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Claims  |
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What is claimed is:
1. An apparatus for intermittently operating a dispensing container at
below freezing temperatures comprising, in combination:
a reservoir;
a chilled coolant fluid normally contained in said reservoir;
conventional refrigeration means in heat exchange relationship with said
coolant fluid for maintaining said coolant fluid at a first temperature
substantially below the freezing point of water;
a dispensing container remote from said reservoir for intermittently
receiving and dispensing a water-containing substance, said container
being provided with a circulant coolant passage, said passage having a
volumetric capacity substantially less than the quantity of coolant fluid
in said reservoir;
conduit means in communication between said reservoir and said passage for
conveying said coolant fluid therebetween, said conduit means including
pump means, and selectively operably valve means to commence and terminate
flow of coolant fluid to said passage;
selectively operable means for intermittently providing said remote
dispensing container with said water-containing substance, and dispensing
such substance from said container after cooling thereof; and
means for coordinating the intermittent operation of said valve and said
dispensing container so that said coolant fluid is supplied to said
passage only during the period of time the water-containing substance is
in said container.
2. An apparatus as defined in claim 1 wherein:
said circulant coolant passage is annular and surrounds said container, and
said coolant flows from said passage into said conduit means at a bottom
end of said passage whereby, upon said termination of flow of coolant
fluid to said passage, any of said coolant remaining in said passage is
gravity drained therefrom for terminating the cooling effect thereof.
3. An apparatus for making a frozen food article comprising:
a frozen food article freezing and dispensing chamber of low thermal mass
having walls on which the frozen food article can be frozen;
means for dispensing water-containing frozen food liquid onto said chamber
walls;
whipper-scraper means for whipping the frozen food article as it freezes on
said walls and scraping it off said walls and dispensing the frozen food
article;
refrigeration means for refrigerating said walls, said refrigeration means
including a separate container of high thermal mass of chilled coolant
which can be controllably discharged behind said walls for refrigerating
said freezing chamber walls; and
control means for maintaining said freezing chamber at ambient temperature
during standby periods and for circulating coolant behind said walls upon
demand for a frozen food article, with operation of said whipper-scraper
means and with supplying of liquid food material to said walls subsequent
to the beginning of circulation of coolant to said walls.
4. The apparatus of claim 3 comprising:
a pump connected to circulate said coolant, said pump selectively,
discharging chilled coolant to said walls;
said food freezer being positioned above said coolant container; and
a coolant return line for gravitationally draining coolant back to said
container.
5. The apparatus of claim 4 comprising:
a recirculating valve positioned at the discharge of said pump, said valve
having an outlet to said food freezer and having an outlet to said coolant
container so that, upon operation of said pump, said valve can return
coolant directly to said coolant container to circulate said coolant and
chill said pump and said valve.
6. The apparatus of claim 5 comprising:
a thermostat at said pump, said thermostat controlling pump operation, and
said control means controls said valve and also controls said pump.
7. The apparatus of claim 3 comprising:
said freezing chamber walls being cylindrical with the axis thereof
positioned away from the horizontal for gravitational discharge of the
frozen food article, said cylindrical chamber being open ended.
8. The apparatus of claim 7 comprising:
an annular coolant chamber positioned behind said walls for receiving said
coolant when refrigeration of said walls is desired;
said food freezer is positioned above said coolant container; and
a gravitational return line for returning coolant from said annular coolant
chamber to said coolant container.
9. A process for intermittently operating a dispensing container at below
freezing temperature, comprising:
maintaining a coolant fluid in a reservoir having a first volumetric
capacity at a temperature substantially below the freezing point of water;
providing a dispensing container with a coolant passage having a second
volumetric capacity substantially less than said first volumetric
capacity;
intermittently providing said dispensing container with a water-containing
substance; and
supplying and circulating the coolant fluid between said reservoir and said
passage in heat exchange relationship with said dispensing container only
in immediate anticipation of and during the period of time the
water-containing substance is in said container for enhanced rapidity of
cooling during the cooling period and for elimination of rime ice
formation on the dispensing container during non-cooling periods.
10. The process of claim 9 further including:
the step of whipping and scraping the water-containing substance as it
freezes in said dispensing container to disperse the whipped and frozen
water-containing substance from the dispensing container.
11. The process of claim 10 wherein:
the termination of the production of the frozen water-containing substance
is accomplished by first terminating the providing of the water-containing
substance, then terminating the circulation of coolant fluid and finally,
after the dispensing container has reached a temperature above the
freezing point of water, terminating the action of the whipper-scraper.
