Patent Application
20200378291
The present subject matter relates generally to the treatment of engine exhaust gases, and more particularly, to exhaust treatment systems of work vehicles for reducing the amount of damage occurring to an exhaust sensor, such as a nitrous oxide (NOx) sensor, due to water impingement. In addition, the present subject matter relates to flow mixer configurations for use within an exhaust treatment system for a work vehicle.
Typically, work vehicles, such as tractors and other agricultural vehicles, include an exhaust treatment system for controlling engine emissions. As is generally understood, exhaust treatment systems for work vehicles often include a diesel oxidation catalyst (DOC) system in fluid communication with a selective catalytic reduction (SCR) system. The DOC system is generally configured to oxidize carbon monoxide and unburnt hydrocarbons contained within the engine exhaust and may include a mixing chamber for mixing an exhaust reductant, such as a diesel exhaust fluid (DEF) or any other suitable urea-based fluid, into the engine exhaust. For instance, the exhaust reductant is often pumped from a reductant tank mounted on and/or within the vehicle and injected onto the mixing chamber to mix the reductant with the engine exhaust. The resulting mixture may then be supplied to the SCR system to allow the reductant to be reacted with a catalyst in order to reduce the amount of nitrous oxide (NOx) emissions contained within the engine exhaust. A NOx sensor is typically positioned downstream of the SCR system to monitor the amount of NOx emissions still remaining in the exhaust flow existing the exhaust treatment system. The data from the sensor may, for example, be used to control the combustion temperature of the engine and/or the amount of reductant injected into the mixing chamber to ensure that the amount of NOx emissions remains below a given amount.
In many instances, condensate water will accumulate within one or more of the components of the exhaust treatment system, such as within the SCR system. When this occurs, water droplets can be released with the flow of exhaust gases exiting the SCR system. These water droplets often impinge onto the downstream NOx sensor, leading to sensor damage and/or failure due to the thermal shock caused by the sudden drop in temperature along the external surface of the sensor. To alleviate this problem, sensor deflectors have been developed that are configured to be positioned immediately upstream of a NOx sensor to shield the sensor from water impingement. However, such solutions tend to reduce the accuracy of the sensor readings due to the substantial disruption of the exhaust flow near the sensor caused by the deflector.
Accordingly, improved systems for reducing the amount of water damage occurring to an exhaust sensor positioned downstream of an engine exhaust treatment system would be welcomed in the technology.
Aspects and advantages of the invention will be set forth in part in the following description, or may be obvious from the description, or may be learned through practice of the invention.
In one aspect, the present subject matter is directed to an exhaust treatment system for a work vehicle. The system includes a selective catalytic reduction (SCR) system configured to react a mixture of exhaust reductant and engine exhaust with a catalyst to generate a treated exhaust flow, with the SCR system including an SCR outlet for expelling the treated exhaust flow therefrom. The system also includes a flow conduit in fluid communication with the SCR outlet for receiving the treated exhaust flow expelled from the SCR system and an exhaust sensor positioned within the flow conduit downstream of the SCR outlet. The exhaust sensor is configured to detect an amount of an emission gas present in the treated exhaust flow. Additionally, the system includes a flow mixer positioned upstream of the exhaust sensor. The flow mixer includes first and second sets of swirler vanes configured to impart a spiraling flow trajectory to the treated exhaust flow flowing between the SCR outlet and the exhaust sensor, with the first set of swirler vanes being spaced radially from the second set of swirler vanes.
In another aspect, the present subject matter is directed to an exhaust treatment system for a work vehicle. The system includes a selective catalytic reduction (SCR) system configured to react a mixture of exhaust reductant and engine exhaust with a catalyst to generate a treated exhaust flow, with the SCR system including an SCR outlet for expelling the treated exhaust flow therefrom. The system also includes a flow conduit in fluid communication with the SCR outlet for receiving the treated exhaust flow expelled from the SCR system, and an exhaust sensor positioned within the flow conduit downstream of the SCR outlet. The exhaust sensor is configured to detect an amount of an emission gas present in the treated exhaust flow. In addition, the system includes a flow mixer positioned upstream of the exhaust sensor. The flow mixer includes first and second sets of swirler vanes configured to impart counter-spiraling flow trajectories to radially inner and outer portions of the treated exhaust flow being directed through the flow mixer.
In a further aspect, the present subject matter is directed to a flow mixer for use within an exhaust treatment system of a work vehicle. The flow mixer includes an outer housing extending between an upstream end of the flow mixer and a downstream end of the flow mixer. In addition, the flow mixer includes an inner flow divider spaced radially inwardly from the outer housing, a first set of swirler vanes extending radially inwardly from the inner flow divider, and a second set of swirler vanes extending radially between the outer housing and the inner flow divider. The first set of swirler vanes is oriented in one of a clockwise helical pattern or a counterclockwise helical pattern and the second set of swirler vanes is oriented in the other of the clockwise helical pattern or the counterclockwise helical pattern such that the first and second sets of swirler vanes are configured to impart counter-spiraling flow trajectories to radially inner and outer portions of an exhaust flow directed through the flow mixer.
