The present invention relates generally to liquid spray nozzle assemblies, and more particularly, to electrostatic spray nozzle assemblies particularly adapted for spray drying liquids by electrostatically charging fluids to facilitate fine liquid particle breakdown and distribution.
In the spray drying industry, electrostatics spray nozzle assemblies are now being used to improve drying efficiency and product quality. While it is desirable to utilize internal components made from non-metallic material, the solvents used in many spray drying applications attack and degrade such materials. Hence, it is necessary that the spray dryer apparatus be designed to ensure that solvents in their liquid state do not come in contact with such degradable plastic components. Typically electrostatic spray dryers have utilized external mix spray nozzle assemblies in which the liquid feed and atomizing gas interact outside the nozzle.
External mix spray nozzles, however, operate at very low liquid flow rates, such as less than 10 kg/hr of feed stock. Such low flow nozzles produce a very fine droplet with at an easily controllable low pressure. To increase the flow rate, however, it is necessary to increase the diameter of the liquid discharge orifice of the nozzle. As the liquid discharge orifice is increased in diameter to reach the higher flow rates, however, the droplet sizes of the spray will also increase. If the droplet size is too large, it will not dry adequately in the dryer chamber even when electrostatically charged. Liquid droplets that are not adequately dried further can coat internal components of the sprayer, impeding optimum operation and requiring cleaning and/or replacement. Larger spray nozzle discharge orifices further result in discharging sprays with greater velocities and momentum. In spray drying applications, this requires longer length and more expensive drying chambers to accommodate such discharging sprays. In order to increase spraying capacity while maintain optimum liquid atomization at low flow rates, it has been necessary to use a multiplicity of electrostatic sprayers, with multiple nozzle bodies, feed lines, compressed gas lines, pumps, and high voltage cables, which is costly and can be cumbersome to install and use.
Internal mix spray nozzle assemblies are known that have the benefit of multistage liquid breakup in atomization which allows the spray nozzle to produce very fine liquid particle discharges. Internal mix spray nozzles, however, operate at higher liquid pressures, which can preclude the use of low pressure operating peristaltic pumps particularly preferred for spray drying in the pharma and flavor industries. Internal mix spray nozzles further utilize considerably smaller amounts of compressed atomizing gases, which can be advantageous when atomizing with non-air gases, such as hydrogen which is desirable in various spray drying applications.
It is an object of the present invention to provide an electrostatic sprayer having an electrostatic spray nozzle assembly that can generate a controllable fine liquid droplet spray with relatively high flow rates particularly advantageous in spray drying applications.
Another object is to provide an external mix electrostatic spray nozzle assembly as characterized above that can be operated at relatively high flow rates in spray dryers having shorter and more compact drying chambers.
A further object is to provide an electrostatic spray nozzle assembly of the forgoing type in which internal degradable plastic or other non-metallic components of the spray nozzle assembly are isolated from sprayed liquid.
Yet another object is to provide an electrostatic sprayer having a spray nozzle assembly of the above kind that can be operated at relatively low pressures, and hence can economically utilize low pressure peristaltic pumps.
Still a further object is to provide an electrostatic spray nozzle assembly of the above kind that has an internal mix spray nozzle for more efficiently producing a controllable fine liquid droplets at lower atomizing gas flow rates particularly advantageous in spray drying.
Yet another object is to provide an electrostatic spray nozzle assembly for use in spray drying that is relatively simple in construction and lends itself to economical manufacture.
Other objects and advantages of the invention will become apparent upon reading the following detailed description and upon reference to the drawings, in which:
While the invention is susceptible of various modifications and alternative constructions, certain illustrative embodiments thereof have been shown in the drawings and will be described below in detail. It should be understood, however, that there is no intention to limit the invention to the specific forms disclosed, but on the contrary, the intention is to cover all modifications, alternative constructions, and equivalents falling within the spirit and scope of the invention.
Referring now more particularly to
The input head 11 is cylindrical in form and the elongated body 12 is a cylindrical body member 15 having an upstream end threadably engaged within a threaded bore of the input hub 11 with a sealing O-ring 16 interposed between the cylindrical body member 15 and input head 11. A liquid feed tube 18 made of stainless steel or other electrically conductive material extends axially through the outer cylindrical body member 15 with an upstream end 18a supported within and extending outwardly thereof for coupling to pressurized liquid supply 19. The liquid feed tube 18 in this instance has a reduced diameter upstream end section 18b that defines a locating shoulder 18c mountable within a counterbore of the input head 11. A sealing O-ring 17 interposed between the liquid feed tube 18 and the input head 11.
