[0001] This invention pertains to a method of cooling and dispensing beverage, and to apparatus
for cooling and dispensing beverage in which the beverage is precooled before admittance
into a storage reservoir; the dispensing rate is far greater than the refill rate.
[0002] Cold beverages, be they carbonated or non-carbonated, are preferably served at a
temperature as close to freezing as is possible. Specifically the preferred serving
temperature is as close to 0 degrees C as is possible. The highest acceptable temperature
of dispensed beverage per the standards for the soft drinks of the Coca-Cola. Company,
the Pepsi-Cola Company, 7-UP Company, Dr Pepper Company, Royal Crown Cola Company
and their many competitors is 4.4 degrees C. A temperature higher than this is considered
unsatisfactory.
[0003] As the beverage temperature becomes higher, ice is needed in the cup and the beverage
then becomes diluted with melting ice water. Off-taste is a problem from melting ice
water, foaming and loss of carbonation is a further problem.
[0004] Ideally a soft drink should be dispensed at 0-2.2 degrees C; 4.4 degrees C is the
upper limit of acceptability. It is very difficult to attain 0 degrees C dispensing
because this is at the freezing point of water and refrigeration controls and temperature
controls are unable to reliably maintain this temperature without occasional freeze-up.
An ice bank type beverage cooler and dispenser can attain dispensing temperature at
or close to 0 degrees C with the use of relatively massive quantities of ice, but
an air-cooled or direct refrigerant cooled beverage cooler and dispenser can reliably
attain only 2.2-4.4°C dispensed beverage.
[0005] The normal desired carbonation for cola, lemon-lime, root beer, and most soft drinks
other than orange is= 3.5 to 4.5 volumes of carbon dioxide gas in the finished drink.
Carbonation devices and systems are very sensitive to water or beverage temperatures.
For example, at 2.2 degrees C, 1.27 kg/sq cm carbon dioxide pressure gives 3.5 volumes
of carbonation; at 7.8 degrees C, 1.76 kg/sq cm is necessary to obtain 3.5 volumes.
In post-mix soft drink dispensing, 5 parts of carbonated water are mixed with 1 part
of non-carbonated syrup and the carbonation of the mixed drink ends up being about
five-sixths of the carbonation of the water. Specifically, if a carbonation of 3.5
volumes is wanted, the carbonated water must have 4.2 volumes. In order to attain
4.2 volumes at 2.2 degrees C a pressure of 1.76 kg/sq cm is required. However as water
warms up the pressure must be increased or the attained carbonation falls off. For
example, 1.76 kg/sq cm at 5.6 degrees C gives 3.8 volumes which dilutes to 3.1 volumes
in the finished drink, and 1.76 kg/sq cm at 8.9 degrees C gives 3.4 volumes which
dilutes to 2.8 volumes in the finished drink, 1.76 kg/sq cm at 12.2 degrees C gives
3.0 volumes which dilutes to 2.5 volumes in the finished drink.
[0006] In commercial and factory soft-drink cooling, carbonation and dispensing systems,
these physical constraints imposed by water, syrup, pressure and temperature are met
with concentrated and relatively expensive hardware which bring horsepower, high pressure,
booster pumps, large heat exchangers and other special and relatively expensive hardware
to bear upon these problems. The constraints are solved with costly componentry.
[0007] What we have been trying to do for several decades is to devise a low-cost, reliable,
simple, relatively uncomplicated method and apparatus for cooling, carbonating and
dispensing soft drinks, the kind of method and apparatus that can be used in a home,
or a professional office, or for weekend parties.
[0008] One such recent attempt is that of John R McMillin as is shown and taught in his
copending United Kingdom Patent Application No 2 133 086. This particular system has
a miniature refrigerator cabinet with a 30 watt electro-mechanical compressor. This
is the smallest compressor available in the world as of this date. Within a cooling
compartment is an evaporator which cools air in the cooling chamber. Within the cooling
chamber are three syrup reservoirs, each of which holds about 1.9 litre of soft drink
syrup. Also within the cooling chamber is a combination water reservoir and carbonator.
