The present invention relates to the field professional kitchen devices and more particular to an exhaust hood for removing cooking by-products from a kitchen environment.
An exhaust hood is a device including a mechanical fan that is installed above the stove or cooktop in the kitchen. It removes airborne grease, combustion products, fumes, smoke, odors, and steam from the air by evacuation of the air. In most exhaust hoods, a filtration system removes grease and other particles. Although many exhaust hoods exhaust air to the outside, some recirculate the air to the kitchen. In a recirculating system, filters may be used to remove odors in addition to the grease. Commercial exhaust hoods may also be combined with a fresh air fan that draws in exterior air, circulating it with the cooking fumes, which are then drawn out by the hood.
U.S. Pat. No. 6,851,421 B2 describes an exhaust hood, which captures and contains a thermal plume by defining a vertical curtain jet. In one embodiment, vertical and horizontal jets can be combined to augment capture and containment. The horizontal jet pushes the plume toward the exhaust vent at the side of the hood and creates a negative pressure field around the forward edge of the hood which helps containment. The hood uses air nozzles in the form of small round holes positioned along the front of the exhaust hood. The nozzles are spaced apart from each other such that they form individual jets which combine into a curtain jet. However, on the one hand, the vertical air curtain may be efficient only for certain hood geometries and proves less efficient for others; on the other hand, the vertical air jets can be annoying for kitchen personnel who have to work below the hood all day.
Therefore, it is an object of the present invention to improve the efficiency and performance of an exhaust hood in terms of capturing and removing cooking by-products and effluents such as airborne grease, combustion products, fumes, smoke, odors, and steam without the need of vertical air jets.
These and other objects that appear below are achieved by an exhaust hood with a housing, which is open towards a bottom face to capture cooking by-products from a cooking appliance positioned below said exhaust hood. The housing has at least a first wall being either a front wall or a rear wall of said housing and a second wall opposite to the first wall. The second wall is at least partly inclined inwardly from the bottom face towards a top face of the housing and has an exhaust vent that communicates with an exhaust fan to extract cooking by-products captured by the housing. The exhaust hood has a fresh air fan and the first wall is shaped to form a first duct which has a number of openings located in a row along a lower edge of the first wall adjacent to the bottom face and oriented to the inside of said housing. The first duct is in communication with the fresh air fan to inject air streams through the openings into the housing in a direction substantially parallel to the bottom face. This creates a vertical flat air stream directed from the first wall towards the second wall. According to one aspect, the openings are in the form of substantially rectangular slots, the long edges of which are oriented in parallel to said bottom face.
According to another aspect of the invention, the exhaust hood has a baffle sheet located at the inside of the first wall above the row of openings, which extends into the housing substantially parallel to the bottom face.
According to yet another aspect, the exhaust hood has a side wall and side wall extension. The side wall extension extends in a direction perpendicular to the bottom face below the housing to form a lateral skirt. The skirt has towards its bottom end a pass-through window forming a passage way for handling food products below the exhaust hood. The side wall extension is shaped to form a side wall duct with openings along a narrow side adjacent to the pass-through window facing downwardly and towards a front of the kitchen hood. The side wall duct is in communication with a fresh air fan to eject vertical and horizontal air streams through the openings, which coalesce to form a vortex that prevents cooking by-products from passing through the pass-through window.
The fresh air fan forces air through the rectangular slots on the inside front and, preferably, also on the sides of the exhaust hood. A close spacing of the rectangular slots creates a horizontal “knife” of air. The baffle sheet above the slots helps create a flat horizontal air stream. The forced air pushes rising smoke and other cooking by-products into the hood and towards the exhaust vent. This aids the ability of the hood to capture smoke at a lower exhaust air flow volume.
The fresh air fan can be arranged to draw air from the ceiling space above the hood, thus having no effect on the kitchen air as would be the case if fresh air was drawn from outside of the kitchen.
Further advantageous aspects are described by the dependent claims. In one aspect, a free end of the baffle sheet is angled by a flat angle downwardly towards the bottom face, preferably by approximately 10 degrees. Additionally or alternatively, a further, second baffle sheet can be provided which extends into the first duct in the direction opposite to the elongation of the first baffle sheet. This second baffle sheet can be angled upwardly at its free end such that it extends inside the duct substantially parallel to the first wall. This geometry improves the creation of the “air knife” stream.
According to another aspect, the openings or slots may have a ratio between their short and long edges of at least 1:10, preferably of at least 1:15. The spacing between neighbored openings can correspond to the dimension of the short edges.
In one embodiment, the first wall is designed to contain an inner and an outer sheet, which are connected to enclose a cavity with substantially trapezoidal cross section that serves as the first duct. The inner sheet can be at least partly inclined inwardly from the bottom face towards a top face of the housing.
According to yet another aspect, the air volume of the injected air streams corresponds to about 5% to 25%, preferably to 8% to 15% of the air volume extracted through said exhaust vent by said exhaust fan.
According to yet another aspect, the housing can have side walls, which are at least partly shaped to form second ducts, each having a number of openings located in a row along a lower edge of the side walls adjacent to said bottom face and oriented to the inside of the housing. The second ducts are in communication with the first duct to inject air streams through their openings into the housing in a direction substantially parallel to the bottom face.
In an embodiment, the second ducts have a substantially triangular shape decreasing in cross section from the first wall towards the second wall. Third and fourth baffle sheets can be provided at the side walls and inside their ducts, which correspond in shape and function to the first and second baffle sheets.
