Information
-
Patent Grant
-
6234223
-
Patent Number
6,234,223
-
Date Filed
Monday, January 24, 200024 years ago
-
Date Issued
Tuesday, May 22, 200123 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Quarles & Brady LLP
- Haas; George E.
-
CPC
-
US Classifications
Field of Search
US
- 141 263
- 141 264
- 141 267
- 141 270
- 141 351
- 141 356
- 141 369
- 141 374
- 141 94
- 141 198
- 141 98
- 141 2
- 141 18
- 141 301
- 222 1466
-
International Classifications
-
-
Disclaimer
Terminal disclaimer
Abstract
A system for dispensing carbonated beverage and ice into an open container uses a bottom filling technique in which the outlet port of the nozzle is proximate to a bottom of the open container in order to dispense the carbonated beverage. Preferably, the carbonated beverage is maintained in a pressurized state within the nozzle until immediately prior to opening the valve in order to maintain appropriate carbonation of the beverage. It is preferred that ice be added after the nozzle is located proximate the bottom of the open container. The ice dispenser includes a funnel located concentrically around the nozzle in order to supply ice around the nozzle into the open container. In order to avoid excessive foaming, it is important that the temperature of the carbonated beverage be chilled to approximately the surface temperature of the ice being added into the open container.
Description
BACKGROUND OF THE INVENTION
The invention relates to the automated dispensing of a carbonated beverage into open containers.
The present invention arose during ongoing efforts by the inventor to improve carbonated beverage dispensing systems. In U.S. Pat. No. 5,603,363 entitled “Apparatus For Dispensing A Carbonated Beverage With Minimal Foaming”, issuing on Feb. 18, 1997, and in U.S. Pat. No. 5,566,732 issuing on Oct. 22, 1996, both incorporated herein by reference, the inventor discloses systems for dispensing carbonated beverage, such as beer or soda, into an open container. The system disclosed in U.S. Pat. 5,603,363 discloses the bottom filling of carbonated beverage into an open container. U.S. Pat. No. 5,566,732 discloses the use of a bar code reader to read indicia on the open container when placed beneath the nozzle that indicates the volume of the open container in order to automate the dispensing procedure, and preferably various aspects of on site accounting and inventory procedures. In these systems, the carbonated beverage is dispensed from a nozzle that has an outlet port placed near the bottom of the open container, i.e. the open container is bottom filled.
As discussed in the above incorporated patents, carbonated beverage often foams while being dispensed into the serving container using conventional filling dispensing systems. This is particularly true when ice and carbonated soft drinks are dispensed into an open container. As a consequence, personnel operating the dispenser must fill the serving container until the level of foam reaches the brim and then wait for the foam to settle before adding additional carbonated beverage. In some instances, several iterations of this process must occur before the container is filled with liquid to the proper serving level. “Topping Off” necessitated by the foaming of the beverage prolongs the dispensing operation and impedes the ability to fully automate the dispensing of the carbonated soft drink. Nevertheless, many establishments have push button activated taps that automatically dispense measured quantities of carbonated beverage. Normally, this automated equipment only partially fills the serving container and the user must still manually “top off” the container after the foam from the automated step settles in order to dispense the proper serving quantity.
SUMMARY OF THE INVENTION
The invention is an automated carbonated beverage and ice dispensing system and method. The invention uses a bottom filling technique for the carbonated beverage, and also provides an efficient manner of adding ice to an open container of carbonated beverage.
In its preferred aspect, the invention involves the step of adding ice to the open container after the open container is placed underneath the nozzle such that the outlet port of the nozzle is proximate the bottom of the open container when the ice is being added to the container. Preferably, the ice is supplied to the open container through a funnel having a outlet through which the downwardly extending carbonated beverage nozzle extends. The ice is supplied circumferentially around the nozzle and into the open container. In order to reduce foaming, the carbonated beverage should be chilled prior to dispensing to a temperature that approximately matches the surface temperature of the ice. Preferably, the invention maintains the carbonated beverage in a pressurized state until immediately prior to dispensing the carbonated beverage, which is desirable in order to control the amount of carbonation within the beverage prior to dispensing the beverage.
Other features and advantages of the invention should be apparent to those skilled in the art upon inspecting the drawings and reviewing the following description thereof.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
is a schematic view of a carbonated beverage dispensing system in accordance with a first embodiment of the invention.
FIG. 2
is a view of a portion of the carbonated beverage dispensing system shown in
FIG. 1
at a point in time in which carbonated beverage is dispensing from the system into an open container.
FIG. 3
is a block diagram illustrating the preferred electronic control system for the system shown in
FIGS. 1 and 2
.
FIG. 4
is a graph illustrating the pressure of the carbonated beverage within the nozzle prior, during, and subsequent to dispensing the carbonated beverage from the nozzle into the open container.
FIG. 5
is a detailed view of the region designated in
FIG. 1
by arrow
5
—
5
which illustrates a preferred embodiment of the valve head incorporating a bottom activation switch.
