This section is intended to introduce the reader to various aspects of art that may be related to various aspects of the present disclosure, which are described below. This discussion is believed to be helpful in providing the reader with background information to facilitate a better understanding of the various aspects of the present disclosure. Accordingly, it should be understood that these statements are to be read in this light, and not as admissions of prior art.
A wide range of applications exists for HVAC systems. For example, residential, light commercial, commercial, and industrial systems are used to control temperatures and air quality in residences and buildings. In certain HVAC systems, exhaust gases or fumes from a space being conditioned by the HVAC system are expelled to a surrounding environment via an exhaust fan unit, sometimes referred to as a laboratory exhaust unit. It is now recognized that traditional exhaust fan units may be inefficient in removing, diluting, and dispersing exhaust gas, and may be susceptible to environmental and other damage. For example, traditional exhaust fan units may not provide adequate protection against gas leakage, flow control, dilution of contaminants, and evacuation to reduce entrainment through other HVAC intake systems or direct contact. Furthermore, traditional exhaust systems may deposit contents of the exhaust gas in small, concentrated areas of the surrounding environment.
A summary of certain embodiments disclosed herein is set forth below. It should be understood that these aspects are presented merely to provide the reader with a brief summary of these certain embodiments and that these aspects are not intended to limit the scope of the disclosure. Indeed, this disclosure may encompass a variety of aspects that may be set forth below.
The present disclosure relates to an exhaust fan unit of a heating, ventilation, and/or air conditioning (HVAC) system. The exhaust fan unit includes an outer fluid path of a nozzle assembly of the exhaust fan unit defined by and between an outer wall of the nozzle assembly and an inner wall of the nozzle assembly. The exhaust fan unit also includes an inner fluid path of the nozzle assembly defined by and radially inward from the inner wall. The exhaust fan unit also includes multiple entrainment ports extending from the outer wall to the inner wall and configured to enable environmental air to pass to the inner fluid path. Each entrainment port includes a bottom surface that tapers downwardly from the inner wall to the outer wall.
The present disclosure also relates to an exhaust fan unit including an outer fluid path of a nozzle assembly of the exhaust fan unit defined by and between an outer wall of the nozzle assembly and an inner wall of the nozzle assembly. The exhaust fan unit also includes an inner fluid path of the nozzle assembly defined by and radially inward from the inner wall. The exhaust fan unit also includes a bottom surface extending radially across the inner fluid path and configured to collect liquids within the inner fluid path. The exhaust fan unit also includes entrainment ports extending from the outer wall to the inner wall and configured to enable environmental air to pass to the inner fluid path. The entrainment ports are configured to drain from the inner fluid path the liquids collected within the inner fluid path.
The present disclosure also relates to an exhaust fan unit having an outer fluid path of a nozzle assembly of the exhaust fan unit defined by and between an outer wall of the nozzle assembly and an inner wall of the nozzle assembly. The exhaust fan unit also includes an inner fluid path defined by and radially inward from the inner wall. The exhaust fan unit also includes dual-tapered shaped entrainment ports extending from the outer wall to the inner wall and configured to enable environmental air to pass to the inner fluid path.
One or more specific embodiments of the present disclosure will be described below. These described embodiments are only examples of the presently disclosed techniques. Additionally, in an effort to provide a concise description of these embodiments, all features of an actual implementation may not be described in the specification. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation-specific decisions must be made to achieve the developers' specific goals, such as compliance with system-related and business-related constraints, which may vary from one implementation to another. Moreover, it should be appreciated that such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure.
When introducing elements of various embodiments of the present disclosure, the articles “a,” “an,” and “the” are intended to mean that there are one or more of the elements. The terms “comprising,” “including,” and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
Additionally, it should be understood that references to “one embodiment” or “an embodiment” of the present disclosure are not intended to be interpreted as excluding the existence of additional embodiments that also incorporate the recited features.
The present disclosure is directed toward heating, ventilation, and/or air conditioning (HVAC) systems and, more particularly, toward an induction scheme of an exhaust fan unit.
