This application claims the benefit of, and priority to, Canadian patent application no. 2,980,178 filed Sep. 25, 2017, the entire contents of which are incorporated by reference herein.
This disclosure relates generally to distributing light in a reaction chamber.
Fluids, such as water or air for example, may be treated, for example to deactivate pathogens, by subjecting the fluid to ultraviolet (“UV”) light in a reaction chamber. Solid-state light sources such as light-emitting diodes (“LEDs”) may produce such UV light, but such light may not be adequately distributed throughout a reaction chamber.
As a result, a reaction chamber may have one or more dark regions exposed to little or no such light. For example, a fully collimated or converging-collimated radiation pattern may conserve power, but may leave dark regions that may lead to decrease in reactor performance, particularly when the reaction chamber consists of one channel only.
Similarly, when local fluid velocity is higher in some locations of a reaction chamber, for example due to introduction of fluid to the reaction chamber from a side of the reaction chamber, fluid at such a higher fluid velocity requires higher UV intensity to reach to similar level of disinfection when compared to fluid having a lower velocity.
Pathogens in fluid passing through such dark regions, or flowing with such high-velocity fluid, may not be deactivated, which may be hazardous to health.
According to one embodiment, there is provided a method of distributing electromagnetic radiation in a reaction chamber extending in a longitudinal direction at least between an inlet of the reaction chamber and an outlet of the reaction chamber, the method comprising causing at least some electromagnetic radiation from at least one electromagnetic radiation emitter to be refracted by at least one lens into the reaction chamber as refracted electromagnetic radiation skewed laterally relative to the longitudinal direction.
According to another embodiment, there is provided a method of distributing electromagnetic radiation in a reaction chamber, the method comprising causing at least some electromagnetic radiation from at least one electromagnetic radiation emitter to be refracted by at least one lens into the reaction chamber as refracted electromagnetic radiation skewed laterally relative to the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter.
In some embodiments, the reaction chamber extends in a longitudinal direction at least between an inlet of the reaction chamber and an outlet of the reaction chamber.
In some embodiments, causing the at least some of the refracted electromagnetic radiation to be refracted into the reaction chamber comprises causing the refracted electromagnetic radiation in the reaction chamber to be skewed laterally relative to the longitudinal direction.
In some embodiments, the longitudinal direction is parallel to a central longitudinal axis of the reaction chamber.
In some embodiments, the inlet is configured to direct fluid into the reaction chamber in an inlet direction non-parallel to the longitudinal direction.
In some embodiments, the inlet direction is substantially perpendicular to the longitudinal direction.
In some embodiments, causing the at least some of the refracted electromagnetic radiation to be refracted into the reaction chamber comprises causing fluence rate of the refracted electromagnetic radiation in the reaction chamber and along the inlet direction from the inlet to be higher with increased distance from the inlet.
In some embodiments, causing the at least some of the refracted electromagnetic radiation to be refracted into the reaction chamber comprises causing a fluence rate of the refracted electromagnetic radiation in a first transverse side of the reaction chamber proximate the inlet to be less than a fluence rate of the refracted electromagnetic radiation in a second transverse side of the reaction chamber opposite the first transverse side of the reaction chamber and opposite the inlet.
In some embodiments, the inlet is configured to direct fluid into the reaction chamber in an inlet direction substantially parallel to the longitudinal direction.
In some embodiments, causing the refracted electromagnetic radiation in the reaction chamber to be skewed laterally relative to the longitudinal direction comprises causing the refracted electromagnetic radiation in the reaction chamber to be skewed laterally relative to the longitudinal direction and towards an extension in the reaction chamber of the inlet direction from the inlet.
In some embodiments, causing the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter to be refracted by the at least one lens into the reaction chamber comprises causing the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter to be: refracted into the reaction chamber by a plurality of lenses spaced apart around an inlet axis extending along the inlet direction; and skewed laterally relative to the longitudinal direction and towards the extension in the reaction chamber of the inlet direction from the inlet.
In some embodiments, the plurality of lenses surround the inlet axis.
In some embodiments, the electromagnetic radiation comprises ultraviolet (“UV”) radiation.
