APPARATUS FOR BLAST FREEZING PALLETIZED PRODUCT

Abstract

Apparatus for blast freezing palletized products is disclosed in which tall racks have openings on at least one side that connect to a plenum chamber, against which stacked pallets can be placed one above another as well as beside one another adjacent the plenum openings, but with the rack providing only one pallet depth to optimize circulation of regular warehouse freezing air through the pallets at a rapid rate for rapid blast freezing.

Description

TECHNICAL FIELD OF THE INVENTION

Embodiments of the present invention generally relate to a blast freezing of various products (e.g., fruits, vegetables, meat, seafood, baked goods, etc.). Embodiments of the present invention specifically relate to an energy efficient use of freezing air in the process of blast freezing various palletized products.

BACKGROUND OF THE INVENTION

Blast freezing is a known process for quickly exposing food products to air chilled to very low temperatures (e.g., −40° F./−40° C.) for a period of time sufficient to completely freeze the food products. FIG. 1 illustrates an example of a palletized product 20 suitable for blast freezing. Palletized product 20 includes a pallet 21 supporting a stacked arrangement of a plurality of food product containers 22 with spacers 23 between rows of containers 22. Such spacers are known in the art for allowing the passage of freezing air between the layers of food product containers. Alternatively or concurrently, the food product containers 22 may have openings in their sides to allow for air flow directly through the containers. FIGS. 2 and 3 illustrate an example of a dedicated blast freezing room 30 enclosing a pallet rack 31 for seating multiple palletized products 20. Pallet rack 31 includes pallet seats arranged in four (4) columns and four (4) rows with each row having a depth covering five (5) pallet seats. Thus, at max capacity, pallet rack 31 could seat eighty (80) palletized products 20.

In operation, blast freezing room 30 is maintained at approximately −40° F./−40° C. and fans 32 atop pallet rack 31 are activated to direct a supply flow 33 of freezing air through the palletized products 20 at a specified flow rate to quickly freeze the palletized products 20. Ideally, the freezing air uniformly flows through spacers 23 to equally freeze the palletized products 20 within approximately the same amount of time. However, as best shown in FIGS. 1 and 3, much of the freezing air follows flow paths 34 around and between the palletized products 20. Less freezing air than desired follows flow paths 35 through spacers 23, as flow paths 35 are in closer contact with the food to be frozen. The limitation in flow through paths 35 is the natural result of flow paths 34 having less resistance to air flow than flow paths 35. Furthermore, as best shown in FIG. 2, the freezing air flowing through the pallets in flow path 35, can pass through five (5) consecutive pallets and be sequentially warmed by each pallet, so as to make the cooling of the pallets on the exit side slower than those on the entrance side.

Additionally, the flow rate through the series of five (5) consecutive pallets tends to have quite a bit of drag. The result is an increase in the amount of time required to adequately freeze all of the palletized products 20, accompanied by the use of colder temperatures from a separate freezing system dedicated to the blast freezing process.

FIG. 4A illustrates a top view of an exemplarily warehouse, freezing storage room 40 having several blast freezing rooms 30 for blast freezing the palletized products 20 and pallet racks 41 for storing frozen palletized products 20. The pallet racks 41 are arranged to form aisles 42 for providing access to pallet racks 41 via a fork lift truck. To maintain the frozen status of the stored palletized products 20, air-cooling evaporators 43 are activated to direct a flow of freezing air through aisles 42. One drawback of freezing storage room 40 is the closely arranged blast freezing rooms 30 limit maneuvering of palletized products by fork lift trucks 44 as shown in FIG. 4B. Another drawback of freezing storage room 40, as with blast freezing room 30, is the pallet racks 31 and 41 as respectively shown in FIGS. 5 and 6 have depths of multiple palletized products 20 that make it difficult and time consuming for fork lift operators to navigate when seating or removing a palletized product 20 from the pallet racks 31 and 41.

