阅读说明：本技术 一种喷嘴 (Spray nozzle ) 是由 肖恩·摩根 于 2019-12-20 设计创作，主要内容包括：本发明涉及可移除的插入件和包括可移除的插入件和喷嘴帽的喷嘴。可移除的插入件具有底部构件和突出构件。喷嘴帽具有环形凸缘,该环形凸缘界定用于插入件的内部定位表面。凸缘径向延伸并终止于限定了平面喷射开口的内部末端。在使用时,底部构件容纳在喷嘴帽内,而突出构件向外突出并位于平面喷射开口之外。(The invention relates to a removable insert and a nozzle comprising a removable insert and a nozzle cap. The removable insert has a base member and a protruding member. The nozzle cap has an annular flange that defines an internal locating surface for the insert. The flange extends radially and terminates at an inner extremity defining a planar spray opening. In use, the base member is received within the nozzle cap and the projecting member projects outwardly and out of the planar spray opening.)

1. A nozzle, comprising:

a removable insert having a base member and a protruding member;

a nozzle cap having an annular flange defining an interior locating surface for the insert, the flange extending radially and terminating at an interior end defining a planar spray opening; and

wherein, in use, the base member is received within the nozzle cap and the projecting member projects outwardly and beyond the planar spray opening.

2. The nozzle of claim 1 including a nozzle body to which the nozzle cap is adapted to be joined, the nozzle body having a fluid receiving portion and a fluid discharge portion and defining a counterbore extending between the fluid receiving portion and the fluid discharge portion and depicting a central axis toward which the flange extends radially.

3. A nozzle according to claim 1 or 2, wherein the protruding member comprises a cylindrical wall defining a channel terminating in an aperture.

4. A nozzle according to claim 3, wherein the planar ejection opening lies in a plane substantially perpendicular to the channel.

5. A nozzle according to any one of the preceding claims, wherein the protruding member of the insert is adapted to be removably fitted into the spray opening.

6. A nozzle according to any one of the preceding claims, wherein the protruding member has an exposed surface that exceeds the planar spray opening.

7. The nozzle of claim 6, wherein the exposed surface comprises an annular platform surrounding the orifice.

8. The nozzle of any preceding claim, wherein the aperture at the distal end of the protruding member is at a distance from the planar spray opening.

9. The nozzle of any preceding claim, wherein the annular flange further has an outer surface that curves towards the tip.

10. A nozzle according to any preceding claim, wherein the insert is in the form of a frusto-conical disc.

11. The nozzle of any one of claims 6 to 10, wherein the exposed surface is linear and tapered, sloping at a constant angle to the planar spray opening.

12. The nozzle of claim 11 wherein the base member further has a tapered outer surface that is linear and inclined at the same constant angle to the planar spray opening.

13. The nozzle of claim 12, wherein the exposed surface and the tapered outer surface are collinear and continuously integrated with one another.

14. The nozzle of claim 12 or 13, wherein the exposed surface and the tapered outer surface are coplanar.

15. The nozzle of any one of claims 12 to 14, wherein the inner locating surface of the annular flange is an inclined surface complementary to the tapered outer surface of the base member.

16. The nozzle of any one of claims 12 to 15, wherein the tapered outer surface of the base member is configured to facilitate smooth insertion of the protruding member into the spray opening of the nozzle cap, resulting in self-alignment or centering of the insert concentric or coaxial with the annular flange of the nozzle cap.

17. The nozzle of any one of claims 1 to 8, wherein the inner locating surface of the annular flange is flush with the planar spray opening.

18. A nozzle according to any one of claims 1 to 8 and 17, wherein the base member provides an annular shoulder having an outer surface which, in use, abuts the internal locating surface.

19. The nozzle of any one of claims 6, 7, 8, 17 and 18, wherein the exposed surfaces curve closer together to form a necked-out member.

20. The nozzle of any of claims 6, 7, 8, 17 to 19, wherein the nozzle has a downstream end portion with a smooth outer profile that transitions in a seamless manner at a tip from the curved outer surface of the annular flange to the curved exposed surface of the protruding member.

21. A nozzle according to any one of the preceding claims, wherein the outer surface of the base member comprises a groove adapted to receive the sealing means.

