BRUNNDAHL LARS (SE)
KIRKA ARDE (US)
WAGNER MICHAEL (US)
AXELSSON KARL-GUNNAR (SE)
ANDERSSON SVEN ARNE (US)
BRUNNDAHL LARS (SE)
KIRKA ARDE (US)
WAGNER MICHAEL (US)
AXELSSON KARL GUNNAR (SE)
| EP0280537A1 | 1988-08-31 | |||
| EP0170209A2 | 1986-02-05 | |||
| EP0433969A1 | 1991-06-26 | |||
| EP0155736A1 | 1985-09-25 | |||
| EP0117329A2 | 1984-09-05 | |||
| US4964444A | 1990-10-23 | |||
| DE1611885A1 | 1972-06-22 | |||
| EP0515077A1 | 1992-11-25 | |||
| US2099252A | 1937-11-16 | |||
| US4938387A | 1990-07-03 |
| 1. | A fill system in a packaging machine for filling a container with a primary and a secondary product, the fill system comprising: primary pump means for pumping a predetermined amount of the primary product received at an inlet thereof to an outlet thereof; a primary fill pipe connected to receive the predetermined amount of primary product from the outlet of the primary Dump means, the primary fill pipe havinc an outlet overlying a container processing path along which the containers are filled and sealed by the packaging machine, the container processing path being generally perpendicular to the orientation of the primary fill pipe; a nozzle connected at the outlet of the primary fill pipe; secondary pump means for pumping a predetermined amount of the secondary product received at an inlet thereof to an outlet thereof; a secondary fill pipe connected to receive the predetermined amount of secondary product from the outlet of the secondary pump means, the secondary fill pipe being concentrically disposed in the primary fill pipe and having an outlet overlying the container processing path; and valve means including a sealing member disposed at the outlet of the secondary fill pipe for controlling the flow of the secondary product from the secondary fill pipe. |
| 2. | A fill system as claimed in Claim 1 wherein the primary product is skim milk and the secondary product is cream. |
| 3. | A fill system as claimed in Claim 2 wherein the valve means is actuated to begin dispensing cream into a container prior to the time that skim milk is dispensed by the primary pump means through the primary fill pipe and into the container thereby to dampen any foaming of the resulting milk mixture in the container. |
| 4. | A fill system as claimed in Claim 3 wherein the dispensing of the predetermined amount of cream into the container is generally complete prior to the time that the skim milk begins to be dispensed into the container. |
| 5. | A fill system as claimed in Claim 1 and further comprising an insulation pipe, the primary fill pipe being concentrically disposed within the insulation pipe and in close conformity therewith to provide a thin gaseous insulating layer between the insulation pipe and the primary fill pipe. |
| 6. | A fill system as claimed in Claim 1 wherein a portion of the nozzle is disposed about the exterior perimeter of the primary fill pipe, the fill system further comprising an insulation pipe, the primary fill pipe being concentrically disposed within the insulation pipe and in close conformity therewith to provide a thin gaseous insulating layer between the insulation pipe and the primary fill pipe, the portion of the nozzle disposed about the exterior perimeter of the primary fill pipe forming a seal between the primary fill pipe and the insulation pipe. |
| 7. | A fill system as claimed in Claim 1 wherein the valve means comprises: an actuator; and a valve rod disposed concentrically within the secondary fill pipe and connected to the actuator, the sealing member being disposed at an end of the valve rod proximate the outlet of the secondary fill pipe. |
| 8. | A fill system as claimed in Claim 7 wherein the sealing member comprises: a sealing ring engaging the valve rod at a flared section of the valve rod; and a nut connected to the guide rod, the nut including a flange engaging the sealing ring, the sealing ring being disposed between the flared section of the valve rod and the flange of the nut. |
| 9. | A fill system as claimed in Claim 7 wherein the valve rod comprises first and second flattened guide sections. |
| 10. | A fill system as claimed in Claim 9 wherein the first and second flattened guide sections are disposed orthogonal to one another. |
| 11. | A fill system as claimed in Claim 1 and further comprising vacuum sealing means for generating a vacuum seal between the actuator and the valve rod to assist in preventing contamination of the secondary fill pipe. |
| 12. | A fill system as claimed in Claim 1 wherein the primary pump means comprises: an inlet pipe connected to receive the primary product at an inlet thereof; a first valve disposed at the output of the inlet pipe; a primary pump mechanism having an inlet connected to receive the primary product from the first valve; and a second valve disposed at the outlet of the primary pump mechanism and controlling the flow of the primary product to the primary fill pipe. 13. |
| 13. | A fill system as claimed in Claim 12 wherein the primary pump mechanism comprises: a pump having a piston, the length of the stroke of the piston determining the predetermined amount of the primary product dispensed; and a servomotor connected to control the length of the stroke of the piston. |
| 14. | A fill system as claimed in Claim 12 wherein the secondary pump means comprises: an inlet pipe connected to receive the secondary product at an inlet thereof; a valve disposed at the output of the inlet pipe; and a secondary pump mechanism having an inlet connected to receive the secondary product from the valve, the secondary pump mechanism having an outlet connected to supply the secondary product to the secondary fill pipe. |
| 15. | A fill system as claimed in Claim 14 wherein the secondary pump mechanism comprises: a pump having a piston, the length of the stroke of the piston determining the predetermined amount of the secondary product dispensed; and a servomotor connected to control the length of the stroke of the piston. |
| 16. | A fill system as claimed in Claim 1 and further comprising a cleaning sleeve disposed about the primary fill pipe. |
| 17. | A fill system as claimed in Claim 16 and further comprising a cleaning cover for sealing an end of the cleaning sleeve proximate the nozzle. |
| 18. | A fill system as claimed in Claim 17 wherein the nozzle is formed from a generally flexible material . |
| 19. | A fill system as claimed in Claim 18 wherein the cleaning cover comprises a plurality of arcuate reservoirs joined together at a portion of the cleaning cover disposed below a central portion of the nozzle. |
| 20. | A method for filling cream and skim milk into a container, the method comprising the steps of: placing a container to be filled below first and second fill pipes, the first fill pipe being concentrically disposed within the second fill pipe; and dispensing a predetermined amount of cream into the container through the first fill pipe; and dispensing a predetermined amount of skim milk into the container through the second fill pipe after a delay period during which an amount of cream is dispensed through the first fill pipe. |
| 21. | A method as claimed in Claim 20 and further comprising the step of programming the delay period through a user interface menu. |
| 22. | A method as claimed in Claim 21 wherein the delay period is dependent on container volume. |
| 23. | A method as claimed in Claim 20 wherein the cream and skim milk are dispensed simultaneously into the container after the delay period. |