FIG. 7 illustrates another example of a prior art blast freezing apparatus 50 located within a warehouse 60 for frozen products. Blast freezing apparatus 50 has a pallet rack 51 for seating multiple palletized products 20 with or without spacers 23. Pallet rack 51 includes pallet seats arranged in ten (10) columns of stacked palletized products, three (3) high. Thus, at minimum capacity, pallet rack 51 could seat thirty (30) palletized products 20. Optionally, the depth could be more than one (1), allowing for sixty (60) or ninety (90) or more palletized products 20.

In operation, air-cooling evaporators 61 are activated to maintain the warehouse 60 at approximately −40° F./−40° C. There are fans 52, without any additional associated evaporators, that are activated to direct a rapidly moving supply flow 54 of freezing air in the warehouse through the palletized products 20 at a specified flow rate to blast freeze the palletized products 20. Ideally, the freezing air uniformly follows flow paths 55 along the sides of palletized products 20 to equally freeze the palletized products 20 within approximately the same amount of time. Fans 52 return the freezing air to the warehouse 60 via a return path 53 extending from fans 52. Because blast freezing apparatus 50 has roughly equal air pressure from one side to the other across the palletized products 20, the flow of freezing air is not as high as might be desired through any horizontal spacers 23 that may be used within palletized products 20. Additionally, the vertical flow paths 55 associated with blast freezing apparatus 50 passes beside three (3) palletized products 20, rather than past just one (1).

As a still further example of prior art, U.S. Patent Application Publication 2006/0185528 to Gerald Tippmann et al. discloses an array of palletized products in a warehouse that have a dedicated fan to bring freezing warehouse air rapidly through the palletized products with only a single pallet thickness for the air path without having a dedicated refrigeration system associated with the air handler. U.S. Pat. No. 3,621,672 to Meredith discloses a blast cooling system that uses racks with seals around pathways from an air plenum to force cooling, non-freezing air through palletized food products in a refrigerated warehouse. Meredith discloses that the air flow can be in either direction as may be desired. Along similar lines, U.S. Pat. No. 7,017,366 to Bottom discloses both vertical and horizontal flexible seal elements to engage the palletized product to direct cooling, non-freezing air through palletized product, rather than around it.

SUMMARY OF THE INVENTION

The invention consists of all of the differences from the above described prior art that would not have been obvious to a person of ordinary skill in the art at the time we made our invention, and as are more particularly set forth in the claims. As one example, tall racks have openings on at least one side that connect to a plenum, against which stacked pallets can be placed one above another as well as beside one another only one pallet deep for circulation of regular warehouse freezing air through the pallets at a rapid rate for rapid blast freezing.

As another example, there are vertically adjustable panels in a rack to accommodate different height palletized products stacked one above another, in a way that allows for sealing between the plenum and the palletized products. In particular, as to a particularly preferred embodiment of the invention, the prior art did not provide for the fixing of the position of adjustable panels through the use of pins that could be inserted into any one of a series of vertically arranged holes to achieve any one of multiple discrete heights that are securely positioned, yet readily adjustable. The vertical adjustability of a member that has a rigid component that may or may not also contain a cushioned or flexible seal allows for much more durability, versatility and suitability for accommodating palletized products of various heights.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates a palletized product with horizontal ventilating spacers permitting air flow between adjacent layers of food product as is known in the art;

FIGS. 2 and 3 illustrates a first exemplary prior art blast freezing apparatus using palletized product as shown in FIG. 1;

FIGS. 4A and 4B illustrate a prior art warehouse floor plan incorporating a large quantity of stored frozen palletized product, and showing several specialized rooms for blast freezing using the apparatus of FIGS. 2 and 3;

FIG. 5 illustrates a loading of a palletized product on the blast freezing apparatus shown in FIGS. 2 and 3 as known in the art;

FIG. 6 illustrates a loading of a palletized product on a storage rack shown in FIG. 5 as known in the art;

