direction by the motor (63) (see FIG. 7B). Specifically, each connecting member (26) that rotatably supports the pair of plate members (25) with respect to the main body member (21b) is rotated in different directions. More specifically, in FIG. 7B, the upper connecting member (26) is rotated clockwise, and the lower connecting member (26) is rotated counterclockwise. As a result, the tips of the pair of plate-like members (25) approach each other and eventually come into contact with each other to close the spray port (24) (see FIG. 7B). Thereby, drying of the spray liquid in the vicinity of the spray port (24) when spraying is stopped can be suppressed.

-Effect of Embodiment 1-
As described above, according to the first embodiment, when the spray flow rate of the spray liquid is decreased, the spray port (24) can be expanded outward by deforming the tip member (21a) of the nozzle (21). Therefore, even when a high-viscosity spray liquid accumulates in the vicinity of the spray port (24), the spray liquid can be normally sprayed without clogging. Accordingly, the spray properties can be constantly stabilized.

  In addition, according to the first embodiment, the tip member (21a) is constituted by the pair of plate-like members (25) configured to be displaceable so that the distance between the tips is variable, whereby the spray port ( The deformable tip member (21a) can be easily formed so that 24) is expanded outward.

  Further, according to the first embodiment, when the spraying is stopped, the pair of plate-like members (25) constituting the tip member (21a) is rotated to close the spraying port (24). Drying of the spray liquid near the spray port (24) can be suppressed. Therefore, solidification of the spray liquid in the vicinity of the spray port (24) can be prevented, and clogging of the spray port (24) can be prevented. Therefore, spraying can be normally performed when the operation is resumed.

<< Embodiment 2 of the Invention >>
The electrostatic spraying device (1) according to Embodiment 2 is obtained by changing the configuration of the nozzle (21) of Embodiment 1.

  Specifically, as shown in FIGS. 8A and 8B, the tip member (21a) of the nozzle (21) according to the second embodiment is a pair of plate-like members (25) similar to the first embodiment. And a shielding plate (27) that covers both sides of the liquid passage formed between the opposed surfaces of the pair of plate-like members (25). The shielding plate (27) is formed so as to be continuous with both side ends of the pair of plate-like members (25), and is bent so as to extend toward the opposing plate-like members (25). And the space | interval of the two shielding plates (27) continuing to the plate member (25) on one side is slightly smaller than the space between the two shielding plates (27) continuing to the plate member (25) on the other side. The shield plate (27) on one side and the shield plate (27) on the other side are arranged so as to partially overlap each other.

  Even when such a tip member (21a) is used, when the spray flow rate is reduced, the connecting member (26) is rotationally driven by the motor (63) as in the first embodiment, and the pair of plate-like members (25) By rotating both plate-like members (25) so that the tips of the two are separated from each other, the spray port (24) is expanded outward (see FIG. 9A). As a result, even if high-viscosity spray liquid accumulates in the vicinity of the spray port (24), the spray port (24) is expanded, so the effective opening area does not decrease, and the spray liquid from the nozzle (21) is normal. Sprayed.

  On the other hand, when the spraying is stopped, as in the first embodiment, the connecting member (26) is driven to rotate by the motor (63), so that the tip ends of the pair of plate-like members (25) abut on each other The spray port (24) is closed by rotating the member (25) (see FIG. 9B). Thereby, drying of the spray liquid in the vicinity of the spray port (24) when spraying is stopped can be suppressed.

  As described above, according to the second embodiment, the same effect as that of the first embodiment can be obtained.

  Further, according to the second embodiment, the side of the liquid passage formed between the opposing surfaces of the pair of plate-like members (25) is covered with the shielding plate (27), and thus formed by the tip member (21a). It becomes difficult for the water in the spray liquid in the liquid passage to evaporate to evaporate, and drying of the spray liquid can be suppressed. Therefore, it is possible to stabilize the spray properties by preventing clogging of the spray port (24).

<< Other Embodiments >>
In each of the above embodiments, the tip member (21a) of the nozzle (21) is constituted by a pair of plate-like members (25) or a pair of plate-like members (25) and a shielding plate (27). The configuration of the tip member (21a) according to the invention is not limited to this. The tip member (21a) according to the present invention may be in any form and member as long as it can be deformed so that the spray port (24) is expanded outward. For example, you may be comprised by the some plate-shaped member.

  Further, the operation of the constituent member when the tip member (21a) is deformed is not limited to that of each of the above embodiments. For example, only one of the pair of plate-like members may rotate, or only one of them may move in parallel. Further, even if the plate-like member constituting the tip member (21a) is formed by a piezoelectric element connected to a power source, and the spray port (24) is configured to be deformable so that it is expanded outward by the voltage of the power source. Good. The tip member (21a) may be configured to be deformable so that the spray port (24) is expanded using a cylindrical piezoelectric element instead of the plate-like member.

  Furthermore, in each said embodiment, the motor (63) was used as a drive means which deform | transforms a front-end | tip member (21a) so that the opening area of a spray nozzle (24) may be increased / decreased based on the instruction | command of a control part (62). However, the spray port adjusting means according to the present invention may be provided with driving means other than the motor (63) to deform the tip member (21a).

  In each of the above embodiments, the infrared sensor is used as the flow rate detection means (61). However, the flow rate detection means (61) is not limited to this and may be any type. The flow rate detecting means (61) may directly detect the flow rate instead of the thickness of the spray liquid.

  Further, in each of the above embodiments, the spray stop state is detected by the infrared sensor that constitutes the flow rate detection means (61), but may be detected by detecting the output voltage of the power supply unit.

  Moreover, in each said embodiment, although the main body member (21b) of the nozzle (21) was formed of a pair of plate-shaped member, what kind of shape may be sufficient and it may be formed in the thin tube shape.

  Further, in each of the above embodiments, the nozzle (21) is formed of a metal material, but the material is not limited to this, and may be formed of a resin or the like.

  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 an electrostatic spraying device including a nozzle for spraying a liquid.

1 Electrostatic spraying device
11 containers
21 nozzles
21a Tip member
24 Spraying mouth
25 Plate member
26 Connecting member
27 Shield plate
60 Adjustment mechanism (spray port adjustment means)
61 Flow rate detection means
62 Control unit
63 motor

Claims (4)

A container (11) filled with a liquid; and a nozzle (21) attached to the container (11) and having a liquid passage, for applying a predetermined voltage to the liquid in the container (11) and the container (11) An electrostatic spraying device that pressurizes the interior and sprays liquid from the tip of the nozzle (21),
The nozzle (21) includes a tip member (21a) configured to be deformable so as to form a spray port (24) and expand the spray port (24) to the outside,
An electrostatic spray device comprising spray port adjusting means (60) for deforming the tip member (21a) so that the spray port (24) expands outward as the spray flow rate decreases. . In claim 1,
The tip member (21a) extends in the spray direction and faces each other, the liquid passage is formed between the facing surfaces, the spray port (24) is formed at the tip, and the distance between the tips is variable. An electrostatic spraying device comprising a pair of plate-like members (25) configured to be displaceable. In claim 2,
The tip member (21a) includes a shielding plate (27) that covers both sides of the liquid passage formed between the opposed surfaces of the pair of plate-like members (25). apparatus. In any one of Claims 1 thru | or 3,
The spraying device, wherein the spraying port adjusting means (60) is configured to deform the tip member (21a) so as to close the spraying port (24) when spraying is stopped.

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