| 24. | A method as claimed in Claim 20 wherein the delay period is of sufficient length so as to allow generally complete dispensing of the cream into the container prior to the time at which the dispensing of the predetermined amount of skim milk is begun. |
| 25. | A method for filling cream and skim milk into a container, the method comprising the steps of: placing a container to be filled below first and second fill pipes, the first fill pipe being concentrically disposed within the second fill pipe ,* dispensing a predetermined amount of cream into the container through the first fill pipe; and dispensing a predetermined amount of skim milk into the container through the second fill pipe, the dispensing of the predetermined amount of skim milk beginning after an initial predetermined amount of cream has been dispensed into the container. |
| 26. | A method as claimed in Claim 25 and further comprising the step of programming the initial predetermined amount of cream through a user interface menu. |
| 27. | A method as claimed in Claim 25 wherein the initial predetermined amount of cream is dependent on container volume. |
| 28. | A method as claimed in Claim 25 wherein the cream and skim milk are dispensed simultaneously into the container after the initial predetermined amount of cream has been dispensed into the container. |
| 29. | A method as claimed in Claim 25 wherein the predetermined amount of cream is substantially dispensed into the container prior to the time at which the dispensing of the predetermined amount of skim milk is begun. |
| 30. | A fill system in a packaging machine for filling a container with a primary and a secondary product, the fill system comprising: a primary fill pipe connected to receive the primary product, the primary fill pipe having an outlet overlying a container processing path along which the containers are filled and sealed by the packaging machine, the container processing path being generally perpendicular to the orientation of the primary fill pipe; a nozzle connected at the outlet of the primary fill pipe; a secondary fill pipe connected to receive the secondary product, the secondary fill pipe being concentrically disposed in the primary fill pipe and having an outlet overlying the container processing path; and a valve mechanism including a sealing member disposed at the outlet of the secondary fill pipe for controlling the flow of the secondary product from the secondary fill pipe. |
| 31. | A fill system as claimed in Claim 30 wherein the primary product is skim milk and the secondary product is cream. |
| 32. | A fill system as claimed in Claim 30 and further comprising an insulation pipe, the primary fill pipe being concentrically disposed within the insulation pipe and in close conformity therewith to provide a thin gaseous insulating layer between the insulation pipe and the primary fill pipe. |
| 33. | A fill system as claimed in Claim 30 wherein a portion of the nozzle is disposed about the exterior perimeter of the primary fill pipe, the fill system further comprising an insulation pipe, the primary fill pipe being concentrically disposed within the insulation pipe and in close conformity therewith to provide a thin gaseous insulating layer between the insulation pipe and the primary fill pipe, the portion of the nozzle disposed about the exterior perimeter of the primary fill pipe forming a seal between the primary fill pipe and the insulation pipe. |
| 34. | A fill system as claimed in Claim 30 wherein the valve means comprises: an actuator; and a valve rod disposed concentrically within the secondary fill pipe and connected to the actuator, the sealing member being disposed at an end of the valve rod proximate the outlet of the secondary fill pipe. |
| 35. | A fill system as claimed in Claim 34 wherein the sealing member comprises: a sealing ring engaging the valve rod at a flared section of the valve rod; and a nut connected to the guide rod, the nut including a flange engaging the sealing ring, the sealing ring being disposed between the flared section of the valve rod and the flange of the nut. |
| 36. | A fill system as claimed in Claim 35 wherein the sealing member comprises: a sealing ring engaging the valve rod at a flared section of the valve rod; and a nut connected to the guide rod, the nut including a flange engaging the sealing ring, the sealing ring being disposed between the flared section of the valve rod and the flange of the nut. |
| 37. | A fill system as claimed in Claim 34 wherein the valve rod comprises first and second flattened guide sections. |
| 38. | A fill system as claimed in Claim 37 wherein the first and second flattened guide sections are disposed orthogonal to one another. |
| 39. | A fill system as claimed in Claim 34 and further comprising vacuum sealing means for generating a vacuum seal between the actuator and the valve rod to assist in preventing contamination of the secondary fill pipe. |
| 40. | A fill system as claimed in Claim 30 and further comprising a cleaning sleeve disposed about the primary fill pipe. |
| 41. | A fill system as claimed in Claim 40 and further comprising a cleaning cover for sealing an end of the cleaning sleeve proximate the nozzle. |
| 42. | A fill system as claimed in Claim 41 wherein the nozzle is formed from a generally flexible material. |
| 43. | A fill system as claimed in Claim 42 wherein the cleaning cover comprises a plurality of arcuate reservoirs joined together at a portion of the cleaning cover disposed below a central portion of the nozzle. |
| 44. | 4A fill system in a packaging machine for filling a container with milk having a user specified milkfat content, the fill system comprising: user interface means for allowing a user to specify the milkfat content of the milk; a primary pump having a piston, the length of the stroke of the piston determining the amount of skim milk dispensed into the container, the primary pump having an inlet receiving the skim milk and an outlet; a primary fill pipe connected to receive the skim milk from the outlet of the primary pump, the primary fill pipe having an outlet overlying a container processing path along which the containers are filled and sealed by the packaging machine,* a secondary pump having a piston, the length of the stroke of the piston determining the amount of cream dispensed into the container, the primary pump having an inlet receiving the cream and an outlet; a secondary fill pipe connected to receive the cream from the outlet of the secondary pump, the secondary fill pipe being concentrically disposed in the primary fill pipe and having an outlet overlying the container processing path; and control means accepting the milkfat content specified by the user at the user interface means for controlling the length of the stroke of the primary pump to dispense a predetermine amount of skim milk into the container and for controlling the length of the stroke of the secondary pump to dispense a predetermined amount of cream into the container. |
| 45. | A fill system as claimed in Claim 44 wherein the control means comprises: a first servomotor connected to actuate the piston of the primary pump; a first servo amplifier connected to control actuation of the first servomotor; a second servomotor connected to actuate the piston of the secondary pump; a second servo amplifier connected to control actuation of the second servomotor; and a PAM connected to send positional instructions to the first and second servo amplifiers based on the milkfat content selected by the user. |