These and other features, aspects and advantages of the present invention will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
A full and enabling disclosure of the present invention, including the best mode thereof, directed to one of ordinary skill in the art, is set forth in the specification, which makes reference to the appended figures, in which:
Reference now will be made in detail to embodiments of the invention, one or more examples of which are illustrated in the drawings. Each example is provided by way of explanation of the invention, not limitation of the invention. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope or spirit of the invention. For instance, features illustrated or described as part of one embodiment can be used with another embodiment to yield a still further embodiment. Thus, it is intended that the present invention covers such modifications and variations as come within the scope of the appended claims and their equivalents.
In general, the present subject matter is directed to an exhaust treatment system for a work vehicle. In several embodiments, the system includes a flow mixer adapted to reduce the amount of water droplet damage occurring to an exhaust sensor, such as a nitrous oxide (NOx) sensor, positioned downstream of an selective catalytic reduction (SCR) system of the exhaust treatment system. For example, the flow mixer may be positioned adjacent to the outlet of the SCR system at a location upstream of the exhaust sensor such that the mixer imparts a spiraling flow trajectory to the flow of treated exhaust expelled from the SCR system. In one embodiment, the flow mixer is configured to impart counter-spiraling flows trajectories to the treated exhaust flow such that both a radially inner spiraling flow and a radially outer spiraling flow of the treated exhaust is directed downstream of the mixer towards the exhaust sensor. Such counter-spiraling flows may facilitate enhanced mixing of the treated exhaust immediately upstream of the exhaust sensor, thereby allowing the sensor to provide more accurate data related to the concentration or amount of the gaseous emission(s) being monitored (e.g., NOx). In addition, the counter-spiraling flows may help facilitate evaporation of any water droplets contained within the treated exhaust and/or may help contain water droplets within the center of the flow of treated exhaust, thereby reducing the likelihood of such water droplets impinging on or otherwise contacting the exhaust sensor.
In accordance with aspects of the present subject matter, the disclosed mixer is positioned relative to SCR outlet to promote improved mixing and turbulence within the flow conduit extending downstream of the SCR outlet, particularly within the area of the conduit extending between the SCR outlet and the location of the downstream exhaust sensor. Specifically, in one or more embodiments of the present subject matter, the mixer is configured to create a highly turbulent flow within a central or radially inner region of the flow conduit, with such turbulent flow having an increased flow velocity relative to the remainder of the treated exhaust flow being directed through the conduit. This highly turbulent flow facilitates the primary break-up of water droplets contained within the treated exhaust by increasing the Weber number (We) associated with the water droplets and also promotes the secondary break-up or atomization of the water droplets by reducing the characteristic atomization timescale. Such improved droplet break-up and atomization results in smaller droplet sizes within the flow conduit. Moreover, the improved mixing and higher turbulence enhances the evaporation of the remaining droplets. Accordingly, the combined effect results in a significant reduction in the probability of large droplets being present downstream of the mixer (e.g., at or adjacent to the location of the exhaust sensor), and, thus, by extension, a substantial reduction in the likelihood of sensor failure or damage due to water droplets impinging on or otherwise contacting the exhaust sensor.
It should be appreciated that, although the disclosed flow mixer is generally described herein with reference to mixing/spiraling the flow of exhaust gases directed between the SCR system and a downstream exhaust sensor to reduce the likelihood of damage occurring to the sensor due to impingement by water droplets, the flow mixer may also be utilized in one or more other locations within an exhaust treatment system and/or may be configured to serve one or more functions within the system. For instance, in addition to being located between the SCR system and the downstream exhaust sensor (or as an alternative thereto), the flow mixer may be positioned within a mixing conduit extending downstream of a DOC system of the exhaust treatment system. In such an embodiment, the flow mixer may be used to impart counter-spiraling flow trajectories to the reductant/exhaust flow expelled from the DOC system to facilitate proper mixing of the reductant and engine exhaust prior to such flow being directed into the downstream SCR system.
Referring now to the drawings,
As shown in
Moreover, the work vehicle 100 may also include an exhaust treatment system 200 for reducing the amount emissions contained within the exhaust from the engine 114. For instance, engine exhaust expelled from the engine 114 may be directed through the exhaust treatment system 200 to allow the levels of nitrous oxide (NOx) emissions contained within the exhaust to be reduced significantly. The cleaned or treated exhaust gases may then be expelled from the exhaust treatment system 200 into the surrounding environment via an exhaust pipe 120 of the work vehicle 100.