FIG. 7 illustrates another prior art blast freezing apparatus that uses racks positioned within a freezing warehouse, where the racks have dedicated air handlers but no associated evaporators for additional cooling, and are not separated by walls or doors from other palletized product being stored in the warehouse;

FIGS. 8 and 9 illustrate a blast freezing apparatus incorporating the present invention;

FIGS. 10-12 illustrate a sealing barrier vertically adjustable with pins, each engaging a desired one of a vertical array of holes to maintain a desired height to accommodate a sealing relationship with various height palletized products, in accordance with the apparatus shown in FIGS. 8 and 9;

FIG. 13 illustrates a pallet guide device which is a part of the apparatus of FIGS. 8 and 9, and which includes angled end members slightly wider at the entrance to assist in alignment when inserting a palletized product;

FIGS. 14A-14D illustrate an exemplary operation of the blast freezing apparatus shown in FIGS. 8 and 9;

FIG. 15 illustrates an exemplary embodiment of a blast freezing portion of a warehouse that incorporates the blast freezing apparatus shown in FIGS. 8 and 9;

FIG. 16 illustrates an exemplary operation of the storage portion of a freezing warehouse as known in the art that is along side in the same large warehouse room that includes the blast freezing portion shown in FIG. 15; and

FIG. 17 illustrates an exemplary operation of the blast freezing portion of the warehouse shown in FIG. 15.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

For the purposes of promoting an understanding of certain principles of the invention, reference will now be made to the embodiments illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the invention is thereby intended, and alterations and modifications in the illustrated device, and further applications of the principles of the invention as illustrated therein are herein contemplated as would normally occur to one skilled in the art to which the invention relates. While the embodiments described below, for example, relate to blast freezing of various products (e.g., fruits, vegetables, meat, seafood, baked goods, etc.) for purposes of illustration, it will be appreciated that the principles of the present invention are equally applicable to the blast freezing of any article.

A blast freezing apparatus in accordance with the presently disclosed embodiments incorporates a plenum space defined by a plenum chamber, and one or more pallet racks for seating palletized products adjacent the plenum space whereby freezing air may flow between the palletized products and the plenum space. Preferably the flow is from the palletized product located in a freezing warehouse and into the plenum space, although the opposite direction can alternatively be used. The blast freezing apparatus in accordance with the presently disclosed embodiments may further incorporate a sealing barrier for seating the palletized products against the plenum chamber. In practice, the plenum chambers, the pallet racks and the sealing barriers as well as the palletized products do not have any limitations as to configurations, dimensions and material composition. Thus, those having ordinary skill in the art will appreciate how to structurally configure and dimension as well as materially compose additional embodiments of the present invention from the descriptions herein of FIGS. 8-15 and 17.

FIGS. 8 and 9 illustrate a blast freezing apparatus 70 incorporating a plenum chamber 80 and a pair of pallet racks 90. Plenum chamber 80 has a rectangular configuration of walls 81-85 defining a plenum space 86. Embedded with top wall 83 is one or more fans 87, which function as air handlers. The fans 87 do not have associated evaporators, as the evaporators that service the warehouse room in which the apparatus is located suffice to provide the needed freezing air.

Formed within side walls 82 and 85 are air channels 88 leading into plenum space 86 as will be further described herein in connection with FIGS. 10-13. Optionally, not shown, the plenum space can incorporate vertical dividers, and plural fans 87, so that the entire array does not have to be filled to seal the air flow, but rather one or more columns can be filled and the remainder can be left open, and just the fans 87 above the filled ones can be operated for partial loads of palletized product 20.

Pallet rack 90 includes pallet seats 91 arranged in twelve (12) columns and five (5) rows with each row having a depth covering a single pallet seat. In other words, pallet rack 90 has a single pallet depth.

