This invention relates to a food processing apparatus. More specifically, this invention relates to a grinder head cooler adapted to receive a coolant that helps maintain the grinder head in a cooled condition during use.
Grinders are food processing and preparation appliances used to grind, chop or mince a variety of foods such as meats, vegetables or fruits. As the density of the food increases such as with meats, during this grinding operation the friction caused by grinding increases the temperature of the grinder head and meat. This temperature rise can be high enough to be conducive to bacteria growth and spoilage during this grinding process. Cooling the grinding head with frozen packs cools the head and meat but does not allow a means for the heat of grinding to escape. As the cooling packs melt the performance of the cooling packs diminish. By providing an apparatus that can cool and remove heat from the grinder head, the cooling pack performance increases by the reduced temperature of the grinder head and extended duration of the frozen packs. This in turn will provide increased food safety reducing the likelihood of spoilage and improve the grinding performance by reducing the adhesion of the ground food to the grinder head.
According to one aspect, an apparatus for grinding food products includes a housing including an inlet for receiving food products to be ground, an outlet for discharging the ground food product, and a grinding portion for housing components operable to grind the food product. The apparatus also includes a cooling pack adapted to be connected to an outside surface of the housing to cool the grinding portion.
According to another aspect, the grinding portion has a generally cylindrical outside configuration that the cooling pack is configured to follow.
According to another aspect, the housing includes one or more tabs, and the cooling pack comprises one or more slots for receiving the tabs to thereby connect the cooling pack to the housing.
According to another aspect, the cooling pack extends circumferentially about 180 degrees around the grinding portion.
According to another aspect, an apparatus for cooling a grinder head includes a cooling pack adapted to be connected to an outer surface of a housing of the grinder head to cool the grinder head housing.
According to another aspect, the cooling pack can have a cylindrical configuration that mates with the cylindrical outer surface of the grinder head housing.
According to another aspect, the cooling pack can extend circumferentially greater than 180 degrees around the grinder head housing.
According to another aspect, the cooling pack can have a freezable and re-freezable construction.
According to another aspect, the cooling pack can include a first cooling pack half that has a cylindrical inner surface, and a second cooling pack half that has a cylindrical inner surface, the first and second cooling packs being connected to each other.
According to another aspect, the apparatus can include a first strap that connects a first end of the first cooling pack half to a first end of the second cooling pack half, the first strap being constructed and arranged to permit the first and second cooling pack halves to move relative to each other. The apparatus can also include a second strap that connects a second end of the first cooling pack half to a second end of the second cooling pack half, the second strap being releasable connectable with at least one of the first and second cooling pack halves.
According to another aspect, the first strap can permit the first and second cooling pack halves to move to an open condition in which the grinder head housing can be positioned between the halves, and wherein the second strap when connected to both cooling pack halves draws the halves together to connect the cooling pack to the grinder head housing.
According to another aspect, at least one of the first and second straps can have an elastomeric construction that applies a force to the cooling pack halves that draws the halves into mating engagement with the outer surface of the grinder head housing.
According to another aspect, at least one of the first and second straps can connect with at least one of the first and second cooling pack halves via an opening in the strap that deforms elastically to receive a tab on the cooling pack, the opening forming an interference with the tab that connects the strap to the cooling pack half.
According to another aspect, the first and second cooling pack halves can include gel-filled cooling packs.
According to another aspect, a grinder head housing cooling apparatus includes first and second cooling pack halves filled with a freezable and re-freezable substance, and at least one connector for connecting the cooling pack halves to each other and to the outer surface of the grinder head housing to cool the grinder head housing through thermal heat transfer.
According to another aspect, each of the cooling pack halves can have a cylindrical configuration that mates with the cylindrical outer surface of the grinder head housing.
According to another aspect, each cooling pack half can extend circumferentially less than 180 degrees around the grinder head housing, and wherein the cooling pack halves together extend circumferentially greater than 180 degrees around the grinder head housing.
According to another aspect, the first cooling pack half can have a cylindrical inner surface, and the second cooling pack half has a cylindrical inner surface.
According to another aspect, the apparatus can also include a first strap that connects a first end of the first cooling pack half to a first end of the second cooling pack half, the first strap being constructed and arranged to permit the first and second cooling pack halves to move relative to each other. The apparatus can also include a second strap that connects a second end of the first cooling pack half to a second end of the second cooling pack half, the second strap being releasable connectable with at least one of the first and second cooling pack halves.
