Patent Grant
9909765
The present disclosure relates generally to exhaust systems, and, more particularly, to systems, methods, and devices for retrofitting short-circuit exhaust hoods to improve performance thereof.
Short-circuit exhaust hoods direct air from an air source toward an exhaust air intake within the recess of the hood to be exhausted together with a load from a fume source. The short-circuit system involves an air source that supplies and directs conditioned air, unconditioned air (typically referred to as make-up air), or a combination thereof into the exhaust hood recess in order to enhance capture and energy efficiency. Short-circuit exhaust hoods have been widely adopted in commercial kitchens due to at least two different motivations. First, it is believed that short-circuit exhaust hoods are more energy efficient than their non-short-circuit counterparts because part of the required exhaust air supply is satisfied with unconditioned air. Second, codes that required a minimum amount of air (in cubic feet per minute (cfm)) to be exhausted from kitchens could be circumvented by the use of short-circuit hoods.
However, most short-circuit hoods simply do not work very well, especially in view of their complexity and cost. In particular, short-circuit hoods have at least two air passages (e.g., one for exhausting fumes and another for introducing make-up air into the exhaust recess) and potentially more than two air passages (e.g., an additional one for introducing conditioned air into the vicinity of the exhaust hood to enhance employee comfort). Despite this added complexity, short-circuit systems have not been able to reduce the volume of conditioned air needed to achieve full capture and containment of a fume load under certain conditions. In fact, a short-circuit system may actually increase the amount of conditioned air that is exhausted. To operate effectively, an exhaust blower or fan for the exhaust hood must operate at a higher speed than if the short-circuit system was not present due to the need to remove not only the effluent-laden air but also the make-up air from the short-circuit supply. Make-up air may also increase turbulence in the vicinity of the fume source, which may increase the volume of conditioned air that is entrained in the effluent, thereby increasing the amount of exhaust required.
Exhaust hood methods, devices, and systems are disclosed herein that improve the performance of short-circuit hoods. Such improvements can be provided relatively inexpensively by utilizing existing features of the structure of short-circuit hoods. The resulting enhancement in performance may exceed that of a regular exhaust hood while avoiding the pitfalls associated with make-up air injection into the exhaust hood recess. In embodiments of the disclosed subject matter, the components of the short-circuit system that inject make-up and/or conditioned air into the exhaust hood recess can be converted into a combination of horizontal and vertical jets at a lower edge of the exhaust hood. Such conversion may be accomplished by installing a retrofit jet generator or plenum into the short-circuit system outlets. The jet generator may include a sheet metal blank with a series of openings that generate the combination of horizontal and vertical jets at a lower edge of the exhaust hood when air from the make-up air or conditioned air source is supplied thereto.
In embodiments, a closed circuit exhaust hood can have an exhaust-buffering recess and a make-up air discharge configured to direct make-up air from a source directly into the hood recess. A method for improving the performance of a closed circuit exhaust hood can include lowering a total volume of air injected into the hood recess by blocking discharge of the make-up air from the source into the hood recess except through at least one opening having a width of no more than 8 mm, and regulating a pressure in air channels leading to the at least one opening to a pressure of approximately 0.2 to 0.5 in water gauge. An initial velocity of the make-up air discharged from the at least one opening can be at least 4 m/s.
In embodiments, a kitchen exhaust can have an exhaust-buffering recess. A make-up air discharge can be configured to direct make-up air directly into the hood recess. A conditioned air discharge can be configured to generate a conditioned air curtain at a forward edge of the hood. The make-up air discharge can have a make-up air discharge opening connected to a make-up air plenum that receives air from a make-up supply through a make-up air intake collar. The conditioned air discharge can have a conditioned air discharge opening connected to a conditioned air plenum that receives air from a conditioned air supply through a conditioned air intake collar. The make-up air and conditioned air intake collars can have volume control dampers fitted thereto. A method for modifying the kitchen exhaust can include removing grills covering the make-up air and conditioned air discharge openings, and affixing a jet generator over the conditioned air and make-up air discharge openings. The jet generator can have vertical and horizontal faces and can define a jet plenum portion that, once affixed, extends into the hood recess in a horizontal direction to permit air from the make-up air plenum to flow to a lower end of the hood. Each of the vertical and horizontal faces can have at least one opening therein. The at least one opening in the horizontal face can face downwardly and be located at the lower end of the hood once the plenum is affixed. The openings in the vertical and horizontal faces can be located to receive air from the jet plenum portion such that vertical and horizontal jets are generated from the received air.