Blast freezing apparatus 70 further incorporates sealing barriers 90 for each air channel 88 as shown in FIGS. 10-12. Sealing barriers 90 encircle air channels 88 for purposes of seating palletized products against plenum chamber 80 as will be further described herein in connection with FIGS. 14A-14D. Each sealing barrier 90 includes seals 91-94. Seals 91 and 92 vertically extend along side walls 82 and 85 adjacent a side perimeter of air channels 88 as best shown in FIGS. 10 and 11. Seal 93 extends along the top perimeter of air channels 88 as best shown in FIGS. 10-12, and may be vertically adjusted up or down by use of pins 95, each of which engage a corresponding hole in a vertical series of holes arrayed to allow various discrete heights for use with different heights of palletized product 20. While pins 95 are preferred, alternatives for fixing either a discrete or continuous vertical position can be used, such as but not limited to ratchet mechanism, gear engaging or other mechanical positioning mechanism that will be apparent to those of skill in the art. Seal 94 serves as a pallet stop and extends along a bottom perimeter of air channels 88 as best shown in FIG. 13.

In order to improve the sealing effect of sealing barriers 90, they can have a surface facing the palletized products that is resilient, such as flexible tubing, or an elastomeric material, foam, spring loaded surface, or any other type of engaging material or surface mechanism, including those used in the prior art Meredith or Bottom patents referenced above. Preferably, each of the barriers 90, including seal 93, include rigid members that provide a rearward stop for pallets as they are inserted into position. As yet a further, less preferred alternative, palletized products 20 can be positioned touching one another, side by side, with vertical sealing barriers then only being used at each side of the combined array of pallets, and along the top and bottom of the array, so as to provide perimeter sealing on a stacking rack that encompasses plural palletized products.

While there is described above the preferred arrangement with the palletized product 20 engaging a seat against plenum chamber 80, alternative, less preferred arrangements could also be used, so long as at some location in the passage of freezing air through the stacked palletized products 20, the freezing air is mostly confined to flowing through the stacked products in the racks rather than around them. As one example, pivoting flaps or expandable tubing fixed to the racks could directly engage or nearly engage the midpoint of the top and sides of the stacked palletized product so as to direct the bulk of the freezing air through the stacked palletized products. When the palletized products are being inserted or removed from their stacked array on the racks, the pivoting flaps or expanding tubing would be retracted away from the palletized products, but when they are in position for blast freezing, the flaps or expanding tubing would be moved close to or touching the palletized products to optimize the blast freezing process.

The same could be done at the front of the stacked palletized products, or elsewhere anywhere along the direction of air flow, so long as the freezing air flow is mostly confined to flowing through the stacked products rather than around them. Thus the plenum can be void of any palletized product as in the preferred rack design, or it can contain part or all of the palletized products in these alternative rack designs.

Blast freezing apparatus 70 further incorporates a pair of guide rails 96 and 97 as best shown in FIG. 13 per pallet seat of pallet rack 90. It should be noted that at the outside ends of the guide rails, the vertical elements are wider apart than along the rest of the guide rails. This is accomplished in the preferred embodiment by an angled portions 98 and 99 on each side, but could also be accomplished by an outwardly curved portion, or other wider configuration, so as to more easily enable initial alignment of a palletized product being inserted into position on the rack. The increase in width at the outside ends of the guide rails is preferably at least 5% greater than the width of the guide rails where they meet seal 94, and most preferably about 10% greater.