The liquid feed tube 18 extends axially through the cylindrical body member 14 for defining and annular atomizing gas passage 25 between a liquid feed tube 18 and the outer cylindrical body member 15. The input head 11 is formed with a radial pressurized gas inlet passage 26 that receives with a gas inlet filling 28 coupled to a suitable pressurized gas supply 29. The gas inlet passage 26 communicates with an annular gas chamber 30 surrounding the liquid feed tube 18 within the input head 11, which in turn communicates with the annular atomizing gas passage 25 through the cylindrical body member 15.
For electrically charging liquid directed into and through the liquid feed tube 18, the input head 11 further has a radial passage 31, in this case upstream of the gas inlet passage 26, that receives a fitting 32 secured to a high voltage cable 34 connected to a high voltage source. The high voltage cable 34 in this instance has a terminal abutment segment 35 biased by a spring 36 into reliable electrically conducting relation with the liquid feed tube 18. With the liquid feed tube 18 electrically charged by the high voltage cable 34 it can be seen that feed liquid through the feed tube 18 is charged along its entire length of travel to the spray nozzle assembly 14. At the same time, pressurized gas is communicated through the annular gas passage 25 between the liquid feed tube 18 and outer cylindrical body member 15.
In accordance with this embodiment of the invention, the spray nozzle assembly 14 is an external mix spray nozzle assembly operable for producing a fine liquid particle spray, particularly suitable for spray drying applications, at relatively high liquid flow rates and low pressures for optimum and economical spray drying operation. To this end, the spray nozzle assembly 14 has a cluster head design comprising a plurality of individual spray tips 40 coupled to common pressurized liquid and gas supplies, in this case, from the liquid feed tube 18 and the annular pressurized gas passage 25, respectively. The illustrated cluster head spray nozzle assembly 14, as best depicted in
In carrying out this embodiment, the spray tips 40 each are made of an electrically conductive metal and in this case have an upstream cylindrical hub 40a, a inwardly tapered forwardly extending section 40b having an outwardly extending radial flange 40c adjacent a downstream end thereof, and a forwardly extending relatively small diameter nose 40d. (
The radial flange 49c of each spray tip 40 is each mounted within a respective one of the cylindrical openings 46 of the nozzle cap 45 with an annular plastic air cap 50 disposed about the spray tip radial flange 49c in interposed sealing engagement between the radial flange 49c and nozzle cap opening 46. The plastic air cap 50 in this case has an L-shape cross section periphery disposed about the front and outer peripheries of each spray tip radial flange 40c with a forwardly extending lip 50a mounted in overlying relation to an annular lip of the nozzle cap opening 46. (
For atomizing liquid discharging from the spray tips 40, the nozzle liquid manifold 41 and nozzle cap 45 define an annular atomizing gas passageway 55 (
In carrying a further feature of this embodiment, liquid directed through the cluster head spray nozzle assembly 14 is subjected to multistage electrostatic charging for enhanced liquid atomization upon discharge from the spray nozzle assembly. To this end, a downstream end of a metallic electrically charged liquid feed tube 18 has a sharp chamfered end 60, preferably charged to about 30 kv, that first focuses an electrostatic field into the feed stock as it is discharged from the feed tube 18 and prior to entry into the spray tips 40, and secondly, the gap between the sharp chamfered end 60 of the charged liquid feed tube 18 and the spray tips 40 creates a capacitance within the gap that has unexpectedly been found to increase the electrostatic charge on the liquid as it is directed to and through the spray tips 40.
In operation, the cluster head spray nozzle assembly 14 has proven to produce quality fine liquid particle spraying optimum for spray drying applications at relatively high liquid flow rates up to 125 kg/hr. Yet the spray tips 40 each have relatively small discharge orifices 49c for enabling low pressure, controllable operation, using peristaltic pumps favored in spray drying applications. The cluster head spray nozzle assembly 14, furthermore, can deliver such high flow rate spraying in much shorter length, such as three to five feet, and hence, in more economical spray drying chambers then hereto for possible when utilizing spray nozzle with larger discharge orifices and liquid pressures to increase flow rate. The multiple electrostatically charged spray patterns discharging from the cluster head spray nozzle assembly in the same chamber further has been found to cause particles to reattach to one another after they have dried, thereby reducing the amount of particles that are too fine to control which can hinder coating efficiency. Finally, it can be seen that all of the internal components of the electrostatic sprayer that are subject to contact by the liquid being sprayed are made of Teflon or stainless steel which are resistant to most liquids to be sprayed. The outer cylindrical body member 15, which preferably is made of a harder polyetherimide material that can be subject to degradation from certain solvents used in spray drying, is maintained out of contact from the liquid feed stock.
