This disclosure is directed to a wind baffle, more particularly a wind baffle for reducing reverse torque during cross-winds, and support frames for heating, ventilation, air conditioning, and refrigeration (HVACR) system cabinets including wind baffles.
Cross-winds can cause fans within outdoor heating, ventilation, HVACR cabinets to experience reverse torque. Fan start-up, particularly with variable-speed fans, is typically at low speeds that struggle or even fail to overcome this reverse torque. This can lead to elevated temperatures within the HVACR cabinet and poor heat transfer at the heat exchanger within the HVACR cabinet. The elevated temperatures, in turn, can lead to shut down of an HVACR system and prevent operation in ambient conditions where there are high cross-winds.
This disclosure is directed to a wind baffle, more particularly a wind baffle for reducing reverse torque during cross-winds, and support frames for HVACR system cabinets including wind baffles.
A wind baffle including multiple concentric baffles provide protection from wind, allowing fans, such as variable-speed fans having low start-up power compared to their power at higher speeds, to avoid exposure to significant reverse torque. The wind baffle can be provided on a panel provided as an add-on for HVACR cabinets exposed to high cross-winds, or integrated into the HVACR cabinets themselves. Such a wind baffle can provide protection from cross-winds while providing only a small pressure drop for an exhaust fan within the HVACR cabinet, thus continuing to allow sufficient exhausting of air from a side exhaust of an HVACR cabinet without requiring additional fan power.
In an embodiment, an HVACR system includes a cabinet including a side discharge vent located on a side wall of the cabinet, a fan, located within the cabinet and at the side discharge vent, and a wind baffle located at the side discharge vent, between the fan and an ambient environment of the cabinet. The wind baffle includes a first baffle and one or more additional baffles. Each of the additional baffles surrounds one of the first baffle or one of the one or more additional baffles. Each of the plurality of concentric baffles has a leading edge at an end towards the ambient environment of the cabinet and a trailing edge at an end towards an interior of the cabinet. The leading edge has a perimeter greater than a perimeter of the trailing edge. The wind baffle also includes a support frame joining each of the plurality of the concentric baffles to the cabinet. The side wall extends vertically from a base of the cabinet to a top of the cabinet.
In an embodiment, each of the first baffle and the one or more additional baffles is straight from the leading edge of the baffle to the trailing edge of the baffle.
In an embodiment, each of the first baffle and the one or more additional baffles includes a curve between the leading edge of the baffle and the trailing edge of the baffle.
In an embodiment, the leading edge of the first baffle has a perimeter that is approximately equal to or greater than a perimeter of a trailing edge of one of the one or more additional baffles, wherein the leading edge of the one of the one or more additional baffles has a perimeter greater than the perimeter of the leading edge of the first baffle.
In an embodiment, each of the first baffle and the one or more additional baffles has a depth of at or about less than 6 inches.
In an embodiment, the one or more additional baffles includes at least two additional baffles.
In an embodiment, the first baffle includes an opening at the trailing edge.
In an embodiment, the first baffle is closed at the trailing edge.
In an embodiment, at least two of the first baffle and the one or more additional baffles have pitches that differ from one another.
In an embodiment, the fan is a variable-speed fan. In an embodiment, the variable-speed fan has a startup speed that is less than a maximum speed of the variable-speed fan and the wind baffle is configured to reduce a reverse torque applied to the variable speed fan
In an embodiment, the first baffle and each of the one or more additional baffles are concentric.
In an embodiment, a method of exhausting air from an HVACR cabinet includes drawing air within the HVACR cabinet towards a side discharge vent located on a side wall of the HVACR cabinet using a variable-speed fan and directing an exhaust from the variable-speed fan through a wind baffle located at the side discharge vent. The wind baffle includes a first baffle and one or more additional baffles. Each of the one or more additional baffles surrounds one of the first baffle or one of the one or more additional baffles. Each of the first baffle and the one or more additional baffles has a leading edge at an end towards the ambient environment of the cabinet and a trailing edge at an end towards an interior of the cabinet. The leading edge has a perimeter greater than a perimeter of the trailing edge. The wind baffle also includes a support frame joining each of the first baffle and the one or more additional baffles to the cabinet. The side wall extends vertically from a base of the cabinet to a top of the cabinet.
In an embodiment, the leading edge of the first baffle has a perimeter that is approximately equal to or greater than a perimeter of a trailing edge of one of the one or more additional baffles, wherein the leading edge of the one of the one or more additional baffles has a perimeter greater than the perimeter of the leading edge of the first baffle.