It should be appreciated that the configuration of the work vehicle 100 described above and shown in
Referring now to
Additionally, as shown in
Moreover, the exhaust treatment system 200 may also include a flow mixer 300 positioned at or adjacent to the outlet 230 of the SCR system 208. As will be described in greater detail below, the flow mixer 300 may be configured to impart a rotating or spiraling flow trajectory to the treated exhaust flow expelled from the SCR system 208. For example, in several embodiments, the flow mixer 300 may be configured to generate counter-spiraling flows of the treated exhaust within the downstream flow conduit 210. Such counter-spiraling flows may facilitate enhanced mixing of the treated exhaust immediately upstream of the exhaust sensor 250, thereby allowing the sensor 250 to provide more accurate data related to the concentration or amount of the gaseous emission(s) being monitored (e.g., NOx). In addition, the counter-spiraling flows may help facilitate evaporation of any water droplets contained within the treated exhaust and/or may help contain water droplets within the center of the flow of treated exhaust through the downstream flow conduit 210, thereby reducing the likelihood of such water droplets impinging on or otherwise contacting the exhaust sensor 250.
Referring now to
As indicated above, in several embodiments, the flow mixer 300 is configured to be positioned at or adjacent to the outlet 230 of the SCR system 208. For example, in the illustrated embodiment, the flow mixer 300 is positioned immediately at the interface between the SCR outlet 230 and an adjacent upstream end 232 of the flow conduit 210. However, in other embodiments, the flow mixer 300 may be positioned at any other suitable location relative to the SCR outlet 230, such as at a location upstream of the interface between the SCR outlet 230 and the upstream end 232 of the flow conduit 210 or at a location downstream of the interface and upstream of the exhaust sensor 250.
Additionally, as shown in
In several embodiments, the flow mixer 300 may be configured to generate counter-spiraling flows of the treated exhaust as the exhaust is directed through the mixer 300 such that the downstream flow profile of the treated exhaust includes a central or radially inner flow region 270 having a flow trajectory that spiral or rotates in a first direction (e.g., clockwise or counterclockwise) and a radially outer flow region 272 having a flow trajectory that spirals or rotates in the opposite direction (e.g., the other of the clockwise or counterclockwise direction). Specifically, in the embodiment shown in
In addition, the shear boundary created between the inner and outer flow regions 270, 272 serves to prevent or reduce the likelihood that any water droplets contained within the inner flow region 270 flow into the outer flow region 272 downstream of the mixer 300. As a result, the outer flow region 272 may correspond to a radial space within the flow conduit 202 of reduced water impingement probability. In this regard, as particularly shown in
Moreover, the highly turbulent flow created within the inner flow region of the flow conduit 202 will typically include an increased flow velocity relative to the remainder of the treated exhaust flow being directed through the conduit 202. This highly turbulent flow facilitates the primary break-up of water droplets contained within the treated exhaust by increasing the Weber number (We) associated with the water droplets and also promotes the secondary break-up or atomization of the water droplets by reducing the characteristic atomization timescale. Such improved droplet break-up and atomization results in smaller droplet sizes within the flow conduit and the higher turbulence enhances the evaporation of the remaining droplets. Accordingly, the likelihood of water droplets impinging against the exhaust sensor 250 may be reduced significantly, thereby reducing the potential for sensor damage due to such water droplet impingements.
Referring now to
As particularly shown in
Additionally, as shown in the illustrated embodiment, first and sets of circumferentially spaced swirler vanes are positioned within the inner and outer flows areas 312, 310 of the mixer 300, respectively. Specifically, the flow mixer 300 includes a plurality of first swirler vanes 320 extending radially inwardly from the inner flow divider 308 within the inner flow area 312 of the mixer 300. Additionally, the flow mixer 300 includes a plurality of second swirler vanes 330 extending radially between the outer housing 302 and the inner flow divider 308 within the outer flow area 310 of the mixer 300. As shown in the illustrated embodiment, each first swirler vane 320 includes an upstream edge 322 (e.g., as indicated by dashed lines in
In several embodiments, each swirler vane 320, 330 may be configured to define a spiral-like profile between its upstream and downstream edges 322, 332, 324, 334. Specifically, each swirler vane 320, 330 may spiral circumferentially as the vane extends axially between its upstream and downstream edges 322, 332, 324, 334. As a result, each set of swirler vanes 320, 330 may define a spiraling or helical pattern within its respective flow area 310, 312 of the mixer 300. This helical pattern may allow the swirler vanes 320, 330 to impart a spiraling flow trajectory to the treated exhaust as it flows through the mixer 300.
In several embodiments, the first set of swirler vanes 320 may define a spiraling or helical pattern that is oriented in an opposite direction than the spiraling or helical pattern defined by the second set of swirler vanes 330. For example, as shown in the illustrated embodiment, the first swirler vanes 320 spiral in a clockwise direction (as viewed in
As particularly shown in
It should be appreciated that, although the mixer configuration shown in
This written description uses examples to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal languages of the claims.
