The present invention relates to an electrostatic device for personal use, and more particularly to a device for spraying a liquid composition by means of an electrostatic force.
WO 03/072263 discloses an electrostatic spraying device having a removable cartridge with a reservoir containing a volume of a liquid composition. The device includes a plunger pump that displaces the liquid out of the reservoir and a nozzle for dispensing the liquid. The nozzle is provided with an emitter electrode which applies a high voltage to the composition being supplied from the reservoir to the nozzle, i.e., electrostatically charge the particles of the liquid composition for spraying the composition by the electrostatic force. In that the liquid composition within the reservoir may be deteriorated upon seeing an electrical current therein, the device is so designed to keep fresh or avoid deterioration of the liquid composition remaining in the reservoir. For this purpose, a field electrode or shield is introduced to surround the reservoir so as to give the same electrical potential to the liquid composition advanced around the nozzle and the composition remaining in the reservoir, and therefore minimizing an undesired current flowing between these zones. Although this scheme of providing the field electrode around the reservoir is suitable for keeping the liquid composition intact, the field electrode itself adds a certain bulk and complexity to the removable cartridge. Consequently, when the cartridge is desired to be sufficiently compact to be easily carried with a person, the cartridge is realized only at an expense of reducing a liquid holding capacity of the reservoir. Thus, there remains a need for making the cartridge as compact as possible, while enabling the cartridge or reservoir to hold a sufficient amount of the liquid composition without causing deterioration during use.
None of the existing art provides all of the advantages and benefits of the present invention.
The present invention is directed to an improved electrostatic spraying device which is capable of giving an increased liquid containing volume to a removable cartridge, yet keeping the cartridge as compact as possible for enhanced handling performance. The device in accordance with the present invention is configured to electrostatically charge and dispense the liquid composition from a supply to a point of dispense, and includes an actuator, a high voltage generator to provide a high voltage, a power source to activate the actuator and the high voltage generator, a reservoir to contain the supply of the liquid composition, and a dispensing unit. The dispensing unit is provided to spray the liquid composition, and includes a supplying means for supplying the liquid composition from the reservoir, which is mechanically connected to the actuator to be driven thereby. An emitter electrode is included in the dispensing unit to be electrically connected to the high voltage generator in order to electrostatically charge the liquid composition. Also included in the dispensing unit is a nozzle that is disposed at the point of dispense for spraying the liquid composition. The device further includes a field electrode connected to the high voltage generator so that the entire liquid composition is given more or less a common electric potential. The reservoir is configured to provide a removable cartridge. One characterizing feature of the present invention resides in that the reservoir is at least partially made of deformable material such that the reservoir is capable of receiving pressure to deform and thus supply the liquid composition out of the reservoir. Thus, the reservoir can be designed into a simple and compact structure, thereby providing an increased liquid containing volume in relation to the bulk of the removable cartridge. The supplying means for supplying the liquid composition from the reservoir may provide positive pressure from outside the reservoir, or negative pressure within the reservoir. Means for providing positive pressure include, for example, pads for compressing the reservoir. Means for providing negative pressure include, for example, suction pumps provided in upstream relation with the reservoir. The field electrode may be provided within the material for making the reservoir, the pads for compressing the reservoir, or in the main body of the device surrounding the reservoir.
In one preferred embodiment, the supplying means is a suction pump having a drive element which is driven by the actuator to suck up the liquid composition from the reservoir to force it out of said nozzle.
In another preferred embodiment, the device includes a housing that carries the actuator, the high voltage generator, and the power source. The housing has a concavity for detachably receiving the reservoir. Preferably, the housing incorporates a motor which drives the actuator for operating the pump, and also incorporates a frame which mounts the motor as well as the high voltage generator. The frame divides an interior space of the housing into a front compartment and a rear compartment. The front compartment accommodates the motor as well as the high voltage generator, while the rear compartment defines the concavity for receiving the reservoir. The housing includes a front shell and a rear shell. The front shell is fitted over the frame to define therebetween the front compartment. Likewise, the rear shell is fitted over the frame to define therebetween the rear compartment. Preferably, the reservoir is coupled to the dispensing unit and is cooperative therewith to define the cartridge. A positioning means is provided on the side of the housing to detachably engage the cartridge with the housing when the reservoir is placed into the concavity. When the cartridge is attached to the housing, the actuator is detachably engaged with a mechanism to activate the pump, and the emitter electrode is detachably in contact with a voltage terminal to receive the high voltage for electrostatical spraying the liquid composition. The positioning means may be realized by a mount formed at the upper end of the housing.
Preferably, the voltage terminal is located below an opening which is formed in the mount to permit the lower end of the emitter electrode to project through the opening for contact with the voltage terminal only when the dispensing unit rests on the mount. In other words, the voltage terminal bearing the high voltage can be kept away from an accidental contact with a human body for safety purpose.