In accordance with present embodiments, an exhaust fan unit includes a mixing box, a fan assembly, a nozzle assembly, and a wind band. The mixing box may be configured to receive exhaust fumes from an internal space of a building. In some embodiments, the mixing box may also receive external air from a surrounding environment, drawn into the mixing box via the fan assembly of the exhaust fan unit, via a Venturi effect, or both. In conditions where the mixing box receives the external air, the mixing box may mix the exhaust fumes from the internal space and the external air from the external environment. In other embodiments or operating modes, the mixing box may only receive the exhaust air from the internal space.
The fan assembly may cause the exhaust air or the mixture of exhaust air and external air to pass to the nozzle assembly of the exhaust fan unit. The nozzle assembly may include an outer flow path, such as an annulus, defined between an outer wall of the nozzle assembly and an inner wall of the nozzle assembly, where the annulus is configured to receive the exhaust air or the mixture of exhaust air passed thereto from the mixing box (e.g., by way of the fan assembly). The nozzle assembly may also include an inner cavity (or flow path) radially inward from the inner wall of the nozzle assembly. That is, the inner cavity may be fluidly separated from the annulus by the inner wall of the nozzle assembly. Entrainment points may be positioned about the nozzle assembly, extending between the outer wall and the inner wall forming the annulus, fluidly separate from the annulus defined between the inner and outer walls of the nozzle assembly. Thus, the entrainment ports may fluidly couple the inner cavity of the nozzle assembly and an external environment surrounding the nozzle assembly, while maintaining fluid separation from the annulus of the nozzle assembly. As the exhaust air or the mixed air exits a top end of the annulus of the nozzle assembly, a flow of the exhaust air or the mixed air may cause a pressure drop in the inner cavity of the nozzle assembly. The pressure drop may cause external air, referred to herein as nozzle entrained air, to pass through the entrainment ports, into the inner cavity of the nozzle assembly, and upwardly through a top end of the inner cavity. The top end of the annulus and the top end of the inner cavity may be disposed at similar axial levels at an exit end of the nozzle assembly.
A wind band may be attached to the nozzle assembly near the exit end of the nozzle assembly. The wind band may extend circumferentially or otherwise about the exit end of the nozzle assembly. As the exhaust air or the mixed air passes through the top end of the annulus of the nozzle assembly and as the nozzle entrained air passes through the top end of the inner cavity of the nozzle assembly, a flow thereof may cause a pressure drop adjacent a gap between the wind band and the nozzle assembly. The pressure drop may cause external air, referred to herein as wind band entrained air, to pass through the gap between the wind band and the nozzle assembly. The exhaust air or mixed air, the nozzle entrained air, and the wind band entrained air may mix radially inward from the wind band and then be ejected from an upper end of the wind band and into the external environment.
In accordance with present embodiments, the inner wall of the nozzle assembly, described above as defining the inner cavity of the nozzle assembly, may include a frustoconical shape, which is herein defined to include a true frustoconical shape or a shape similar to a frustoconical shape. That is, the inner surface of the inner wall of the nozzle assembly may flare, slope, or taper outwardly from an entry side of the nozzle assembly toward the exit side of the nozzle assembly. The frustoconical shape may be defined by a diameter that increases non-linearly, meaning that the diameter of the inner wall of the nozzle may increase non-linearly along an axial direction of the nozzle assembly, from a bottom of the frustoconical shape (i.e., the entry side of the nozzle assembly) upwardly. The outer wall of the nozzle assembly may include a cylindrical shape. One or both of these shapes may contribute to improved air flow performance of the exhaust fan unit. For example, a flow path of the outer flow path (e.g., annulus) defined between the inner wall and the outer wall of the nozzle assembly may include a restricted cross-sectional area, which enables a pressure drop that causes acceleration of the fluid flow through the annulus.
Further, the frustoconical shape may include a bottom or lower surface (e.g. lower horizontal surface) defining a floor of the inner cavity. The floor defining the inner cavity, and a shape of the entrainment ports of the nozzle assembly, may contribute to improved rain/liquid drainage from the nozzle assembly, which improves air flow performance and protects electronic components, such as fan assembly components and/or damper components, from rain damage. For example, the entrainment ports of the nozzle assembly may include a tapered shape (e.g., a tear-drop or leaf shape) that includes a tapered bottom surface sloping downwardly from the inner surface of the nozzle assembly to the outer surface of the nozzle assembly, thereby enabling rain collected on the horizontal floor to drain through the entrainment ports and into the external environment. It should be noted that the floor of the inner cavity may be flat or curbed. For example, the floor may form a bowl shape. These and other features will be described in detail below.