The reservoir is closed and pressurized with carbon dioxide gas and sized to hold
about 18.9 litre of water. The reservoir has a float and needle valve fill control
connected to a water supply line. An outlet from the reservoir goes to a dispensing
nozzle.
[0009] The carbonation pressure upon the reservoir and the water therein is at 1.76 kg/sq
cm constant and the thermostat is pre-set to maintain the water at about 1.7 degrees
C. When this system is initially filled with water and syrup, it takes about 72 hours
for the water and syrup to be cooled and carbonated to produce a drink at 2.2 degrees
C. This system produces an excellent finished beverage with a reliable 3.5 volume
of carbonation and 2.2 degrees C temperature.
[0010] The problem is lack of dispensing capacity. As drinks are dispensed, cold carbonated
water is drawn out of the reservoir and is replaced by relatively warm non-carbonated
water which needs to be cooled and carbonated. The refilling rate is far in excess
of the cooling capacity of the refrigeration system and the water in the reservoir
increases in temperature and decreases in carbonation until the system can no longer
dispense a satisfactory drink. As this machine was embodied, it could dispense up
to twenty 6 oz (177 ml) drinks before the carbonated water became too warm and the
carbonation became too low. Specifically, dispensing of 3540 ml of beverage withdraws
2950 ml of water from the reservoir. After replacement of the 2950 ml of cold carbonated
water with warm non-carbonated water, the water in the reservoir warms up to 5.1 degrees
C and has at the most 3.8 volumes of carbonation. The dispensed drink will be at 4.6
degrees C or higher and have 3.2 or less volumes of carbonation. When ice is placed
in the drink, the temperature will go down, but the flavour and carbonation both become
diluted.
[0011] One method that has been utilized to increase the dispensing capacity of this unit
is to shut off the water inlet. Then you can dispense the entire contents without
dilution, warm-up and carbonation loss. The problem with this is that it is a nuisance
and the refrigeration capacity, during the period in which the water is shut off,
is lost. After dispensing, when the water line is then turned back on, the refrigeration
starts itself. The dispenser will have to recover itself during the night and on following
days.
[0012] It can be seen that this system works and dispenses well, but it does not have sufficient
dispensing capacity to enable it to utilize and dispense its cooled and carbonated
contents.
[0013] It is an object of the present invention to provide a cold beverage dispenser of
low cost and minimal complexity that has a substantial dispensing capability.
[0014] By the present invention there is provided a beverage cooling apparatus including
a cabinet, a water reservoir located within the cabinet, means to cool the air inside
the cabinet, means to carbonate the water within the reservoir and means to supply
water to the reservoir characterised in that water is supplied to the reservoir through
a precooler which has a substantial restriction to flow therethrough so as substantially
to precool the water prior to entering the reservoir.
[0015] The present invention further provides a beverage cooling and dispensing apparatus,
comprising
a) a refrigerator having a cabinet, a cold air cooling chamber in the cabinet, and
a refrigeration evaporator for withdrawal of heat from the air within the chamber;
b) a beverage reservoir in the cooling chamber;
c) a beverage outlet form the reservoir to a - dispensing valve; and
d) a thermally conductive precooler in a beverage inlet to the reservoir, said precooler
being within the air in the cooling chamber and in thermal communication with the
refrigeration evaporator via the air in the cooling chamber, said precooler having
a substantial restriction to flow of beverage therethrough.
[0016] The precooler may have a surface area to volume ratio at least a magnitude greater
than the surface area to volume ratio of the reservoir. The ratio may be at least
two magnitudes greater, may be in the range 200 to 400 and may be about 350.
[0017] The precooler may have an exchange capacity at least approaching the heat exchange
capacity of the reservoir amd may have a greater capacity which may be an order of
magnitude greater. The mass of the precooler may exceed the mass of the beverage therein.
[0018] The precooler may be an elongate length of tubing, which may be a capillary tube
with a length to diameter ratio of at least 1000:1, or 5000:1, or at least 6000:1.
The capillary tube may have a fitting on the inlet and outlet ends, a plastic connector
tube between the outlet end fitting and the reservoir, and a plastic connector tube
connected to the inlet end fitting.
[0019] There may be a check valve between .the capillary tube and the reservoir. The tubing
may be a helical coil which may be below and spaced from the refrigerator structure.