In an embodiment, the one or more additional includes at least two additional baffles.
In an embodiment, the exhaust from the variable speed fan has a pressure drop of less than at or about 0.1 inches of water across the wind baffle when directing the exhaust from the variable-speed fan through the wind baffle at the side discharge vent.
In an embodiment, drawing air within the HVACR cabinet towards a side discharge vent includes reducing a susceptibility of the variable speed fan to a reverse torque applied thereto, when the variable-speed fan is operated at a startup speed that is less than a maximum speed of the variable-speed fan.
In an embodiment, the first baffle and each of the one or more additional baffles are concentric.
This disclosure is directed to a wind baffle, more particularly a wind baffle for reducing reverse torque during cross-winds, and support frames for heating, ventilation, air conditioning, and refrigeration (HVACR) system cabinets including wind baffles.
Fans, such as variable-speed fans, can be used to direct exhaust out of an HVACR system cabinet, for example through a side discharge vent. Fan start-up, particularly with variable-speed fans, is typically at low speeds that may lack sufficient torque to overcome the fan spinning in the reverse direction. This can lead to elevated temperatures within the HVACR cabinet, for example due to poor exhausting of air that has been heated by a condenser included within the HVACR cabinet. The elevated temperatures, in turn, can reduce function at a heat exchanger in HVACR cabinet, or even lead to shut down of an HVACR system and prevent operation in ambient conditions where there are high cross-winds.
A wind baffle can be used at or near the side discharge vent to reduce pressure applied by a cross wind entering through the side discharge vent. The wind baffle may include a plurality of baffle elements configured to deflect airflow from outside the HVACR system cabinet that is flowing towards or through the side discharge vent. The plurality of baffle elements may include, for example, baffles such as conic baffles. In an embodiment, the plurality of baffle elements are arranged to overlap when viewed in a direction perpendicular to the plane of the side discharge vent. In an embodiment, the plurality of baffle elements each have the same general shape (i.e. square, rectangular, triangular, circular) and each individual baffle element differs from the other baffle elements in size. In an embodiment, each of the plurality of baffle elements are spaced evenly from one another. In an embodiment, each of the plurality of baffle elements are concentric with one another.
First baffle 102 may be the innermost baffle of the plurality of baffles included in wind baffle 100. First baffle 102 includes a leading edge (not shown) and a trailing edge 102b. The trailing edge 102b is on a side of first baffle 102 towards support frame 108, and the leading edge is opposite the trailing edge 102b. In an embodiment, the surfaces of first baffle 102 extending from the leading edge to the trailing edge 102b are straight, with no curvature along the path from a point on the leading edge to the nearest point on the trailing edge 102b. In an embodiment, the first baffle 102 has the shape of a surface of a truncated cone. In an embodiment, the surfaces of the first baffle 102 extending from the leading edge to the trailing edge 102b include a concave or convex curve along the path from a point on the leading edge to the nearest point on the trailing edge 102b. Such curvature can be seen in
In an embodiment, a center portion 114 of first baffle 102 may be open at the trailing edge of the first baffle 102. In an embodiment, the center portion 114 of first baffle 102 may be closed, for example by a flat surface extending across the trailing edge of first baffle 102. In an embodiment, center portion 114 of first baffle 102 may be enclosed by the center panel 110 of support frame 108.
In an embodiment, the trailing edge of first baffle 102 may be joined to support frame 108 at center panel 110, for example by a weld, an adhesive, or a plurality of mechanical fasteners such as screws distributed along the trailing edge 102b of first baffle 102. In an embodiment, the trailing edge of first baffle 102 may be joined to support beams 112, for example by way of a mechanical fastener such as a screw, a weld, adhesive, or any other suitable connection securing the first baffle 102 to the support beams 112.