Turning now to the drawings,
The exhaust fan unit 10 includes a mixing box 18, a fan assembly 20, a nozzle assembly 22, and a wind band 24. The mixing box 18 may couple to a vent or vent system 26 extending from the internal space 14 of the building 12 toward a roof 28 of the building 12. In some embodiments, a damper 30 may be positioned between the mixing box 18 and the vent system 26, where the damper 30 is configured to open and close to enable and disable, respectively, a flow of exhaust gas to the mixing box 18. The damper 30 may also include intermediate settings that enable a certain pre-determined amount of flow therethrough. The damper 30 may be a part of the exhaust fan unit 10, or a separate component from the exhaust fan unit 10 (e.g., a part of the roof 28 or building 12 and interfaced with the exhaust fan unit 10).
The mixing box 18 also includes an outdoor air inlet 31 (e.g., hood or louver) and a damper 32 (e.g., “bypass damper”) configured to be opened and closed to enable a flow of outdoor air through the outdoor air inlet 31 and into the mixing box 18. The damper 32 may include intermediate settings that enable a certain pre-determined amount of flow therethrough under certain conditions. As shown, the damper 32 may be positioned within the mixing box 18 downstream from the outdoor air inlet 31 (e.g., hood or louver). An additional damper 33 may be disposed between the mixing box 18 and the fan assembly 20, and may be utilized to control a flow of fluid (e.g., air, exhaust gas or a mixed fluid of exhaust gas and air drawn into the mixing box 18 via the outdoor air inlet 31) from the mixing box 18 to the fan assembly 20.
The fan assembly 20, which sits above the mixing box 18 in the illustrated embodiment, may include an outer shell, such as a cylindrical outer shell, and a fan 21 disposed in the outer shell, where the fan 21 is configured to draw the flow of exhaust gases from the vent system 26 into the mixing box 18, and the flow of outdoor air through the outdoor air inlet 31 and into the mixing box 18. In some embodiments, the fan 21 may extend between the fan assembly 20 and the mixing box 18 (e.g., the fan 21 may extend partially into the mixing box 18). In certain operating conditions, the damper 32 may be closed to disable a flow of outdoor air through the outdoor air inlet 31, in which case only the exhaust gas is drawn into the mixing box 18. In other operating conditions, the damper 32 may be opened to enable a flow of outdoor air through the outdoor air inlet 31, and the outdoor air may be mixed with the exhaust gas in the mixing box 18. A combination of exhaust gas and outdoor air may be referred to herein as a “mixed fluid.” While other dampers may also be incorporated into the mixing box 18, such dampers will be described in detail with reference to later drawings.
The fan assembly 20 may pass the exhaust gas or the mixed fluid from the fan mixing box 18, through the fan assembly 20, and to the nozzle assembly 22. The nozzle assembly 22 may include an outer wall and an inner wall, an annulus positioned radially between the outer wall and the inner wall, and an inner cavity positioned radially inward from the inner wall. The annulus may be configured to receive the exhaust gas or the mixed fluid. The annulus, inner cavity, and corresponding features (e.g., outer wall and inner wall) will be illustrated and described in detail with reference to later drawings. The nozzle assembly 22 may also include multiple entrainment ports 34 extending from the outer wall of the nozzle assembly 22 to the inner wall of the nozzle assembly 22. That is, the entrainment ports 34 may be defined by structural features of the nozzle assembly 22 extending between the outer and inner walls of the nozzle assembly 22, and the entrainment ports 34 may be fluidly coupled to the inner cavity of the nozzle assembly 22. Thus, the entrainment ports 34 may define openings that fluidly couple the inner cavity of the nozzle assembly 22 with the surrounding environment 16 around the exhaust fan unit 10. Further, the entrainment ports 34 may be fluidly separated from the annulus defined radially between the inner and outer walls of the nozzle assembly 22.