Each coil may be spaced from the next coil.
[0020] The helical coil may be suspended and hung in a general U-shape within the cooling
chamber and may be hung from its inlet and outlet ends, the ends being spaced from
each other. The helical coil may be hung from a reservoir retainer and may be hung
by a pair of S-shaped hanger clips.
[0021] The tubing may be wound around the reservoir and may be wound in the form of a helical
coil. The coil may be spaced outward from the reservoir. There may be a coil rack
on two sides of the reservoir.
[0022] There may be a water pressure regulator on an upstream end of the precooler, the
regulator may be outside the cooling chamber. The reservoir may be a sealed and pressurised
water tank, the tank including a level control connected to an outlet of theprecooler,
the level control having a valve operable for closing the beverage inlet and for maintaining
a pressurised gas head upon water in the tank.
[0023] The present invention further provides a beverage precooler for a beverage cooling
and dispensing apparatus, comprising
a) an elongate length of tubing having a restrictive inner passageway and an exterior
surface area at least a magnitude greater than the volume of the passageway; and
b) means on each end of the tubing for connection to an inlet line and outlet line
respectively.
[0024] The coils may be fabricated closed and installed open.
[0025] The present invention yet further provides a beverage precooler kit for a beverage
cooling and dispensing apparatus,comprising
a) a thermally conductive beverage precooler having an inlet, and outlet, a passageway
having a substantial restriction to flow of beverage therethrough, and an external
surface area at least a magnitude treater than the volume of the passageway; and
b) a beverage pressure regulator installable on the upstream end of the inlet, said
regulator being set to effect a constant pressure upon the inlet.
[0026] The pressure regulator may be preset to a pressure range between 35 to 45 PSIG.
[0027] The present invention yet further provides a method of cooling and dispensing cold
beverage, comprising the steps of:
a) storing a supply of previously precooled beverage in a storage reservoir;
b) dispensing servings of cold beverage from the storage reservoir at intermittent
intervals;
c) replenishing the storage reservoir supply with new beverage at an incoming flow
rate substantially less than the dispensing flow rate by:
i) restricting the incoming beverage flow to a trickle, and
ii) running the incoming trickle flow through a precooler; while
d) cooling both the reservoir and the precooler, and the beverage therein.
[0028] The supply may be pressurised with a pressurised gas head. The dispensing volumumetric
flow rate may exceed the volumetric trickle flow rate by at least a magnitude, by
at least two magnitudes, may be in the range 400 to 500 times the trickle flow rate.
The pressure of the beverage may be located upstream of the precooler. The trickle
flow may be cooled to 4.4 degrees C or less prior to the trickle flow being admitted
into the precooler, The reservoir and precooler may be cooled by a common flow of
cooled air, which flow may-be convective.
[0029] The method may further include the steps of:
a) maintaining the heat exchange capacity of the precooler during dispensing and replenishing,
and
b) decreasing the heat exchange capacity of the reservoir during dispensing so that
the precooler absorbs more of the cooling as the level of the beverage in the reservoir
decreases.
[0030] The heat exchange capacity of the reservoir may be decreased to less than one tenth
of that of the precooler.
[0031] The method may include the steps of deep cooling the precooler to just above the
freezing point of the beverage, after the reservoir has been replenished and after
the trickle flow has been terminated. The beverage may be carbonated after it has
trickled past the precooler. The reservoir may be pressurised with carbon dioxide
gas at a generally constant pressure and the pressure of the beverage may be regulated
upstream to a generally constant pressure higher than that of the carbon dioxide pressure.
The trickle flow may be provided with a check to prevent backflow into the precooler.
The trickle flow may be restricted with an elongate length of thermally conductive
tubing. The tubing being the precooler and being air cooled.