Second baffle 104 is a baffle, having a perimeter greater than that of the first baffle 102 at an equivalent point along its depth. Second baffle 104 is outside of first baffle 102. Second baffle 104 surrounds first baffle 102. In an embodiment, second baffle 102 radially surrounds first baffle 102. Second baffle 104 includes a leading edge (not shown) and a trailing edge 104b. The trailing edge is on a side of second baffle 104 towards support frame 108, and the leading edge 104a is opposite the trailing edge. In an embodiment, the surfaces of second baffle 104 extending from the leading edge 104a to the trailing edge are straight, with no curvature along the path from a point on the leading edge 104a to the nearest point on the trailing edge. In an embodiment, the second baffle 104 has the shape of a surface of a truncated cone. In an embodiment, the surfaces of the second baffle 104 extending from the leading edge 104a to the trailing edge can include a curve along the path from a point on the leading edge to the nearest point on the trailing edge. Such curvature can be seen in
Third baffle 106 is a baffle, having a perimeter greater than that of the second baffle 104 at an equivalent point along its depth. Third baffle 106 is outside of second baffle 104. Third baffle 106 surrounds second baffle 104. In an embodiment, third baffle 106 radially surrounds second baffle 104. Third baffle 106 includes a leading edge 106a and a trailing edge 106b. The trailing edge 106b is on a side of third baffle 106 towards support frame 108, and the leading edge 106a is opposite the trailing edge. In an embodiment, the surfaces of third baffle 106 extending from the leading edge 106a to the trailing edge 106b are straight, with no curvature along the path from a point on the leading edge 106a to the nearest point on the trailing edge 106b. In an embodiment, the third baffle has the shape of a surface of a truncated cone. In an embodiment, the surfaces of the third baffle extending from the leading edge 106a to the trailing edge 106b can include a curve along the path from a point on the leading edge 106a to the nearest point on the trailing edge 106b. Such curvature can be seen in
The first, second, and third baffles 102, 104, 106 may each be concentric with one another. At least one of the first, second, and third baffles 102, 104, and 106 may have a pitch angle between a line from the leading edge to the trailing edge and a line perpendicular to the plane of support frame 108 that differs from the pitch angles of at least one of the other baffles. In an embodiment, the pitch angles of each of the first, second, and third baffles 102, 104, 106 are all the same as one another. Pitch angles and their relationships to one another can be seen in
Support frame 108 includes a center panel 110 and a plurality of support beams 112 extending from the center panel 110. In an embodiment, the support beams 112 are evenly radially distributed around center panel 110, such that the angle between any two adjacent support beams 112 is the same as the angle between any other two adjacent support beams 112. For example, the angle between each of support beams 112 may be at or about 180° in an embodiment including two support beams 112, at or about 120° in an embodiment including three support beams 112, at or about 90° in an embodiment including four support beams 112 as shown in
In an embodiment, wind baffle 100 may include two or more baffles joined to support frame 108. In an embodiment of wind baffle 100, the first baffle 102 and the second baffle 104 may be included and the third baffle 106 excluded. In an embodiment where wind baffle 100 includes more than three baffles, additional baffles can be provided outside of the third baffle 106. In this embodiment, the additional baffles beyond third baffle in 106 are each larger in perimeter at a leading edge than the preceding baffle at its leading edge. In this embodiment, the additional baffles are also concentric with all of the other baffles of the wind baffle 100, including first baffle 102.
Each of first, second, and third baffles 102, 104, 106, and the support frame 108 may include one or more metals or alloys, for example, aluminum or steel. Each of first, second, and third baffles 102, 104, 106, and the support frame 108 may include one or more plastics. In an embodiment, all of first, second, and third baffles 102, 104, 106, and the support frame 108 are made of the same material. In an embodiment, at least one of first, second, and third baffles 102, 104, 106, and the support frame 108 includes materials different from the other components of wind baffle 100.
HVACR system cabinet 200 may be a cabinet surrounding one or more components of an HVACR system, such as a residential heat pump, air conditioner, refrigerator, ventilation system, or the like. In an embodiment, HVACR system cabinet 200 is an outdoor cabinet for an air conditioner system. In an embodiment, HVACR system cabinet 200 contains at least one of a compressor and an evaporator (not shown).
Wind baffle 202 may be, for example, the wind baffle 100 described above. Wind baffle 202 includes a first baffle 204, a second baffle 206, a third baffle 208, and support beams 210 of a support frame, the ends of which are visible in the view shown in
In
Support beams 210 are part of a support frame (not shown), obscured by the first, second, and third baffles 204, 206, 208 in the view shown in
The ends of support beams 210 may be fixed to an exterior of the HVACR system cabinet 200, for example at connection points 212 distributed on the HVACR system cabinet 200 surrounding the side discharge vent. Connections between the support beams 210 and the HVACR system cabinet 200 may be any suitable mechanical connection to secure the wind baffle 202 in place relative to HVACR system cabinet 200, for example, welds, or screws or other mechanical fasteners.