FIG. 6
is a view similar to
FIG. 5
showing the bottom activation switch being actuated and the valve open in order to dispense carbonated beverage from the nozzle into the open container.
FIG. 7
is a schematic view of another embodiment of the invention.
FIG. 8
is a detailed view of the region in
FIG. 7
designated by arrows
8
—
8
which illustrates the valve head configuration of the system in FIG.
7
.
FIG. 9
is a view similar to
FIG. 8
showing a bottom activation switch being actuated in order to open the valve and dispense carbonated beverage from the nozzle into the open container.
FIG. 10
is a schematic view of another embodiment of the invention.
FIGS. 11A through 11C
show various embodiments of valve heads, each having a distinct configuration for the distribution surface on the valve head.
FIG. 12
is a schematic drawing showing an automated open container holder.
FIG. 13
is a schematic view similar to
FIG. 12
which shows the open container being automatically lowered as it is being filled.
FIG. 14
is a detailed view of the region depicted by arrows
14
—
14
in FIG.
13
.
FIG. 15
is a graph illustrating a possible pouring profile for the systems shown in
FIGS. 12-14
in which the Y-axis represents the relative distance of the bottom of the open container from the outlet port of the nozzle with respect to time during filling.
FIGS. 16A through 16D
show the preferred manner of adding ice into an open container being filled with carbonated beverage.
FIG. 17
is a schematic view of still another embodiment of the invention.
DETAILED DESCRIPTION OF THE INVENTION
FIG. 1
illustrates a carbonated beverage dispensing system
10
that maintains the carbonated beverage
12
in a pressurized state, i.e. at a pressure substantially above atmospheric pressure such as 15 psi, when the valve
14
for the dispensing nozzle
16
is in a closed position. In
FIG. 1
, the source of carbonated beverage is designated by reference numeral
18
. A carbon dioxide source
20
is connected to the source of carbonated beverage
18
via line
22
in order to supply gas that forces the carbonated beverage out of the source container
18
as is common practice. The source container
18
would typically be a keg of malt beverage such as beer, or could be a source of carbonated water to which flavored syrup is mixed downstream in the case of soft drinks.
FIG. 1
shows a valve
24
in line
22
that is electronically controlled by controller
26
in order to regulate the pressure within the source
18
of carbonated beverage. Alternatively, the system pressure is set manually, or by a conventional regulator on the carbon dioxide source.
The pressurized carbonated beverage is supplied from the source
18
of carbonated beverage through line
28
to a pressurized chamber
30
. Pressure transducer
29
monitors the pressure of the carbonated beverage within the pressurized chamber
30
and dispensing nozzle
16
, and outputs a signal to the electronic controller
26
. An in-line chiller
32
chills the carbonated beverage flowing through line
28
to a desired temperature. The in-line chiller
32
is controlled by the electronic controller
26
. As described later in connection with
FIG. 3
, the chiller
32
is preferably a zeroΔT freon bath chiller. The volume of the pressurized chamber
30
is relatively arbitrary, but in this embodiment is approximately one gallon. The dispensing nozzle
16
extends downward from the pressurized chamber
30
. The dispensing nozzle preferably has a diameter of ¾ to 2 inches, and has a length sufficient for bottom filling open containers which are typically used in connection with the system
10
. For example, the nozzle
16
may typically be 12 or more inches in length.
The valve head
14
is connected to a valve stem
34
which passes longitudinally along the center axis of the nozzle
16
and extends upward through the pressurized chamber
30
. An electronically controlled actuator
36
, such as a servo motor or a pneumatic actuator, is mounted to the top of the chamber
30
. The valve actuator
36
is connected to the valve stem
34
and selectively positions the valve head
14
with respect to the outlet port
38
of the nozzle
16
. The electronic controller
26
outputs a control a signal to the valve actuator
36
through line
56
. In the system shown in
FIG. 1
, a bottom activation switch
40
is provided along a base surface of the valve
14
. When the bottom
42
of the open container
44
presses the switch
40
upward, the switch
40
sends a signal through line
46
physically located in part within the valve stem
34
to the electronic controller
36
.
The system
10
also preferably includes an elastomeric bladder
48
mounted along one of the surfaces of the pressurized chamber
30
. A bladder actuator
50
, such as a servo motor or a pneumatic actuator, is connected to the elastomeric bladder
48
. As depicted in
FIGS. 1 and 2
, the bladder
48
is in contact with the carbonated beverage
12
in the pressurized chamber
30
. During operation of the system
10
, the electronic controller
26
controls the actuator
50
to move the elastomeric bladder
48
from the position shown at
FIG. 1
to the position shown in FIG.
2
. In the retracted position in
FIG. 2
, the pressure of the carbonated beverage within the chamber
30
and the nozzle
16
is reduced to a selected pressure in order to dispense the carbonated beverage through the outlet port
38
of the nozzle
16
.