Preferably, the suction pump is located on the side of the nozzle and outwardly of the reservoir or the concavity, enabling the reservoir to occupy the full space of the concavity with the attendant share of increased liquid containing volume.
A motor may be incorporated in the housing to drive the actuator for operating the pump, and is supported by the frame. The frame is configured to divide the interior space of the housing into a front compartment and a rear compartment. The front compartment is provided to accommodate therein the motor as well as the high voltage generator, while the rear compartment defines the concavity for receiving the reservoir. With this arrangement, the concavity receiving the reservoir can be formed on one side of the housing free from the motor and the high voltage generator both of which are inherently bulky, and can be therefore designed into an optimum configuration in match with the capacity of the reservoir, which in turn enables to design the device combining aesthetic and functional appeal.
Considering that the high voltage generator includes a transformer which is inherently bulky and occupies much space, the device is advantageously designed to make the housing compact by arranging the transformer in stack with the motor within the front compartment. Further, a battery also relatively bulky may be accommodated within the front compartment for energizing the motor. Also for making the housing compact, the battery is arranged in a side-by-side relation with the motor in a direction perpendicular to a vertical axis of the housing and arranged in stack with the transformer along the vertical axis.
While the specification concludes with claims particularly pointing out and distinctly claiming the invention, it is believed that the present invention will be better understood from the following description of preferred, nonlimiting embodiments and representations taken in conjunction with the accompanying drawings in which:
FIGS. 6 to 8 are respectively exploded perspective views of a removable cartridge utilized in the above device;
Now referring to FIGS. 1 to 7, there is shown an electrostatic spraying device in accordance with a preferred embodiment of the present invention. The device is configured into a self-contained portable structure that is compact enough to be easily carried with. The device is basically composed of a main body housing 10 and a removable cartridge 200 containing a volume of a liquid composition to be electrostatically sprayed according to a mechanism already disclosed in WO 01/12336, WO 01/12335, US 2001-0020653A, US 2001-0038047A, US 2001-0020652A, US 2001-0023902A, and WO 03/072263, incorporated herein by reference. The liquid composition utilized in the device include those disclosed in WO 03/072263, also incorporated herein by reference, i.e., an emulsion having conductive and insulating phases, although not limited thereto.
The housing 10 is dimensioned to be grasped by a user's hand and incorporates an electric motor 30, a high voltage generator 40, and a battery 50, i.e., a power source for activating the motor and the high voltage generator 40. The motor 30 actuates a dispensing unit 220 provided on the side of the cartridge 200 to dispense the liquid composition, while the high voltage generator 40 applies a high voltage of 1000 volts or more to the liquid composition being dispensed for electrically spraying the liquid composition on a user's. The housing 10 is formed with a concavity 12 for receiving a reservoir 210 of the cartridge 200 containing the liquid composition. In a preferred embodiment, an inner cover 20 is detachably fitted over the upper end of the housing 10 to hold therebetween the dispensing unit 220 of the cartridge 200. In another preferred embodiment, an outer cover 26 is detachably fitted over the inner cover 20 to conceal therebehind the dispensing unit 220 for protection thereof when the device is not in use.
The cartridge 200 is preferably composed of the reservoir 210 and the dispensing unit 220. The reservoir 210 may be suitably made of a plastic material which is deformable according to the contents of the liquid composition. The reservoir 210 may be made by the same resilient material, or combination of a rigid material and resilient material. An example of commercially available material suitable for providing the reservoir is the laminated film of VM-PET (Vacuum Metalised Polyethylene Terephthalate) having a thickness of 12 microns and LLDPE (Linear Low Density Polyethylene) having a thickness of 60 microns. Commercially available films are GLAE by Toppan for VM-PET, and FCS by Tocello for LLDPE. The reservoir may also be made of conductive material and being electrically connected to the high voltage generator so that the liquid composition therein is provided with more or less a common electric potential.