22. The nozzle of claim 21, wherein the sealing device is an O-ring.

23. The nozzle of any preceding claim, wherein the counterbore is defined by a cylindrical wall that terminates in a retaining lip that acts as a barrier to hold the insert in place.

24. The nozzle of any preceding claim, comprising a swirl unit upstream of the insert.

25. A nozzle according to any preceding claim, wherein the nozzle cap has an upstream end adapted to engage a fluid receiving portion of the nozzle body in use.

26. A nozzle as claimed in claim 24 or 25, wherein the nozzle cap provides a mechanism for securely holding the insert and vortex unit in place and compresses the sealing means when the upstream end is in threaded engagement with the fluid receiving portion of the nozzle body.

27. A removable insert for fitting into a nozzle cap of a nozzle, the insert having a base member and a projecting member, the nozzle cap having an annular flange defining an internal locating surface for the insert, the flange extending radially and terminating at an internal extremity defining a planar spray opening; wherein, in use, the base member is received within the nozzle cap and the projecting member projects outwardly and beyond the planar spray opening.

Technical Field

The present invention relates broadly to a nozzle. More particularly, the present invention relates to a nozzle having an improved insert (commonly referred to as orifice disc) and nozzle cap combination.

Background

Spray drying of milk or dairy products involves spraying concentrated milk at very high pressure (typically 200-500BarG) through a pressure atomising nozzle into a heated cyclonic drying chamber, the inlet temperature of which at the nozzle operation is about 120 to 160 degrees celsius. These drying temperatures combine with the atomized liquid which then dries into fine particles, producing suspended milk powder which slowly moves to the bottom of the cyclone as it cools to an exit temperature of about 60 degrees celsius, and is then collected and bagged.

Some atomized liquids often deposit on the entire surface of the atomizing nozzle before they are completely dry due to their close proximity to the spray orifice (i.e., the outlet). A disadvantage of the nozzles currently on the market is that they tend to allow the slow accumulation of atomized, but semi-dried liquid on and around the spray orifice located in the hotter portion of the dryer. Over time, this liquid not only dries out, but also slowly boils on the surface of the heated nozzle. This can result in the build up of one layer after another until a significant amount of the cooked product generates enough cumulative heat to begin combustion. This accumulation of charred product can slowly release into a properly dried cooled clean powder, causing its contamination with charred particles known as "char particles". The level of coking particles is measured periodically in the collected powder and the results form part of the powder classification process. High levels of coking particles naturally lead to degradation of the powder, thereby significantly affecting its market value.

Another problem associated with the operation of the dryer is that the combination of the chamber temperature and the suspended powder produced by the drying of the atomized liquid can over time create and develop a fire source creating a significant fire risk. The source of fire is caused by the previously described atomized liquid depositing on and around the surface of the hot atomizing nozzle, accumulating thereon, and eventually drying and cooking into a large quantity of cooked product with sufficient accumulated heat to initiate combustion. Whenever deposits occur or are expected to occur with existing nozzles, operators often need to shut down the dryer prematurely to avoid the deposits developing into an explosive ignition source that can seriously damage the dryer, resulting in days of down time or production interruption, or worse, complete loss of drying equipment due to an uncontrollable or contained fire. The need for such premature shutdown significantly impacts the daily productivity of the dryer.

It is noted that the above-mentioned nozzles face the challenge of operating at very high pressures. They require pressure integrity to withstand the stress and strain of such pressures, which relies on maintaining a minimum material thickness and profile of the nozzle cap tip of the metering wear component. Typically, this desired thickness can encroach into the spray zone and can interact with the spray plume, causing spray product to accumulate on the nozzle cap. Accordingly, there is a need to maintain or enhance the pressure integrity of the nozzle, allowing for higher operating pressures, as well as higher flow rates and higher production rates, while reducing build-up that can occur with thicker and more robust nozzle caps. Problematically, the thicker and more robust nozzle caps commonly employed in the prior art in an effort to increase pressure intensity would result in further intrusion into the spray plume and exacerbate build-up, product contamination, and fire risk.

It is therefore an object of the present invention to provide a nozzle with an insert which may meet the above-mentioned needs, and/or which may overcome or ameliorate the above-mentioned disadvantages and problems, or which at least provides a useful alternative.