To blast freeze a palletized product 20, a seating of a palletized product 20 involves a guiding of the palletized product 20 to sealing barrier 90 via guide rails 96 and 97, using angled portions 98 and 99 to aid in initial alignment, as sequentially shown in FIGS. 14A-14C. If necessary, prior to or subsequent to guiding the palletized product 20 to sealing barrier 90, seal 93 is vertically adjusted up or down to close any potential air gaps between air channel 88 and a top perimeter of the palletized product 20 while maintaining air flow passage for the top spacer 23 of the palletized product 20 as best shown in FIG. 14C, as viewed from inside the plenum. Upon palletized product 20 being properly sealed, fans 87 are activated to cause a uniform flow 100 of freezing air within the palletized product 20 in a substantially horizontal direction primarily through the spacers 23 into plenum space 86 as best shown in FIG. 14D. The flow rate of freezing air through the palletized product 20 is preferably greater than 50 feet per minute and most preferably greater than 100 feet per minute. With these flow rates, the temperature difference between the air temperature and the desired product temperature can be substantially less than in other rack mounted blast freezing units. The temperature difference can be as low as about 10° F., rather than the about 30° F. or more as is found in other rack mounted blast freezing units. A typical temperature goal is 0° F. for the product being blast frozen, and a typical warehouse temperature is −10° F.

The use of a single depth pallet rack with a vertically adjustable upper plenum opening member is preferred in conjunction with the seal barrier around the perimeter of the opening so as to provide a very efficient arrangement to rapidly and efficiently blast freeze the palletized products 20. This allows an array (having at least a height of at least two pallet assemblies and a width of at least two pallet assemblies) to blast freeze economically. Increasing the array to 3 by 6 (height by width) or more preferably 4 by 8 or 5 by at least 10 (height by width) further adds to the efficiencies.

FIG. 15 illustrates a freezing warehouse 110 having a storage section 120, a blast freezing section 130 and an air-cooling section 140. Storage section 120 includes rows of storage pallet racks 121 spatially arranged to form aisles 122. Each pallet rack 121 may have, as examples, a single pallet depth or a multiple pallet depth for providing easy access to the stored palletized products. Blast freezing section 130 includes rows of blast freezing apparatuses (e.g., blast freezing apparatus 70 of FIGS. 8 and 9) also spatially arranged to form aisles 131 in warehouse 110. The single pallet depth of the pallet racks of apparatuses 130 provides easy access to the seated palletized products. Air-cooling section 140 includes a row of air-cooling evaporators 141 for providing freezing air within blast freezing room 110 for both the freezing of palletized products in section 130 and the storage of frozen palletized products in section 120.

Alternatively, the storage pallet racks of storage section 120 may be omitted and replaced by additional blast freezing apparatuses 130. Typically, in a warehouse, storage occupies more than twice the space as the blast freezing apparatus, and preferably occupies more than 10 times the space of the blast freezing apparatus, and most preferably even more.

FIG. 16 illustrates prior art freezing storage room 40 shown in FIG. 4. It can be compared with FIG. 17 which illustrates a room 110 that contains the blast freezing apparatus of the invention. In the preferred embodiment, the two will be placed adjacent one another, to combine in one large commonly cooled room, regular warehouse storage and rack based blast freezing with seal directed horizontal freezing air flow through stacked in a rack, palletized products. Such combination is as shown in FIG. 15.

While the invention has been illustrated and described in detail in the drawings and foregoing description, the same is to be considered as illustrative and not restrictive in character, it being understood that only the preferred embodiment has been shown and described and that all changes and modifications that come within the spirit of the invention are desired to be protected.

Claims

1. A blast freezer for an array of pallet assemblies each including a plurality of products supported by a pallet, the blast freezer comprising: a source of freezing air,an air flow chamber including an air flow handler and an array of side air openings for facilitating a flow of freezing air between the air flow chamber and said freezing air source; anda pallet rack for positioning the array of pallet assemblies relative to the array of side air flow openings for channeling the flow of freezing air between the air flow chamber and the freezing air source through the array of pallet assemblies, wherein the pallet rack has a depth corresponding to the thickness of a single pallet assembly to facilitate freezing of the products supported by the pallet assemblies.

2. The blast freezer of claim 1, wherein the pallet assemblies include air flow passages for facilitating the flow of freezing air through the pallet assemblies.