According to another aspect, the first strap can permit the first and second cooling pack halves to move to an open condition in which the grinder head housing can be positioned between the halves, and wherein the second strap when connected to both cooling pack halves draws the halves together to connect the cooling pack to the grinder head housing.
According to another aspect, at least one of the first and second straps can have an elastomeric construction that applies a force to the cooling pack halves that draws the halves into mating engagement with the outer surface of the grinder head housing.
According to another aspect, at least one of the first and second straps can connect with at least one of the first and second cooling pack halves via an opening in the strap that deforms elastically to receive a tab on the cooling pack, the opening forming an interference with the tab that connects the strap to the cooling pack half.
According to another aspect, the first and second cooling pack halves can include gel-filled cooling packs.
According to another aspect, a cooling pack can be attached circumferentially to the outer surface of a grinder head of a grinder appliance. Food is placed in a food tray attached to a cylindrical entry port on the grinder head. Food is pushed in to this entry port of the grinder head, an electric motor turns an auger internally in the grinder head grinding the food. The heat generated by this grinding operation needs to be controlled to prevent spoilage of the food.
According to this aspect, the circumferentially wrapped cooling pack includes a heatsink retained between two cooling pack halves. The heatsink transfers heat from the grinder head to ambient air. The cooling pack and the heatsink have circumferences that matches the circumference of the outer surface of the grinding head. Both the cooling pack and the heatsink thereby are in direct thermal contact with the grinder head. The cooling packs cool the grinder head by the physical phase change process of ice to water. These cooling packs, however, do not have a means to distribute the heat of the grinder head to ambient air. The heatsink provides a thermal conduit path through the cooling pack enclosure transporting heat from the grinder head to be dispersed to ambient air. The heatsink improves the cooling performance for cooling the grinder head by conducting the thermally generated heat of the grinder head to ambient air thereby reducing the heat load of the grinder head and allowing the cool packs a slower rate of phase change due to the reduced temperature gradient of the grinder head to the cool pack surface.
For a better understanding of the invention, reference may be made to the accompanying drawings.
A known food processing apparatus 10 in the form of a meat grinder is illustrated in
Whole or cubed raw meat is fed into the inlet 16 on top of the grinder head, and the meat is propelled horizontally on the rotating screw conveyor, which can also squash and partially mix the meat as it is propelled. At the end of the screw conveyor, the knife is positioned in front of and adjacent to the fixed hole plate. The screw conveyor forces the meat past the knife and through the plate. The rotating knife blades mince or grind the meat, which is discharged through the holes in the plate and through the outlet 18. The size of the holes in the plate determines the fineness of the ground meat.
According to a first embodiment of the invention, the meat grinder 10 includes a cooling feature that counteracts heating due to friction between internal components. This helps prevent the meat from heating up as it is ground, which can cause the ground meat to stick to the grinder components and inhibit or halt the grinding process. The cooling feature can have a variety of configurations.
In the illustrated embodiment, the housing 20 includes a pair of tabs 30 that serve to support a cooling pack 32. The cooling pack 32 has a generally semi-cylindrical configuration that mates with a lower portion of the grinder housing 20. The cooling pack 32 includes a pair of slots 34 that are spaced and configured to receive the tabs 30. The tabs 30 cooperate with the slots 34 to support the cooling pack 32 on the housing 20. In the illustrated embodiment, the cooling pack 32 extends circumferentially around about half of, i.e., about 180 degrees around, the housing 20. The extent to which the cooling pack 32 extends circumferentially around the housing 20 can vary.
The cooling pack 32 can be filled with a coolant, such a liquid/gel-type substance commonly found in freezer chilled cooling packs. These gel in the gel packs are primarily water-based and include a gel-forming substance, such as hydroxyethyl cellulose or a vinyl-coated silica gel. Other materials can be added to prevent bacterial growth. Advantageously, the substance in such gel packs can formulated to have a freezing point below that of water (32° F.) and therefore can enhance the cooling of the grinder head 12.
The cooling pack 32 can have a variety of constructions. For example, the cooling pack 32 can be formed of plastic, metal, or a combination of plastic and metal. In one example construction, the cooling pack 32 can have a plastic portion that defies the coolant containing portion of the pack, and a metal portion fixed to the outside of the plastic portion to provide a metallic appearance. The metal portion can also lend strength and durability to the cooling pack 32, especially to the slots 34 that receives the tabs 30. This can be advantageous in that the metal or metal portions of the slots 34 can provide increased durability in comparison with plastic.