Disclosure of Invention

According to an aspect of the present invention, there is provided a nozzle comprising:

a removable insert having a base member and a protruding member;

a nozzle cap with an annular flange defining an interior locating surface for the insert, the flange extending radially and terminating at an interior end defining a planar spray opening; and

wherein, in use, the base member is received within the nozzle cap and the projecting member projects outwardly and beyond the planar spray opening.

Preferably, the nozzle includes a nozzle body to which the nozzle cap is adapted to be joined, the nozzle body having a fluid receiving portion and a fluid discharge portion and defining a counter bore extending between the fluid receiving portion and the fluid discharge portion and depicting a central axis towards which the flange extends radially.

Preferably, the protruding member comprises a cylindrical wall defining a channel terminating in an aperture. More preferably, the planar ejection opening is located in a plane substantially perpendicular to the channel.

Preferably, the protruding member of the insert is adapted to be removably fitted into the ejection opening. More preferably, the protruding member has an exposed surface beyond the planar ejection opening. Even more preferably, the exposed surface comprises an annular platform surrounding the aperture. Most preferably, the orifice at the distal end of the protruding member is at a distance from the planar ejection opening.

Preferably, the annular flange also has an outer surface that curves towards the tip.

In a preferred embodiment, the insert is in the form of a frustoconical dish. Preferably, the exposed surface is linear and tapered, being inclined at a constant angle to the planar spray opening. More preferably, the bottom member also has a tapered outer surface that is linear and inclined at the same constant angle to the planar spray opening. As such, the exposed surface of the protruding member and the tapered outer surface of the base member are collinear and continuously integrated with one another. Preferably, the exposed surface of the protruding member and the tapered outer surface of the base member are also coplanar. In this embodiment, the inner locating surface of the annular flange is an inclined surface complementary to the tapered outer surface of the base member. Thus, the tapered outer surface of the base member can facilitate smooth insertion of the protruding member into the spray opening of the nozzle cap, resulting in self-alignment or centering of the insert concentric or coaxial with the annular flange of the nozzle cap.

In another preferred embodiment, the inner locating surface of the annular flange is flush with the planar spray opening. The base member in the form of a disc preferably provides an annular shoulder having an outer surface which in use abuts the inner locating surface. Preferably, the exposed surfaces are curved closer together to form a neck-like projecting member. In this embodiment, the nozzle has a downstream end portion having a smooth outer profile that transitions in a seamless manner from the curved outer surface of the annular flange to the curved exposed surface of the projecting member at the tip.

Preferably, the outer surface of the base member comprises a groove adapted to receive the sealing means. More preferably, the sealing means is an O-ring.

Preferably, the countersink is defined by a cylindrical wall terminating in a retaining lip which acts as a barrier to hold the insert in place. More preferably, the nozzle comprises a vortex unit upstream of the insert. Even more preferably, the nozzle cap has an upstream end adapted to engage the fluid receiving portion of the nozzle body in use. Most preferably, the nozzle cap provides a mechanism for securely holding the insert and vortex unit in place and compresses the sealing device when the upstream end is threadedly engaged with the fluid receiving portion of the nozzle body. The arrangement is such that the fastening of the nozzle cap to the nozzle body results in a compression seal of the sealing means.

According to one aspect of the invention, there is provided a removable insert for fitting into a nozzle cap of a nozzle, the insert having a base member and a projecting member integral with the base member, the nozzle cap having a downstream end with an annular flange defining an internal locating surface for the insert, the flange extending radially towards a central axis and terminating in a tip defining a planar spray opening; the nozzle includes a nozzle body having a fluid receiving portion and a fluid discharge portion and defining a counterbore extending between the fluid receiving portion and the fluid discharge portion and depicting a central axis;

wherein, in use, the base member is received within the nozzle cap and the projecting member projects outwardly and out of the planar spray opening.

Drawings

Various aspects of the invention will now be described in connection with the non-limiting embodiments described in the figures, in which:

FIG. 1 is a cross-sectional view of a preferred embodiment nozzle with an insert, the nozzle being threadably connected to a coupling (coupling);

FIG. 2 is a perspective cross-sectional view of the insert of FIG. 1 in connection with a nozzle cap;

FIG. 3 is a perspective view of the nozzle of FIG. 1, showing the projecting member of the insert of FIG. 1 projecting from the spray opening defined by the nozzle cap and located outside of the nozzle cap;

FIG. 4 is a cross-sectional view of another preferred embodiment nozzle with an insert, the nozzle being threadably connected to the coupling;

FIG. 5 is a perspective cross-sectional view of the insert of FIG. 4 in connection with a nozzle cap; and

fig. 6 is a perspective view showing the protruding member of the insert of fig. 4 protruding from and standing above the spray opening defined by the nozzle cap of fig. 5.