In embodiments, a kitchen exhaust can have an exhaust-buffering recess. A make-up air discharge can be configured to direct make-up air directly into the hood recess. A conditioned air discharge can be configured to generate a conditioned air curtain at a forward edge of the hood. The make-up air discharge can have a make-up air discharge opening connected to a make-up air plenum that receives air from a make-up supply through a make-up air intake collar. The conditioned air discharge can have a conditioned air discharge opening connected to a conditioned air plenum that receives air from a conditioned air supply through a conditioned air intake collar. The make-up air and conditioned air intake collars can have volume control dampers fitted thereto. A method for modifying the kitchen exhaust can include disconnecting the make-up air intake collar from the make-up air supply, removing the make-up air volume control damper, fitting a fan to the make-up air collar, removing the make-up air and conditioned air discharge grills, and affixing a jet generator over the conditioned air and make-up air discharge grills. The fan can be arranged such that air is drawn thereinto and such that ambient conditioned air is supplied through the make-up air intake collar into the make-up air plenum. The jet generator can have vertical and horizontal faces and can define a jet plenum portion that, once affixed, extends into the hood recess in a horizontal direction to permit air from the make-up air plenum to flow to a lower end of the hood. Each of the vertical and horizontal faces can have at least one opening therein. The at least one opening in the horizontal face can face downwardly and can be located at the lower end of the hood once the plenum is affixed. The openings in the vertical and horizontal faces can be located to receive air from the jet plenum portion such that vertical and horizontal jets are generated from air supplied by the fan.
In embodiments, a method for modifying a short-circuit exhaust hood can include exchanging a jet generator for a make-up air discharge register, which covers an outlet of an air supply plenum and through which air from the air supply plenum enters into a recess of the short-circuit exhaust hood. The exchanging can include removing the discharge register and sealing upper and lower portions of the jet generator around the air supply plenum outlet. The jet generator together with surfaces of the short-circuit exhaust hood can form a plenum that conveys air from the air supply plenum outlet to a plurality of first and second openings in the jet generator. The first openings can be constructed to form horizontally directed jets at a lower end of the recess. The second openings can be constructed to form vertically directed jets at the lower end of the recess. The jet generator can have a protruded shape in cross-section such that both the first and second openings are spaced from the upper portion of the jet generator and the air supply plenum outlet in a horizontal direction.
In embodiments, a jet generating apparatus can be used in a short-circuit exhaust hood having a make-up air supply plenum with an outlet in fluid communication with a recess of the short-circuit exhaust hood. The jet generating apparatus can include a first portion, a second portion, an outlet portion, and an intermediate portion. The first portion can extend in a substantially vertical direction. The second portion can extend in a substantially horizontal direction. The outlet portion can be provided at a horizontal end of the second portion and include a plurality of first and second openings therein. The intermediate portion can connect the first portion to the outlet portion. The first openings can be constructed to form first jets in the horizontal direction, and the second openings can be constructed to form second jets in the vertical direction. The first and second portions can be constructed to seal the air supply plenum outlet when installed in the short-circuit exhaust hood. The outlet portion can have a protruded shape in cross-section such that both the first and second openings are spaced from the first portion in the horizontal direction.
In embodiments, a method for modifying a short-circuit hood can include replacing a make-up air system or conditioned air supply system, which provides a flow of air at a front of the short-circuit hood via a respective outlet, with a jet generator that forms a combination of horizontally and vertically directed jets along a lower portion of a recess of the short-circuit hood at said front.
In embodiments, a short-circuit hood can include a plenum adjacent the hood, the plenum having an interior volume separated from an interior volume of the hood recess by a wall. A method of modifying the short-circuit hood can include removing a portion of the wall to communicate at least a portion of the internal volume of the plenum with the interior volume of the hood recess, thereby expanding the interior volume of the recess. A curved wall can be affixed in position to replace the removed portion of the wall. The curved wall may form a curved angled lip portion at a lower edge of the hood that curves toward a fume intake facing an interior of the hood recess. A jet generator can be affixed to the hood in order to generate generally horizontal and generally vertical jets along the lower edge of the hood. The jet generator may include an integrated or separate controller and sensor for detecting an exhaust load. The controller can be connected to the exhaust system and a rate of flow of the exhaust of the exhaust system may be regulated by the controller responsively to a signal from the sensor.
Objects and advantages of embodiments of the disclosed subject matter will become apparent from the following description when considered in conjunction with the accompanying drawings.
Embodiments will hereinafter be described with reference to the accompanying drawings, which have not necessarily been drawn to scale. Where applicable, some features may not be illustrated to assist in the illustration and description of underlying features. Throughout the figures, like reference numerals denote like elements.