FIG. 1
also shows an adjustable flow restriction device
51
located in pressurized line
28
between the source
18
of the pressurized carbonated beverage and the chamber
30
and nozzle
16
. One purpose of the adjustable flow restriction device
51
is to create a time lag for the recovery of pressure within the nozzle
16
after the bladder
48
has been retracted. Another purpose is to maintain appropriate carbonation of the beverage upstream of the flow restriction device
51
.
An electronically controlled venting valve
52
is mounted to the pressurized chamber
30
. The venting valve
52
is opened in order to fill the pressurized chamber
30
and nozzle
16
with carbonated beverage during start up.
The system
10
shown in
FIGS. 1 and 2
operates generally in the following manner. The electronic controller
26
adjusts valve
24
in pressurized carbon dioxide line
22
in order to force carbonated beverage from the source
18
into pressurized line
28
or, as mentioned, the initial system pressure can be set manually or by a conventional regulator on the carbon dioxide source. A typical pressure for pressurized line
28
would be 15-30 psi, although this pressure is discretionary. The in-line chiller
32
chills the pressurized carbonated beverage to a desired temperature (for example, 36.5 degrees Fahrenheit for certain beers, or the surface temperature of ice added to the open container for soft drinks). The chilled and pressurized carbonated beverage then flows through the flow restriction device
51
and into the pressurized chamber
30
and nozzle
16
with the valve
14
in a closed position as shown in FIG.
1
. With the valve
14
closed, the pressure of the carbonated beverage in the nozzle achieves equilibrium pressure which is the same as the pressure in the pressurized line
28
and substantially greater than atmospheric pressure.
In order to dispense carbonated beverage into the open container
44
, the open container
44
is placed underneath the nozzle
16
with the outlet port
38
for the nozzle
16
proximate the bottom
42
of the open container
44
. The system
10
is then activated to initiate a dispensing cycle, for example by pushing the bottom
42
of the open container
44
against the activation switch
40
on the bottom of the valve head
14
, or in accordance with a barcode system such as disclosed in incorporated U.S. Pat. No. 5,566,732, or by some other push button or electronic control. After system activation, the dispensing valve
14
is maintained in a closed position and the electronic controller
26
initiates the dispensing cycle. First, the electronic controller sends a control signal through line
54
to the bladder actuator
50
to retract the elastomeric bladder
48
and reduce the pressure of the carbonated beverage
12
contained in the nozzle
16
and chamber
30
to a lesser pressure that is appropriate for controlled dispensing of the carbonated beverage from the outlet port
38
of the nozzle
16
into the open container
44
. Preferably, the retraction of the bladder
48
,
FIG. 2
, reduces the pressure of the carbonated beverage
12
in the nozzle
16
to a pressure slightly greater than atmospheric pressure, and in any event no more than 6 psi greater than atmospheric pressure. The valve head
14
is opened once the pressure of the carbonated beverage has been reduced to the selected dispensing pressure, thus allowing carbonated beverage to flow from the nozzle outlet port
38
into the open container
44
in a controlled manner as illustrated in FIG.
2
. Because the pressure of the carbonated beverage is known during the dispensing procedure, the amount of carbonated beverage filling the open container
44
accurately corresponds to the precise time period that the valve
14
is open. The dispensing valve
14
is closed after the predetermined time period. The presentation of the carbonated beverage within the open container
44
is likely to be extremely repeatable because the temperature and the dispensing pressure of the carbonated beverage are tightly controlled. Other features of the system
10
described in connection with other Figures help to improve the repeatability of the presentation of the carbonated beverage in the open container.
FIG. 4
is a plot illustrating the pressure of the carbonated beverage within the nozzle
16
as a function of time over the course of a dispensing a cycle.
FIG. 4
shown by way of example that the pressure of the carbonated beverage within the nozzle
16
at time T=0, (i.e. before the dispensing cycle) is 15 psi. As shown in
FIG. 4
, the pressure of the carbonated beverage in the nozzle is reduced from 15 psi to 1 psi prior to dispensing the carbonated beverage from the nozzle. The time period designated T
1
in
FIG. 4
shows the pressure drop of the carbonated beverage within the nozzle form 15 psi to 1 psi. As mentioned, this occurs immediately before the valve
14
is opened. Once the pressure in the nozzle
16
is reduced to the desired dispensing pressure, i.e. 1 psi in
FIG. 4
, the valve
14
is opened to dispense the carbonated beverage. In
FIG. 4
, the valve
14
is opened during the time period designated T
2
. Note that
FIG. 4
shows that the pressure during the time period T
2
is a constant pressure which in many applications is preferred, however, is not strictly necessary. At the end of the time period T
2
, the valve
14
is closed. The pressure on the carbonated beverage within the nozzle
16
and the chamber
30
recovers during time period T
3
. In the system
10
shown in
FIGS. 1 and 2
, the elastomeric bladder
48
is allowed to relax to the home position shown in
FIG. 1
during time period T
3
after the valve
14
is closed. Subsequent dispensing cycles are not typically initiated until the pressure of the carbonated beverage within the nozzle
16
and the chamber
30
is fully recovered, however, this is not necessary (e.g., the bladder operation is controlled in response to the signal from the pressure transducer
29
). It may be important to properly adjust the flow restriction device
51
in order to achieve constant or nearly constant pressure during the time period T
2
. That is, depending on the overall volume of the chamber
30
and nozzle
16
, an inadequate flow restriction
51
may allow a premature pressure rise in the nozzle
16
before it is time to close the valve
14
. An inadequate flow restriction
51
can be overcome by modulating bladder actuator
50
.