[0032]
Figure 1 is an elevational view of a schematic of the apparatus of the present invention
and of apparatus with which the method of the present invention may be practiced;
Figure 2 is an elevational front view, with the door open, of the preferred structural
embodiment of the apparatus of the present invention;
Figure 3 is a top plan view, in section, of the apparatus of Figure 2;
Figure 4 is front elevational detail view of part of the apparatus of Figure 2;
Figure 5 is a side plan view of the structure of Figure 4;
Figure 6 is a front elevational view, with the door open, of an alternative referred
structural embodiment of the apparatus of the present invention;
Figure 7 is a top plan view, in section, of the apparatus of Figure 6;
Figure 8 is a detail view of part of the apparatus of Figure 6;
Figure 9 is a detail view of the structure of Figure 8 shown collapsed;
Figure 10 is a graph showing relative heat exchange capacity; and
Figure 11 is a graph showing relative absorption of cooling capacity.
[0033] According to the principles of the present invention a beverage cooling and dispensing
apparatus; as schematically shown in Figure 1 and generally indicated by the numeral
10 and hereinafter referred to as the dispenser 10, has a refrigerator 12 having a
cold air cooling chamber 14 within which is a cold beverage reservoir 16 and a beverage
precooler 18 which restricts flow into the reservoir 16 and precools the flow before
it is admitted to the reservoir 16.
[0034] The refrigerator 12 has a cabinet 20 and an openable door 22 which define and enclose
the cooling chamber 14. Outside of the chamber 14 is a compressor 24 and inside of
the chamber is a cooling evaporator 26 which is connected to the compressor 24 in
a conventional manner. The compressor 24 is as small as possible; the preferred compressor
24 is a 30 watt (.04 HP) output miniature compressor manufactured by Sanyo Electric
of Japan. The refrigerator 12 could be any domestic type refrigerator that has a cooled
cold air chamber without specific provision for direct heat transfer to cool beverage
via a coil immersed in an ice water bath, an eutectic tank or other intimate contact
structure. The refrigerator 12 regardless of type has an evaporator 26 that cools
the air in the chamber 14, and the cold air cools the reservoir 16 and the precooler
18. While the preferred refrigerator 12 has convective flow of cooled air, forced
cold air flow as seen in domestic refrigerators is an alternative.
[0035] The beverage reservoir 16 holds several discrete servings of beverage. For example,
a preferred capacity of the reservoir 16 is 18.9 litre. A 10 ounce (296 ml) post-mix
drink takes 8 ounces (237 ml) of water and the reservoir 16 will store cold water
sufficient for the draw of about eighty of these drinks or for one hundred twenty
eight smaller 6 ounce (177 ml) drinks. The reservoir 16 has a float and valve fill
control 28 which automatically controls the maximum water level 30 so that there is
always a head space 32 for a gas head on top of the water. The reservoir 16 has a
carbon dioxide inlet 34 with a porous diffuser element 36 in the bottom of the reservoir
16. A syphon tube 38 extends from the bottom of the reservoir 16 to a beverage outlet
line 40 which extends to a dispensing valve 42.
[0036] A syrup container 44 is mounted on the inside of the door 22 and in the cooling chamber
14. A syrup line 46 leads to a dispensing nozzle 48. The dispensing componentry is
more fully described in UK Patent Application No 2 133 086A.
[0037] An important feature of this invention is the precooler 18 which is in the cold air
cooling chamber 14 and upstream of the reservoir 16. A plastic supply line 50 leads
from the outside and preferably from a municipal or potable water supply to the precooler
18, and a plastic inlet line 52 connects the precooler 18 to the reservoir 16 via
the fill control 28. If the supply line 50 is connected to a municipal water supply
where the pressure frequently fluctuates and is unpredictable, a water pressure regulator
54 is installed in the supply line 50 and on the outside of the refrigerator 12. The
regulator 54 is pre-set to a constant outlet pressure in the range of 2.46-3.16 kg/sq
cm and a preferred pressure is 2.8 kg/sq cm. Each end of the precooler 18 has a fitting
56 for being connected to the supply line 50 or the inlet line 50. The inlet line
50 has a double check valve 58 for allowing flow from the precooler 18 to the reservoir
16 and for precluding backward flow from the reservoir 16 to the precooler 18.
[0038] A small compressed gas cylinder 60 and pressure regulator 62 for carbon dioxide gas
are inside the cooling chamber 14. A gas line 64 connects the regulator 62 to the
reservoir 16 and to the syrup container 44. The gas regulator 62 is pre-set to give
a constant output pressure of 1.76 kg/sq cm which is less than the output pressure
of the water regulator 54 by 1.05 kg/sq cm.