Make-up air flows from a supply duct 106 into a supply plenum 108 and out through a discharge grill or register 114. The make-up air may also be supplied by a fan (not shown) located remote from the exhaust hood, for example, on the roof of the building. The discharge grill 114 diffuses and directs a large volume of air directly into the recess. The discharge grill 114 may extend only partly along a width of the hood 101. Note that the width of the hood 101 is taken to be the dimension of the hood in the direction perpendicular to the plane of the cross-section illustrated in
In embodiments of the disclosed subject matter, a short-circuit hood as described with respect to
By providing the series of jets at or near the lower edge of the exhaust hood recess, the vertically directed jets can form an air curtain that confines the entry of conditioned air into the exhaust stream to an effective aperture defined by the terminus of the air curtain while the horizontally directed jets can form a virtual barrier to prevent (or at least reduce the amount of) fumes from being drawn from the recess by external air movements. The large volume defined by the canopy interior, extended by the vertically directed jets, creates a large buffer zone to smooth out transients in plug flow. The horizontally directed jets ensure that fumes captured in the exhaust recess can be retained in the exhausted recess until removal by the exhaust plenum. This enhanced capture efficiency permits the exhaust fan (or blower) to operate at a slower speed while enforcing full capture and containment. This in turn minimizes the amount of conditioned air that must be extracted with a concomitant reduction in energy loss.
In general, a conversion device 200 can be added to an already installed short-circuit exhaust system 201, which may include an exhaust fan 208 for removing gas from an exhaust hood 206 and an air supply 210 for supplying air to a make-up air plenum 204 for introduction into the exhaust hood 206. The conversion device 200 includes a jet generator 202 that can be installed between a make-up air plenum 204 and the exhaust hood 206, as shown in
Individual jets are directed either in a substantially vertical direction (i.e., from the hood toward the ground) or in a substantially horizontal direction (i.e., parallel to the ground and toward the exhaust outlet side of the hood). The jets directed in a particular direction may coalesce into a planar jet (e.g., a vertical curtain jet or an unattached horizontal planar jet) a short distance from the nozzles from which they originate.
Multiple jets that have nozzles with smaller diameters and that propel air at a higher velocity are generally more effective than a single jet with one long and narrow nozzle or even multiple jets with much larger nozzles. The effectiveness of the air jets depends, in large part, on its output velocity. Air jets with larger nozzles must discharge air at a faster rate to achieve a comparable output velocity. On the other hand, smaller nozzles generally produce much smaller scale turbulence and tend to disturb the thermal flow created by the cooking surface to a lesser degree than larger scale turbulence. Smaller nozzles also require less air. Jets with lower output velocities create an air flow that dissipates more quickly due to loss of momentum to viscosity and may have a throw that is only a short distance from the nozzle. Operation and design of the plenums forming the jets can be such that the jets are formed with such dimensions and velocity that the jet air flow dissipates prior to or shortly after reaching the effluent plume 103 and/or the cooking appliance 120.
Each jet can be formed by a respective air nozzle formed in a jet generating plenum. Although not a requirement, the nozzles for generating jets in a particular direction along a particular lower edge of the exhaust hood can be positioned to form a substantially straight line. The nozzles may simply be perforations in a plenum defined by a metal blank of the conversion apparatus attached to the short-circuit system. Alternatively, they may be nozzle sections with a varying internal cross section that minimizes expansion on exit. The nozzles may contain flow conditioners such as settling screens and/or or flow straighteners. The initial velocities of the horizontal jets may be between 2 and 3.5 times the initial velocities of the vertical jets, the initial velocity in this case being the point at which individual jets coalesce into a single planar jet.
The horizontal and/or vertical jets may be directed parallel with respect to each other. That is, horizontal jets may emanate from the plenum and proceed laterally across the lower portion of the recess in non-intersecting directions. Alternatively, some of the horizontal jets may be angled with respect to other horizontal jets. For example, horizontal jets located at corners of the hood, i.e., in or around the intersection of front edge of the hood with its sides may be angled toward the center of the hood where an exhaust vent is located. Thus, when the hood has a relatively large aspect ratio (i.e., width of the front edge of the hood as compared to the width of the side edge of the hood), the horizontal jets at the corners can be angled toward the center to enhance capture and containment of exhaust. Alternatively or additionally, the plenum that forms the jets may have an angled or curved geometry, as viewed in a top-down plan view of the hood, such that horizontal jets emanating in a direction substantially perpendicular to the plenum surface are automatically angled toward the center of the hood.