FIG. 3
is a schematic drawing showing the preferred chiller system
32
A, which is referred to herein as the zeroΔT chiller
32
A. In
FIG. 3
, the pressurized line
28
from the source of pressurized carbonated beverage flows through the evaporator
64
. The evaporator
64
is preferably a flooded, freon-bath heat exchanger, although other conventional heat exchangers such as tube-in-tube heat exchangers may be suitable. The preferred flood freon-bath heat exchanger
64
is sized so that, under all normal operating conditions, the heat exchanger
64
has sufficient chilling capacity in order that the temperature of the carbonated beverage flowing from the evaporator
64
matches the temperature of the freon bath. In this manner, the temperature of the pressurized carbonated beverage flowing into the chamber
30
and the nozzle can be precisely determined by the temperature of the freon bath. The temperature of the freon bath in the evaporator
64
is monitored by a pressure transducer
66
which transmits a signal to the electronic controller
26
. Block
68
in
FIG. 3
which is labeled data input illustrates that the desired temperature of the carbonated beverage can be input as data into the controller
26
, e.g., through a keypad or from electronic memory, etc. In turn, the controller
26
adjusts the position of valve
70
to change the pressure in the flooded, freon-bath of the evaporator
64
in order to obtain the desired temperature for the freon-bath. The valve
70
shown in
FIG. 3
is a three-way valve. The primary purpose of valve
70
is that of an expansion valve in the freon refrigeration cycle. However, valve
70
can be adjusted so that a portion or all of the freon flowing to the valve
70
bypasses the evaporator
64
and flows directly through line
72
to the compressor. Typically, it is desirable to bypass the evaporator
64
entirely when the system
10
is in stand-by mode (i.e., hot gas by-pass), and there is no carbonated beverage
28
flowing through the evaporator heat exchanger
64
. Utilizing such a bypass during stand-by mode is preferable to turning off power to the compressor because compressor start up times are significant and compressor duty life is severely shortened by repeated starting and stopping.
Referring now to
FIG. 5 and 6
, it may be desirable to provide a valve head
14
with a bottom activation switch
40
. The valve head
14
has a proximal end
74
that is attached to the valve stem
34
, and a distal end
76
. The diameter of the valve head
14
at the proximal end
74
is less than the diameter of the valve head at the distal end
76
as is apparent from
FIGS. 5 and 6
. The valve head
14
includes a distribution surface
78
that contacts the carbonated beverage as it is stored in the nozzle
16
and as it flows through the outlet port
38
of the nozzle
16
. The valve
14
also includes a base surface
80
that is generally horizontal along the distal end
76
of the valve
14
. The valve head
14
is preferably made of stainless steel, and can be an integral component with the valve stem
34
, although this is not necessary for implementing the invention. A star-shaped hub
82
aligns the valve stem
34
within the nozzle
16
. It is desirable that the valve stem be accurately aligned in order for the dispensing carbonated beverage to form a full 360° curtain having substantially symmetric thickness. Inaccurate alignment will corrupt the symmetry of the curtain and result in sub-optimal dispensing. The stainless steel valve stem
34
and head
14
contains a longitudinal bore
84
that houses wires
46
which transmit signals from the activation switch
40
. The activation switch
40
is preferably an optical sensor
86
that is glued into the bore
84
along the base surface
80
of the valve head
14
such that the sensor
86
extends downward beyond the base surface
80
of the valve head
14
. An elastomeric seal
88
covers the switch
40
and is secured to the base surface
80
of the valve head using fasteners
90
. The fasteners
90
are counter sunk within groove
92
in the base surface
80
of the valve head. A spring
94
(or other elastic material) is located around the sensor
86
for the switch
40
. In the embodiment shown in
FIGS. 5 and 6
, the sensor
86
as well as the spring
94
reside primarily within a central recess
96
on the base surface
80
of the valve head
14
. In
FIG. 5
, the spring
94
provides biasing pressure against the seal
88
, and the sensor
86
measures the distance to the seal
88
in the open position. In order to close the switch
40
, the user pushes the open container
44
upward so that the bottom
42
of the container pushes upward against the seal
88
and the spring
94
. The sensor
86
measures the distance to the seal
88
in the closed position as shown in FIG.