In some embodiments, the at least one electromagnetic radiation emitter comprises at least one UV light-emitting diode (“UV-LED”).
In some embodiments, the at least one electromagnetic radiation emitter comprises at least one light-emitting diode (“LED”).
In some embodiments, the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter has a principal radiation direction.
In some embodiments, the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter is substantially axially symmetric about the principal radiation direction.
In some embodiments, the refracted electromagnetic radiation is distributed axially asymmetrically relative to the principal radiation direction of the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter. In some embodiments, a fluence rate of the refracted electromagnetic radiation on a first transverse side of the principal radiation direction is greater than a fluence rate of the refracted electromagnetic radiation on a second transverse side of the principal radiation direction opposite the first transverse side of the principal radiation direction.
In some embodiments, the at least one lens comprises at least one lens having an optical axis non-parallel to the principal radiation direction.
In some embodiments, the at least one lens comprises at least one lens having an optical axis parallel to and spaced apart from the principal radiation direction.
In some embodiments, the at least one lens comprises at least one axially asymmetric lens.
According to another embodiment, there is provided a reactor apparatus comprising: a body defining an inlet, an outlet, and a reaction chamber extending in a longitudinal direction at least between the inlet and the outlet; at least one electromagnetic radiation emitter; and at least one lens configured to refract at least some electromagnetic radiation from the at least one electromagnetic radiation emitter into the reaction chamber as refracted electromagnetic radiation skewed laterally relative to the longitudinal direction.
According to another embodiment, there is provided a reactor apparatus comprising: a body defining a reaction chamber; at least one electromagnetic radiation emitter; and at least one lens configured to refract at least some electromagnetic radiation from the at least one electromagnetic radiation emitter into the reaction chamber as refracted electromagnetic radiation skewed laterally relative to the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter and into the reaction chamber.
In some embodiments: the body further defines an inlet of the reaction chamber and an outlet of the reaction chamber; and the reaction chamber extends in a longitudinal direction at least between the inlet and the outlet.
In some embodiments, the at least one lens is configured to cause the refracted electromagnetic radiation in the reaction chamber to be skewed laterally relative to the longitudinal direction.
In some embodiments, the longitudinal direction is parallel to a central longitudinal axis of the reaction chamber.
In some embodiments, the inlet is configured to direct fluid into the reaction chamber in an inlet direction non-parallel to the longitudinal direction.
In some embodiments, the inlet direction is substantially perpendicular to the longitudinal direction.
In some embodiments, the at least one lens is configured to cause fluence rate of the refracted electromagnetic radiation in the reaction chamber and along the inlet direction from the inlet to be higher with increased distance from the inlet.
In some embodiments, the at least one lens is configured to cause a fluence rate of the refracted electromagnetic radiation in a first transverse side of the reaction chamber proximate the inlet to be less than a fluence rate of the refracted electromagnetic radiation in a second transverse side of the reaction chamber opposite the first transverse side of the reaction chamber and opposite the inlet.
In some embodiments, the inlet is configured to direct fluid into the reaction chamber in an inlet direction substantially parallel to the longitudinal direction.
In some embodiments, the at least one lens is configured to cause the refracted electromagnetic radiation in the reaction chamber to be skewed laterally relative to the longitudinal direction and towards an extension in the reaction chamber of the inlet direction from the inlet.
In some embodiments, the at least one lens comprises a plurality of lenses spaced apart around an inlet axis extending along the inlet direction.
In some embodiments, the plurality of lenses surround the inlet axis.
In some embodiments, the at least one electromagnetic radiation emitter comprises at least one emitter of UV radiation.
In some embodiments, the at least one emitter of UV radiation comprises at least one UV-LED.
In some embodiments, the at least one electromagnetic radiation emitter comprises at least one LED.
In some embodiments, the at least one electromagnetic radiation emitter is configured to cause the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter to have a principal radiation direction.
In some embodiments, the at least one electromagnetic radiation emitter is configured to cause the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter to be substantially axially symmetric about the principal radiation direction.