12. The process of making a frozen food article in a food freezing chamber
which is maintained at above freezing temperatures during standby periods
comprising the steps of:
supplying and circulating a coolant fluid at a temperature below the
freezing point of water through a coolant fluid path in said food freezer
from a source of coolant fluid having a greater thermal mass than said
food freezer to quickly reduce the temperature of the food freezer below
the freezing point of water;
allowing the food freezer walls to reach a sub-freezing temperature;
placing water-containing liquid food on the walls of said food freezer; and
operating a whipper-scraper adjacent to the walls of the food freezer to
whip the water-containing food substance as it freezes and scrape it from
the walls to dispense the frozen food article from the food freezer.
13. The process of claim 12 wherein the process of producing the frozen
food article is terminated by the steps of:
terminating supply of the water-containing liquid food to the walls of the
food freezer;
terminating supply of the coolant fluid to the walls of the food freezer so
that the wall temperature rises above the freezing point of water and
remaining food substance is permitted to gravitationally drain from the
walls; and
terminating action of the whipper-scraper. |
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Claims |
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Description |
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BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention is directed to a method and apparatus for making a frozen
food article, and particularly an apparatus which is maintained in a ready
state for freezing, without having the freezing chamber at reduced
temperature to prevent retention of portions of prior frozen food and to
prevent the formation of rime ice.
2. Brief Description of the Prior Art
The conventional refrigerating or freezing device comprises a compressor
which compresses a refrigerant gas such as Freon, ammonia or nitrogen
which is then expanded into an evaporator to allow the fluid to expand and
evaporate and in so doing absorb heat whereby an article may be cooled or
frozen. This fluid is then again compressed and condensed and the cycle is
repeated. In some cases, a container is surrounded by coils or is
submerged in a liquid which has been cooled by a refrigerating apparatus
so that an article placed in the container is either cooled or frozen. An
example is seen in the U.S. Pat. to Spreen, No. 1,764,653. In this patent
there is disclosed a refrigerating system which includes a compressor and
an evaporator which is immersed in a liquid. Also, submerged in this
liquid are containers into which articles to be cooled can be placed and
maintained in a cooled or frozen state. Another example is seen in the
U.S. Pat. to O'Neil, et al., No. 2,058,098. This patent shows a
refrigerating and dispensing system whereby the evaporating coils surround
a soda dispenser to cool the beverages so that upon demand the beverages
may be dispensed into such containers as paper cups and the like.
In the U.S. Pat. to Palmer, No. 3,041,852, there is disclosed a
refrigerating apparatus which is contained in one unit whereby the coolant
is transferred via a coil to a separate container which, in the example
shown, is a garbage container. Thus, a compressor and evaporative unit is
contained in one unit and a separate container to receive the evaporative
coolant is utilized to cool an article contained therein.
As will appear from the further portions of this specification, this prior
art is not directly pertinent, but is generally directed to refrigeration
systems for food materials. In addition, Ash U.S. Pat. No. 2,590,061
discloses a system wherein a fluid is maintained at a relatively constant
temperature for dispensing to and cooling a remote vat but this fluid is
not recirculated back to the reservoir, because the fluid is not a
coolant. Bright U.S. Pat. No. 2,040,828 is similar to Ash, but it must be
noted that the volumetric capacity of Bright's fermentation tank is
substantially greater than the volumetric capacity of his cooling
apparatus, which is largely opposite from the teaching set forth below.
Furthermore, while Haley U.S. Pat. No. 2,720,084 employs a separate
refrigerator for chilling a circulating coolant, the coolant is for air
conditioning service and there is no teaching of a particular type of food
freezing chamber.
SUMMARY OF THE INVENTION
This invention is characterized by a refrigerating unit which cools a
coolant in a coolant chamber of large thermal capacity. An open-ended food
freezing chamber of low thermal capacity is at ambient temperature at
standby but, when food freezing is desired, the coolant is circulated
through coolant space in the chamber to rapidly chill the chamber. After
the food is frozen, the coolant is drained from the cooling space to
permit the chamber to return to ambient temperature.
It is thus an object of this invention to provide both a method and
apparatus for making a frozen food article, where the frozen food chamber
is open at the end and where it is supplied with a coolant when it is
required, and is permitted to remain at ambient temperature when cooling
is not required, to prevent the buildup of rime ice during idle periods.
It is a further object to provide a method and apparatus for making a
water-containing frozen food article from fruit or vegetable juice, or
from fruit or vegetable puree to result in a comestible in chilled whipped
slush form for ease and desirability of consumption. It is yet another
object to provide a method and apparatus for making a frozen food slush
edible which is satisfactory for use as the operative element of an
automatic dispensing machine for such a food product, which is capable of
periods of non-operation without objectionable results.