The horizontal and vertical jets can be formed on the front edge of the exhaust hood (i.e., an edge opposite the exhaust outlet and/or closest to a working edge of the cooking appliance). In addition, the horizontal and vertical jets can be formed at other edges of the exhaust hood, such as, but not limited to side or rear edges of the exhaust hood. A common plenum can be used to form the jets on the front and additional edges of exhaust hood, although multiple separate plenums are also possible according to one or more contemplated embodiments.
The jet generator 150 can be, for example, an angled sheet metal blank. First openings 142 and second openings 160 can be provided in the angled sheet metal blank. Alternatively or additionally, the first and/or second openings may be formed by interaction of portions of the jet generator 150 with respective portions of the hood 101 and/or supply plenum 108. The shape of the jet generator 150 can be such that at least a portion thereof extends away from the plenum 108 into the area of the recess 102. For example, the jet generator 150 may have a nose shape or other protruded shape in side view. The “nose” shape of the jet generator 150 can include a bevel 151 that directs air at a front portion of the recess 102 back toward the center of the hood, as indicated by the arrow 154.
The jet generator 150 can be formed to extend around the side edges of the hood 101 as well as the front edge thereof. Thus, the jet generator 150 can be constructed to have laterally extending side portions to form a u-shape in top down plan view (see, for example,
The openings 142 and 160 allow air from the supply plenum 108 to escape into the recess of the exhaust hood, but the volume of supply air is substantially reduced from the rate of the original short-circuit system of
Another way to describe the configuration of the holes 142 and 160 is in terms of the equivalents of isothermal planar free jets that are formed by holes 142 (producing horizontally directed jets) and holes 160 (producing vertically directed jets). For example, holes 142 can each have a diameter of 5 mm and can be provided linearly in the jet generator 150 at a spacing of 32 mm on centers, and holes 160 can each have a diameter of 3.4 mm and can be provided linearly in the jet generator 150 at a spacing of 32 mm on centers. The holes can be simply punched into sheet metal of about 12 gauge, for example. The air supply to the holes 142 and 160 in the jet generator 150 can be at a pressure of 0.2 to 0.4 in water gauge, for example, 0.265 to 0.31 in water gauge. However, other configurations, including hole sizes, spacings, plenum pressures, elongated linear slots, hole shapes, etc., for generating curtain jets are also possible according to one or more contemplated embodiments.
In a typical short-circuit exhaust hood, the air flowing through the make-up grill 114 is about 50 cfm per linear foot of the hood (in a direction of the width of the exhaust hood), although wide variations in this number are possible. However, after insertion of the jet generator 150 according to embodiments of the disclosed subject matter, the resulting air flow emanating as horizontal and vertical jets is between 5 and 15 cfm per linear foot.
Additionally or alternatively, other changes to the short-circuit hood may be made to reconfigure the make-up air or conditioned air flow into the hood as horizontal and vertical jets. Referring to
In the configuration of
Referring now to
At 708, the discharge grill 114 in the supply plenum 108 can be removed, leaving behind a supply plenum outlet 614. At 710, a jet generator 650 can be installed at the supply plenum outlet 614 so at replace the discharge grill 114 with the plenum 615. As noted herein, the jet generator 650 can have a plurality of openings or holes 642, 660 therein. At 712, unused air flow paths of the short-circuit hood can be capped and/or blocked. For example, the air curtain duct 118 can be capped by cap 606 at the HVAC unit collar 506. Additionally or alternatively, the diffuser 517 can be removed, leaving behind an air curtain outlet 516, which can then be blocked by sealing portion 616, as shown in
At 714, air can be provided to the supply plenum 108 by running fan 604, which in turn feeds holes 642 and 660 in jet generator 650 to form the horizontal jets 640 and vertical jets 646, respectively. Jet generator 650 can have a nose structure with a forward edge portion 650a and side edge portions 650b that wrap around the inside surfaces of the hood 500 so as to create vertical and horizontal facing openings 642, 600 along the lower edge of the hood 500. The fan can be controlled so as to regulate the pressure in the air supply plenum 108 to between 0.2 and 0.5 in water gauge and to provide a total volume flow rate of between 10 and 25 cubic feet per second (cps).