[0039] There are two preferable structural embodiments utilizing the precooler 18. In both
of these embodiments the refrigerator 12, reservoir 16 and other components are essentially
identical unless otherwise described.
[0040] Figures 2-5 illustrate a first preferred structural embodiment in which the precooler
18A is wound into a relatively small diameter helical coil spring which is suspended
by its ends in a general U-shape. In front of the reservoir 16 is a transverse reservoir
retainer bar 66. A pair of S-shaped hanger clips 68 each have an upper end 70 over
the bar 66, and lower end 72 under a precooler fitting 56. Each lower end 72 has a
slot 74 for receiving the precooler 18. The precooler 18A is wound closed but when
hanging as seen in Figures 2 and 3, each individual coil 76A is spread from each adjacent
coil 76A and cold air moves freely over and between each coil 76A.
[0041] Figures 6-9 illustrate the second preferred embodiment structural embodiment in which
the precooler 18B is around the reservoir 16 in a relatively large discrete helical
spring. Again the coils 76B are wound closed but installed spread from each other
and spaced from the reservoir 16. The spread precooler 18B has at least two coil racks
78, each of which has an inner plate 80 and an outer plate 82. The plates have a corrugation
that loosely receives the coils 76B and which keeps the coils 76B spread from each
other. The plates 80, 82 are fastened together by spot welding or wire ties. The second
precooler 18B folds up for inventory and shipping as is seen in Figure 9 with the
racks 78 and coils 76B nested against each other side-by-side. Both precoolers 18A,
18B are positioned underneath the evaporator 26 so that cold air off the evaporator
26 connectively drafts down, over and through the precoolers 18A, 18B.
[0042] Each precooler 18A, 18B embodiment has its advantages and disadvantages. Both precoolers
18A, 18B have the same thermal exchange capacity and-the costs are comparable. The
first precooler 18A lends itself to retrofit and to installation as an optional accessory.
The disadvantage is its physical vulnerability. The second precooler 18B is very well
protected and takes less volume in the chamber 14 and is ideally suited when all units
of the dispenser 10 are to be built with the precooler 18B. The disadvantage is that
precooler 18B requires removal of the reservoir 16 from the refrigerator 12 for installation,
therefore retrofit and line item assembling are not easily done.
[0043] The first precooler 18A is ideally suited for a retrofit or line item assembly kit
wherein the precooler 18A, regulator 54, hanger clips 68 and various tubing and fittings
are packed as a kit either discretely or with the balance of the componentry such
as the reservoir 16 if a complete dispenser kit is desired.
[0044] The precooler 18 per se, whether embodied in the first version 18A or the second
version 18B, is an elongate length of thermally conductive tubing that has a significant,
high and precise, restriction to the flow of liquid therethrough. The preferred tubing
is copper refrigeration capillary tubing. A specific preferred capillary tubing is
hard drawn copper tubing having a 1.07 mm inside diameter passageway, a 2.4 mm outside
diameter, and a length of 15.24 metres. This preferred precooler 18 has an internal
area of 511 sq cm, an internal volume of 13.6 cc and an external area of 1142 sq cm.
With this preferred precooler 18, and with the water pressure regulator 54 set at
2.8 kg/sq cm and with the carbon dioxide pressure regulator 62 set at 1.76 kg/sq cm
which gives a 1.05 kg/sq cm pressure differential, the flow rate of water through
the precooler 18 and therefore the fill rate of water into the reservoir 16 is about
296 cc per hour. This flow rate is a mere trickle, and is about 1.7 drops of water
per second. Each molecule of water is in the precooler 18 about 2 minutes and 45 seconds
during flow through the precooler 18. The precooler 18 has a length to outside diameter
(L:OD) ratio of at least 1000:1, or of at least 50000:1, and the preferred structure
has a ratio of 6350:1. The ratio of the length of the inside diameter (L:ID) is significantly
greater and is at least 10,000:1 with the preferred ratio being in a range between
14,000 and 15,000:1. The precooler 18 presents an external area to the cold air that
is over twice the internal area in contact with the water. The external area of the
precooler 18 is at least 200 times the volume of the internal passageway measured
in inches. The specific preferred ratio is 213:1 of square inches to cubic inches,
and 84:1 square centimetres to cubic centimetres. The mass of the precooler 18 is
significantly greater than the mass of the water it will hold. Specifically a preferred
precooler 18 is 476 05 grams and holds 13.6 grams of water for a 35:1 ratio of precooler
18 mass to internal water mass.