Installation of the cooling pack 32 on the grinder head 12 is illustrated in
Once positioned appropriately relative to the grinder head 12, the cooling pack 32 is maneuvered onto the housing 20, as indicated generally by the arrow B in
Next, the cooling pack 32 is slid in the direction indicated generally by the arrow C in
Advantageously, the removable cooling pack 32 allows for the use of multiple cooling packs in an interchangeable fashion. When the cooling packs 32 heat up during use and lose their effectiveness, they can be swapped with frozen standby packs, thus eliminating the need to halt the grinding process for a prolonged period.
During use, the cooling packs 32 help to maintain the grinder head 12 at a low temperature. For example, the coolant in the packs 32 can maintain the grinder head 12 at about 40° F. or less. The advantage of a coolant/gel-filled cooling pack 32 is that the gel can be formulated for cooling below 32° F.
A second embodiment is illustrated in
Whole or cubed raw meat is fed into the inlet 206 on top of the grinder head, and the meat is propelled horizontally on the rotating screw conveyor, which can also squash and partially mix the meat as it is propelled. At the end of the screw conveyor, the knife is positioned in front of and adjacent to the fixed hole plate. The screw conveyor forces the meat past the knife and through the plate. The rotating knife blades mince or grind the meat, which is discharged through the holes in the plate and through the outlet 208. The size of the holes in the plate determines the fineness of the ground meat.
According to the second embodiment of the invention, the apparatus 100 provides a cooling feature to the meat grinder 200 that counteracts heating due to friction between internal grinder components. This helps prevent the meat from heating up as it is ground, which can cause the ground meat to stick to the grinder components and inhibit or halt the grinding process. The cooling feature can have a variety of configurations.
In the embodiment illustrated in
The first cooling pack half 104 includes a first or upper end 110 and a second or lower end 112. The second cooling pack half 106 includes a first or upper end 114 and a second or lower end 116. The apparatus 100 includes a first strap 120 connects the lower ends 112, 116 of the halves 104, 106 such that the ends are positioned adjacent each other. The first strap 120 can be constructed of an elastomeric material, such as rubber or plastic. In this construction, the first strap 120 includes a pair of elongated openings 122 that mate with respective tabs 124 on each of the lower ends 112, 116. The tabs 124 can be larger than the openings 122 so as to form an interference. The elastomeric first strap 120 can stretch so that the tabs 124 can fit through the openings 122 and will return under their own resilience to their original form to maintain the strap connected to the halves 104, 106 via the interference fit. This is best illustrated in
The lower ends 112, 116 can be connected in alternative manners. For example, the lower ends 112, 116 can be interconnected by a mechanical hinge or by a hinge that is molded integrally with the cooling pack 102. The manner in which the lower ends 112, 116 of the halves 104, 106 are interconnected is not critical as long as the requisite relative movement of the halves is permitted.
The apparatus 100 also includes a second strap 130 that has a first end 132 connected to the upper end 114 of the second half 106 of the cooling pack 102 and an opposite second end 134 that is releasably connectable with the upper end 110 of the first half 104 of the cooling pack 102. The second strap 130 can be constructed of an elastomeric material, such as rubber or plastic. The connections between the second strap 130 and the cooling pack 102 can have any configuration that permits the pack to be fastened to the housing 210 and released from the housing.
In the embodiment illustrated in
The second end 134 of the second strap 130 includes one or more elongated openings 150 that are connectable with a tab 152 on the upper end 110 of the first half 104 of the cooling pack 102. The tab 152 and opening 150 can cooperate to connect the second end 134 of the second strap 130 to the first half 104 in a manner similar or identical to that shown in
The connections of the second strap 130 can have alternative configurations. For example, the first end 132 of the strap 130 can be connected to the second half 106 via a mechanical fastener, such as a rivet. The second end 134 of the strap 130 can be connected to the first half 104 via a mechanical fastener, such as a buckle.