| 46. | A fill system as claimed in Claim 44 wherein the interface means comprises: a display; a plurality of keys for actuation by the user to facilitate user selection of the milkfat content of the milk dispensed into the containers; and a processor for sending user prompt information to the display. |
| 47. | A fill system as claimed in Claim 44 wherein the interface means comprises: a display; a plurality of keys for actuation by the user to facilitate user selection of the milkfat content of the milk dispensed into the containers; and a processor for sending user prompt information to the display and accepting key presses of the plurality of keys by the user for selection of the milkfat content of the milk dispensed into the containers, the processor connected to send signals to the PAM thereby facilitating actuation of the first and second servomotors. |
| 48. | A fill system as claimed in Claim 44 wherein the interface means comprises a plurality of keys for actuation by the user to facilitate user selection of the milkfat content of the milk dispensed into the containers. |
| 49. | A fill system as claimed in Claim 44 and further comprising: a first valve mechanism disposed to control the flow of skim milk from the primary fill pipe; and a second valve mechanism disposed to control the flow of cream from the secondary fill pipe. |
| 50. | A fill system as claimed in Claim 49 wherein the control means is further connected to actuate the first and second valve mechanisms, the control means actuating the second valve mechanism to begin dispensing cream into the container prior to the time that the first valve mechanism is actuated to begin dispensing skim milk from the primary fill pipe and into the container thereby to dampen any foaming of the resulting milk mixture in the container. |
| 51. | A fill system as claimed in Claim 50 wherein the control means actuates the first and second valves so that the dispensing of the predetermined amount of cream into the container is generally complete prior to the time that the skim milk begins to be dispensed into the container. |
| 52. | A fill pipe for use in filling a cool product into a container in a filling machine, the fill pipe comprising: a generally cylindrical fill pipe for dispensing the cool product therethrough, the fill pipe having an outlet overlying a container processing path along which containers are filled and sealed by the packaging machine; a nozzle connected about the exterior perimeter of the outlet of the fill pipe; an insulation pipe, the fill pipe being concentrically disposed within the insulation pipe and in close conformity therewith, the portion of the nozzle disposed about the exterior perimeter of the fill pipe forming a seal between the fill pipe and the insulation pipe to inhibit dripping of condensation into the container; and an insulating layer disposed between the fill pipe and the insulation pipe. |
| 53. | A fill pipe as claimed in Claim 52 wherein the insulating layer is air. |
FIELD OF THE INVENTION
The present invention relates to a filling system
for use in a packaging machine. More particularly, the present invention relates a filling system for filling
a primary product and a secondary product into a container as it is transported along the processing path of a packaging machine and wherein the primary product may be skim milk and the secondary product may be cream.
BACKGROUND OF THE INVENTION
There are a number of milk products with different
fat contents on the market today. In the U.S., for
example, skim milk, 1% Milkfat, 2% Milkfat, and whole milk are available. Abroad in Sweden there are, for
example, minimum milk with 0.1 % fat, light milk with
0.5 % fat, "middle" milk with 1.5 % fat, and "standard" milk with 3.0 % fat. Government regulations dictate that the fat content given on the packages must be
accurate. Therefore, the production of milk with a
certain, guaranteed fat content, usually called
standardization of milk, is an important process step in
a dairy.
The standardization process has traditionally been carried out according to two different general methods:
batch standardization in tanks or direct in-line standardization. The first step of each of these methods is to separate whole milk into cream and skim milk. The term "whole" milk or raw milk is used for
milk as it is delivered to the dairies with a fat
content around 4 %.
When using batch standardization two methods are
used -- pre-standardization and post-standardization. In pre-standardization, the milk is standardized prior
to pasteurization. When the milk is standardized to a fat content higher than the fat content in the raw milk, cream is mixed with the milk in proportions which
provide the desired fat content. If the standardization
takes place lowers the fat content, the raw milk is diluted with skim milk. The standardized milk is
pasteurized after analysis of the fat content and any corrections necessary to assure an accurate fat content.
In post-standardization, pasteurized milk is mixed
with cream or skim milk depending on whether the fat
content is to be adjusted upwards or downwards in the
same way as is practiced for the pre-standardization. Some risks for re-infection are present, however, since post-standardization involves mixing products that have already been pasteurized.
Both pre-standardization and post-standardization methods require large tanks. Further, analysis of the
resulting milk and a possible correction of the fat
content is labor-intensive. The second general method, direct-standardization, has therefore been an attractive alternative for many
years. According to this method, the fat content is
adjusted to the required level by remixing a certain amount of the cream obtained from the separator with
skim milk also obtained from the centrifugal separator.
This remixing takes place in the skim milk pipeline
connected to the skim milk outlet from the centrifugal separator.
The pasteurization usually takes place in
connection with the standardization. Whole milk is preheated to a temperature suitable for the separation
of the cream from the skim milk. The standardized milk
that is obtained after the remixing of suitable amounts
of cream and skim milk after passage of the centrifugal
separator is then heated and pasteurized.
The methods described above are used for manufacture of milk with a preselected fat content. A
desired amount of milk is produced. If milk with
another fat content should be produced, the system must
be adjusted to new preset values and volumes.
The different milk products with a varying fat
content mentioned above may be produced by in-line standardization. The packaging does not take place
immediately after the standardization but the milk products are intermediately stored in large tanks in the
dairy. Usually, different kinds of consumer milk are
packaged firstly when the distributors working on the
market have delivered their orders for a suitable amount of packages of consumer milk with differing fat content.
During decades of development, manufacturers of
packaging machines have devised a variety of ways to form, fill and seal containers, such as gable top
cartons, with milk and other liquids stored in the large tanks. Today, the most prevalent packaging machines for gable top cartons are adapted to receive the carton blank after it has been side sealed. The process of
side sealing involves sealing opposite vertical edges of the carton blank together to form a polygonal (usually
rectangular) sleeve. The sleeve is received on an
indexable mandrel wheel which rotates the sleeve into respective positions where the end of the sleeve extending outwardly from the mandrel is folded and sealed to form the bottom of the carton.