In some embodiments, the at least one lens is configured to cause the refracted electromagnetic radiation to be distributed axially asymmetrically relative to the principal radiation direction of the at least some electromagnetic radiation from the at least one electromagnetic radiation emitter. In some embodiments, the at least one lens is configured to cause a fluence rate of the refracted electromagnetic radiation on a first transverse side of the principal radiation direction to be greater than a fluence rate of the refracted electromagnetic radiation on a second transverse side of the principal radiation direction opposite the first transverse side of the principal radiation direction. In some embodiments, the at least one lens has an optical axis non-parallel to the principal radiation direction.
In some embodiments, the at least one lens has an optical axis parallel to and spaced apart from the principal radiation direction.
In some embodiments, the at least one lens comprises an axially asymmetric lens. Other aspects and features will become apparent to those ordinarily skilled in the art upon review of the following description of illustrative embodiments in conjunction with the accompanying figures.
Referring to
The inlet 112 extends along an inlet axis 116 and is therefore configured to direct fluid into the reaction chamber 104 in an inlet direction 118 that may be an extension of the inlet axis 116 into the reaction chamber 104 and may be substantially perpendicular to the longitudinal direction 106. However, the inlet direction 118 may differ in other embodiments and may, for example, be in other directions non-parallel to the longitudinal direction 106. The reaction chamber 104 has a transverse side 120 proximate the inlet 112, and a transverse side 122 opposite the transverse side 120 and opposite the inlet 112. In the embodiment shown, because the inlet direction 118 is non-parallel to the longitudinal direction 106, fluid in the reaction chamber 104 may flow faster in regions of the reaction chamber 104 that are downstream from the inlet 112 than in other regions of the reaction chamber 104, and fluid in the reaction chamber 104 may flow faster in the transverse side 122 than in the transverse side 120.
The reactor apparatus 100 includes a translucent or transparent wall 124 at the longitudinal end 108, and a translucent or transparent wall 126 at the longitudinal end 110. The reactor apparatus 100 also includes a reactor head 128 proximate the longitudinal end 108 and positioned to direct electromagnetic radiation through the translucent or transparent wall 124 and into the reaction chamber 104 from the longitudinal end 108. The reactor apparatus 100 also includes a reactor head 130 proximate the longitudinal end 110 and positioned to direct electromagnetic radiation through the translucent or transparent wall 126 and into the reaction chamber 104 from the longitudinal end 110. Therefore, the translucent or transparent walls 124 and 126 may be translucent or transparent electromagnetic radiation from different reactor heads such as those described herein, for example.
The reactor head 128 includes a UV light-emitting diode (“UV-LED”) 132, a lens 134, and a lens 136. In the embodiment shown, the lens 134 is a half-ball lens and the lens 136 is a plano-convex lens, although alternative embodiments may differ. At least some UV radiation from the UV-LED 132 may be refracted by the lens 134, at least some UV radiation refracted by the lens 134 may be refracted by the lens 136, and at least some UV radiation refracted by the lens 136 may be directed through the translucent or transparent wall 124 and into the reaction chamber 104 from the longitudinal end 108. Therefore, the UV-LED 132, the lens 134, and the lens 136 may collectively function as a UV source (or, more generally, as an electromagnetic radiation source) for a reaction chamber such as reaction chambers described herein, for example. As shown in
In general, a principal radiation direction of electromagnetic radiation may be an intensity-weighted average direction of travel of the electromagnetic radiation or may be defined in other ways. In general, electromagnetic radiation may be axially symmetric or may be axially asymmetric about its principal radiation direction.
