Airstream Propelled Spray Atomizer Apparatus and Method of Fluid Atomization by Codirectional Airstream Propulsion

Abstract

An airstream propelled spray atomizer apparatus and method of fluid atomization by codirectional airstream propulsion enables controllable atomization of a second fluid into a first fluid for use in surface treatment and cleaning. A user is able to alter the amount of atomization of the second fluid, from a spray to a mist, during spray operations without having to stop and change nozzles. Further, effectuating atomization via in-stream introduction rather than via structural impediments disposed interior to the nozzle prolongs nozzle life over extended operations.

Claims

1. An airstream propelled spray atomizer apparatus comprising: a nozzle having an elongate barrel operatively coupled in fluid communication with a compressor, said barrel having an aperture; a catheter disposed coaxially interior to the barrel; a terminus disposed endwise upon the catheter; wherein a first fluid pressurized within the compressor is selectively introducible into the barrel for ejection out of the aperture and a second fluid, disposed in fluid communication with the catheter, is selectively introducible at the terminus into the barrel whereby the second fluid is atomized by introduction into the first fluid when said first fluid is forced through the barrel.

2. The airstream propelled spray atomizer apparatus of claim 1 wherein the barrel includes a first section and a second section, said first section having an inner diameter wider than an inner diameter of the second section whereby the first fluid is accelerated by movement into the second section.

3. The airstream propelled spray atomizer apparatus of claim 2 wherein the catheter is disposed coaxially within the barrel.

4. The airstream propelled spray atomizer apparatus of claim 3 wherein the terminus is disposed in the second section of the barrel spaced back from the aperture such that the second fluid is introduced into a mixing zone interior to the barrel previous to ejection out the aperture.

5. The airstream propelled spray atomizer apparatus of claim 4 further comprising: an airflow circuit routing the first fluid from the compressor, said airflow circuit mediated by action of a spray air valve; a fluid circuit routing the second fluid from a reservoir connectable to the fluid circuit, said fluid circuit mediated by action of a fluid drawback valve; a control circuit branching a control signal off of the airflow circuit when an air trigger valve is opened, said control circuit routing the control signal to pressurize the spray air valve and the fluid drawback valve; an airstream circuit openable by action of the spray air valve, said airstream circuit in open communication with the barrel member; a trigger member operatively communicating with the air trigger valve wherein depression of the trigger member instantiates the control signal to pressurize the fluid drawback valve and the spray air valve; and a fluid metering valve disposed in operational communication with the fluid circuit downstream from the fluid drawback valve wherein the volume of the second fluid introduced through the catheter is regulable; wherein depression of the trigger member initiates atomization of the second fluid into the first fluid and the fluid metering valve enables control of the volume of the second fluid atomized and whereby release of the trigger member closes the trigger valve.

6. An airstream propelled spray atomizer apparatus comprising: a handheld nozzle having; an elongate barrel having an aperture; a catheter disposed interior to the barrel; a terminus disposed endwise upon the catheter; a handle member; a trigger member disposed in operational communication with an air trigger valve whereby depression of the trigger member opens the air trigger valve and restoration of the trigger member closes the air trigger valve; a fluid supply line disposed in operational communication with a fluid drawback valve and a fluid metering valve, said fluid supply line operatively couplable with a reservoir; an airflow supply line disposed in operational communication with a spray air valve, said airflow supply line operatively couplable with a compressor; an airstream supply line operatively coupling the barrel to the airflow supply line downstream of the spray air valve; and a control signal line branched off of the airflow supply line to route a control signal to pressurize and open the fluid drawback valve and the spray air valve, said control signal line operationally coupled with the air trigger valve; wherein a first fluid is forcible from the compressor as an airstream into the barrel and out the aperture and a second fluid is introducible into the airstream for atomization therein.

7. The airstream propelled spray atomizer apparatus of claim 6 further comprising a fluid metering valve disposed in communication with the fluid supply line wherein the volume of the second fluid introduced into the airstream is regulable.

