The present invention is directed to an apparatus for packaging articles using shrink-wrap film and, particularly, to an improved heat tunnel that can be used for various film configurations.
It is known in the art to overwrap articles in a web of heat shrinkable film to form a multipack package by separating a tube of such film wrapped around spaced groups of articles along a weakened zone by shrinking the tube adjacent the zone and then by shrinking the tube section formed thereby around the articles to form a package. See U.S. Pat. No. 3,545,165.
Previous methods of packaging such as the above have involved feeding the groups of articles into a heat tunnel in series, with the film wrapped around the articles from the leading edge of the group to the trailing edge of the group.
The groups G are then fed on the conveyor into a heat tunnel T. Heat and (typically) forced air is applied to the junction J between adjacent groups G, causing the film layer L to soften at the junction J and pinch off between the groups G, at the same time shrinking tightly against the groups G as shown. This results in complete packages P of articles A, with the film shrunk about them. The closed ends E of the packages P (known as “bulls eyes”) are at ends of the packages P in the direction of travel of the conveyor C (shown by the arrow).
An extension to the above apparatus is shown in
The apparatus shown in
In yet another variation (which the Assignee has used in the past), cut sleeves of film F are used, one sleeve per article group, instead of a continuous layer of film F around the groups G1, G2, G3, etc. However, the groups G are fed serially into the heat tunnel T with the articles A in each group G oriented in such a manner that the film F will be shrunk around each group G with the resulting closed ends E (“bulls eyes”) oriented transverse to the direction of travel of the conveyor C. To improve throughput, multiple parallel streams of articles A may be fed into the heat tunnel T.
The present application discloses an improved heat tunnel for use with both pre-perforated and non-perforated shrink wrap film.
In the packaging industry, aesthetics has become an increasingly important issue, both for the package that is produced and the machine that produces it. When the film is shrunk around the end of a package, it should leave a circular opening, the “bulls eye”, and should be free of wrinkles. This should be consistent from package to package and over a variety of product sizes.
Many of the challenges in producing aesthetically pleasing “bulls eyes” stem from the way that current heat tunnels operate. Current heat tunnels often produce deformed bulls eyes due to uncontrolled airflow. That is, as the group of articles enclosed in shrink-wrap film enters the heat tunnel, the film is subjected to various disruptive air currents, causing the film to flutter as it is shrunk. This uncontrolled airflow results in the film wrinkling and shrinking non-uniformly, which in turn results in unaesthetically pleasing bulls eyes. Furthermore, current heat tunnels are not generally adjustable for various product sizes.
There is a need for a new heat tunnel capable of producing consistently good bulls eyes with controlled shrink and that is adjustable for a range of product sizes.
There is also a need for a new heat tunnel to reduce the heat transfer to the outer skin of the heat tunnel, increasing the operating efficiency and improving the working environment around the machine by lowering the temperature.
There is also a need for a more aesthetically appearing heat tunnel and one of reduced size.
All of the above needs are addressed by the present invention.
A heat tunnel for applying heated air to articles to enclose the articles in shrink-wrap film, the heat tunnel includes:
(a) at least one air supply unit, the air supply unit further comprising a source of heated air, a fan, a heated air plenum, air ducts, and a return air plenum;
(b) a conveyor; and
(c) a heat shroud spaced from the conveyor,
wherein multiple air supply units can be provided along the conveyor to create a heat tunnel of desired length.
A principal object and advantage of the present invention is that a heat tunnel according to a preferred form provides a balanced laminar flow of air through the conveyor and controlled airflow from the sides. This creates shrink film covered packages with consistently shaped bulls eyes, a minimum distortion of graphics, and a minimum of wrinkles.
Another principal object and advantage of the present invention is that a heat tunnel according to a preferred form permits vertical adjustment of the heat shroud to ensure consistent results over a range of product sizes.
Another principal object and advantage of the invention is that the heated air passing through the conveyor contacts the film under the product and results in an “air weld” of the film lap seam.
Another principal object and advantage of the invention is that the heated air has a minimum contact with the product conveyor, so that the conveyor can be maintained at a relatively cool temperature of about 220° F. As a result, the film does not stick to the conveyor and less heat energy is lost to the environment.