Side discharge vent 302 is an opening in a side wall of HVACR system cabinet 300 allowing airflow to be directed out of the HVACR system cabinet 300. The side discharge vent 302 permits exhaust of air out of the HVACR system cabinet 300. The side discharge vent 302 permits the exhaust to leave the HVACR system cabinet 300 on a side of the HVACR system cabinet. For example, air heated by heat exchange with a condenser located within the HVACR system cabinet 300 can be discharged through the side discharge vent 302. The condenser can be an outdoor heat exchanger included in a refrigeration circuit. In an embodiment, a plane of the side discharge vent 302 is substantially vertical. In an embodiment, side discharge vent 302 is circular in shape. In an embodiment, the side discharge vent can be another shape, for example, square. In an embodiment, side discharge vent 302 is located centrally on a side wall of HVACR system cabinet 300. Side discharge vent 302 may include a mount for fan 304. Side discharge vent 302 is disposed on a side wall of the HVACR system cabinet. The side wall of the HVACR system cabinet 300 extends vertically from a base of the HVACR system cabinet 300 to a top of the HVACR system cabinet 300.
Fan 304 is a fan located within the HVACR system cabinet 300. Fan 304 may be located in the path of airflow through the side discharge vent 302. Fan 304 may be configured to direct air out of HVACR system cabinet 300 by way of side discharge vent 302. In an embodiment, the blades of fan 304 are oriented to drive air outwards with respect to HVACR system cabinet 300 when rotating in their normal direction. Airflow entering the HVACR system cabinet 300 through side discharge vent 302, such as a cross-wind, may apply force to the blades of fan 304, producing a torque opposite the direction of rotation of fan 304. Fan 304 may be powered by an electric motor. Fan 304 may be a variable-speed fan. In an embodiment, fan 304 is controlled by a variable speed drive. In an embodiment, starting operations of fan 304 occur at speeds below the maximum speed of fan 304.
Wind baffle 306 is a wind baffle joined to the HVACR system cabinet 300, for example, wind baffle 100 described above and shown in
The wind baffle 306 may further include a support frame, such as the support frame 108 described above for wind baffle 100, including center panel 110 and support beams 112. The support frame may be provided on a trailing edge side of the wind baffle 306. The support beams of the support frame may extend past a perimeter of the side discharge vent 302 when the center of the support frame is centered within the side discharge vent 302. The portion of each support beam extending past the side discharge vent 302 may include a connection point to the HVACR system cabinet 300. Connections between the support beams and the HVACR system cabinet 300 may be any suitable mechanical connection to secure the wind baffle 306 in place relative to the side discharge vent 302. Connections at those connection points may include, for example, adhesives, welds, screws or other mechanical fasteners or any other suitable connection of the wind baffle 306 to the HVACR system cabinet 300.
HVACR cabinet 400 is a cabinet containing part of an HVACR system, for example an outdoor unit of a refrigeration circuit. The HVACR cabinet 400 can contain a condenser which rejects heat to air within the HVACR cabinet 400. HVACR cabinet 400 includes heat exchanger 412.
Side discharge vent 402 is an opening in a side wall of HVACR system cabinet 400. Side discharge vent 402 allows airflow to be directed out of the HVACR system cabinet 400. The side discharge vent 402 permits exhaust of air out of the HVACR system cabinet 400. For example, air heated by heat exchange with a condenser located within the HVACR system cabinet 400 can be discharged through the side discharge vent 402. The condenser can be an outdoor heat exchanger included in a refrigeration circuit. In an embodiment, a plane of the side discharge vent 402 is substantially vertical. In an embodiment, side discharge vent 402 is circular in shape. In an embodiment, the side discharge vent can have another shape, for example square. In an embodiment, side discharge vent 402 is located centrally on a side wall of HVACR system cabinet 400. Side discharge vent 402 may include a mount for fan 404. Side discharge vent can be, for example, circular or square in shape.
Fan 404 is a fan configured to draw air within HVACR system cabinet 400 and exhaust air towards the side discharge vent 402. Fan 404 can be a variable-speed fan. Fan 404 can be powered by an electric motor. In an embodiment, the blades of fan 404 are oriented to drive air outwards with respect to HVACR system cabinet 400 when rotating in their normal direction. Airflow entering the HVACR system cabinet 400 through side discharge vent 402, such as a cross-wind, may apply force to the blades of fan 404, producing a torque opposite the direction of rotation of fan 404. In an embodiment, fan 404 is controlled by a variable speed drive. In an embodiment, starting operations of fan 404 occur at speeds below the maximum speed of fan 404. Fan 404 can draw air through heat exchanger 412 as it exhausts air through side discharge vent 402.