To facilitate economical manufacture of the electrostatic sprayer 10, it will be appreciated that the cluster head spray nozzle assembly 14 may be preassembled for efficient mounting in the nozzle body 12. The spray nozzle assembly 14 in preassembled condition in this instance can be assembled in cylindrical body member 15 by positioning into the cylindrical body member 15 from an upstream end, as depicted in
Referring now more particularly to
In carrying out this embodiment of the invention, the electrostatic spray nozzle assembly 71 is an internal mix spray nozzle assembly operable for directing a fine liquid particle spray for optimum usage in spray drying. The illustrated spray nozzle assembly 71 basically comprises a dome configured spray tip 72, an inner air guide 74 mounted directly upstream of the spray tip 72, and a center locator 75 for supporting the downstream end of the liquid feed tube 18 centrally within the air guide 74 and spray tip 72.
The illustrated dome configured spray tip 71 has an upstream cylindrical passage section 72 that communicates with an inwardly converging mixing chamber 72a, which in turn communicates through a smaller diameter cylindrical passage section 72b that defines a spray discharge orifice 72c. The spray tip 71 has an outwardly extending radial flange 74 supported against a reduced diameter annular retention lip 75 of the outer cylindrical nozzle body member 18. A sealing O-ring 76 is interposed between the dome of the spray tip 71 and an inner annular side of retaining lip 75 of the cylindrical body member 15.
The air guide 74 has an outer cylindrical wall section 74a mounted within the cylindrical body member 15 and a forwardly extending annular hub 74b concentrically mounted within an annular counterbore of the spray tip 71. The center locator 75 has a central opening 75a in which a liquid feed tube 15 extends and is supported in a plurality of radial support legs 75b. The radial legs 75b in this case are supported adjacent their downstream ends within the cylindrical wall 74a of the air guide 74. The said air guide 74 has an inwardly curved internal wall 74c for channeling and converging pressurized atomizing gas from the annular gas passage 25 through a small annular gas passage 78 surrounding the liquid feed tube 18.
In further carrying out this embodiment, the liquid feed tube 18 includes an end segment section 18a axially coupled thereto formed with a reduced diameter liquid passage section 80 that communicates with a plurality of cross slots 81 for directing pressurized liquid flow streams radially outwardly of the liquid feed tube 18 for interaction and atomization by pressurized atomizing gas directed through the narrow annular air passage 78 directly across the cross slots 81. In this instance there are four circumferentially spaced cross slots 81 which define an impingement surface 82 at the end of the feed tube segment 18a against which liquid directed through the liquid feed tube 18 impinges and is forcefully directed out radially outwardly for interaction with the pressurized atomizing gas. It will be understood that the extension segment 18a of the liquid feed tube 18 also is made of an electrically conductive metallic material and is fixed in electrically contacting relation to the liquid feed tube 18.
In keeping with a further important feature of this embodiment, the liquid feed tube end segment 18a has a sharp pointed end 18b disposed within the mixing chamber 72b of the spray tip 71 for focusing an electrostatic field therefrom in a manner that enhances electrostatic charging and atomization of the liquid particles within the spray tip mixing chamber 72b prior to discharge from the spray nozzle assembly 14. The terminal pointed end 18a of the feed tube 18 is located centrally within the spray tip mixing chamber 72b for focusing the electrostatic field into the atomized liquid particles as they converge and exit the discharge passage 72b.
In operation, the electrostatic sprayer 70 is operable for efficiently producing quality fine liquid particle atomized spray at high liquid feed stock rates up to 125 kg/hr with less pressurized atomizing gas requirements, which is particularly advantageous when using non-air atomizing gas, such as hydrogen gas commonly used in spray drying. Nitrogen is used to protect against a dust explosion, which is a higher risk with electrostatic spraying, also has the ability to absorb large amounts of moisture. Like in the previous embodiment, liquid is charged as it is directed through the metal liquid supply tube 18 simultaneous with the direction of pressurized gas through the annular chamber 25 surrounding the liquid supply tube 18. In this instance, the liquid breaks up in multiple stages, first by impinging upon the impingement surface 82 at the downstream end of the liquid supply tube segment 18a and transverse direction through the radial discharge passages 81 for interaction with pressurized atomizing gas directed across radial liquid discharge passages 81. The atomized liquid is then directed by the atomizing gas into the downstream mixing chamber 72b of the spray tip 71 where fine liquid particles are further charged by the focused electrostatic fields promulgated by the sharp pointed end 18b liquid feed tube segment 18b for further enhanced atomization prior to discharge from the exit orifice 72c as a very fine liquid particle spray for efficient spray drying.
This patent application claims the benefit of U.S. Patent Application No. 62/773,875 filed Nov. 30, 2018, which is incorporated by reference.
Number | Date | Country | |
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62773875 | Nov 2018 | US |