6
, and control signals are transmitted through wires
46
to the electronic controller
26
. In turn, the electronic controller
26
controls the opening and positioning of the valve head
14
with the respect to the outlet port
38
of the nozzle
16
. If a waterproof optical sensor
86
is used, the seal
88
and spring
94
are not necessary. In a system using a waterproof optical sensor, the optical sensor measures the distance to the bottom of the open container, rather than the distance to the spring-biased seal.
Still referring to
FIGS. 5 and 6
, the valve head
14
includes a circumferential groove
98
that is located at the distal end
76
of the valve head between the distribution surface
78
and the base surface
80
. An O-ring elastomeric seal
100
is placed in the circumferential groove
98
. When the valve head
14
is closed, as shown in
FIG. 5
, it is important that the O-ring seal
100
seat against the nozzle
16
to form a tight seal that is capable of preventing the leakage of pressurized carbonated beverage. Note that in
FIG. 5
, the O-ring seal
100
seats directly against the outlet port
38
for the nozzle
16
. In some applications, however, it may be desirable to have the O-ring seal
100
seat directly against an inside wall of the nozzle
16
.
In many circumstances, such as the dispensing of malt beverages, it is desirable to greatly redirect the trajectory of the carbonated beverage more horizontally before dispensing. This is accomplished in accordance with the invention by using a valve head
14
in which the distribution surface
78
has a specialized geometry. In particular, a first portion of the distribution surface
102
near the proximal end
74
of the valve head
14
is sloped more steeply downward than a second portion
104
of the distribution surface
78
that is located closer to the distal end
76
of the valve head
14
. With this geometry, the valve head
14
gently redirects the flow of carbonated beverage when it initially flows towards the valve head
14
, yet continues to further redirect the flow at downstream portion
104
in order to achieve a more preferable dispensing trajectory.
FIGS. 7 and 8
show a slightly different embodiment
110
of the invention. It should be understood that various components of the system
10
shown on
FIG. 1
such as the chiller, the source of carbon dioxide
20
, and the source of carbonated beverage
18
are depicted generally by block
112
labeled “beverage” in FIG.
7
. In the system
110
shown in
FIG. 7
, the adjustable flow control device
51
of
FIG. 1
has been replaced by a fixed flow control restriction
5
1
A. In addition, the chilled and pressurized carbonated beverage flows from line
28
through the fixed flow control restriction
51
A directly into the chamber defined by the nozzle
16
. The volume of carbonated beverage within the flow control nozzle
16
downstream of the flow control restriction
51
A in
FIG. 7
can be less than the volume of the open container. In the system
110
shown in
FIG. 7
, the valve head
14
A is located within the nozzle
16
when the valve is closed as shown more specifically in the detailed view of FIG.
8
. It is important that the O-ring seal
100
A,
FIG. 8
, engage tightly against the inside surface
16
A of the nozzle when the valve head
14
A is in a closed position. Similar to the system
10
shown on
FIG. 1
, the system
110
shown in
FIG. 7
has an electronically controlled valve actuator
36
that is connected to a valve stem
34
and controls the position of the valve head
14
A. The system
110
also includes a vent valve
52
A that is opened to initially fill the nozzle
16
with beverage.
One distinct difference between the system
110
shown in FIG.
7
and the system
10
shown in
FIG. 1
is that the system
110
in
FIG. 7
does not use an elastomeric bladder to reduce the pressure of carbonated beverage contained in the nozzle
16
prior to dispensing carbonated beverage from the nozzle
16
. Rather, upon initiation of the dispensing cycle (e.g., the engagement of activation switch
40
against the bottom
42
of the open container
44
), the electronic controller
26
transmits a control signal through line
56
to instruct the valve actuator
36
(e.g. a servo motor or pneumatic actuator) to move the valve head
14
A downward within the nozzle
16
prior to opening the valve
14
A. This operation is illustrated in FIG.
9
. The phantom locations for the O-ring seal
100
A depicted by reference numerals
114
are an illustrative home location for the O-ring seal
10
A. The valve
14
A is located with the O-ring seal
100
A in the home position
114
prior to the initiation of the dispensing cycle, and the carbonated beverage within the nozzle
16
is pressurized. Upon initiation of the dispensing cycle, the electronic controller instructs the valve actuator
36
to move the valve
14
A downward so that the O-ring seal
100
A is in an intermediate position identified by reference numbers
116
. At this point in the process, the valve
14
A is still closed inasmuch as the O-ring seal
100
A prevents the dispensing of carbonated beverage from the outlet port
38
A of the nozzle
16
. The purpose of moving the valve head
14
A from the home position
114
to the intermediate position of
116
is to slightly expand the size of the volume contained within the nozzle
16
and the flow restriction device
51
A in order to reduce the pressure of the carbonated beverage within the nozzle
16
. In this respect the system
110
operates substantially identically to the system
10
shown in FIG.
1
. After the pressure has been reduced within the nozzle
16
, the electronic controller
26
then opens that valve
14
A,
FIG. 9
, in order to allow carbonated beverage to dispense through the outlet port
38
A into the open container
44
. Note that the combined volume within the nozzle
16
and the fixed flow control restriction
51
A is probably smaller than the volume contained within the chamber
30
and nozzle
16
in the system
10
of FIG.