As best shown in FIGS. 6 to 9, in a preferred embodiment the dispensing unit 220 includes a pump 230 and a nozzle 240 which are integrated into a single structure. The pump 230 is a gear pump having a flat base 231 molded from a plastic material and formed with a plug 232 for detachable insertion into a fitment 212 secured to a mouth of the reservoir 210. The pump 230 includes a metal plate 270 mounted in the base 231 of the molded plastic. The metal plate 270 is formed in its upper surface with a pump chamber receiving a pair of intermeshing gears 234, an inflow channel 236 extending from within the plug 232 to the chamber, and an outflow channel 237 extending from the chamber to the nozzle 240. The pump chamber as well as the channels 236 and 237 are sealed by an emitter electrode 250 secured between the base 231 and the nozzle 240. The gears 234 are arranged to have their individual rotation axes extending perpendicular to the plane of the base 231, realizing a flat pump structure sufficient to be capable of being disposed between the reservoir 210 and the nozzle 240 only at a minimum extra dimension with respect to the height or length of the dispensing unit 220. One of the gears 234 is coupled to a joint 238 projecting on the lower face of the base 231 for detachable driving connection with the motor 30 disposed within the housing 10. As the gears are driven to rotate, the liquid composition is sucked up from the reservoir 210 through the inflow channel 236 and expelled through the outflow channel 237 to the nozzle 240. Preferably, the nozzle 240 is molded from a compatible plastic material as the base 231 to have an internal nozzle pathway 242 extending from the bottom center to an apex 243, as best shown in
The emitter electrode 250 is disposed between the base 231 of the pump 230 and the bottom 241 of the nozzle 240 in order to apply the high voltage to and charge the liquid composition being dispensed through the nozzle 240. In a preferred embodiment, the emitter electrode 250, which is connected to receive the high voltage from the high voltage generator 40 in the housing 10, includes a center antenna 251 and a coaxial cylinder 252. The center antenna 251 extends into the nozzle pathway 242 to charge the liquid composition being dispensed in cooperation with the cylinder 252 that is provided to surround the nozzle pathway 242 to avoid the undesired corona discharging for suitable electrostatic spraying. The top end of the center antenna 251 is receded from the apex 243 of the nozzle 240 to give a sufficient insulation distance therebetween.
As best shown in FIGS. 13 to 16, the metal plate 270 is formed integrally with a pin 254 which projects through the base 231 for detachable electrical connection with a voltage terminal 176 provided on the side of the housing 10 to relay the high voltage to the emitter electrode 250. Turning back to
As shown in
The rear compartment 150 may be accommodated with a field electrode which surrounds the reservoir 210 to give the same electrical potential to the liquid composition within the reservoir 210 and to the liquid composition within the dispensing unit 220 for keeping the entire liquid composition free from seeing the electric current which may deteriorate the liquid composition. Such deterioration is particularly seen in emulsion compositions and compositions having particles dispersed therein.
As best shown in
It is noted in this connection that the metal plate 270 and the 250 of the dispensing unit 220 are electrically connected to the field electrode 170 and therefore act as additional field electrode covering the pump. Also, the metal plate 270 is formed with a metal tube 271 which is inserted into the plug 232 to charge the liquid composition within the plug, and therefore acts also as a further field electrode. Thus, the liquid composition is electrically charged along the entire path from the reservoir 210 to the nozzle 240. Instead of using the metal tube 271, it is equally possible to provide an extension which extends from at least one of the plates 171 and 172 and projects outwardly from the concavity to cover the plug 232 and the adjacent part of the dispensing unit.
In a preferred embodiment, when the outer cover 26 is fitted over the housing 10, as shown in
With reference to FIGS. 27 to 29, the cartridge 200 is again explained in details with respect to geometrical configuration of the reservoir 210. One preferred embodiment of the reservoir as shown as 210 is made from a deformable plastic material into a flat bag which has a planar configuration of a segment of an approximate circle and has a mouth to which the fitment 212 is attached. The fitment 212 is molded from a plastic material to have a socket 214 for removably receiving the plug 232 of the dispensing unit 220. In detail, the reservoir 210 is shaped into the segment of circle defined between a chord and a circumference of an approximate circle greater than a circumference of a semicircle. The mouth or the fitment 212 is located at a center of the chord such that the distance from the mouth to any point of the circumference of the circle can be made approximately the same, providing smooth sucking up of the liquid composition from the reservoir and deforming according to the amount of liquid composition left in the reservoir, such that residue left in the end can be kept to a minimum.
Referring to
In a preferred embodiment, the device also includes a selector 70 for selecting one of three modes, i.e., a lock mode for disabling the operation, a spraying mode for enabling the liquid composition to be electrostatically sprayed, and a dripping mode for enabling the liquid composition to be dispensed out of the nozzle without being electrostatically charged. The selector 70 includes a handle 71 which is rotatable around the ring 127 for selecting one of three positions, i.e., a lock position, a spraying position, and a dripping position, as shown in
The above operation will be explained also with reference to
All documents cited in the detailed description of the Invention are, in relevant part, incorporated herein by reference; the citation of any document is not to be construed as an admission that it is prior art with respect to the present invention.
While particular embodiments of the present invention have been illustrated and described, it would be obvious to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the invention. It is therefore intended to cover in the appended claims all such changes and modifications that are within the scope of this invention.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP04/01359 | 2/9/2004 | WO | 8/8/2006 |