Abstract
A mechanical apparatus comprised of a plurality of pods in the form of an annular cylindrical sleeve. All pods containing liquid are to be frozen for the purpose of dynamically transfer/impart its charged thermal energy to a directly contacted beverage object placed within. The pods are joined to each other by latitudinal elastic bands allowing it to expand readily and grip onto varying size beverage containers. Furthermore, the plurality of pods and a beverage container are disposed in an insulated holder; a sealable cap is then inserted to seal off and insulate the discharging of thermal energy therein from ambient conditions. A beverage in the form of can or bottle might be placed in the apparatus to achieve desired chill temperature for an extended length of time in high ambient temperature conditions.
Claims
1. An apparatus for the purpose of chilling a canned or bottled object, it is comprising: a. a cup like structure for receiving; b. a removable chiller of the form annular cylindrical sleeve capable of receiving a canned or bottled object, for which both are placed inside said cup like structure; then c. a removable cap with built-in seal structure to slip over, make contact with the canned or bottled object and latch onto said cup like structure to close-off the chamber within; and d. a raiser for adding more height to a shorter canned or bottled object placed inside said cup like structure.
2. The removable chiller of claim 1, wherein the removable chiller further comprising of a plurality of identical pods, whereas identical pods are collectively joined on equal spacing by latitudinal elastic bands.
3. The removable chiller of claim 1, wherein the removable chiller further comprising of a plurality of identical pods, whereas each identical pod is a partial fraction of an annular cylindrical sleeve.
4. The removable chiller of claim 1, wherein the removable chiller further comprising of a plurality of identical pods, whereas identical pods are collectively joined on equal spacing to form an annular cylindrical sleeve.
5. The latitudinal elastic bands of claim 2, wherein said latitudinal elastic bands are attached permanently and transversely on convex sides of identical pods.
6. The latitudinal elastic bands of claim 2, wherein said latitudinal elastic bands exerting radial compression force upon a cylindrical object placed within said removable chiller.
7. The latitudinal elastic bands of claim 2, wherein said latitudinal elastic bands enabling said removable chiller's interior compartment to expand/contract readily and uniformly when receiving/removing a cylindrical object.
8. The latitudinal elastic bands of claim 2, wherein said latitudinal elastic bands controlling the identical pods of said removable chiller to move out/in diametrically from a central axis when receiving/removing a cylindrical object.
9. The latitudinal elastic bands of claim 2, wherein said latitudinal elastic bands are classified as flexible rings.
10. The identical pods of said removable chiller to move out/in diametrically of claim 8, wherein the column spaces between the ends of adjacent identical pods are grown/shrunk radiantly and equally when receiving/removing a cylindrical object.
11. The identical pods of said removable chiller to move out/in diametrically of claim 8, wherein the annular cylindrical sleeve's natural formation can be reshaped to form an upright or inverted annular conical sleeve when fitting over a conical object.
12. The optional raiser of claim 1, wherein said optional raiser adding more height for a shorter cylindrical object.
Description
DESCRIPTION OF THE DRAWINGS
(1) For a more complete understanding of the present invention and the advantage thereof, reference is now made to the following description taken in conjunction with the accompanying drawing in which:
(2) FIG. 1 is an exploded perspective view of the invention.
(3) FIG. 2 is an exploded cross sectional front elevation view of the invention.
(4) FIG. 3 is a cross sectional view of a pod taken along line 8-8 in FIG. 2.
(5) FIG. 4 is a top plan view of the removable chiller assembly.
(6) FIG. 5 is a cross sectional front elevation view of the invention with relation to a 16 oz can inserted.
(7) FIG. 6 is a cross sectional front elevation view of the invention with relation to a 12 oz bottle inserted.
(8) FIG. 7 is a cross sectional front elevation view of the invention with relation to a 12 oz can inserted including the optional raiser.
(9) FIG. 8 is a top plan view of the removable cap.
(10) FIG. 9 is a top plan view of the cup with an expanded removable chiller inside. The natural state of the removable chiller is shown as dashed lines.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
(11) Referring to FIG. 1, there is shown an embodiment of an apparatus of the present invention. In the preferred embodiment, the apparatus comprises a main body portion 1, a removable chiller 2, a cap 3, and a optional raiser 4.
(12) To make reading and identifying the elements easier to follow; from here on: the body portion 1, a removable chiller 2, a removable cap 3, and a optional raiser 4 will be referred as a cup 1, a chiller 2, a cap 3, and a raiser 4 respectively.
(13) The main body portion 1 is a cup like configuration designed to receive the chiller 2, a raiser 4 (optional), a cap 3, and a beverage object to be chilled (FIGS. 5-7). The cup 1 is preferably constructed singularly of thermoplastic resins such as Polycarbonate, ABS, LDPE, or HDPE etc. All depended, but not limited to, on the desired strength, durability, cosmetically, availability and cost factor. It is further noted that the cup 1 also be made of metals such as Aluminum, Stainless Steel, Titanium etc. for high end market. With metal construction, there should be consideration of a rubber or thermoplastic layer on the interior wall of cup 1 to insulate/shield the high thermo conductivity associated with the metals. It is to reduce frosting and condensing conditions occur on the cup's exterior wall.