Another principal object and advantage of the present invention is that the outer surface of the heat tunnel stays cooler during operation, thus making the heat tunnel safer and more comfortable to work around and also increasing operating efficiency due to the reduced heat loss.
Another principal object and advantage of the present invention is improved appearance, with a curved heat shroud and a lower profile.
Another principal object and advantage of the present invention is that the conveyor is adjustable to use either side-by-side cut tubes of articles or articles enclosed in pre-perforated shrink wrap film.
Another principal object and advantage of the present invention is that a heat tunnel according to a preferred form can be used with a single chain conveyor the full width of the machine or with multiple chains running side by side with center air ducts.
Another principal object and advantage of the present invention is that the conveyor construction allows air from the heated air plenum to freely pass through it to the product.
Another principal object and advantage of the present invention is that the conveyor temperature is controlled by a cooling fan that circulates air across the full width of the conveyor.
Another principal object and advantage of the present invention is that a heat tunnel according to a preferred form produces a sound reduction of approximately 13% compared to previous models.
Another principal object and advantage of the present invention is that the OEM rated service life of the heaters is in excess of 20,000 hours of operation.
Another principal object and advantage of the present invention is that a heat tunnel according to a preferred form provides modular air supply units having a source of heated air, a fan, a heated air plenum, air ducts, and a return air plenum, so that the modular air supply units may be arranged in series with a separate conveyor and heat shroud to produce a heat tunnel of variable length, so that the length of the heat tunnel may be adjusted to correspond to the speed of incoming articles, providing sufficient time for the articles to reach the shrinking temperature of the shrink wrap film and for the shrink-wrap film to shrink around the articles.
In one aspect, the present invention is an apparatus 10 for applying heat to articles A and to enclose the articles A in shrink-wrap film F.
The apparatus 10 (
The apparatus 10 further comprises a source of heated air 18. The apparatus 10 further comprises (
The apparatus 10 further comprises (
The apparatus 10 further comprises a return air plenum 30 returning air to the source of heated air 18.
The apparatus 10 further comprises a shroud 32 partially enclosing the conveyor 12 along the first direction and spaced from the conveyor 12 at a displacement. With the conveyor 12, shroud 32 forms a film shrinking area 34 between the conveyor 12 and the shroud 32 (
In one embodiment, the heated air plenum 20 further comprises a bottom surface 25 spaced from and opposing the top surface 22 and forming a duct 36 therebetween. The duct 36 has a height 38, and the height 38 progressively decreases along the first direction, as best seen in
In one embodiment (
In one embodiment, the apparatus 10 further comprises a conveyor cooling fan 40 which also aids in keeping the temperature of the conveyor 12 significantly lower than in earlier devices.
In one embodiment, the apparatus 10 further comprises a side air duct 50 adjacent the conveyor 12 along the first direction, with the side air duct 50 transmitting heated air from the heated air plenum 20. The side air duct 50 may optionally have a supplemental heat source 52 (
In one embodiment (
In one embodiment (
In one embodiment (
In one aspect, the present invention is an apparatus 110 for applying heated air to articles A and to enclose the articles A in shrink-wrap film F.
The apparatus 110 (
The apparatus 110 further comprises a source of heated air 18. The apparatus 110 further comprises (
In one embodiment (
In one embodiment, the apparatus 110 further comprises a side air duct 50 adjacent the conveyor 112 along the first direction, with the side air duct 50 transmitting heated air from the heated air plenum 20 transversely across the conveyor 112.
The apparatus 110 further comprises a return air plenum 30 returning air to the source of heated air 18.
The apparatus 110 further comprises a shroud 32 partially enclosing the conveyor 112 and spaced from the conveyor 112. With the conveyor 112, shroud 32 defines a film shrinking area 34 between the conveyor 112 and the shroud 32.
In one embodiment, the heated air plenum 20 is tapered vertically along the conveyor 112 in the direction of movement of the conveyor 112, as best seen in
In one embodiment (
In one embodiment (
In one aspect, the invention is an apparatus 210 (
In one embodiment (
In one embodiment (
In one embodiment (
In one embodiment, the source of heated air 18 is removable from the air supply unit 220.
In one embodiment, the source of heated air 18 is controlled to maintain a constant temperature in the heated air plenum 20.
In one embodiment, the apparatus 210 further comprises a sensor 230 (
In one embodiment, the fan 26 has a variable speed to adjust the flow of heated air through the heated air plenum 20.