After the carton bottom has been formed, it is
removed from the mandrel and transported along a
processing path to a filling station. There, the carton
is filled from a storage tank that, for example,
contains the standardized and pasteurized milk. Filling takes place through a single fill tube and nozzle. Once the carton has been filled, the top of the carton is
folded into the familiar gable top configuration and is
heat sealed, thus completing the packaging process. One example of a known packaging machine that operates
generally in accordance with these principles is
described in U.S. Patent No. 3,789,746 to Martensson et al. Additional features of such machines are disclosed in U.S. Patent Nos.: 5,161,938; 5,011,467; 5,009,339; 4,979,728; 4,964,444; 4,861,328; 4,783,088; 4,759,171;
and 4,493,687. All of the foregoing patents are hereby
incorporated by reference.
Trends within the field of packaging machines point
toward increasingly high capacity machines intended for rapid, continuous filling and sealing of a very large
number of identical or similar packaging containers, e.g., such as containers of the type intended for liquid contents such as milk, juice, and the like. The filling
system of the packaging machine is important to the throughput and size of the machine since it is generally
bulky and filling is often a slow process.
Additionally, rapid transition between different container contents, such as milk of varying milkfat
concentrations, is often difficult and labor intensive. Further labor intensive mixing steps may precede the filling of the storage tanks where the container
contents include a primary and secondary product that are mixed together to form the final product. Accordingly, it is desirable to provide a filling system for a packaging machine that fills a single package with
both primary and secondary products in a fast and
efficient manner.
SUMMARY OF THE INVENTION
A fill system for use in a packaging machine is
disclosed for filling a container with a primary and a
secondary product The fill system includes a primary
pump system for pumping a predetermined amount of the primary product received at an inlet thereof to an outlet thereof. A primary fill pipe having an outlet
overlying a container processing path along which the containers are filled and sealed by the packaging machine is connected to receive the predetermined
amount of primary product from the outlet of the primary
pump system. A nozzle is connected at the outlet of the fill pipe.
The fill system further includes a secondary pump
system for pumping a predetermined amount of the
secondary product received at an inlet thereof to an outlet thereof. A secondary fill pipe is connected to receive the predetermined amount of secondary product
from the outlet of the secondary pump system. The secondary fill pipe is concentrically disposed in the primary fill pipe and has an outlet that likewise
overlies the container processing path. A valve
mechanism is disposed, for example, concentrically
within the secondary fill pipe and includes a sealing
member positioned at the outlet of the secondary fill pipe. The sealing member is operable to control the flow of the secondary product from the secondary fill
pipe.
In accordance with one embodiment of the fill system, the primary product is skim milk and the
secondary product is cream. The skim milk and cream are dispensed into the packaging container in the necessary
proportions to provide milk having a selected milkfat concentration. In such instance, the valve mechanisms and/or pump mechanisms may, for example, be actuated to
begin dispensing cream into the container prior to the time that skim milk is dispensed by the primary pump system through the primary fill pipe and into the
container. Alternatively, the dispensing of the
predetermined amount of cream into the container may be generally complete prior to the time that the skim milk begins to be dispensed into the container. By
dispensing at least a small amount of cream into the
container prior to dispensing skim milk, filling speeds may be increased since the cream tends to dampen any
foaming of the resulting milk mixture in the container.
The primary fill pipe, in accordance with one embodiment thereof, may be adapted for use in filling a cool product into the container. In accordance with this adaptation, the fill pipe is formed as a generally
cylindrical pipe for dispensing the cool product therethrough and has an outlet overlying the container
processing path. A nozzle is connected about the exterior perimeter of the outlet of the fill pipe. The
fill pipe is concentrically disposed within an insulation pipe and is in close conformity therewith.
When so engaged, the portion of the nozzle disposed
about the exterior perimeter of the fill pipe forms a
seal between the fill pipe and the insulation pipe to inhibit dripping of condensation into the container. Additionally, a thin insulating layer, such as air, is
disposed between the fill pipe and the insulation pipe so that the insulation pipe itself is less subject to the forming of condensation about its exterior.
The fill system may include a user interface and
control system that facilitates user selection of the milkfat content of the dispensed milk and, further,
controls actuation of the various valves and pumps to
effect proper dispensing in accordance with the user's
selection. The system includes a user interface for
allowing the user to specify the milkfat content of the
milk. Any number of user interfaces are suitable for
such use. The control system accepts the selections made by the user from the user interface and effects automatic control of the dispensing of the primary and secondary products into the container. In accordance with one embodiment of a controllable fill system, the system
employs primary and secondary piston pumps. The length of the stroke of the piston of the primary pump determines the amount of skim milk that is dispensed
into the container. Similarly, the length of the stroke
of the piston of the secondary pump determines the amount of cream dispensed into the container. The
primary fill pipe is connected to receive the skim milk from the outlet of the primary pump, while the secondary
fill pipe is connected to receive the cream from the outlet of the secondary pump. As previously described,
the secondary fill pipe is concentrically disposed in
the primary fill pipe, both fill pipes having outlets
overlying the container processing path. The control system controls the length of the stroke of the primary
pump to dispense a predetermine amount of skim milk into
the container and further controls the length of the stroke of the secondary pump to dispense a predetermined amount of cream into the container. Numerous control
system configurations are suitable for use in the fill system.
Other objects, features, and advantages of the fill
system will become apparent upon review of the following
detailed description and drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of the fill system.
FIG. 2 is a side elevational view of a fill pipe assembly used in the fill system of FIG. 1 FIGs. 3 - 13 illustrate the valve rod, sealing
ring, and nut of the valve assembly that is concentrically disposed in the secondary fill pipe.
FIGs. 14 and 15 are schematic diagrams showing
operation of the fill system during production suction
and dispensing.
FIGs. 16 - 18 are schematic diagrams showing operation of the fill system during rinsing.
FIGs. 19-21 are schematic diagrams showing operation of the fill systems during initial filling of the primary and secondary products.
FIGs. 22 and 23 are schematic diagrams showing operation of the fill system during draining of the
primary and secondary products from the system.
FIG. 24 is a schematic diagram of showing operation
of the fill system during sanitization.
FIG. 25 is a cross-sectional view illustrating one embodiment of a pump mechanism suitable for use in the
present fill system.
FIGs. 26-33 illustrate several embodiments of a
user interface and control system suitable for use in the present invention.
FIGs. 34 -40 are flow diagrams that illustrate several ways in which the user interface and control
system may operate.