[0045] The reservoir 16 by contrast has a preferred structural size of 22.86 cm by 50.8
cm high and is of thin section stainless steel. Both the inner and outer area of the
reservoir 16 are about 4450 cm
2 for an effective water volume of 18930 cc which gives an area to volume ratio for
the reservoir 16 of 0.24:1 the area to volume ratio is substantially less than one
and substantially less than the equivalent ratios for the precooler 18.
[0046] The precooler 18 has an area to volume ratio which is at least one hundred times
and preferably in the range of two hundred to four hundred times the equivalent ratio
of the area to volume of the reservoir 16. A specific preferred ratio between the
area to volume ratios of the precooler 18 and reservoir 16 is 350:1.
[0047] The precooler 18 has a heat exchange capacity that at least approaches the heat exchange
capacity of the reservoir 16, and it is preferable for the precooler 18 to have a
heat exchange capacity greater than the reservoir 16. The precooler 18 may be serpentine
(18), small helical coil (18A), bi
g helical coil (18B) fin and tube, a flat plate device, or a radiator device having
high heat exchange capacity. When the dispenser 10 has its reservoir 16 filled and
the dispenser is not being utilised for dispensing, the majority of the cooling load
is taken by the water in the reservoir 16 which was admitted into the reservoir 16
at about 4.4 degrees C and which is subsequently deep cooled down to about 1.7 degrees
C; this is as cold as the water can be reliably cooled without freezing problems.
During the period when the reservoir 16 is filled and no dispensing is taking place,
the precooler stabilises at 1.7 degrees C and no cooling load is taken by the precooler
18. The water in the reservoir 16 takes all of the available cooling capacity and
deep cools from the acceptable 4.4 degrees C to the preferred 1.7 degrees C.
[0048] During dispensing, the precooler 18 can and does consume most of the cooling capacity
because the precooler 18 then has a heat exchange capacity greater than the reservoir
16. During dispensing the relative heat exchange capacity of the reservoir 16 decreases
as the precooler 18 heat exchange remains constant. The absolute amount of units of
heat exchange are not accurately known but the ratios can be approximated. For example:
1. When there is no replenishing flow into the reservoir 16, there is no flow through
the precooler 18. The precooler 18 and the water therein deep cool to about 1.7 degrees
C. The precooler 18 then presents no load to the cooling system and has no further
heat exchange capability.
2. When the reservoir 16 is being replenished, the flow of water into the precooler
will have an inlet temperature of about 23.9 degrees C and an outlet temperature of
4.4 degrees C. The heat exchange capability and relative ability to absorb cooling
capacity can be expressed as (precooler area presented to the cold air ) X (average
temperature differential of the water, above the cold air normally at 0 degrees C).
3. The reservoir 16 presents a variable heat exchange load in the cooling chamber
14. As the water level decreases, the cooling load decreases. An approximation of
these loads, on a relative scale:
[0049] Figure 10 is an attempt to illustrate the relative heat exchange capacity of the
precooler 18 and reservoir 16. When water is flowing through the precooler 18 its
capacity is maximum, and when flow stops its capacity decreases to zero. The reservoir
16 capacity decreases as the water level decreases because the area of the bottom
and cylindrical side decreases. This graph is approximate only and it is suspected
but not ascertained that the reservoir 16 curve lies substantially lower because there
is no agitator mechanism in the reservoir 16 and convection and C0
2 bubbles entering the reservoir 16 are relied upon to move the water and even out
the temperatures in the water within the reservoir 16.