First concentric baffle 406 has a leading edge 406a and a trailing edge 406b. Leading edge 406a is located at the end of the first concentric baffle 406 that is towards the ambient environment surrounding HVACR system cabinet 400. Leading edge 406a has a width LLE1. Trailing edge 406b is located at the end of first concentric baffle 406 that is towards fan 404. Trailing edge 406b has a width LTE1. Trailing edge 406b has a perimeter that is smaller than the perimeter of leading edge 406a. The distance from leading edge 406a to trailing edge 406b in a direction perpendicular to the side wall of HVACR cabinet 400 including side discharge vent 402 is the depth D1. An angle between first concentric baffle 406 and the plane of the side wall of HVACR system cabinet 400 including the side discharge vent 402 is the pitch P1.
Second concentric baffle 408 surrounds first concentric baffle 406. Second concentric baffle 408 is concentric with first concentric baffle 406. Second concentric baffle 408 has a leading edge 408a and a trailing edge 408b. Leading edge 408a is located at the end of the second concentric baffle 408 that is towards the ambient environment surrounding HVACR system cabinet 400. Leading edge 408a has a width LLE2. Trailing edge 408b is located at the end of second concentric baffle 408 that is towards fan 404. Trailing edge 408b has a width LTE2. Trailing edge 408b has a perimeter that is smaller than the perimeter of leading edge 408a. The distance from leading edge 408a to trailing edge 408b in a direction perpendicular to the side wall of HVACR cabinet 400 including side discharge vent 402 is the depth D2. An angle between second concentric baffle 408 and the plane of the side wall of HVACR system cabinet 400 including the side discharge vent 402 is the pitch P2.
Third concentric baffle 410 surrounds first concentric baffle 406 and second concentric baffle 408. Third concentric baffle 410 is concentric with first concentric baffle 406 and second concentric baffle 408. Third concentric baffle 410 has a leading edge 410a and a trailing edge 410b. Leading edge 410a is located at the end of the third concentric baffle 410 that is towards the ambient environment surrounding HVACR system cabinet 400. Leading edge 410a has a width LLE3. Trailing edge 410b is located at the end of third concentric baffle 410 that is towards fan 404. Trailing edge 410b has a width LTE3. Trailing edge 410b has a perimeter that is smaller than the perimeter of leading edge 410a. The distance from leading edge 410a to trailing edge 410b in a direction perpendicular to the side wall of HVACR cabinet 400 including side discharge vent 403 is the depth D3. An angle between third concentric baffle 410 and the plane of the side wall of HVACR system cabinet 400 including the side discharge vent 402 is the pitch P3.
The widths of the leading edges 406a, 408a, and 410a and the trailing edges 406b, 408b, and 410b can be selected such that LLE1≥LTE2 and LLE2≥LTE3. In an embodiment where side discharge vent 402 is circular in shape, each of the widths is a diameter. The widths of the 406a, 408a, and 410a and the trailing edges 406b, 408b, and 410b can be such that the perimeter of first concentric baffle leading edge 406a is greater than or substantially equal to the perimeter of second concentric baffle trailing edge 408b, and the perimeter of second concentric baffle leading edge 408a is greater than or substantially equal to the perimeter of third concentric baffle trailing edge 410b.
In an embodiment, each of the concentric baffles 406, 408, 410 can have depths that are substantially equal to one another. In an embodiment, at least some of the depths may vary among the first, second, and third concentric baffles 406, 408, 410. In an embodiment D1<D2≈D3, as shown in
In an embodiment, each of the concentric baffles 406, 408, 410 have pitch angles substantially equal to one another. In an embodiment, at least some of the pitch angles vary among the first, second, and third concentric baffles 406, 408, 410. In an embodiment, P1<P2≈P3, as shown in
Heat exchanger 412 can form a portion of the wall of HVACR cabinet 400. Heat exchanger 412 is a heat exchanger that allows air to flow into HVACR cabinet 400. In heat exchanger 412, a refrigerant exchanger heat with the air flowing through heat exchanger 412 into the HVACR cabinet 400. In an embodiment, heat exchanger 412 forms part of a wall of HVACR cabinet 400 that is opposite the wall including side discharge vent 402. Heat exchanger 412 can be, for example a tube-and-fin heat exchanger. Air that has exchanged heat at heat exchanger 412 can be the air that is exhausted through side discharge vent 402.