The above-described annulus of the nozzle assembly may be fluidly coupled with a space above the nozzle assembly 22, defined by the wind band 24. That is, the exhaust gas or mixed fluid may empty from the annulus of the nozzle assembly 22 into a flow path defined by the wind band 24. The flow of the exhaust gas into the wind band 24 may cause a pressure drop within the inner cavity of the nozzle assembly 22, and the pressure drop may cause a flow of outside air into the cavity of the nozzle assembly 22 via the entrainment ports 34. The cavity of the nozzle assembly 22 may also empty into the flow path defined by the wind band 24. Accordingly, the outside air drawn into the cavity of the nozzle assembly 22 may exit the nozzle assembly 22 and mix with the exhaust gas or mixed fluid that exits the annulus of the nozzle assembly 22 into the flow path defined by the wind band 24.
Additionally, an entrainment gap 36 may be defined between an inner surface of the wind band 24 and the outer surface of the nozzle assembly 22. The entrainment gap 36 may operate to fluidly couple the external environment 16 with the flow path defined inside the wind band 24. Accordingly, additional outside air may be drawn into the flow path defined inside the wind band 24 via the entrainment gap 36. The additional outside air may mix with the exhaust gas or mixed fluid, and the entrained air introduced via the entrainment ports 34 as described above. An outlet 38 of the wind band 24 may enable the exhaust fan unit 10 to expel the fluids passed therein and therethrough to the surrounding environment 16.
In accordance with present embodiments, the inner wall of the nozzle assembly 22, described above as defining the cavity of the nozzle assembly 22, may include a frustoconical shape. Further, the frustoconical shape may be defined by a diameter that increases non-linearly, meaning that the diameter of the inner wall of the nozzle may increase non-linearly along an axial direction of the nozzle assembly, from a bottom of the frustoconical shape upwardly, in the illustrated embodiment. The outer wall of the nozzle assembly 22 may include a cylindrical shape or prismatic shape. These shapes, individually or together, may contribute to improved air flow performance of the exhaust fan unit 10 and corresponding fan assembly 20. Further, the frustoconical shape may include a horizontal surface, such as a horizontal bottom surface, defining a floor of the inner cavity. The horizontal floor, and a shape of the above-describe entrainment ports 34 of the nozzle assembly 22, may contribute to improved rain drainage from the nozzle assembly 22, which improves air flow performance and protects electronic components, such as components of the fan assembly 20 and/or damper 30, 32 (or other damper) components, from water damage. For example, the entrainment ports 34 of the nozzle assembly 22 may include a tear-drop or leaf shape that includes a tapered bottom surface sloping downwardly from the inner surface of the nozzle assembly 22 to the outer surface of the nozzle assembly 22, thereby enabling rain collected on the horizontal floor to drain through the entrainment ports 34 and into the external environment 16. These and other features will be described in detail below.
In the illustrated embodiment, the inner wall 50 tapers outwardly non-linearly. In other embodiments, the inner wall 50 may include a linear taper. The shape of the inner surface of the inner wall 50 may form a frustoconical shape of the inner cavity 60. The shape of the outer surface of the inner wall 50 may enable a restricted cross-sectional area of the annulus 54 (i.e., inner flow path) at the exit end 58 of the nozzle assembly 22 that causes acceleration of the exhaust fumes or mixed fluid through the annulus 54 and into the flow path 40 defined by the wind band 24.
As previously described, the nozzle assembly 22 also includes the entrainment ports 34 fluidly coupling an inner cavity 60 defined radially inward from the inner wall 50 of the nozzle assembly 22. The inner cavity 60 is fluidly separate from the annulus 54 by way of the inner wall 50. As the exhaust fumes or mixed air are passed from the annulus 54 of the nozzle assembly 22 to the flow path 40 defined by the wind band 24, a pressure drop may cause environmental air to pass through the entrainment ports 34 and into the inner cavity 60. The environmental air passing through the entrainment ports 34 may be referred to as nozzle entrained air. The dual-tapered (e.g., leaf or tear-drop shape) of the entrainment ports 34 in the illustrated embodiment may improve an air flow of the nozzle entrained air therethrough. The environmental air (i.e., nozzle entrained air) may be drawn from the inner cavity 60, through the exit side 58 of the nozzle assembly 22, and into the flow path 40 defined by the wind band 24 via the above-described pressure drop. The environmental air (i.e., nozzle entrained air) may then mix with the fluid passed from the outer annulus 54 to the flow path 40 defined by the wind band 24.