(14) The chiller 2 comprises of plurality of pods 21, each pod 21 is a partial fraction of an annular cylindrical sleeve (FIG. 4), whereas, the concave side (211) and convex side (212) are of concentric circles. Pods 21 are collectively joined on equal spacing by latitudinal elastic bands 22 to form an annular cylindrical sleeve 2 (FIGS. 1 & 4). A pod 21 is generally constructed of any thermoplastic resins with suitable strength, durability, availability, and cost factor. It is of utmost important, the wall thickness of a pod 21 be constructed as thin as possible, yet still meet the strength and durability requirements, and for maximum thermal energy transfer to a desired object. Because the wall thickness of pod 21 acting as an insulating layer, thermoplastic is not as good as metal in term of thermal conductivity, thus the thermo energy discharge of the thermoplastic pods to an object is less effective when they are in contacted with each other. It is highly preferred that pods 21 be made of metal that has excellent rate of thermal conductivity such as Copper or Aluminum. These metals are highly ductile and can be made very thin wall and yet met the strength and durability requirements. FIG. 3 shown a cross section of a pod 21 filled with distilled water 23 to approximate 90% of its volume. The 10% air volume 24 is allowed for freeze expansion of the distilled water 23 inside. Distilled water 23 is chosen for its purity, non-toxic and faster freezing rate over gel material. The method of filling pods 21 with distilled water 23 then seal off the mean for filling the water is readily known and can be done in variety of techniques, thus it is not discussed here.
(15) The chiller 2 is a plurality of pods 21 (FIG. 4) joined on equal spacing by latitudinal elastic bands 22. A latitudinal elastic band 22 is preferably made of Rubber like materials such as Silicone, Neoprene, EPDM etc. that possessed high UV tolerant, good elongation and good retention characteristics. The significant of the latitudinal elastic bands 22 (FIG. 1) is paramount. The latitudinal elastic bands 22 enable the chiller 2 to expand/contract readily and uniformly the interior compartment 25 to receive different objects of varying diameters (FIGS. 5-7, 9). As the chiller's 2 interior compartment 25 expanding/contracting when receiving/removing a beverage object; it's causing each pod 21 to move out/in diametrically, while the column spaces (26) (FIGS. 1,4,9) between end edges of adjacent pods 21 are also growing/shrinking radiantly and equally accordingly. More and of equal important is the latitudinal elastic bands 22 exerting a radial gripping action upon the inserted object. Naturally, the radial gripping action causing a direct contact of the pods' 21 concave surfaces 211 (FIGS. 1,4,9) with the object. Inherently, the direct and full surface contact and the radial compression force (gripping action) of the chiller 2 imposing on the object are the absolute must desired conditions for maximum transfer of thermal energy.
(16) As more fully illustrated in FIGS. 1 & 2, the cap 3 contributes to the all important of the invention; by capping and sealing off, the dissipation rate of thermal energy from the beverage object and the chiller 2 is trapped, delayed, circulated and insulated from ambient conditions. The cap 3 is comprised of two parts of two different materials molded together. The base cap 31 is preferably constructed of thermoplastics resins with suitable strength, durability, cosmetically, availability, and cost factor. It is designed to press and snap over cup 1. The ring seal 32 is preferably constructed of Silicone, Neoprene, Thermoplastic Elastomer etc. that possesses high UV tolerance, good elongation and good retention characteristics. The aperture 33 (FIGS. 1 & 8) is designed to be smaller than the smallest known diameter of a cylindrical object. The ring seal 32 is made thin so its inner lip 321 can stretch easily over a bigger diameter (FIGS. 5-7) and produce a tight seal on the inserted object. Importantly, the ring seal 32 is molded directly with base cap 31 to form a single partthe cap 3.
(17) Further illustration of the embodiment of the invention is shown the raiser 4 (FIGS. 1, 2 & 7). The raiser 4 is generally constructed of any thermoplastic resins with suitable strength, durability, availability, and cost factor. The raiser 4 is an optional part and used only when an inserted object is shorter than the cup 1 and cap 3 disposed of together. This unique part allows pods 22 being made taller and have bigger volume to produce more thermal energy, and more surface contact with the object. All of which are desired conditions for the best thermal transfer.
(18) FIGS. 5-7 shown an annular space 5. It is important to know that chiller 2 may be distorted and bulged due to freeze expansion of distilled water 23 on each pod 21. The annular space 5 is designed to accommodate the distortion and bulging of the chiller 2 and also providing a separation space to cup 1.
(19) A quick look at FIG. 1, one will note the simplicity of the design and the use of the invention. Prior to usage, the chiller 2 is froze to an icy condition. It is then slips over a pre-chilled canned or bottled object (FIGS. 5-7). Depending on the object's height; the optional raiser 4 will be used as illustrated in FIG. 7. The canned or bottled object together with the chiller 2 and the optional raiser 4 are placed in cup 1. The cap 3 then slips over the object and continues to move down to snap onto the cup 1. The inner lip 321 (FIGS. 1,2,5-7) of seal ring 32 expands and stretches over the object to seal off and insulate the chamber below. Icy condition (charged thermal energy) of the chiller 2 is protected by the sealed chamber. It is being insulated to deliver and maintain maximum coldness to a beverage object for an extended length of time; which is the novelty of the invention.
(20) As known from above, the embodiment of the invention illustrates and details the simple, effectiveness and usefulness of an apparatus to deliver the desired chill temperature to any canned or bottled beverages.
(21) It will be apparent that many applications will lend themselves to utilization of this invention. Although, the invention is particularly suited for chilling canned or bottled beverages, the invention could be modified and utilized for other industries.
(22) While certain novel features of this invention have shown and described in the annexed claims, it will be understood that various omissions, substitutions and modifications in the forms and details of the apparatus illustrated and in its operation can be made by those skilled in the art without departing from the spirit of the invention.