Referring to
As shown in
As shown in
As indicated above, in the embodiment shown, fluid in the reaction chamber 104 may flow faster in regions of the reaction chamber 104 that are downstream from the inlet 112 than in other regions of the reaction chamber 104, and fluid in the reaction chamber 104 may flow faster in the transverse side 122 than in the transverse side 120. As shown in
Referring to
The UV radiation from the UV-LED 158 may be substantially axially symmetric about a principal radiation direction 168, and the optical axis 162 is substantially collinear with the principal radiation direction 168, although alternative embodiments may differ. However, the optical axis 166 is non-parallel and oblique to the principal radiation direction 168 and to the optical axis 162. In the embodiment shown, an oblique angle between the optical axis 166 and the principal radiation direction 168 (or between the optical axis 166 and a longitudinal direction of a reaction chamber, such as the longitudinal direction 106 of the reaction chamber 104, for example) may be between about 1 degree and about 45 degrees, although alternative embodiments may differ. As a result, UV radiation refracted by the lens 164 is not substantially axially symmetric about the principal radiation direction 168, but is rather skewed laterally relative to the principal radiation direction 168 and skewed laterally relative to the UV radiation refracted from the UV-LED 158. In other words, a fluence rate or local intensity of the UV radiation from the UV-LED 158 and refracted by the lenses 160 and 164 is greater on one transverse side of the principal radiation direction 168 (above the principal radiation direction 168 in the orientation of
In the embodiment of
Referring to
The UV radiation from the UV-LED 182 may be substantially axially symmetric about a principal radiation direction 192, and the optical axes 186 and 190 are parallel to and spaced apart from the principal radiation direction 192. In the embodiment shown, a separation distance between the optical axes 186 and 190 and the principal radiation direction 192 may be about 1% to about 37.5% of a diameter of the lens 184, although alternative embodiments may differ. As a result, as with the reactor head 156, UV radiation refracted by the lens 188 is not substantially axially symmetric about the principal radiation direction 192, but is rather skewed laterally relative to the principal radiation direction 192 and skewed laterally relative to the UV radiation refracted from the UV-LED 182. In other words, a fluence rate or local intensity of the UV radiation from the UV-LED 182 and refracted by the lenses 184 and 188 is greater on one transverse side of the principal radiation direction 192 (above the principal radiation direction 192 in the orientation of
Referring to
The UV radiation from the UV-LED 196 may be substantially axially symmetric about a principal radiation direction 206, and the optical axis 200 is substantially collinear with the principal radiation direction 206, although alternative embodiments may differ. However, the optical axis 204 is parallel to and spaced apart from the principal radiation direction 206 and from the optical axis 200. In the embodiment shown, a separation distance between the optical axis 204 and the optical axis 200 may be about 1% to about 37.5% of a diameter of the lens 198, although alternative embodiments may differ. As a result, as with the reactor head 156, UV radiation refracted by the lens 202 is not substantially axially symmetric about the principal radiation direction 206, but is rather skewed laterally relative to the principal radiation direction 206 and skewed laterally relative to the UV radiation refracted from the UV-LED 206. In other words, a fluence rate or local intensity of the UV radiation from the UV-LED 196 and refracted by the lenses 198 and 202 is greater on one transverse side of the principal radiation direction 206 (above the principal radiation direction 206 in the orientation of
Referring to
The reactor heads of
As another example, referring to
Therefore, the UV-LEDs 224 and 226 and the lenses 228, 232, and 236 may collectively function as a UV source (or, more generally, as an electromagnetic radiation source) for a reaction chamber such as reaction chambers described herein, for example. Further, at least some UV radiation from the UV-LED 226 may be refracted by the lens 232, at least some UV radiation refracted by the lens 232 may be refracted by the lens 236, and at least some UV radiation refracted by the lens 232 and by the lens 236 may be directed into the same reaction chamber.
The UV radiation from the UV-LED 224 may be substantially axially symmetric about a principal radiation direction 240, and the optical axis 230 is substantially collinear with the principal radiation direction 240, although alternative embodiments may differ. Further, the
UV radiation from the UV-LED 226 may be substantially axially symmetric about a principal radiation direction 242, and the optical axis 234 is substantially collinear with the principal radiation direction 242, although again alternative embodiments may differ. However, the optical axis 238 is non-parallel and oblique to the principal radiation directions 240 and 242 and to the optical axes 230 and 234. In the embodiment shown, an oblique angle between the optical axis 238 and the principal radiation directions 240 and 242 (or between the optical axis 238 and a longitudinal direction of a reaction chamber, such as the longitudinal direction 106 of the reaction chamber 104, for example) may be between about 1 degree and about 45 degrees, although alternative embodiments may differ.