8. The airstream propelled spray atomized apparatus of claim 7 wherein the catheter is disposed coaxially interior to the barrel such that the terminus is disposed interior to the second section spaced back from the aperture.

9. The airstream propelled spray atomizer apparatus of claim 8 wherein the barrel further comprises a first section and a second section, wherein the first section has an inner diameter wider than the inner diameter of the second section whereby the airstream is accelerated into the second section.

10. A method of atomizing a fluid by codirectional airstream propulsion comprising the steps of: accelerating a first fluid along an elongate barrel towards an aperture; and introducing a second fluid into the accelerated first fluid from a terminus coaxially disposed interior to the barrel, said terminus spaced back from the aperture to define a mixing zone; wherein the second fluid is atomized by introduction into the first fluid for ejection from the aperture as an atomized mist.

11. The method of claim 10 wherein the amount of atomization of the second fluid is controllable by the speed the first fluid is moved through the barrel whereby the second fluid is not atomized at a minimal speed and the second fluid is maximally atomized at a maximum speed.

12. The method of 10 wherein the first fluid is accelerated down the barrel by controlled release from a compressor coupled in operative communication with the barrel.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

Figures

[0018] FIG. 1 is a side elevation view of an example embodiment.

[0019] FIG. 2 is a diagrammatic longitudinal cross-section of the barrel of the example embodiment illustrated in FIG. 1.

[0020] FIG. 3 is a flow diagram view of an example embodiment of the present apparatus and method set forth herein.

[0021] FIG. 4 is a side elevation view of an example embodiment of a fluid supply line and an airflow supply line disposed connected to a control panel, which control panel is mounted on a voluble frame (here, a dolly) for mobility.

[0022] FIG. 5 is a side elevation view of the example embodiment pictured in FIG. 4, showing the handheld nozzle attached to the control panel by means of the fluid supply line, airflow supply line, airstream supply line, and control signal line.

[0023] FIG. 6 is a detail view of the example embodiment pictured in FIG. 5, showing a close up view of fluid supply line, airflow supply line, airstream supply line, and control signal line.

[0024] FIG. 7 is a side elevation view of the example embodiment of the handheld nozzle illustrated in FIG. 4.

[0025] FIG. 8 is a side elevation view of the other side of the example embodiment of the handheld nozzle illustrated in FIG. 7.

DETAILED DESCRIPTION OF THE DRAWINGS

[0026] Discussing now the accompanying figures illustrating example embodiments of the instant airstream propelled spray atomizer apparatus and method of atomizing a fluid by codirectional airstream propulsion. FIG. 1 illustrates a side elevation view of a handheld nozzle 100 with central section 60 cut away to reveal interior components and connections. The handheld nozzle 100 includes a handle member 50, a central section 60, and a barrel 70. The central section 60 includes a rear side 62 and a front side 64. On the front side 64 for manual engagement by a user grasping the handle member 60 is a trigger member 66, depressible to relay an airflow and generate a control signal pressure upon a fluid drawback valve 18, to open a fluid circuit 300 to the fluid supply line 110, and simultaneously pressurize a spray air valve 26 to open the airflow circuit 200 to the airstream supply line 112. Thus, manual depression of the trigger member 66 opens the fluid circuit 300 while simultaneously instantiating the airflow circuit 200 to produce the airstream ejected from the nozzle point 150.

[0027] Release of the trigger member 66 therefore ceases airflow in the control circuit 500 and thereby simultaneously depressurizes the fluid drawback valve 18 to prevent throughflow of fluid into the fluid supply line 110 and depressurizes a spray air valve 26 to prevent airflow into the airstream supply line 112. The trigger member 66 thereby serves as a deadman control requiring active engagement for spray operations to be maintained.