Further advantages and characteristics of the invention will become apparent by the below description of embodiments making reference to the accompanying drawings, in which:
A canopy-style exhaust hood 1 is shown in
The rear wall 3 with the exhaust vent 6 forms an exhaust plenum and is connected to an exhaust fan, which can be either internal to the hood 1 or external to it, e.g. roof mounted.
In the illustrated embodiment, the exhaust hood is of modular design and can be split in the middle into two parts 1a, 1b for simplified transport and installation. Moreover, the side walls 4, 5 can be removed and the hood expanded with further middle parts.
As shown in
The front wall 2 is shaped to form an air duct 20 of triangular cross section. The fresh air fan sits at the inlet of this front wall air duct and draws air from the ceiling space above the hood into the duct 20 and injects the air in the form of flat air streams through the slots 10 into the housing in a direction substantially parallel to its bottom face. The forced air injection creates a flat air stream that is directed from the front wall 2 towards the rear wall 3 and the exhaust vent 6. The inner wall panels 21 are removable for cleaning purposes. Alternatively, the fresh air fan can also be attached to an outside vent thus pulling air from outside of the building or connected to a duct on the kitchen's HVAC system, i.e. the overall building heating, ventilating and air-conditioning (HVAC) system of the kitchen.
A smaller fresh air fan draws air from above the exhaust hood 1 and forces the air through the slots 10 around the internal perimeter of the hood 1. The fresh air 19 thus injected pushes the smoke and other by-products 13 from the appliances 12 towards the exhaust vent 6 and into hood filters 16.
The air streams created by the forced fresh air are shown schematically in
In
A side wall 4 of the hood 1 is shown in
The air flow volume of air forced by fresh air fan 18 through the slots 10 is approximately 20 cubic feet per minute, per linear foot of the hood 1. This amounts to approximately 10% of the exhaust air rate moved by the exhaust fan of the hood 1 through exhaust vents 6. The exhaust hood of the embodiment with two hood segments a, 1b is operated with two exhaust fans which have an exhaust airflow volume that will vary with the length of the hood.
To summarize, the exhaust hood 1 uses a fresh air fan 18 to pull fresh air from the ceiling space above the hood. The air is then distributed around the perimeter of the hood 1, through rectangular slots 10, in a vertical air stream which pushes rising smoke from the cooking appliances 12 below into the hood filters 16.
It should be noted that in the present embodiments, the exhaust hood is shown with its exhaust vent 6 and grease filters oriented towards the backside of the hood such as towards a wall of the kitchen. It should be understood that such a kitchen hood can also be installed the opposite way, i.e. with its vent and filters oriented to the front side of the kitchen. The terms front side and rear side of the exhaust hood are therefore used interchangeably and without limitation to the way the exhaust hood can and will be installed in a kitchen.
A further embodiment of a kitchen hood is depicted in
In some instances, when the appliance on the end does not require interaction with equipment outside the hood, a single layer, angled hanging skirt can be added to hold the smoke and effluent inside the confines of the hood. However, such a hanging skirt can be cumbersome for the kitchen personnel when the appliance on the end underneath the hood requires interaction with equipment outside the hood. In this case, the angled panel will interfere with the moving of product from underneath the hood to the appliance outside the hood.
For these reasons, the hood 1 in the third embodiment has a special skirt 30 with a pass-through window 31 at its lower end that serves as a passage way for the kitchen personnel to move a product from the appliance underneath the hood to another appliance outside the hood. The skirt 30 can either be attached to and hanging from either of the side walls 4, 5 of the hood 1 or can be integral with the side walls 4, 5. A special forced air ejection system is provided at the pass-through window 31 to hold the smoke inside the hood, i.e. prevent effluents from escaping through the open pass-through window 31.
The skirt 30 is double walled and defines a duct, which is connected via a connection port 32 at the bottom edge of the side wall 5 to the ducts 26 and 20 of the hood 1. Thus fresh air from fan 18 can pass through the port 32 into the hollow space of the double-walled skirt. Along the edges 33, 34 of the pass-through window 31 at its narrow side, the skirt has openings 35 similar in shape, size and spacing to the slots 10, through which air streams 36, 37 will be ejected. The air streams 36, 37 are directed vertically downwards and horizontally in a forward direction toward the front of the hood 1. As these air streams 36, 37 coalesce, they create a vortex 38 which prevents cooking byproducts from passing through the pass-through window. Together the rising effluents from a kitchen appliance positioned flush to the pass-through window, a rising turbulence, which can be described as a kind of “mini tornado” will be created.
Alternatively, instead of connecting the double-walled skirt with the ducts 26 and 20, a separate fan could be provided for the side wall skirt.
The coalescence of streams 36 and 37 and formation of air vortex 38 is further supported by baffle sheets 33′ and 34′ extending next to the openings 35 from the inner sheet wall of the skirt 30 into the pass-through window 31. Further air slots 40 at the inside of the skirt, i.e. facing inside the space confined by the hood, eject streams of fresh air which together with an inward-facing baffle sheet or flange 41 cause the “mini tornado” to rise into the housing of the hood and directly into the exhaust vents 6.
This application is a continuation of U.S. application Ser. No. 15/850,220, filed Dec. 21, 2017, which is incorporated by reference as if fully set forth.
Number | Date | Country | |
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Parent | 15850220 | Dec 2017 | US |
Child | 16744713 | US |