3. The blast freezer of claim 2, wherein each air flow passage is defined by a spacer between at least two products.

4. The blast freezer of claim 1, further comprising: an air flow barriers interactive with the pallet assemblies for inhibiting the flow of freezing air around a perimeter of each of the pallet assemblies into the air flow chamber as freezing air flows between the air flow chamber and said freezing air source through the pallet assemblies.

5. The blast freezer of claim 4, wherein the air flow barrier is selected from a group consisting of at least one pallet seal encircling a perimeters of the air openings and at least one pallet flap adjacent the perimeters of the pallet assemblies.

6. The blast freezer of clam 4, wherein the air flow barrier includes at least one pallet seal encircling the perimeters of each of the air openings; andwherein the pallet rack is for positioning a side of each of the pallet assemblies against the at least one pallet seal.

7. The blast freezer of claim 6, wherein each of the at least one pallet seals has an upper portion that is vertically adjustable to allow for different height pallet assemblies to be used yet still have sealing along the side of a pallet assembly near its top.

8. The blast freezer of claim 6, wherein the pallet rack includes pallet guides for guiding the pallet assemblies against their corresponding pallet seals when placed in position.

9. The blast air freezer of claim 1, wherein the air flow handler pulls freezing air through the pallet assemblies into the air flow chamber.

10. The blast air freezer of claim 1 wherein the blast freezer is positioned within a freezer storage warehouse and the source of freezing air used for blast freezing is the same as is used for storage, but with the blast freezer forcing higher air flow rates through the pallets being frozen compared to the flow rates supplied to the stored, already frozen pallets.

11. The blast air freezer of claim 10 in which the source of freezing air is between 10 degrees and −20 degrees Fahrenheit.

12. The blast air freezer of claim 11 in which the source of freezing air is at about −10 degrees Fahrenheit.

13. The blast freezer of claim 1 wherein the side openings in the plenum that are adjacent pallet assemblies have vertically adjustable panels at the top of the openings to accommodate different height palletized products.

14. The blast freezer of claim 13 in which said panels are rigid.

15. The blast freezer of claim 14 additionally comprising locating pins between the panels and racks to allow for ready adjustment of the vertical position of said vertically adjustable panels.

16. The blast freezer of claim 15 in which the rack has a series of vertically arranged holes for pin engagement at different heights to permit ready adjustment of panel height.

17. The blast freezer of claim 1 in which said rack is sized to allow for an array of at least three pallet assemblies high and at least six pallet assemblies wide, while maintaining a depth of only one pallet assembly.

18. The blast freezer of claim 17 in which said rack is sized to allow for an array of at least four pallet assemblies high and at least eight pallet assemblies wide, while maintaining a depth of only one pallet assembly.

19. The blast freezer of claim 18 in which said rack is sized to allow for an array of five pallet assemblies high and at least ten pallet assemblies wide, while maintaining a depth of only one pallet assembly.

20. The blast freezer of claim 1 in which said rack is sized to allow for an array of five pallet assemblies high and at least ten pallet assemblies wide, while maintaining a depth of only one pallet assembly.

21. The blast freezer of claim 1 in which the an air flow handler has the capacity to provide for an air flow rater of freezing air through the palletized products at greater than 50 feet per minute.

22. The blast freezer of claim 1 in which the an air flow handler has the capacity to provide for an air flow rater of freezing air through the palletized products at greater than 100 feet per minute.

23. The blast freezer of claim 1 in which for each position in said pallet rack for positioning a pallet assembly there is just one corresponding side air opening in said air flow chamber.

24. The blast freezer of claim 1 comprising an air flow barrier interactive with the pallet assemblies for inhibiting the flow of freezing air around a perimeter of each pallet assembly as freezing air flows between the air flow chamber and the freezing air source through the pallet assemblies.

25. The blast freezer of claim 24, wherein the air flow barrier is selected from a group consisting of at least one pallet seal encircling a perimeter of the air opening and at least one pallet flap adjacent the perimeter of the pallet assembly.