[0028] As shown in FIG. 1, in cutaway section and shown fed through the handle member 50, airflow is routed to barrel 70 via airflow supply line 114 from an associated air compressor or other compressed air supply 10 which us connected in fluid communication with airflow supply line 114. Airflow into the airstream circuit 400 requires depression of trigger member 66 to route airflow into airstream supply line 112 which routes airflow into the barrel 70 for forcible direction interior to the barrel through the space surrounding interior catheter 80 (see also FIG. 2). In at least one example embodiment contemplated as part of this disclosure, pressure is further reduced by the narrowing of barrel 70 from first section 72 to second section 74, and airflow is ejected as airstream out nozzle point 150 (see for example FIG. 2).

[0029] Control signal line 116 routes a branched airflow to pressurize the fluid drawback valve 18 and actuate delivery of fluid through into fluid supply line 110. Fluid supply line routes fluid to fluid metering valve 30 for manual control, whereby the volume of fluid introduced through catheter 80 is regulable by a user, even during active spray operations. Fluid metering valve 30, disposed on the rear side of the central section, thus enables controllable introduction of fluid, from the fluid reservoir 14, into the airstream via catheter 80 (see for example FIG. 2). Mixing of the fluid into the airstream in mixing chamber 152 between terminus 82 of catheter 80 and nozzle point 150 atomizes the fluid to eject an atomized spray. See for example FIG. 2.

[0030] The atomized spray is controllable, between a minimum atomization (that is, essentially a stream of liquid fluid emitted from the nozzle when airflow is reduced to zero) and a maximum atomization (that is, generation of a mist of fine droplets in a maximized pressure differential between the fluid introduced into the airstream relative an airflow pressure interior to the barrel).

[0031] Control of the airflow may be adjustable to regulate airflow and the resulting airstream between the minimum and maximum airstreams. In some embodiments, airflow (or, in other embodiments, a first fluid flow) may be regulated by control of air pressure (or first fluid pressure), at the source itself or by action of additional metering valves (not shown). Further, in some embodiments, control of the fluid (or, as case may be, second fluid) may likewise be effectuated by control of the fluid pump 20, which is contemplated in some embodiments to be operable at a range of settings to induce a corresponding range of fluid pressures introducible into the fluid circuit 300.

[0032] FIG. 2. illustrates a longitudinal cross section of an example embodiment of the nozzle barrel 70, shown in diagrammatic form. Airflow is forced at pressure into first section 72 of barrel 70 through airstream supply line 112. Under pressure, airflow is forced through second section 74 of barrel 70, where pressure is further reduced. Airflow is directed along the barrel 70 around catheter 80, which is disposed along a central, longitudinal axis down the barrel 70 length, coaxially disposed interior to the barrel 70. Fluid is introducible into the catheter 80 through fluid supply line 110, for dispersal at terminus 82, which terminus 82 is set back a predetermined distance from barrel 70 aperture 154 at nozzle point 150. The distance between the terminus 82 and the aperture 154 represents a mixing zone 156 wherein the fluid introduced into the airstream is atomized and forcibly ejected in the airstream.

[0033] In the pressure differential extant between the airstream and fluid introduced into the mixing zone, RT instability may serve to atomize the fluid into fine droplets for conveyance as an ejected, directable mist. Control of airflow pressure interior to barrel 70 may control the atomization or aspiration of fluid ejected therefrom. Thus, a minimum pressure sustained interior to barrel 70 may result in a stream of liquid, as water from a hose, whereas a maximum pressure may eject a finely articulated spray of mist consisting of atomized water droplets of a minimized size and ejected as a cloud at force. A range of fluid applications is thereby enabled, and operable continuously during spray operations, from a directable mist or cloud to a directed jet of fluid, without a user having to cease spray operations and interchange a nozzle, element, or other structural feature of the apparatus.