Detailed Description

Referring to fig. 1, 2 and 3, a first preferred embodiment of a nozzle 10 is shown as being threaded into a coupling 11 having a cavity 13, the cavity 13 being adapted to receive a portion of a spray gun (not shown). The nozzle 10 has, among other components, a nozzle body 12, a removable insert 14, and a nozzle cap 16. The nozzle body 10 has a fluid receiving portion 18 and a fluid discharge portion 20. The nozzle body 10 also defines a counter bore 22, the counter bore 22 extending between the fluid receiving portion 18 and the fluid discharge portion 20 and depicting a central axis 24.

As best shown in fig. 1 and 2, the removable insert 14 has a base member 26 and a protruding member 28 that is integral with the base member 26. The nozzle cap 16 has a downstream end 30 with an annular flange 32 defining an interior locating surface 34 for the insert 14. The annular flange 32 extends radially toward the central axis 24 and terminates at an inner annular tip 36 that defines a planar spray opening 38. In use, the base member 26 is received within the nozzle cap 16, while the projecting member 28 projects outwardly and beyond the planar spray opening 38. The projecting member 28 has a cylindrical wall 40 defining a passage 42 terminating in an aperture 44. It should be understood that the planar jet opening 38 lies in an imaginary plane a as shown in phantom. The imaginary plane a is substantially perpendicular to the channel 42.

Referring to fig. 1 and 2, the protruding member 28 of the insert 14 is configured to fit snugly and removably into the planar spray opening 38. The projecting member 28 has an exposed surface 46 that extends beyond the planar ejection opening 38. As such, the aperture 44 at the distal end of the protruding member 28 is spaced a distance from the planar ejection opening 38. With the orifice 44 sufficiently elevated and beyond the planar spray opening 38 (or imaginary plane A), it should be appreciated that the spray plume (not shown) ejected from the orifice 44 is significantly further from the spray opening 38 and indeed the nozzle cap 16. This provides the following major benefits: deposition and accumulation of atomized liquid on and around all surfaces of the projecting member 28 and the downstream end of the nozzle cap 16 generally is significantly reduced. The annular flange 32 also has an outer surface 48 that curves toward the tip 36.

As shown in fig. 1 and 2, in this embodiment, the insert 14 is in the form of a frustoconical dish. The exposed surface 46 is linear and tapered to be inclined at a constant angle to the planar ejection opening 38. The exposed surface 46 terminates in an annular platform 47 surrounding the orifice 44. The annular platform 47 is parallel to an imaginary plane indicated by the dashed line B. The base member 26 also has a tapered outer surface 50, which outer surface 50 is also linear and inclined at the same constant angle to the planar spray opening 38. Thus, the exposed surface 46 of the protruding member 28 and the tapered outer surface 50 of the base member 26 are collinear, coplanar, and continuously integrated with one another. This continuous uninterrupted surface as a combination of exposed surface 46 and tapered outer surface 50 provides the following benefits: the frustoconical dish can be brought into smooth and natural engagement with the annular flange 32, with the projecting members 28 projecting through the planar ejection openings 38. In this embodiment, the inner locating surface 34 of the annular flange 32 is an inclined surface that is complementary to the tapered outer surface 50 of the base member 26. Thus, the tapered outer surface 50 of the base member 26 can facilitate smooth insertion of the protruding member 28 into the spray opening 38 of the nozzle cap 16, resulting in self-alignment or centering of the insert 14 concentric or coaxial with the annular flange 32 of the nozzle cap 16. As mentioned above, it should be appreciated that the exposed surface 46 and the tapered outer surface 50 are actually integral and one continuous surface. The continuous surface is configured and angled such that it engages the annular flange 32 and projects smoothly through the spray opening 38 without being pinched or caught. In addition, the annular flange 32 is designed and dimensioned to facilitate the protrusion member 28 to pass entirely through and protrude beyond the planar ejection opening 38. The distance between the planar ejection opening 38 and the platform 47 is indicated by the arrow C-C. This clearly illustrates that the orifice 44 (outlet in a functional sense) is substantially spaced from the planar spray opening 38 and lies substantially outside the planar spray opening 38.