1
. Therefore it may be necessary during the dispensing cycle in the system
110
shown in
FIG. 7
to open the vent valve
52
A momentarily in order to ensure that a proper dispensing pressure is achieved and maintained during the dispensing cycle.
FIG. 10
shows a system
210
in accordance with another embodiment of the invention. In system
210
shown in
FIG. 10
, the pressure of the carbonated beverage within the nozzle
16
is reduced prior to dispensing by a variable pressure valve illustrated as block
212
. In system
210
, when the bottom
42
of the open container
44
engages activation switch
40
to initiate a dispensing cycle, the electronic controller
26
transmits a control signal through line
214
to the variable pressure valve
212
.
FIG. 10
shows the variable pressure valve
212
located in pressurized line
28
upstream of the flow restriction device
51
A, although it would be possible to locate the variable pressure valve
212
downstream of the flow restriction device
51
A, or implement the system without the flow restriction device
51
A. When the electronic controller
26
sends a signal to the variable pressure valve
212
indicating the initiation of the dispensing cycle, the variable pressure valve reduces the pressure within the nozzle
16
. Thereafter, the dispensing valve
14
is opened as with the earlier systems
10
and
110
. If necessary, the venting valve
52
A can be opened during the dispensing cycle in order to ensure the appropriate dispensing pressure.
FIGS. 11A through 11C
show three different valve head configurations. In
FIG. 11A
, the valve head
314
has a distribution surface
378
having a constant downward slope, i.e., is the shape of the valve head
314
in
FIG. 11A
is generally cone shape. An O-ring
300
seal is located within a circumferential groove between the distribution surface
378
and the base surface
380
as described above in connection with
FIGS. 5 and 6
. With the valve head
314
shown in
FIG. 11A
, the flow of carbonated beverage through the nozzle
16
is initially redirected in 360° as carbonated beverage impinges valve head
314
as depicted by arrow
382
. In order to minimize undesirable turbulence and foaming when the carbonated beverage impacts the valve head
314
, it is important that the slope of the distribution surface
378
be relatively steep in order to not agitate laminar flow. The trajectory of the carbonated beverage flowing along the valve head
314
as it dispenses into the open container
44
is generally in the direction represented by arrow
384
in FIG.
11
A. With a beverage dispensing trajectory as represented by arrow
384
, the trajectory distance for the carbonated beverage between the distribution surface
78
and bottom
42
of the open container
44
is given by the arrow X. The magnitude of distance X in
FIG. 11A
depends on the distance of the valve head
314
from the bottom
42
of the open container
44
. The trajectory angle of arrow
384
has a relatively steep decent, however. With the valve head
314
in
FIG. 11A
, the carbonated beverage impacts the bottom
42
of the container
44
at a relatively abrupt angle when the valve head
314
is located close to the bottom
42
of the open container
44
.
FIG. 11B
shows a valve head
14
similar to that disclosed in FIG.
5
. In valve head
14
shown in FIG.
11
B and
FIG. 5
, the distribution surface
78
includes a first portion
102
, and a second portion
104
. Each portion
102
,
104
is in the shape of the truncated cone. The slope of the distribution surface
78
of the first portion
102
descends more steeply than the slope of the distribution surface
78
of the second portion
104
. When the carbonated beverage flowing through the nozzle
16
initially impinges the first truncated cone portion
102
of the valve
14
, the flow of carbonated beverage is redirected in accordance with arrow
482
. As the carbonated beverage adjacent the valve distribution surface
78
continues to flow along the valve distribution surface
78
, it impinges the second truncated cone portion
104
which redirects the flow adjacent the valve
14
in accordance with arrow
484
. In this manner, valve
14
gently redirects the flow of carbonated beverage twice in order to obtain a flow trajectory that is less steep than the valve head
314
shown in FIG.
11
A. With the valve head
14
shown in
FIG. 11B
, the trajectory distance from the valve head distribution surface
78
to the bottom
42
of the open container
44
is given by arrow Y. Note that the magnitude of arrow Y in
FIG. 11B
is generally greater than the magnitude of arrow X shown in
FIG. 11A
because the trajectory angle of arrow
484
in
FIG. 11B
is more shallow than the trajectory angle of arrow
384
in FIG.
11
A.
FIG. 11C
shows a valve head
414
in which the slope of the distribution surface
478
becomes continuously less steep as the distribution surface
478
extends from the proximal end
474
to the distal end
476
of the valve head
414
. When the carbonated beverage initially impinges the distribution surface
478
, it is gently redirected as depicted by arrow
483
, and it continues to be gently redirected to a less steep trajectory as illustrated by arrow
485
. The magnitude of the arrow labeled Z in
FIG. 11C
designates the trajectory distance of the carbonated beverage as it leaves the distribution surface
478
before it hits the bottom
42
of the open container
44
. Note that with the valve head configuration in
FIG. 11C
, it is possible that the trajectory of the carbonated beverage flowing from the valve head
414
be flatter than with the configurations shown in
FIGS. 11B and 11A
.