FIGs. 41 and 42 are graphs illustrating how the fill system may begin dispensing cream before it begins
dispensing skim milk. FIG. 43 is an exemplary velocity profile illustrating piston velocity as a function of time for
each of the primary and secondary pumps.
FIG. 44 illustrates a still further embodiment of a user interface and control system for use in the
present fill system.
DETAILED DESCRIPTION OF THE DRAWINGS
FIG. 1 is a perspective view of the various components of one embodiment of a fill system, shown generally at 30. The illustrated fill system 30 includes two parallel filling stations 35 and 40 that
overlie respective parallel container processing paths
45 and 50 along which respective lines of containers are filled and sealed. Each of the filling stations 35 and
40, as will be set forth in detail below, dispense a primary and secondary product into each of the
containers as the containers are transported along their respective container processing paths 45 and 50.
Although two separate filling stations 35 and 40 are
illustrated, a single filling station is also contemplated as being suitable for use in a packaging machine.
The fill system 30 includes a primary product inlet
55 for accepting a primary product, such as skim milk, from a primary product storage tank (not illustrated) . A secondary product inlet 60 is connected to accept a
secondary product, such as cream, from a secondary
product storage tank (not illustrated) . Inlet pipes 70 and 75 guide the primary product to a primary pump
mechanism 80 that, as will become apparent from the
description below, includes a dual piston pump, each piston respectively associated with one of the filling
stations 35 and 40. Similarly, inlet pipes 90 and 95
guide the secondary product to a secondary pump mechanism 100 which likewise includes a dual piston
pump.
The pump mechanisms 80 and 100 are connected to
respective intermediate pipes 105, 110, 115, and 120. Intermediate pipes 105 and 110 proceed from respective
piston cylinders of the primary and secondary pump
mechanisms 80 and 100 to guide the primary and secondary
products to fill tube assembly 125. Intermediate pipes 115 and 120 proceed from respective piston cylinders of the primary and secondary pump mechanisms 80 and 100 to
guide the primary and secondary products to fill tube
assembly 130. A plurality of valve mechanisms 132, 135, 137, 140, 142, 145, 147, 150, 155, and 160 control the
flow of the primary and secondary products along the pipes 70, 75, 90, 95, 105, 110, 115, and 120 in a manner that will be described below that is dependent on
whether the fill system is to be cleaned, initially filled, drained, or is engaged in production filling.
The valves may be constructed in accordance with one or
more of the teachings of U.S. Patent Nos. 3,643,679;
4,913,185; and European Patent 191 192B1. To ensure hygenic operation of the system, each of the valves may be connected to a vacuum generator which vacuum isolates
several of the valves moving components from the valve
chamber.
All of the various illustrated product conducting
pipes that are utilized in the fill system 30 may be
inclined. As such, the tasks of draining the system
and, further, eliminating air bubbles in the system as it is filled, become easier to implement.
The fill system 30 may be used to replace a single product fill system used in an existing packaging machine. In such instance, it is desirable to provide a support frame 175 as a component of the overall fill system 30. For example, the illustrated fill system may
be mounted for use in a packaging machine such as a Model TR/7 currently available from Tetra Rex Packaging
Systems, Inc., of Buffalo Grove, IL.
Each fill tube assembly 125 and 130 at each filling
station 35 and 40 is supplied with both the primary and secondary products. One embodiment of a fill tube
assembly 125 suitable for use in the present filling
system is illustrated in FIG. 2.
The fill tube assembly includes a primary fill pipe
180 and a secondary fill pipe 185 that is concentrically disposed in the primary fill pipe 180. The primary fill
pipe 180 accepts primary product from intermediate pipe
110 at inlet 190 while the secondary fill pipe 185 accepts secondary product from intermediate pipe 105 at inlet 195. A nozzle 200 that may be formed from a
flexible material, such as , is disposed at the outlet 205 about the exterior perimeter of the primary fill pipe 180. The nozzle 200 may be
constructed in accordance with the teachings of U.S.
Patent No. , to . The secondary fill pipe 185 proceeds concentrically into the primary fill pipe 180 and has an outlet 210
disposed a distance above outlet 205 of the primary fill pipe 180. As such, the primary and secondary products may, if desired, be mixed in the primary fill pipe 180 prior to being dispensed into a container through nozzle
200.
A valve mechanism, shown generally at 215, controls
the flow of the secondary product from the outlet 210 of
the secondary fill pipe 185. The valve mechanism 215 includes an actuator 220 disposed at the upper portion of the secondary fill tube 185. The actuator 220
includes a pneumatically operated cylinder 225 that houses a piston that, in turn, is connected to actuate a valve rod 230 that is disposed concentrically within
the secondary fill pipe 185. The valve rod 230 includes flattened guide members 235 that may be arranged
orthagonally. A sealing member 237 is disposed on the valve rod 230 proximate the outlet 210 of the secondary fill tube 185. The sealing member 235 engages the outlet 210 to seal off the flow of secondary product from the secondary fill tube 185 when the actuator 225 moves the valve rod 230 and sealing member 237 to the
illustrated position. The actuator 225 may be
pneumatically operated to move the valve rod 230 and
sealing member 237 to a second position in which the sealing member 237 is disengaged from the outlet 210
thereby allowing the secondary product to flow from the
secondary fill pipe 185.
FIGs. 3 - 13 illustrate the components constituting
the valve rod 230 and the sealing member 237. As shown,
the sealing member 237 engages the flared end 240 of the
valve rod 230. A fastening stem 245 extends from the
flared end 240. The sealing member 237 may be formed as
two separate components: a nut 250 that, for example, is
constructed of stainless steel, and a sealing ring 255 that, for example, is constructed from hardened Teflon. When assembled, the nut 245 engages the fastening stem 245 with the sealing ring 255 disposed therebetween.
FIGs. 8 and 13 are cross-sectional views of the sealing ring 255 and nut 250 illustrating the various
aspects of their respective constructions that enhance
sealing and stability of construction. For example,
sealing ring 255 includes beveled surfaces 260 that conform to the outlet 210 of the secondary fill pipe 185
to enhance the integrity of the seal therebetween when the rod 230 and sealing member 237 are in the aforementioned first position. Further, the nut 250
includes cutting edges 265 that engage the sealing ring
255 when the valve rod 230 and sealing member 255 are
assembled thereby providing secure engagement therebetween.