The features of the present invention which are believed to be novel are
set forth with particularity in the appended claims. The present
invention, both as to its organization and manner of operation, and
together with further objects and advantages thereof may be understood
best by reference to the following description taken in connection with
the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWING
The single FIGURE of the drawing is a side elevational view of the
apparatus, somewhat schematically arranged, and with parts broken away and
parts shown in section, together with a schematic layout of the control
system whereby the various portions of the apparatus are controlled.
DESCRIPTION OF THE PREFERRED EMBODIMENT
The refrigeration unit is generally indicated at 2 in the drawings.
Refrigeration unit 2 includes motor 4 which operates compressor 6 and fan
11. The compressor delivers high pressure refrigerant gas through conduit
8 to condenser 10. Heat is rejected to the atmosphere from the condenser,
particularly aided by air circulation thereover induced by fan 11. The
refrigerant gas is condensed to refrigerant liquid in condenser 10 and the
liquid is delivered through high pressure liquid line 12 to expansion
valve 13. The liquid is expanded to lower pressure and evaporates to a gas
in evaporator coils 14, with a reduction in temperature and consequent
receipt of heat from the region outside of evaporator coil 14. The warmed
low pressure refrigerant gas is connected to the suction of compressor 6
to complete the refrigerant cycle. This type of conventional refrigerator
often has a thermostatically controlled expansion valve 13 which is
responsive to the temperature surrounding evaporator coils 14. In such a
case, the cycling of the compressor is pressure controlled, so that high
pressure refrigerant liquid is always available as refrigeration need
occurs.
Refrigerator unit 2 is a conventional cooling refrigerating apparatus in
which the compressor compresses the refrigerant fluid which is then
condensed, and then the high pressure refrigerant liquid is expanded into
the exaporator coil to receive the heat contained in the coolant 20 around
the evaporator coil. When coolant 20 has a freezing point below
32.degree.F, such as ethylene glycol or a mixture of ethylene glycol and
water, the coolant 20 can be cooled to a temperature below 32.degree.F,
for example -10.degree.F or lower. A half and half mixture of ethylene
glycol and water is preferred as coolant 20, but other liquid coolants
capable of effectively operating in the -10.degree.F range are also
satisfactory. Container 16 contains the coolant and includes thermal
insulation 18 to minimize the gain of heat into coolant 20 through the
walls of container 16. The container may have a cover 19 to minimize
thermal convective losses from the top surface of the coolant.
Coolant circulating pump 24 takes suction by intake line 22 from the bottom
of coolant 20. Pump 24 discharges into outlet conduit 28, which is
connected to three-way valve 30. One of the outlets from three-way valve
30 is through return or recirculating conduit 26 which returns the pump
coolant back to container 16. Switch 25 controls the electric motor which
drives pump 24. Temperature sensor 27 senses the temperature of the
coolant in container 16 and, when the temperature rises substantially
above the normal temperature of coolant 20, then both the refrigeration
motor 4 of refrigeration unit 2 and the pump 24 turn on, with valve 30 in
the recirculating position. For example, if a normal temperature of
coolant 20 is -10.degree.F, then the pump can turn on when the temperature
sensor 27 detects a local temperature at that point above -5.degree.F. The
pump thus pumps and recirculates the coolant 20 to keep line 22, pump 24,
line 28 and valve 30 chilled, as well as to prevent thermal stratification
of the coolant in container 16. Of course, the coolant handling parts are
preferably insulated to conserve refrigeration. The refrigeration unit 2
and pump 24 run until temperature sensor 27 is satisfied.
Three-way valve 30 is preferably the solenoid-actuated type and is
controlled by master control unit 31. When actuated, valve 30 connects
valve inlet line 28 to outlet coolant line 29. Furthermore, master control
unit 31 is also connected to switch 25 so that when valve 30 is actuated
to discharge into line 29, the pump 24 is always operative. Thus, when
valve 30 is actuated, the thermal control of switch 25 from temperature
sensor 27 is overridden, and pump 24 runs continuously as described in the
operational sequence below.
Food freezer 32 is open-ended, top and bottom, and has cylindrical freezing
walls 33 therein. Annular coolant chamber 36 surrounds the freezing walls
33. Thermal insulation 34 surrounds the outside of the annular coolant
passage 36 to minimize thermal loss. Coolant line 29 is connected to the
top of passage 36 and return conduit 38 is connected to the bottom of
passage 36. It is thus seen that, with pump 24 on and with valve 30 open
to line 29, coolant 20 circulates through annular coolant chamber 36 and
flows back to container 16 through return conduit 38. The volume of
annular coolant chamber 36 is very small as compared to the volume of
container 16, for example about 1/64 of the volume. Also, walls 33 are
thin so that there is very low heat capacity in food freezer 32. If
freezer 32 starts at ambient temperature, from the beginning of
circulation of coolant 20 through annular coolant passage 36, it is only a
very short time, e.g., less than three seconds, until the walls 32 are
sub-freezing. The large volume of chilled coolant, its fast circulation,
and the low thermal mass of freezer 32 provide fast cooldown. Freezer 32
is positioned above container 16 so that when the pump stops, chamber 36
quickly gravity drains.