As a result, as with the reactor head 156, UV radiation refracted by the lens 238 is not substantially axially symmetric about the principal radiation direction 240 or 242, but is rather skewed laterally relative to the principal radiation directions 240 and 242 and skewed laterally relative to the UV radiation refracted from the UV-LEDs 224 and 226. In other words, a fluence rate or local intensity of the UV radiation from the UV-LEDs 224 and 226 and refracted by the lenses 228, 232, and 236 is greater on one transverse side of the principal radiation directions 240 and 242 (above the principal radiation directions 240 and 242 in the orientation of
Again, the reactor head of
Further, similar to the embodiment of
The reactor heads of
Reactor heads according to other embodiments may define one or more fluid conduits that may function as inlets or outlets to reaction chambers. Further, reactor heads according to other embodiments may include more than one electromagnetic radiation emitter. For example, referring to
The electromagnetic radiation sources 258, 260, 262, 264, 266, 268, 270, and 272 may be similar to electromagnetic radiation sources as described above and as illustrated in
Referring to
The electromagnetic radiation sources 282, 284, 286, 288, 290, 292, 294, and 296 may be similar to the UV-LED 132, the lens 134, and the lens 136 shown in
Referring to
The electromagnetic radiation source 328 may be positioned along the central axis 330 so that the electromagnetic radiation sources 312, 314, 316, 318, 320, 322, 324, and 326 also surround the electromagnetic radiation source 328. Like the electromagnetic radiation sources 312, 314, 316, 318, 320, 322, 324, and 326, the electromagnetic radiation source 328 may also produce electromagnetic radiation (such as UV radiation, for example) that is substantially collimated or that diverges, and a principal radiation direction of electromagnetic radiation produced by the electromagnetic radiation source 328 may also be substantially parallel to the central axis 330 of the reactor head 310. In some embodiments, the electromagnetic radiation source 328 may be larger and/or may produce electromagnetic radiation at more power or intensity than the electromagnetic radiation sources 312, 314, 316, 318, 320, 322, 324, and 326 individually.
In general, reactor heads such as those described above may direct electromagnetic radiation (such as UV radiation, for example) into different reaction chambers of different reactor apparatuses. In some embodiments, such reaction chambers may have longitudinal ends, and such reactor heads may be positioned to direct electromagnetic radiation into such reaction chambers from one or both of such longitudinal ends.
For example, referring to
The reactor apparatus 332 also includes a reactor head 344 proximate the longitudinal end 340 and positioned to direct electromagnetic radiation into the reaction chamber 336 from the longitudinal end 340. The reactor head 344 may be similar to the reactor head 244.
Therefore, the reactor head 344 defines an inlet 346 to the reaction chamber 336 proximate the longitudinal end 340, the inlet 346 extends along an inlet axis 348, and the inlet 346 is configured to direct fluid into the reaction chamber 336 in an inlet direction that may be an extension of the inlet axis 348 into the reaction chamber 336. In the embodiment shown, the inlet axis 348 and the inlet direction are substantially collinear with or parallel to a central longitudinal axis 350 of the reaction chamber 336 extending in the longitudinal direction 338, but alternative embodiments may differ.
Fluid in the reaction chamber 336 may flow faster in regions of the reaction chamber 336 that are downstream from the inlet 346 than in other regions of the reaction chamber 336. Also, because the reactor head 344 may be similar to the reactor head 244, principal radiation directions of electromagnetic radiation sources of the reactor head 344 may also be skewed laterally towards the inlet direction and thus towards the central longitudinal axis 350 of the reaction chamber 336, as shown in
Because fluid in the reaction chamber 336 may flow faster in regions of the reaction chamber 336 that are downstream from the inlet 346 than in other regions of the reaction chamber 336, and because principal radiation directions of electromagnetic radiation sources of the reactor head 344 may be skewed laterally towards the inlet direction as shown in
The reactor body 334 also defines an outlet 352 of the reaction chamber 336 proximate the longitudinal end 342. The reaction chamber 336 therefore extends in the longitudinal direction 338 at least between the inlet 346 and the outlet 352.