Condensation at the exterior ct " a fill pipe often
results when the fill pipe is use to dispense a cool
product, such as refrigerated milk. This condensation
can drip into the container as it is being filled
thereby compromising the hygiene of the contents. Accordingly, the primary fill pipe 180, as illustrated
in FIG. 2, is concentrically disposed in an insulation
pipe 275 and is in close conformity therewith. A thin
insulating layer 280 may be disposed between the exterior of the primary fill pipe 180 and the interior
of the insulation pipe 275. The portion of the nozzle
200 proceeding about the exterior of the primary fill pipe 180 forms a seal with the primary fill pipe 180 and
the insulation pipe 275. Any condensation forming on the primary fill pipe 180 is thus prevented from
dripping into the carton. Further, condensation on the exterior of the insulation pipe 275 is reduced, if not
eliminated, since the insulation pipe 275 is insulated from the primary fill pipe 180 by the insulating layer
280. Alternatively, or in addition to the foregoing, the insulation pipe 275 may be formed from an insulating
material. A cleaning sleeve 290 is disposed about the
exterior of the insulation pipe 275 and includes fluid
apertures 295 and 300. A cleaning cover 310 is placed
at the mouth 315 of the cleaning sleeve 290 to seal off
the flow of fluid from the mouth 310 during cleaning. The cleaning cover 310 comprises a plurality of arcuate
reservoirs 320 joined together at a portion of the cleaning cover 310 that is disposed below a central
portion of the nozzle 200. The reservoirs 320 divert
the flow of cleaning fluid that flows from the primary
and secondary fill pipes 180 and 185 so as not to cause nozzle 200, such as one formed from a flexible material, to deform from the backslash that may occur with a cover
plate that does not have such reservoirs. An inflatable
bladder (not illustrated) may be used to assist sealing between the mouth 315 and the cover 310.
FIGs. 14 and 15 are schematic block diagrams of the
fill system 30 illustrating the operation of the pump
mechanisms 80 and 100, the valve mechanisms 135 - 160, and valve mechanism 215 of the secondary fill pipes 185
during production suction and filling. As illustrated, pump mechanisms 80 and 100 each include dual piston pumps 350 and 355 that are driven by a respective motor
360 and 365, such as a servomotor. The dual piston
pumps 350 may be pumps such as the type shown in FIG. 25 that is designed to simultaneously drive two pistons. In production filling, the fill system 30 first
executes a production suction operation. This operation, illustrated in FIG. 14, involves closing or
maintaining closure of valve mechanisms 140, 145, 147,
150, and 215 while opening valve mechanisms 132, 135, 137, 155 and 160. Servomotors 350 and 355 operate the pistons of their respective dual pumps 350 and 355 to
draw in a predetermined amount of the primary and
secondary products from the inlet pipes 70, 75, 90, and
95. The servomotor operation is illustrated by the arrows adjacent the pistons of the pumps.
After a predetermined amount of each of the primary and secondary products has been suctioned through inlet pipes 70, 75, 90, and 95 from the primary and secondary storage tanks, the fill system 30 begins the dispensing
operation illustrated in FIG. 15. During this operation, valve mechanisms 132, 137, 140, 155, and 160 are closed or remain closed and valve mechanisms 135,
142, 147, and 215 are opened or remain open.
Servomotors 360 and 365 operate their respective dual
piston pumps 350 and 355 in the manner illustrated by the adjacent arrows to dispense the predetermined
amounts of the primary and secondary products through
the primary and secondary fill pipes 180 and 185 and
nozzle 200 and into containers 200 disposed beneath the
pipes on the respective container processing paths 45
and 50.
FIGs. 16 - 18 schematically illustrate rinsing
of the fill system 30. Before rinsing, the cleaning
covers 310 are placed over the mouths 315 of the cleaning sleeves 290. During the initial step
illustrated in FIG. 16, the cross-over pipes 500 and 510 are rinsed by opening valve mechanism 135 and 145 while
closing valve mechanisms 132, 137, 150, and 160.
In a secondary product rinsing step, illustrated in
FIG. 17, the secondary product system is rinsed by
opening valves 155, 160, and 215 and providing rinsing
fluid at inlet 60. The servomotor 360 is activated to operate the secondary pump mechanism 350. The rinsing
fluid flows through the secondary product system and
into pipes 520 and 530, the fluid ultimately exiting the primary product inlet 55 through valves 140 and 150.
In a primary product rinsing step, illustrated in
FIG. 18, the valves associated with the secondary
product system are closed while the valve mechanisms associated with the primary system are opened. Rinsing
fluid is supplied at inlet 60 and enters the primary
system through valve 145. The servomotor 365 is activated to operate the primary pump mechanism 355.
The rinsing fluid flows through the primary product
system and ultimately exits the primary product inlet 55. When the system is drained after rinsing, the
resulting fluid is diverted out drain valve 570.
FIGs. 19 - 21 illustrate one manner in which the
fill system 30 is initially filled with the primary and secondary product prior to the production filling
process. In the filling up process, the valves 132, 137, 155, and 160 are first opened while the valves 142, 147, and 215 are closed. This allows the upper portion
of the primary and secondary systems to fill with the
respective product. As shown in FIG. 20, the pump
mechanisms 350 and 355 are then actuated by the servomotors 360 and 365 while valve mechanisms 132 and
137 are closed and valve mechanisms 142 and 147 are
opened. This facilitates removal of air from the primary and secondary systems and, further, facilitates filling of the lower portion of the primary product
system. Finally, as illustrated in FIG. 21. Valve
mechanisms 142 and 147 are again closed while the
servomotors 360 and 365 actuate the pump mechanisms 350
and 355 .
FIGs. 22 and 23 illustrate the draining of the
primary and secondary products from the system. In FIG.
22, the primary product is drained by opening valve mechanisms 132, 137, and 142 while operating the primary
pump mechanism 355. The cleaning cover 310 is disposed
over the cleaning sleeve 290. The primary product is
diverted from the apertures 295 and 300 of the cleaning sleeve 290 to a primary product holding tank 580. The
secondary product is similarly drained, as illustrated
in FIG. 23, into a further secondary product holding tank 590.
FIG. 24 illustrates system sanitization. During sanitization, all valve mechanisms are opened. The
cleaning covers 310 are also in place.