Turning to fig. 4, 5 and 6, in another preferred embodiment 14A of the insert, the inner locating surface 34A of the annular flange 32A is flush with the planar ejection opening 38A, the planar ejection opening 38A being on an imaginary plane D indicated by the dashed line. The base member, in this embodiment in the form of an annular disc 26A, is configured to provide an annular shoulder 52 having an outer surface 54, which outer surface 54 abuts, in use, the inner locating surface 34A. In this embodiment, the exposed surfaces 46A curve closer together to form the necked protruding member 28A. The exposed surface then reaches an annular plateau 47A indicated by a dashed line E. The nozzle 10A has a downstream end portion 30A with a smooth outer profile that transitions in a seamless manner from the curved outer surface 56 of the annular flange 32A at the terminal end 36A to the curved exposed surface 46A of the protruding member 28A. Again, the distance between the planar ejection opening 38A and the platform 47A is indicated by arrows F-F. This clearly illustrates that the orifice 44 is substantially spaced from the planar ejection opening 38A and is located substantially outside the planar ejection opening 38A.

Referring back to fig. 1, the inclined outer surface 50 of the base member 26 has a groove 58, the groove 58 being configured to receive a sealing device in the form of an O-ring 60. The counterbore 22 is defined by a cylindrical wall 62, the cylindrical wall 62 terminating in a retaining lip 64, the retaining lip 64 serving as a barrier to retaining the insert 14 in place. The nozzle 10 (and 10A) has a swirl element 66 located upstream of the insert 14. The nozzle cap 16 has an upstream end 68 which is adapted to engage the fluid receiving portion 18 of the nozzle body 12 in use.

In both of the above-described embodiments of the nozzles 10 and 10A, the nozzle cap 16 provides a mechanism for securely holding the insert 14 and the vortex unit 66 in place and compresses the sealing device (i.e., O-ring) 60 as the upstream end 68 is threadably engaged with the fluid receiving portion 18 of the nozzle body 12. This arrangement causes the nozzle cap 16 to be secured to the nozzle body 12 resulting in a compression seal by the sealing device (i.e., O-ring) 60.

It should be noted that the insert 14 in the form of a bore disk is a component that may require periodic replacement and is typically made of a wear resistant material (e.g., tungsten carbide or ceramic).

Having now described in some detail preferred embodiments of the present invention, it will be apparent to those skilled in the art that the nozzle of the present invention may provide at least the following advantages:

1. it assists the atomization process by reducing the accumulation of spray splash on the nozzle cap, thereby allowing the dryer to run longer, thereby improving productivity by minimizing interruptions and downtime;

2. the insert helps keep the nozzle bore (i.e., the outlet) a distance from the spray opening defined by the nozzle cap, thereby moving the spray plume further and substantially away from the nozzle cap, thereby reducing the likelihood of any char particles settling and accumulating on the nozzle end and the protruding member itself;

3. the generation of the coking particles is reduced to the maximum extent, so that the quality and the value of the milk powder are improved; and

4. the possibility of forming a burning fire source is reduced, thereby reducing the risk of fire.

Those skilled in the art will appreciate that the invention described herein is susceptible to variations and modifications other than those specifically described. For example, as shown in FIG. 1, the vortex unit 66 and the insert 14 are held in place by the nozzle body 12, which is also commonly referred to as a snap ring for the nozzle body 12. The body 12 or grommet with retaining lip 64 provides the following benefits: a) to assist in positioning and securing the insert 14 in place to facilitate aligned engagement of the insert 14 with the nozzle cap 16. However, this body 12 or snap ring may be omitted in a more economical arrangement as shown in the embodiment shown in FIG. 5, wherein the insert 14 and vortex unit 66 are simply held in place against the nozzle cap 16 by a retainer provided near the upstream end of the nozzle cap 16. All such variations and modifications are considered to be within the scope and spirit of the present invention, the nature of which is to be determined from the foregoing description.

It will be understood that any admission in the specification of prior art does not constitute an admission that such prior art forms part of the common general knowledge in the relevant art.