Further, pressure drop across wind baffles according to embodiments was also modeled at an ambient dry bulb temperature of 120 F and a wet bulb temperature of 80 F, while operating a standard fan for the HVACR cabinet at 1000 revolutions per minute. Modeled under these conditions, the pressure drop being less than at or about 0.1 inches of water. In an embodiment, the modeled pressure drop was at or about 0.02 inches of water. The low pressure drop across wind baffles according to embodiments indicates that wind baffles according to embodiments do not provide undue to excessive resistance to exhaust from the HVACR cabinet.
Aspects:
It is understood that any of aspects 1-12 can be combined with any of aspects 13-18.
Aspect 1. A heating, ventilation, air conditioning and refrigeration (HVACR) system, comprising:
a first baffle;
one or more additional baffles, wherein each of the one or more additional baffles surrounds the first baffle or one of the one or more additional baffles, and
a support frame, fixed to an exterior of the cabinet, the support frame joining each of the first baffle and the one or more additional baffles to the cabinet.
Aspect 2. The HVACR system according to aspect 1, wherein each of the first baffle and the one or more additional baffles is straight from the leading edge of the baffle to the trailing edge of the baffle.
Aspect 3. The HVACR system according to aspect 1, wherein each of the first baffle and the one or more additional includes a curve between the leading edge of the baffle and the trailing edge of the baffle.
Aspect 4. The HVACR system according to any of aspects 1-3, wherein the leading edge of the first baffle has a perimeter that is approximately equal to or greater than a perimeter of a trailing edge of one of the one or more additional baffles, wherein the leading edge of the one of the one or more additional baffles has a perimeter greater than the perimeter of the leading edge of the first baffle.
Aspect 5. The HVACR system according to any of aspects 1-4, wherein each of the first baffle and the one or more additional baffles has a depth of at or about less than 6 inches.
Aspect 6. The HVACR system according to any of aspects 1-5, wherein the one or more additional baffles includes at least two additional baffles.
Aspect 7. The HVACR system according to any of aspects 1-6, wherein the first baffle includes an opening at the trailing edge.
Aspect 8. The HVACR system according to any of aspects 1-6, wherein the first baffle of the plurality of concentric baffles is closed at the trailing edge.
Aspect 9. The HVACR system according to any of aspects 1-8, wherein at least two of the first baffle and the one or more additional baffles have pitch angles that differ from one another.
Aspect 10. The HVACR system according to any of aspects 1-9, wherein the fan is a variable-speed fan.
Aspect 11. The HVACR system according to aspect 10, wherein the wind baffle is configured to reduce a susceptibility of the variable speed fan to a reverse torque applied thereto, when the variable-speed fan has a startup speed that is less than a maximum speed of the variable-speed fan.
Aspect 12. The HVACR system according to any of aspects 1-11, wherein the first baffle and each of the one or more additional baffles are concentric.
Aspect 13. A method of exhausting air from an HVACR cabinet, comprising:
a support frame joining each of the first baffle and the one or more additional baffles to the cabinet, and the side wall extends vertically from a cabinet base to a cabinet top.
Aspect 14. The method according to aspect 13, wherein the leading edge of the first has a perimeter that is approximately equal to or greater than a perimeter of one of the one or more additional baffles, wherein the leading edge of the one of the one or more additional baffles has a perimeter greater than the perimeter of the leading edge of the first baffle.
Aspect 15. The method according to any of aspects 13-14, wherein the one or more additional baffles includes at least two additional baffles.
Aspect 16. The method according to any of aspects 13-15, wherein the exhaust from the variable speed fan has a pressure drop of less than at or about 0.1 inches of water across the wind baffle when directing the exhaust from the variable-speed fan through the wind baffle at the side discharge vent.
Aspect 17. The method according to any of aspects 13-16, wherein drawing air within the HVACR cabinet towards a side discharge vent includes reducing a susceptibility of the variable speed fan to a reverse torque applied thereto, when the variable-speed fan is operated at a startup speed that is less than a maximum speed of the variable-speed fan
Aspect 18. The method according to any of aspects 13-17, wherein the first baffle and each of the one or more additional baffles are concentric.
The examples disclosed in this application are to be considered in all respects as illustrative and not limitative. The scope of the invention is indicated by the appended claims rather than by the foregoing description; and all changes which come within the meaning and range of equivalency of the claims are intended to be embraced therein.
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