FIG. 25 illustrate one embodiment of a pump
mechanism 350 suitable for use in the present fill
system 30. The pump mechanism 350 includes a belt drive portion 600, a screw drive portion 610, a piston portion 620, and a cylinder 630. The belt drive portion 600 is connected for actuation to the shaft 640 of the
servomotor 365. The shaft 640 drives a drive belt 650 which, in turn, actuates the screw drive portion 610.
The screw drive portion 610 is connected to drive the
piston portion 620 in a back and forth direction,
illustrated here at arrow 660, based on the direction of rotation of the shaft 640 of the servomotor 365.
Movement of the piston 670 in the piston portion 620 causes the cylinder 630 to alternately fill the cylinder 690 through inlet 680 with the product and empty the product from the cylinder 630 through outlet 690. A
membrane 700 is disposed about the piston 670 to
hygienically isolate the piston 670 from the cylinder 630. Such a construction is shown in U.S. Patent No. 5,090,299 which is hereby incorporated by reference. In
the presently disclosed embodiment, the belt 650 drives two such screw drive and piston assemblies to effect the
dual pump mechanism. The screw drives and piston assemblies may be disposed in a side-by-side relationship. The belt may be disposed about a tensioning gear to maintain the proper tension for
effective driving of the dual pump mechanism.
FIGs 26 - 33 illustrate several hardware embodiments of a user interface and control system
suitable for use in the present fill system 30. FIG. 25
illustrates an embodiment of the system that may be used
in an existing machine, such as a Tetra Pak TR/7
packaging machine, that has been converted to employ the
presently disclosed fill system. As illustrated in FIG.
25, the user interface and control system, designated generally at 800 may include a VME bus rack 810 that
includes a programmable logic controller ("PLC") 820, an I/O interface device 830, a communication device ("CMM")
840, and a programmable axis controller ("PAM") 850. The PLC 820, I/O 820, CMM 840, and PAM 850 may all communicate with one another along a VME bus. The
system 800 also includes a control panel 860 and a
machine controller 870 that already exists in the
machine to control the movement and sealing of the containers as they proceed through the machine.
The PLC 820 controls the interface between the existing machine controller 870 and the added user
interface and control system 800. Such control may, for
example, occur via the I/O interface device 830 along a serial communications line 880 or the like. Data may be exchanged to ensure coordination between the container
filling by the fill system and the movement of the
containers along the container processing path within
the existing machine.
The CMM 840 acts as an interface with the control
panel 870 which facilitates user entry of the relative proportions of the primary and secondary products as
well as the container volume. Key presses may be
communicated to the CMM 840 which, in turn, may
communicate the key presses to the PLC 820 and/or PAM 850 for further processing. Similarly, the PAM 850
and/or PLC 820 may communicate information to the
control panel 860 via the CMM 840 for displaying information to the user.
The PAM 850, which may be a PAM such as one available from Socapel, communicates along lines 890 and 900 with servo amplifiers 910 and 920, which may be servo amplifiers such as the Model ST-1 also available
from Socapel. Servo amplifier 910 controls the motion
of the piston of the primary pump 355 along one or more lines 930 while servo amplifier 920 controls the motion of the piston of the secondary pump 350 along one or
more lines 940. The servo amplifiers 910 and 920 may also include input and output lines, shown here as lines 950 and 960, that interface with the inlet and outlet valves of the respective primary and secondary fill
systems. The opening, closing, and status of the inlet
and outlet valves may thus be controlled and detected. A variety of control panels 860 suitable for use in
the present fill system 30 are disclosed in FIGs. 27 -
30. As illustrated in FIG. 27, the control panel 860 may include a display screen 950, a plurality of
vertically oriented selection keys 960 along a side thereof and a further plurality of horizontally disposed
keys 970 along, for example, the bottom thereof. The screen 950, such as an LCD screen or CRT, may be used to
display user prompt information. In the example of the
display panel shown in FIG. 27, the user is prompted,
for example, to first select the volume of the container that is to be filled. Five potential selections are
shown, each having a keyswitch 960 located adjacent the
screen label corresponding to the particular container volume selection. The user may then, for example, be prompted to enter the desired milkfat content of the
milk that is to fill each of the containers as
illustrated in FIG. 28. Again, five potential selections are shown, each having a keyswitch 960 located adjacent the screen label corresponding to the
particular milkfat content. A screen area 980 may be
used, for example, to indicate total volume of product
in each of the storage tanks, to display the status of
the machine, etc. The horizontal keys 970, for example, may be used to initiate the filling cycle, toggle between menus, etc.
FIG. 29 illustrates a further control panel 860 that may be used in the present system. In this example, the panel 860 is a touch screen monitor. Virtual keys 900 are displayed to prompt the user to
select, for example, the desired container volume and milkfat content.
FIG. 30 illustrates a still further control panel
860 which may, for example, be a smart panel such as a
Model HE6930IU367 panel manufactured by and available from Homer electronics. Here, for example, the display
1000 may be a 2-line vacuum fluorescent display.
Function keys F1-F12 may be pre-programmed to execute, for example, stored recipes. Numerous other display panel configurations are possible, the illustrated configurations being exemplary in all respects.
In another embodiment of the user interface and
control system 860 shown in FIG. 31, the control panel 860 may be connected for control by, for example, an
industrial personal computer 1010 ("PC") . The PC 1010,
in turn, may be connected for communication along bus 1020 with the PAM 850. Bus 1020 may be, for example, a
VME bus, or any other bus suitable for use with the
particular PAM type. The PAM 850 communicates motion information to servo amplifiers 910 and 920 along, for
example, a fibre optic link 1030. Each of the servo amplifiers 910 and 920 is respectively associated with
the servo motors 360 and 365 controlling the movement of the pistons in the primary and secondary pumps 350 and
355. The servo amplifiers communicate error information
to the PAM 850 which, in turn, may execute a system shutdown upon the occurrence of an error. The error
information may further be communicated from the PAM 850
to the PC 1010 for display on the control panel 860.
FIG. 32 illustrates another configuration for the user interface and control system 800. In this
configuration, a programmable logic controller 820
("PLC") is connected for communication with the PC 1010.
The PLC 820 may be a Series 90 Controller available from GET Fanuc Automation. The PLC 820 communicates with individual axis controllers 1040 and 1050 that control
the motion of the servomotors 360 and 365 via respective
servo amplifiers 1060 and 1070.