The cooling pack 102, i.e., the cooling pack halves 104, 106, can be filled with a coolant, such a liquid/gel-type substance commonly found in freezer chilled cooling packs. The cooling pack 102 is thus freezable and re-freezable. These gel in the gel packs are primarily water-based and include a gel-forming substance, such as hydroxyethyl cellulose or a vinyl-coated silica gel. Other materials can be added to prevent bacterial growth. Advantageously, the substance in such gel packs can formulated to have a freezing point below that of water (32° F.) and therefore can enhance the cooling of the grinder head 202. The cooling pack 102 can have a variety of constructions. For example, the cooling pack 102 can be formed of plastic, metal, or a combination of plastic and metal.
To install the apparatus 100 on the grinder head 202, the apparatus is placed in an open condition as shown in
Advantageously, the removable cooling pack 102 allows for the use of multiple cooling packs in an interchangeable fashion. When the cooling packs 102 heat up during use and lose their effectiveness, they can be swapped with frozen standby packs, thus eliminating the need to halt the grinding process for a prolonged period. During use, the cooling pack 102 helps to maintain the grinder head 202 at a low temperature. For example, the coolant in the packs 102 can maintain the grinder head 202 at about 40° F. or less. The advantage of a coolant/gel-filled cooling pack 102 is that the gel can be formulated for cooling below 32° F. The elastomeric construction of the straps 120, 130 can urge the cooling pack 102 against the housing 210 to help ensure effective heat transfer, i.e., cooling, of the grinder head 202.
Another example configuration is illustrated in
A cooling pack assembly 320 is secured to the grinder head 302 and extends circumferentially around the grinder head. The cooling pack assembly 320 can be similar in some respects to the cooling pack 102 of
The cooling pack assembly 320 includes a left-half side 322 and a right half side 324 that attach circumferentially to the grinder head 12 to cool the grinder head during the grinding operation. To enhance the cooling effect, the cooling pack assembly 320 includes a heatsink 350. The heatsink 350 is supported at least partially by the cooling pack halves 322, 324 in contact with the grinder head 302.
The cooling pack halves 322, 324 are connected together by three connection straps: a front lower connection strap 340, a rear lower connection strap and 342, and a top front connection strap 344. The cooling pack assembly 320 when attached to the grinder head 302 circumferentially wraps around and directly contacts the corresponding surface of the grinder head and wraps more than 180 degrees around its circumference. When assembled together, the cooling pack halves 322, 324 form a recessed heatsink receiving portion 370 for receiving and retaining the heatsink 350 in the cooling pack assembly 320.
With reference now to
When the cooling pack assembly 320 is secured to the grinder head 302, the upper heatsink surface 352 mates with and engages the corresponding surface of the grinder head. The upper heatsink surface 352 is configured such that its entire surface, or substantially its entire surface, touches and engages the surface of the grinder head 302. This complete and direct engagement provides a direct thermal connection and provides a thermally conductive conduit path to the heatsink fins 354. In use, the heatsink 350 will draw heat from the grinder head 302 through the heatsink upper surface 352, which will be conducted to the heatsink fins 354, which dissipate the heat to the ambient air.
Referring now to
Now referencing
While aspects of the present invention have been particularly shown and described with reference to the preferred embodiment above, it will be understood by those of ordinary skill in the art that various additional embodiments may be contemplated without departing from the spirit and scope of the present invention. For example, the tab/slot configuration used to connect the cooling pack to the housing could be replaced with an alternative connection without departing from the spirit and scope of the invention. Other aspects, objects, and advantages of the present invention can be obtained from a study of the drawings, the disclosure, and the appended claims.
This application is a continuation-in-part of U.S. patent application Ser. No. 14/686,448, filed on Apr. 14, 2015, which is a non-provisional application based on U.S. Provisional Application No. 61/979,212, filed Apr. 14, 2014. The disclosures of these applications are hereby incorporated by reference in their entireties.
Number | Name | Date | Kind |
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1942083 | Biancalana | Jan 1934 | A |
3217793 | Coe | Nov 1965 | A |
3436948 | Portal | Apr 1969 | A |
4187711 | Lavochkin | Feb 1980 | A |
4281520 | Norwood | Aug 1981 | A |
5192039 | Williams | Mar 1993 | A |
Number | Date | Country |
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2735116 | Sep 2011 | CA |
Number | Date | Country | |
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20190056163 A1 | Feb 2019 | US |
Number | Date | Country | |
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61979212 | Apr 2014 | US |
Number | Date | Country | |
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Parent | 14686448 | Apr 2015 | US |
Child | 16125934 | US |