FIG. 12 through 14
illustrate a system
510
that has an automated container holder
512
is connected to a lifting actuator
514
. The lifting actuator
514
moves the container holder
512
between a fully raised position designated by FRP in
FIG. 12 and a
down position designated DP in FIG.
12
. The lifting actuator
514
is preferably driven by a servo motor or an electronically controlled pneumatic mechanism. The lifting actuator
514
receives a control signal from the electronic controller via line
516
in order to control the positioning of the container holder
512
. To use the system
510
, the user places the open container
44
on the platform while the platform is located in the down position DP, FIG.
12
. The system is then actuated either by a push button, by barcode reading means as disclosed in U.S. Pat. No. 5,566,732, or other activation means. The activation signal is provided to the electronic controller
26
via line
518
, FIG.
12
. Upon receiving the activation signal, the electronic controller
26
initiates the dispensing cycle. This initiation involves the reduction of pressure of the carbonated beverage in the nozzle
16
as discussed previously. Also, a control signal is transmitted through line
516
to the lift actuator
514
to lift the container holder from the down position DP to the fully raised position FRP. When the container holder
512
is positioned in the fully raised position, FRP,
FIG. 12
, the bottom
42
of the open container
44
is located proximate to the outlet port of the nozzle
16
. With the open container
44
in the fully raised position and the pressure appropriately reduced in the nozzle
16
, the electronic controller
26
transmits a control signal through line
56
to valve actuator
36
to open the valve
14
and begin dispensing carbonated beverage into the open container
44
. Referring to
FIGS. 13 and 14
, the system
510
is capable of lowering the container platform
512
as the open container
44
is being filled. It is desirable that the outlet port
38
remain submerged during the filling process (see FIG.
14
). The positioning of the container holder
512
during the filling process is controlled by instructions from the electronic controller
26
via line
516
to the lifting actuator
514
.
In order to achieve a desired presentation for the carbonated beverage within the filled open container
44
, it may desirable to position the container holder during the filling process in accordance with a pre-selected electronic pouring profile. This feature is illustrated in FIG.
15
. Still referring to
FIGS. 12 and 13
, the distance of the container holder
512
from the fully raised position, FRP, is displayed as a function
520
of time during an arbitrary filling cycle. The position of the curve
520
in
FIG. 15
is referred to herein as the pouring profile. The pouring profile
520
is preferably stored electronically in memory that is accessible to the electronic controller
26
. The pouring profile
520
in
FIG. 15
assumes that it take 2 seconds to fill the container
44
. As the container holder
512
moves from the fully raised position, FRP, at Time=0 to the down position, DP, at Time=2 seconds, intermediate motion rate and direction of the container holder
512
vary. In other words, while the open container
44
is being filled, the container may be lowered at slow rate, a fast rate, or may even be raised slightly in order to achieve the desired presentation.
In some applications, it may be desirable to selectively move and position the valve
14
with respect to the nozzle outlet port
38
while the carbonated beverage is dispensing from the nozzle
16
. In these applications, the selective motion and positioning of the valve
14
during the dispensing of beverage is preferably accomplished in accordance with a predetermined dispensing profile, which is stored electronically in memory accessible to the electronic controller
26
. In this manner, the electronic controller
26
can be programmed to cause the valve head
14
to flutter, or otherwise be selectively positioned and moved during the dispensing of carbonated beverage in order to vary dispensing flow characteristics.
FIG. 16A through 16B
illustrate a system similar to the system
510
shown in
FIGS. 12 through 14
, but further including a funnel
612
for adding ice
614
into the open container
44
. The funnel
612
preferably has an outlet
614
, through which the downwardly extending carbonated beverage nozzle
16
extends, such that ice is supplied circumferentially around the nozzle
16
into the open container, see FIG.
16
B. The ice
616
is added to the open container
44
before dispensing the carbonated beverage into the open container
44
or contemporaneously with adding the carbonated beverage into the open container
44
. As mentioned previously, it is important when adding carbonated beverage
12
and ice
616
into an open container
44
that the temperature of the carbonated beverage closely match the surface temperature of the ice
616
in order to reduce excessive foaming. While
FIGS. 16A through 16B
show the ice being added via a circumferential funnel
612
, it is not necessary that the ice be added circumferentially. For example, the ice could be added to the container using a chute or some other means which does not circumvent the nozzle
16
. Also, it would be possible to add the ice by hand, and still achieve efficient filling in accordance with the invention.
Referring to the specific apparatus shown in
FIGS. 16A through
d
, the open container
44
is initially set into position on the container holder platform
512
with the platform in the down position DP as shown in FIG.
16
A. The electronic controller
26
then instructs the actuator
514
to move the container holder
512
to the fully raised FRP as shown in FIG.