A similar system is illustrated in FIG. 33. Here,
however, the PLC 820 does not directly communicate with the control panel 860. Rather, such communications are
managed through the PC 1010. Any number of user interface and control systems
are suitable for use in the present fill system. The foregoing illustrated embodiments are but several such
systems and are intended to be exemplary of such
systems. FIGs. 34 - 40 are flow diagrams that describe some of the many ways that are contemplated for operation of the user interface and control system. The illustrated
flow diagrams can be implemented with hardware and/or software. The basic exemplary operation of the system is
shown in FIG. 34 wherein the primary product is skim
milk and the secondary product is cream. As illustrated, the user first selects the volume or size
of the container that is to be filled at 1110. The milkfat content, such as skim, 1%, 2%, whole milk, or cream is then selected at 1120. The user may further optionally select the number of containers that are to
be filled at 1130. Based on the volume and milkfat
information that is input by the user, the control
system automatically selects the proper motion profile
at 1140, including the stroke length for the pistons of the primary and secondary pumps 355 and 350. The motion profiles are then continuously implemented to fill
successive cartons until such time as the production quantity is filled, a manual stop is detected, or an error is detected.
FIGs 35 - 38 illustrate one method for selection of
the motion profiles of the pistons based on the user
inputs. In accordance with the illustrated method, motion profiles are stored, for example, in a read only
memory (ROM) . One motion profile is stored for each
combination of volume and milkfat content that is selectable. For example, as illustrated in FIG. 35, if volume 1 (i.e., 1 gallon) is selected for the container volume, the system may then ascertain the selected milkfat concentration at steps 1150 through 1190. If the milkfat concentration that was selected falls within
the proper range for acceptable inputs, the system
selects and implements one of the proper motion profile
at steps 1200 through 1240. A similar process ensues if one of the other container volumes has been selected.
FIG. 39 illustrates another method for selection of
the proper motion profile. Here, for example, a single
motion profile may be stored in ROM or the like for each
of the primary and secondary pumps 355 and 350. The motion profiles may then have their characteristics, such as the amplitude of the stroke length, altered based on the volume and milkfat concentration selected
by the user.
FIG. 40 illustrates one method for implementing the
fill operation using, for example, the user interface and control system 800 shown in FIG. 26. This method may be implemented by the software utilized in the PAM that is, for example, a PAM available from Socapel. In
the illustrated embodiment of the method, the inlet valves 132, 137, 155, and 160 and outlet valves 142, 147, and 215 as well as the pumps 350 and 355 are controlled by the PAM, servo amplifiers, and the
associated servo motors 360 and 365. As would be understood by those skilled in machine controllers, the VM comparator referred to in steps 1250 - 1280 is the virtual master that is part of the PAM configuration.
Two different motion profiles are illustrated in
FIG. 41 and 42 showing the dispensing of cream from the
secondary pump 350 prior to the dispensing of skim from
the primary pump 355. The illustrated profiles show piston position as a function of time over two cycle
periods. In FIG. 41, the pumps 350 and 355 are in a suction
portion of the cycle up to time tl. From time tl to time t2, both the primary and secondary pumps 355 and 350 are
in a dwell period. At time t2, the secondary pump 350
exits the dwell period and begins the dispensing portion
of its cycle while the primary pump 355 remains in the dwell portion of the cycle until time t3 at which point
both skim milk and cream are in the process of being dispensed into the container. Dispensing is completed
at t4 and a new cycle begins at t5. The delay period between t2 and t3 may, if desired, be programmable
through the user interface. This delay may also be
based on the amount of initial cream that is dispensed into the container.
In the alternative, or in addition to, the foregoing manner of dispensing cream before skim milk,
the valve mechanisms 142, 147, and 215 may be used in a timed relationship to execute the desired fill timing
and the delay period between skim milk and cream
dispensing.
In FIG. 42, the pumps 350 and 355 are in a suction portion of the cycle up to time tl. From time tl to time
t2, both the primary and secondary pumps 355 and 350 are in a dwell period. At time t2, the secondary pump 350 exits the dwell period and begins the dispensing portion
of its cycle while the primary pump 355 remains in the dwell portion of the cycle until time t3 at which point the cream has been completely, or close to completely
dispensed into the container. At time t3, the primary
pump 355 begins to dispense skim milk into the container. Dispensing is complete at time t4 and a new
cycle begins at t5.
FIG. 43 illustrates velocity of the pistons as a function of time over a single suction/dispensing cycle.
FIG. 44 illustrates a still further embodiment of
a user interface and control system for use in an
existing packaging machine such as the aforementioned
TR/7 wherein further control circuitry is utilized to facilitate the use of existing machine components. In
particular, the illustrated control system includes
further circuitry for interfacing with the existing cam drive of the machine.
In accordance with known methods of changing the
operation of a packaging machine to accommodate various
carton volumes, a plurality of cams may be disposed about a single cam shaft extending along the length of
the packaging machine. For a given package volume, only
a single set of cams engage the various moving operational portions of the machine. When the package volume is changed by the user, the cam shaft is shifted along its axis until a further set of cams engage the
moving operational portions of the machine. The further set of cams impart the motion required to operate the
machine at the further selected carton volume.
In the illustrated system, the PAM 850 is directly
connected to the existing machine controller 870. A further servo amplifier 1300, such as the aforementioned
ST-1, is connected in a ring configuration with the
previously noted servo amplifiers 910 and 920 shown in FIG. 26. The output of the servo amplifier 1300 is
connected along one or more lines 1305 to drive a cam
drive motor 1310 that, for example, may be a "dumb"
motor that already exists in the machine to rotate the cam shaft. A first resolver 1320 is disposed to monitor
the rotation of the cam shaft and report its position to
the existing machine controller 870 along one or more lines 1325. A second resolver 1330 is disposed to
monitor the rotation of the cam shaft and report its
position to servo amplifier 1300 along one or more lines 1335. Since the servo amplifier controls the rotation
of the cam shaft, it becomes possible to more accurately coordinate the operation of the existing machine with
the newly added fill system.
While preferred embodiments of the invention have
been described hereinabove, those of ordinary skill in the art will recognize that the embodiments may be modified and altered without departing from the central spirit and scope of the invention. Thus, the preferred
embodiments described hereinabove are to be considered
in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended. Therefore, all changes and modifications which come within the meaning and range of equivalency of the
claims are intended to be embraced herein.