[0050] Figure 11 illustrates the absorption of 100% of the available and utilised cooling
capacity firstly as taken in part by the precooler 18 shown below the solid line,
and secondly as taken in part by the reservoir 16 shown above the line. It can be
seen that when the dispenser 10 has been sitting unused and the reservoir 16 is filled
and there is no flow in the precooler 18, that virtually all of the cooling is absorbed
by the reservoir 16 during deep cooling of the reservoir water from 4.4 degrees C
to 1.7 degrees C or lower. As dispensing is started, the fill control 28 opens and
water flows through the precooler 18. The precooler 18 immediately takes the majority
of the cooling available. As cold water is withdrawn from the reservoir 16, the reservoir
16 takes less and less of the cooling and the precooler 18 takes more until when the
reservoir 16 is temporarily empty, the precooler 18 takes all of the cooling. The
exact location of the line between full and empty in Figure 11 is not precisely known
and it is suspected to be substantially higher and closer to the alternative dotted
line, again due to absence of forced water circulation in the water reservoir 16.
[0051] During operation of the dispenser 10 and in the practice of the method of the present
invention, the refrigeration compressor 24 is turned on, the syrup container 44 or
containers as the case may be, has syrup placed in it, and the supply line 50 is connected
to a source of water. If the water pressure is high or fluctuating, the regulator
54 applies only the predetermined and preset 2.81 kgs/sq cm on the precooler 18. The
water flow through the precooler 18 is restricted to a trickle flow of about 296 cc
per hour which is about 1.7 drops per second. This trickle flow is cooled from an
anticipated 23.9 degrees C to 4.4 degrees C and then admitted to the reservoir 16.
The reservoir 16 is pressurised with carbon dioxide gas at 1.76 kgs/sq cm which then
carbonates the precooled water to about 3.9 volumes of carbonation. Over a period
of about 60-72 hours the reservoir 16 will fill and the water and syrup will all be
cooled to below 4.4 degrees C. This takes an extended period of time because the compressor
has only a 30 watt output. This period is called initial pull down.
[0052] After pull down, the dispenser 10 is ready for dispensing with the water and syrup
at close to 1.7 degrees C after deep cooling. The carbonation of the water will gradually
increase to about 4.4 volumes.
[0053] When dispensing is done, the standard dispensing flow rate is in the range of 44.4-88.7
cc per second . Part of the flow is syrup and part is water. The water portion is
usually 5/6 of the total flow so the water dispensing flow rate is typically in the
range of 40.0-73.9 cc per second. this water dispensing rate is substantially greater
than the flow rate through the precooler 18, specifically at the lowest dispensing
rate of 40 cc per second and with the low rate through the precooler 18 being 0.082
cc/second, it is about 487 times the precooler 18 flow rate. As soon as the dispensing
starts, the fill control 28 re-opens and replenishing of the dispensed water begins.
The gas head propels out the water to be dispensed, and new water begins to flow in
the precooler 18. The high thermal mass of the precooler 18 effectively cools the
first couple of minutes flow and then heat exchange from water to precooler 18 and
then to cold air in the chamber 14 begins. The small compressor 24 can easily keep
up to the restricted flow through the precooler 18. The restricted flow or trickle
is at least a magnitude (10X) less and preferably two magnitudes less (100X) than
the dispensing flow. The preferred trickle flow is in the range of 1/400 to l/500th
of the dispensing flow rate. The trickle flow is always cooled to less than 4.4 degrees
C which is the maximum acceptable dispensing temperature. The reservoir 16 and precooler
18 are commonly cooled with a convective air flow off of the evaporator 26. _
[0054] This dispenser 10 and the method herein described, enable the building of a very
large reserve of individual servings, for example eighty 296 cc drinks over an extended
period of time. This entire built up inventory can be dispensed without warm up and
while the refrigeration is on and rebuilding.