In one embodiment, the fan 26 is removable from the air supply unit 220.
In one embodiment, the side air duct 50 has an adjustable opening.
In one embodiment, the side air duct 50 has a diffuser 51.
In one aspect, the air supply unit 220 is modular.
In one embodiment, a plurality of the modular air supply units 220 may be serially arranged thereby producing a heat tunnel of variable length, as best seen in
In one embodiment, the heated air plenum 20 is tapered in cross section transversely to the direction of heated air movement with the cross sectional area of the plenum 20 progressively decreasing away from the fan 26 as best seen in
In one embodiment, the modular air supply unit 220 further comprises a retractable center air duct 54 receiving heated air from the heated air plenum 20.
Operation of the invention will now be described in reference to the Figures.
Articles A to be shrink-wrapped are received on an infeed conveyor (not shown) with the shrink-wrap film positioned about the articles A illustratively shown in
Articles A then move from the infeed conveyor to the conveyor 12, 112 as in
In the case of the various aspects of the present invention, articles A move along the conveyor 12, 112 within the apparatus 10, 110, 210. As they do so, heated air from the source of heated air 18 is driven by the fan 26 along the heated air plenum 20. Heated air then exits the heated air plenum 20 through the second apertures 24. As the conveyor 12, 112 moves along the heated air plenum 20, the first apertures 14, which are in substantial alignment with the second apertures 24, allow heated air to directly contact the shrink-wrap film F under the articles A, producing an air weld. Because the heated air does not contact the conveyor 12, 112 except at the link bars 15 (as shown in
As the heated air moves through the heated air plenum 20 away from the fan 26, an amount of air volume is lost out of each of the second apertures 24 in the top surface 22 of the plenum 20. To maintain constant air pressure, the volume of the plenum 20 needs to be reduced accordingly before the next set of apertures 24. The present invention decreases the cross sectional area of the plenum 20 away from the fan 26, thereby adjusting the volume of the plenum 20 in order to keep relatively constant pressure across the length of the plenum 20.
As heated air moves through the second apertures 24 and first apertures 14, the specific size of the second apertures 24 and the alignment with the first apertures 14 produces significantly less turbulence in the heated air, so that a substantially vertical laminar air flow is produced. This in turn causes less fluttering of the shrink-wrap film, resulting in more aesthetically pleasing bulls eyes.
In the case in which the articles are enclosed within shrink-wrap film F such that the open ends of the shrink-wrap film F are oriented transversely across the conveyor 12, 112, the side air ducts 50 provide heated air directed at these openings.
In the case in which the conveyor 12, 112 is split into two side-by-side chains 12a, 12b, the optional, retractable center air duct 54 is provided to direct heated air at the open ends of the shrink-wrap film F facing the center of the conveyor 12, 112.
Both the side air ducts 50 and the center air duct 54 may be provided with an adjustable opening to adjust the volume of heated air flowing out. In addition, a nozzle or diffuser may be provided to direct the heated air at the articles A.
Utilizing modular air supply units 220 serially arranged to produce a heat tunnel T of variable length, the film shrinking process can be optimally adjusted for the speed of incoming articles A.
Further improvements include the ability to maintain the source of heated air 18 at a constant temperature in the heated air plenum 20. This can be done by providing the sensor 230 (
A number of serviceability improvements are included in the invention. The source of heated air 18 can be removed from the air supply unit 220 for service and/or replacement, as can the fan 26. In addition, an entire air supply unit 220 can be removed from the heat tunnel and replaced.
In another embodiment, the second apertures 24 may have small nozzles 24A (
In another embodiment, an optional film separator 250 may be added at the infeed end of the heat tunnel as shown in
In another embodiment (
The present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof, and it is therefore desired that the present embodiment be considered in all respects as illustrative and not restrictive, reference being made to the appended claims rather than to the foregoing description to indicate the scope of the invention.
This application is a division of U.S. patent application Ser. No. 10/680,538 filed Oct. 7, 2003, which claims the benefit of co-pending U.S. Patent Application Ser. No. 60/473,372, filed May 23, 2003.
Number | Date | Country | |
---|---|---|---|
Parent | 11004698 | Dec 2004 | US |
Child | 11460547 | Jul 2006 | US |