Motor 40 is mounted so that its shaft 42 extends into the freezing chamber
defined interiorly of freezing walls 33. Three beater-scraper blades 44
are mounted on shaft 42 and engage substantially against the circular
walls 33. Blades 44 are straight axially along the length of shaft 42, but
have angularly notched edges 45 which serve to advance frozen material
downwardly along the freezing walls 33. Cup 52 is positioned below the
open lower end of the interior freezing chamber defined by walls 33. Motor
40 is controlled from master control unit 31.
Reservoir 48 contains the food product to be frozen. The food product
contains water, and it may be a juice of fruits or vegetables.
Furthermore, it may be a puree of fruits or vegetables, containing some
fruit pulp. It is a sufficiently liquid fluid to be able to be pumped and
sprayed. Juices of tree fruits, berries, and other fruits, as well as
vegetables and purees thereof, are suitable materials to serve as a liquid
starting material for the frozen food article. Any convenient means can be
employed to spray the food material from nozzle 50 onto the walls 33.
Conveniently, air compressor 47 pressurizes reservoir 48 and, upon opening
of valve 49, the liquid food product is delivered under pressure through
line 46 to nozzle 50. The nozzle delivers the fluid to walls 33 as a thin
liquid layer which is frozen and then processed by the scrapers.
In considering the operation, pump 24 operates on a thermostatic cycling
basis to maintain coolant 20 circulated to prevent thermal stratification
in container 16, to keep lines 22 and 28 cool, and to keep pump 24 and
valve 30 cool. The coolant 20 is maintained at -10.degree.F or below. When
a frozen food article is desired, the cycle is initiated at master control
unit 31. The initiation can be by way of deposit of a coin in the
mechanism, when the apparatus is a coin dispenser. Otherwise, it is simply
a start cycle button. At the start cycle, valve 30 is actuated to
discharge coolant into line 29, pump 24 is continuously operated and a 2
to 3 second time delay is held before spraying of the liquid food material
to permit the chamber walls 33 to be properly chilled. Due to the low heat
capacity of food freezer 32, chilling is quickly accomplished. Whipper
motor 40 can be started at the start cycle or can wait until the beginning
of the liquid spraying portion of the cycle. The whipper scraper blades 44
rotate at a sufficiently high speed to ship the food material and entrap
air therein. Valve 49 is opened, when timer 51 is started by master
control unit 31, to permit reservoir 48 to discharge the liquid food
material out of nozzle 50. Solenoid-actuated valve 49 remains open a
predetermined length of time, controlled by timer 51, to permit spraying
of a desired quantity of liquid food material. While other quantity
measuring means are conceivable, a time-operated valve in conjunction with
a pressurized reservoir feeding the nozzle provides sufficient accuracy of
liquid food material dispensing. The liquid food material spray rate out
of nozzle 50 is such that the freezing chamber is not completely filled.
Air is always present so that the high speed whipper-scrapers 44 whip and
aereate the liquid as it is frozen. A speed of 1000 rpm of the
whipper-scrapers is suitable with most food materials. The high
refrigeration capacity supplied from container 16 coupled with the small
volume and low thermal mass of food freezer 32 permits continuous freezing
of the liquid food material, while it is beaten and scraped. Scraping
moves the whipped and frozen food material down into cup 52.
With the cup still in place, coolant valve 30 is switched to recirculate
the coolant down return line 26, and the annular coolant chamber 36
quickly gravitationally drains down return conduit 38 so that no more
refrigeration is supplied to food freezer 32. The low thermal capacity now
permits the interior of the food freezer to quickly warm up. With the
whipper-scraper rotating and the cup in place, any of the frozen material
which has been retained on the walls is released and runs down into the
cup, for self-cleaning. Finally, the whipper scraper is turned off and cup
52 is removed. The complete cycle for producing the frozen food article is
in order of seconds rather than minutes so that it is convenient to
operate as a coin operating dispensing device.
With the food freezer 32 now warmed up, rime ice does not form so that
there is no rime ice contamination of the next made article, and there is
no rime ice formation to freeze the blades 44 in place. Accordingly, the
freezing chamber remains clean and ready for the next operation.
This invention having been described in its preferred embodiment, it is
clear that it is susceptible to numerous modifications and embodiments
within the ability of those skilled in the art and without the exercise of
the inventive faculty. Accordingly, the scope of this invention is
intended to be defined by the scope of the following claims.
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