16
B. Contemporaneously, the electronic controller
26
instructs the source of ice to discharge ice
616
into the funnel
612
, and eventually into the open container
44
as shown in
FIG. 16B and C
. The funnel outlet
16
is sized slightly smaller than the typical opening for the container
44
. The electronic controller
26
is programmed to dispense carbonated beverage into the open container
44
while the ice is falling into the container
44
or shortly thereafter. Preferably, the container holder
512
and the open container
44
are lowered during the filling process as depicted in
FIG. 16B
so that the open container
44
filled with ice and carbonated beverage is ready for service.
Alternatively, it may be desirable to partially fill the container with ice before adding the carbonated beverage. In this case, the nozzle
16
will not be placed into the open container to a bottom filling position, rather it is placed within the open container above the ice. In order to avoid excessive foaming, it is important that the carbonated beverage be chilled to a temperature substantially equal to the surface temperature of the ice that was added into the open container.
FIG. 17
illustrates a system
710
in accordance with still another aspect of the invention. The system
710
includes a second actuator
711
connected to the controller
26
by a line
712
. The actuator
711
serves to vertically move a piston
713
disposed around the valve stem
34
within the nozzle
16
above the flow inlet to the nozzle
16
. The piston
713
is generally circular in shape and includes a central opening
714
through which the valve stem
34
passes. To prevent the pressurized beverage from flowing upwardly past the piston
713
, the piston includes a pair of O-ring seals
715
and
716
. Seal
715
extends about the circumference of the central opening
714
in the piston
713
and engages the valve stem
34
to form a seal between the piston
713
and the valve stem
34
. Seal
716
extends about the outer circumference of the piston
713
and engages the inner surface of the nozzle
16
to form a seal between the nozzle
16
and the piston
713
. The piston
713
also includes a vent channel
717
extending through the piston
713
parallel to valve stem
34
. The channel
717
is connected to a venting valve
52
a
on the exterior of the system
710
. The pressure in the system
710
is monitored by a pressure transducer
719
located on the nozzle
16
and connected to the controller
26
by line
720
. In operation, the nozzle
16
is filled with the carbonated beverage
112
. Venting valve
52
a
allows the system to be purged of air during the filling process. After purging, the vent
52
a
is closed. The carbonated beverage fills the nozzle
16
until the desired beverage storage pressure is reached, as measured by transducer
719
. In order to dispense the carbonated beverage, the controller
26
activates actuator
711
to raise shaft
718
and the piston
713
in order to decrease the pressure within the nozzle
16
. When the pressure is sufficiently reduced within the nozzle
16
as measured by transducer
719
, the controller
26
then initiates actuator
36
to move the valve stem
34
and valve head
14
downwardly to dispense the beverage into the open container
44
. The transducer
719
continues to monitor the pressure of the carbonated beverage within the nozzle
16
during the pour. It is preferred that the controller
26
continues to transmit instructions to the piston actuator
711
to move the piston
713
during the pour in order to maintain an appropriate pressure within the nozzle
16
for pouring.
The invention has been described herein in connection with several embodiments, each including various features which may be desirable in various applications. It should be recognized that various alternatives and modifications of the invention are possible within the scope for the invention. Therefore, the scope of the invention should be interpreted by reviewing the following claims which particularly point out and distinctly claim the invention. Various alternatives and other embodiments are contemplated as being within the scope of the following claims which particularly point out and distinctly claim the subject matter regarded as the invention.
Claims
- 1. A system for dispensing carbonated beverage into an open container comprising:a source of carbonated beverage; a downwardly extending nozzle which is adapted to dispense carbonated beverage into an open container such that an outlet port for the nozzle is in close proximity to a bottom of the open container when dispensing of the carbonated beverage is initiated; a valve that controls the flow of carbonated beverage dispensing from the nozzle into the open container; a valve actuator that positions the valve with respect to the outlet port of the nozzle; an ice dispensing system which dispenses ice into the open container when the nozzle is located such that the outlet port of the nozzle is in close proximity with the bottom of the open container; an activation sensor that outputs an activation signal; and an electronic controller that receives an activation signal and outputs a signal to control the valve actuator in order to initiate dispensing of the carbonated beverage from the nozzle into the open container.
- 2. A system as recited in claim 1 wherein the ice dispenser comprises a funnel having an outlet through which the downwardly extending carbonated beverage nozzle extends such that the ice is supplied circumferentially around the nozzle into the open container.
- 3. A system as recited in claim 1 further comprising a chiller for chilling the carbonated beverage flowing from the source of carbonated beverage to the nozzle.
- 4. A system as recited in claim 3 wherein the chiller chills the carbonated beverage so that carbonated beverage dispensing from the nozzle into the open container is chilled to approximately a surface temperature of the ice.
- 5. A system as recited in claim 1 in which the open container is at least partially filled with ice before dispensing of the carbonated beverage into the open container is initiated.
US Referenced Citations (25)