The wind band 24 may also draw environmental air through a gap between the wind band 24 and the outer wall 52 of the nozzle assembly 22, referred to as the entrainment gap 36. The environmental air drawn through the entrainment gap 36 may be referred to as wind band entrained air. The wind band entrained air may mix with the nozzle entrained air and the exhaust fumes or mixed fluid passed to the flow path 40 from the nozzle assembly 22.
In accordance with the present disclosure, an exhaust fan unit includes a nozzle assembly having an inner wall defining a cavity radially inward from the inner wall, and an outer wall that defines a flow annulus radially between the inner wall and the outer wall. Entrainment ports may also extend between the inner wall and the outer wall, defining a flow passage fluidly separate from the flow annulus and coupling the cavity of the nozzle assembly with a surrounding environment. The inner wall of the nozzle assembly, described above as defining the inner cavity of the nozzle assembly, may include a frustoconical shape. Further, the frustoconical shape may be defined by a diameter that increases non-linearly, meaning that the diameter of the inner wall of the nozzle may increase non-linearly along an axial direction of the nozzle assembly, from a bottom of the frustoconical shape upwardly. The outer wall of the nozzle assembly may include a cylindrical shape. One or both of these shapes may contribute to improved air flow performance of the exhaust fan unit. Further, the frustoconical shape may include a horizontal surface, such as a horizontal bottom surface, defining a floor of the inner cavity. The horizontal floor defining the inner cavity, and shape of the above-describe entrainment ports of the nozzle assembly, may contribute to improved rain drainage from the nozzle assembly, which improves air flow performance and protects electronic components, such as fan assembly components and/or damper components, from rain damage. For example, the entrainment ports of the nozzle assembly may include a tear-drop or leaf shape that includes a tapered bottom surface sloping downwardly from the inner surface of the nozzle assembly to the outer surface of the nozzle assembly, thereby enabling rain collected on the horizontal floor to drain through the entrainment ports and into the external environment. These and other features of the exhaust fan unit improves air flow performance of the exhaust fan unit, distribution of exhaust gas contents, rain drainage, and electronics protection.
While only certain features and embodiments have been illustrated and described, many modifications and changes may occur to those skilled in the art, such as variations in sizes, dimensions, structures, shapes and proportions of the various elements, values of parameters, such as temperatures and pressures, mounting arrangements, use of materials, colors, orientations, and so forth, without materially departing from the novel teachings and advantages of the subject matter recited in the claims. The order or sequence of any process or method steps may be varied or re-sequenced according to alternative embodiments. It is, therefore, to be understood that the appended claims are intended to cover all such modifications and changes as fall within the true spirit of the disclosure. Furthermore, in an effort to provide a concise description of the exemplary embodiments, all features of an actual implementation may not have been described, such as those unrelated to the presently contemplated best mode, or those unrelated to enablement. It should be appreciated that in the development of any such actual implementation, as in any engineering or design project, numerous implementation specific decisions may be made. Such a development effort might be complex and time consuming, but would nevertheless be a routine undertaking of design, fabrication, and manufacture for those of ordinary skill having the benefit of this disclosure, without undue experimentation.
This application is a continuation of U.S. patent application Ser. No. 16/836,671, entitled “EXHAUST FAN UNIT OF A HEATING, VENTILATION, AND/OR AIR CONDITIONING (HVAC) SYSTEM,” filed Mar. 31, 2020, which claims priority from and the benefit of U.S. Provisional Application Ser. No. 62/945,621, entitled “EXHAUST FAN UNIT OF A HEATING, VENTILATION, AND/OR AIR CONDITIONING (HVAC) SYSTEM,” filed Dec. 9, 2019, which are hereby incorporated by reference in their entireties for all purposes.
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Parent | 16836671 | Mar 2020 | US |
Child | 18100246 | US |