The jet generator plenum may have a dimension (indicated at 833) relative to the front-back dimension of the hood that is thin, for example, 50 to 150 cm and may extend across the forward face of the hood. The jet generator creates linear jets in a generally horizontal direction 828 and a generally vertical direction 829 along the forward edge of the hood. The linear jets may be formed by flowing air through openings 838, 840, which may be an array of holes or a slit. The vertical and horizontal jets may also circumnavigate the hood lower edge on one or both lateral sides. In a canopy configuration, the vertical and horizontal jets may also circumnavigate the hood lower edge on all sides including the forward and back sides. In such configurations, separate plenums 830 may be used for each rectangular face of the hood 801 or the plenums may be combined. For example, a single plenum may wrap around two sides, three sides or all sides of the hood 801. At the corners, the lower part of the jet generator plenum 830 indicated at 837 may be beveled to allow positioning against an adjacent plenum on another face of the hood 801 as illustrated in
A further feature that may or may not be present in any of the embodiments of
As above, the jet generator creates linear jets in a generally horizontal direction 828 and a generally vertical direction 829 along the forward edge of the hood. The linear jets may be formed by an array of holes or a slit. The vertical and horizontal jets may also circumnavigate the hood lower edge on one or both lateral sides with suitable arrangement of the plenum 848. In a canopy configuration, the vertical and horizontal jets may also circumnavigate the hood lower edge on all sides including the forward and back sides.
A further feature that may or may not be present in any of the embodiments of
As above, the jet generator creates linear jets in a generally horizontal direction 828 and a generally vertical direction 829 along the forward edge of the hood. The linear jets may be formed by an array of holes or a slit. The vertical and horizontal jets may also circumnavigate the hood lower edge on one or both lateral sides with suitable arrangement of the plenum 848. In a canopy configuration, the vertical and horizontal jets may also circumnavigate the hood lower edge on all sides including the forward and back sides.
For any of the embodiments of
It will be evident to those skilled in the art that the embodiments of the disclosed subject matter are not limited to the details disclosed herein, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. For example, while jets have been described as formed using a series of round nozzles, it is clear that it is possible to form jets using a single slot or non-round nozzles. Also, the source of air for the jets may be room air, outdoor air or a combination thereof. In addition, embodiments of the disclosed subject matter are applicable to any process that forms a thermal plume, not just a kitchen range. The principles disclosed and described herein can be applied to many different types and styles of exhaust hoods, including, but not limited to back shelf and canopy style hoods.
Features of the disclosed embodiments may be combined, rearranged, omitted, etc., within the scope of the invention to produce additional embodiments. Furthermore, certain features may sometimes be used to advantage without a corresponding use of other features.
It is thus apparent that there is provided, in accordance with the present disclosure, exhaust hood methods, devices, and systems. Many alternatives, modifications, and variations are enabled by the present disclosure. While specific embodiments have been shown and described in detail to illustrate the application of the principles of the present invention, it will be understood that the invention may be embodied otherwise without departing from such principles. Accordingly, Applicants intend to embrace all such alternatives, modifications, equivalents, and variations that are within the spirit and scope of the present invention.
The present application is a U.S. national stage entry of International Application No. PCT/US12/45751, filed Jul. 6, 2012, which claims the benefit of U.S. Provisional Application No. 61/505,520, filed Jul. 7, 2011, both of which are hereby incorporated by reference herein in their entirety.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/US2012/045751 | 7/6/2012 | WO | 00 | 3/7/2014 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2013/006789 | 1/10/2013 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 3727753 | Starr et al. | Apr 1973 | A |
| 4124021 | Molitor | Nov 1978 | A |
| 4286572 | Searcy | Sep 1981 | A |
| 4346692 | McCauley | Aug 1982 | A |
| 4373509 | Neitzel | Feb 1983 | A |
| 5251608 | Cote | Oct 1993 | A |
| 6484713 | Schmitt et al. | Nov 2002 | B1 |
| 6851421 | Livchak et al. | Feb 2005 | B2 |
| 8038515 | Livchak et al. | Oct 2011 | B2 |
| 20090032011 | Livchak et al. | Feb 2009 | A1 |
| 20110021128 | Livchak et al. | Jan 2011 | A1 |
| 20110053483 | Ritzer et al. | Mar 2011 | A1 |
| 20110094497 | Schrock et al. | Apr 2011 | A1 |
| 20110114076 | Robison | May 2011 | A1 |
| Number | Date | Country |
|---|---|---|
| WO2009129539 | Oct 2009 | WO |
| WO 2010065793 | Jun 2010 | WO |
| Entry |
|---|
| International Search Report and Written Opinion for International Application No. PCT/US12/45751, dated Oct. 16, 2012. |
| Number | Date | Country | |
|---|---|---|---|
| 20140202445 A1 | Jul 2014 | US |
| Number | Date | Country | |
|---|---|---|---|
| 61505520 | Jul 2011 | US |