[0034] FIG. 3 illustrates a diagrammatic view of an example embodiment of the method of atomizing a fluid by codirectional airstream propulsion. A compressed air supply 10 provides a pressurized airflow into airflow via compressed air regulator 12 to circuit 200 for ejection of the airstream and for instantiating a control signal for means of operating a fluid circuit 300 and airstream circuit 400. An associated fluid pump 20, disposed in operational communication with a fluid reservoir 14, pumps fluid into the fluid circuit 300 (via priming valve 16) for ejection into the airstream produced at the nozzle 100. Fluid, however, is prevented from accessing the fluid supply line 110 by action of fluid drawback valve 18, which remains closed until pressurized by means of the control signal branched into control circuit 500 from the airflow circuit 200.

[0035] Activation of the compressed air supply 10 therefore instantiates the control signal, controllable by depression of trigger member 66 to effectuate opening of trigger air valve 28. When trigger air valve 28 is opened by manual depression of the trigger member 66, the control signal pressurizes the drawback valve 18 to open throughflow of fluid pumped is by fluid pump 20 from fluid reservoir 14 to the fluid supply line 110. Air control signal also pressurizes spray air valve 26 to open airstream circuit 400 routing airflow to nozzle for ejection therefrom. Release of the trigger member 66 therefore closes air trigger valve 28, which shuts off control signal and effectuates depressurization of the spray air valve 26, to close off the airstream circuit 400 to the nozzle 100. Simultaneously, fluid drawback valve 18 is depressurized, closing off the fluid circuit 300. When depressurization of the fluid drawback valve 18 occurs, a plunger 19 reseats to seal off the fluid circuit 300 and prevent displacement of fluid remnant in the fluid supply line 110 and thereby prevent dripping from the nozzle 100.

[0036] Priming bypass valve 16 allows for priming the fluid pump 20 by bleeding air from the fluid circuit 300 between the pump 20 and the fluid circuit 300 by bypassing the fluid drawback valve 18. Thus, fluid pressure is attainable previous to spray operations when the pump 20 is primed. Once air is bled from the fluid circuit 300, the priming bypass valve 16 may be closed, the compressed air supply 10 activated, and spray operations begun. Continuous operations may be maintained even while adjusting the atomization produced at the nozzle, between the minimum atomization and the maximum atomization disclosed.

[0037] Fluid pump regulator 22 and control air regulator 24 regulate pressure within the circuits.

[0038] FIG. 4 depicts an example embodiment of a fluid supply line 110 and an airflow supply line 114 coupled to a control panel 700 that is mounted to a voluble frame member 702 (in this example embodiment, a dolly). Airflow supply line 114 is couplable to a compressor (not shown). Fluid supply line 110 is couplable to a reservoir and associated pump 20. Switch member 704 disposed upon control panel 700 housing opens a valve to is enable introduction of airflow into the airflow circuit 200. Once the airflow circuit 200 is activated, the airstream is producible when the trigger member 66 is depressed.

[0039] FIG. 5 depicts the other side of the example embodiment of apparatus shown in FIG. 4. Fluid supply line 110, airstream supply line 112, airflow supply line 114, and control signal line 116 are shown. FIG. 6 is a detail view of the embodiment shown in FIG. 5 showing the various supply lines 110, 112, 114, and 116 for routing the associated airflow circuit 200, fluid circuit 300, airstream circuit 400, and control circuit 500 by manual action effectuated at the nozzle 100.

[0040] FIGS. 7 and 8 are side elevation views of the example embodiment of the nozzle 100 shown in FIG. 5. Fluid supply line 110, airstream supply line 112, airflow supply line 114, and control signal line 116 are shown arranged upon the nozzle 100 to enable actuation of spray operations when trigger member 66 is depressed. Fluid metering valve 30 controls the volume of the second fluid introduced into the airstream to produce a spray or a mist as desired without having to change the nozzle 100. Control of the spray to mist functionality is enabled midstream. The airstream may be regulated by a valve controlling pressure of the airstream circuit (not shown) or by controlling the output pressure on the compressor (not shown).

[0041] Additional embodiments that mount the invention set forth herein to mobile, portable, or other frames and or units are contemplated as within the scope of the present disclosure.