[0055] For example, in a home where a party is hosted on a weekend, the dispenser 10 can
take Wednesday, Thursday and Friday to build up.its inventory of cold beverage. On
Saturday dispensing is started and the compressor 24 turns on and the dispenser 10
begins replenishing at 10 ounces (296 cc) per hour. Over an eight hour party the capacity
of the reservoir 16 and the replenishing flow of 2960 cc can be dispensed. If the
reservoir 16 is the previously referred to 18.93 liters, the total cooled and carbonated
water available is 21.9 liters which is then mixed with 4.4 liters of syrup to give
26.3 liters of finished post mixed soft drinks. This is 89 servings at 296 cc or 148
servings at 177 cc. If the party extends until sunday evening the dispenser 10 can
replenish for 32 hours, and provide an additional 9460 cc of cold carbonated water
to provide 34.1 liters of soft drink which is 115 large drinks or 193 small drinks
before the reservoir 16 goes empty. The dispenser 10 then replenishes itself from
Sunday night until Wednesday.
[0056] During refill after the reservoir 16 has been emptied, and during the initial filling
of the dispenser 10, the just filled contents of the reservoir 16, be it one serving,
a 1/4 full, 1/2 full, 3/4 full or just short of full, are cold carbonated water at
or below 4.4 degrees C ready to be dispensed and consumed. The reservoir 16 never
contains water which is too warm.
[0057] This same dispenser 10 and method lends itself to professional offices, cabins, and
any other site where the dispenser 10 can replenish itself all night, for several
days or over a weekend and prepare itself for a period of high dispensing that exceeds
its refrigeration capacity.
[0058] This dispenser 10 and method is ideally suited for placement within a domestic refrigerator,
having forced air circulation or convection. Forced air circulation will increase
the total cooling and dispensing capacity and enable the usage of a larger and more
expensive compressor. The size and cost of the precooler 18 and reservoir 16 may also
be reduced with forced circulation of cooled air.
[0059] The kit having the precooler 18 is ideally suited for upgrading older beverage dispensing
devices.
[0060] Although other advantages may be found and realised and various and minor modifications
may be suggested by those versed in the art, be it understood that I wish to embody
within the scope of the patent warranted hereon, all such improvements as reasonably
and properly come within the scope of my contribution to the art.
1. A beverage cooling apparatus including a cabinet, a water reservoir located within
the cabinet, means to cool the air inside the cabinet, means to carbonate the water
within the reservoir and means to supply water to the reservoir characterised in that
water is supplied to the reservoir through a precooler which has a substantial restriction
to flow therethrough so as substantially to precool the water prior to entering the
reservoir.
2. Apparatus as claimed in Claim 1 further characterised in that the precooler has
a surface area to volume ratio at least two magnitudes greater than the surface area
to volume ratio of the reservoir.
3. Apparatus as claimed in Claim 1 or Claim 2 further characterised in that the precooler
is an elongate length of tubing.
4. Apparatus as claimed in Claim 3 further characterised in that the precooler has
a length to diameter ratio of at least 1000:1, preferably at least 5000:1 and further
preferably at least 6000:1.
5. Apparatus as claimed in any one of Claims 1 to 4 further characterised in that
there is provided a water pressure regulator on an upstream end of the precooler.
6. A beverage precooler kit for beverage cooling Land dispensing apparatus-comprising
a thermally conductive beverage precooler having an inlet, an outlet, a passageway
having substantial restriction to flow of beverage therethrough, and an external surface
area at least a magnitude greater than the volume of the passageway, and a beverage
pressure regulator installable on the upstream end of the inlet, said regulator being
set to effect a maximum or constant pressure upon the inlet.
7. A method of cooling and dispensing cooled beverage comprising the steps of:-
a) storing a supply of previously precooled beverage in a storage reservoir;
b) dispensing servings of cold beverage from the storage reservoir at intermittent
intervals;
c) replenishing the storage reservoir supply with new beverage at an incoming flow
rate substantially less than the dispensing flow rate by:
i) restricting the incoming beverage flow to a trickle, and
ii) running the incoming trickle flow through a precooler; while
d) cooling both the reservoir and the precooler, and the beverage therein.
8. A method as claimed in Claim 7 in which the dispensing flow rate exceeds the trickle
flow rate by at least two magnitude.
9. A method as claimed in Claim 7 or Claim 8 in which the trickle flow is cooled to
4.4 degrees C or less prior to the trickle flow being admitted to the precooler.
10. A method as claimed in any one of Claims 7 to 9 in which the precooler is deep
cooled to just above the freezing point of the beverage, after the reservoir has been
replenished and after the trickle flow has been terminated.