The reactor apparatus 332 also includes a reactor head 354 proximate the longitudinal end 342 and positioned to direct electromagnetic radiation into the reaction chamber 336 from the longitudinal end 342. The reactor head 354 may be similar to the reactor head 280 or the reactor head 310. Therefore, electromagnetic radiation from electromagnetic radiation sources of the reactor head 354 may be substantially collimated or may be divergent, and principal radiation directions of electromagnetic radiation sources of the reactor head 354 may be substantially parallel to a central axis 356 of the reactor head 354, as shown in
Referring to
The reactor apparatus 358 also includes a reactor head 370 proximate the longitudinal end 366 and positioned to direct electromagnetic radiation into the reaction chamber 362 from the longitudinal end 366. The reactor head 370 may be similar to the reactor head 244 and defines an inlet 372 to the reaction chamber 362 proximate the longitudinal end 366. Therefore, the inlet 372 extends along an inlet axis 374, and the inlet 372 is configured to direct fluid into the reaction chamber 362 in an inlet direction that may be an extension of the inlet axis 374 into the reaction chamber 362. In the embodiment shown, the inlet axis 374 and the inlet direction are substantially collinear with or parallel to a central longitudinal axis 376 of the reaction chamber 362 extending in the longitudinal direction 364, but alternative embodiments may differ. Because the reactor head 370 may be similar to the reactor head 244, principal radiation directions of electromagnetic radiation sources of the reactor head 370 may also be skewed laterally towards the inlet direction and thus towards the central longitudinal axis 376 of the reaction chamber 362, as shown in
The reactor apparatus 358 also includes a reactor head 378 proximate the longitudinal end 368 and positioned to direct electromagnetic radiation into the reaction chamber 362 from the longitudinal end 368. The reactor head 378 may be similar to the reactor head 244 and defines an outlet 380 to the reaction chamber 362 proximate the longitudinal end 366. Therefore, the reaction chamber 362 extends in the longitudinal direction 364 at least between the inlet 372 and the outlet 380. Further, the outlet 380 extends along an outlet axis 382. In the embodiment shown, the outlet axis 382 is substantially collinear with or parallel to the central longitudinal axis 376 of the reaction chamber 362, but alternative embodiments may differ. Because the reactor head 378 may be similar to the reactor head 244, principal radiation directions of electromagnetic radiation sources of the reactor head 378 may also be skewed laterally towards the central longitudinal axis 376 of the reaction chamber 362, as shown in
Fluid in the reaction chamber 362 may flow faster in regions of the reaction chamber 362 that are downstream from the inlet 372 and that are upstream from the outlet 380 than in other regions of the reaction chamber 362. Because principal radiation directions of electromagnetic radiation sources of the reactor heads 370 and 378 may be skewed laterally towards the central longitudinal axis 376 of the reaction chamber 362, as shown in
The reactor apparatuses and reactor heads described above are examples only, and alternative embodiments may differ. For example, reactor heads according to alternative embodiments may include different combinations of one or more electromagnetic radiation emitters and one or more lenses that may skew electromagnetic radiation from the one or more electromagnetic radiation emitters laterally similarly to the embodiments described above, or in different ways.
Further, reactor apparatuses according to alternative embodiments may have one or more inlets, one or more outlets, one or more reaction chambers, and one or more reactor heads that may be similar to the embodiments described above, or that may vary in different ways. For example, reactor apparatuses according to alternative embodiments may define one or more than one reaction chamber, and may include one, two, or more than two reactor heads such as those described herein positioned to direct electromagnetic radiation into each such reaction chamber.
In general, embodiments such as those described herein may involve laterally skewed electromagnetic radiation in a reaction chamber such that UV radiation fluence rate or local intensity in the reaction chamber may, in general, be higher in regions where fluid flow velocity in the reaction chamber may also be higher, and total UV exposure to fluid flowing through the reaction chamber may be more consistent than in other reactor apparatuses without such skewed UV radiation. Such relatively more consistent total UV exposure may enhance treatment of fluid that flows in the reaction chamber and may, for example, deactivate pathogens in the fluid more effectively than in other reactor apparatuses without such skewed UV radiation.
Although specific embodiments have been described and illustrated, such embodiments should be considered illustrative only and not as limiting the invention as construed according to the accompanying claims.
Number | Date | Country | Kind |
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2980178 | Sep 2017 | CA | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CA2018/051212 | 9/25/2018 | WO | 00 |