The invention relates to funnels for transferring bulk products such as food products into a package.
When filling a package with a bulk product, the bulk product typically falls from a weight scaling system and is shaped into a smaller cross-section by a funnel so as to fit into the package. The package has an opening in a common plane of a specific cross-sectional area. The funnel has a cross-sectional area that must be considerably less than the cross-sectional area of the package in order to consistently get the bulk product into the package. Commonly, a closed duckbill, which is easy to fit into an open package, is put at the exit of the funnel. After the duckbill is lowered into the package, it is opened so that product may then enter the package. However, after exiting the funnel and entering the open duckbill, the product is no longer contained on all four sides, rather, having an opening on two of the sides so that product is prone to spill out of and not enter the package, causing product loss and weight inaccuracies. Lances to gas flush the package are typically mounted slightly above the package and away from motion of the duckbill and are therefore subject to the Coanda effect which states that in free surroundings, a jet of fluid entrains and mixes with its surroundings as it flows away from a nozzle. In an alternate design, a duckbill is not utilized and both the funnel and lances are lowered into the package independent of each other to better contain the product and to eliminate the Coanda effect.
At the time of filling the package such as with bulk food product, atmospheric oxygen must be displaced in the interior of the package with a gas mixture of nitrogen and carbon dioxide for example to prevent the bulk food product from molding and thus increasing shelf life. This is commonly accomplished using a gas lance that direct a gas mixture under pressure into the filled package. Such lances are typically mounted alongside the funnel and duckbill and blow the gas mixture into the package without entering the package. Using this type of lance, the residual oxygen levels in the package remain well above 3% and, for example, with shredded Cheese, an Oxygen scavenger needs to be added to attain the common extended shelf life. The lances must be positioned above and outside of the duckbill in order not to interfere with duckbill movement and with filling the package. Since the lances never enter the package, this design is subject to the Coanda effect. Accordingly, when the lances blow the gas mixture into the package from outside the package, oxygen is pulled into the package as well. Further, due to the small cross-sectional area into which the lance blows the gas mixture, the velocity of the gas mixture is high and the bulk food products are often blown out of the package causing food product loss and weight inaccuracies.
Using a Cartesian coordinate system, as the bulk product falls down through the funnel, it falls in the z axis direction. The funnel moves the bulk product in both the x axis direction and the y axis direction at the same time thus shaping the stream of bulk product in order to get it into the package. When the bulk product stream is being shaped simultaneously in the x axis and y axis directions, it is referred to as the funnel effect and is prone to funnel plugs which cause manufacturing delays.
In one construction, the disclosure provides a funnel for transferring bulk products to a package in a manufacturing line comprising an entry end where bulk products enter the funnel, an exit end where the bulk products exit the funnel and enter a package and at least one wall cormecting the entry end to the exit end, wherein the exit end of the funnel is coped.
In another construction, the disclosure provides a method for transferring bulk products to a package in a manufacturing line comprising the steps of providing a funnel having an entry end where bulk products enter the funnel, an exit end where the bulk products exit the funnel and enter a package at least one wall connecting the entry end to the exit end, the exit end of the funnel being coped, moving the coped exit end of the funnel entirely into the package and filling the package with bulk products traveling through the funnel without significant bulk product loss and without the use of a duckbill.
In another construction, the disclosure provides a funnel assembly for transferring bulk products in a z axis, x axis and y axis direction to a package in a manufacturing line comprising an intermediate funnel having an entry end wherein bulk products enter the funnel assembly, the intermediate funnel configured such that bulk products travel through the intermediate funnel in a stream in the z axis direction and the stream is shaped in the x axis direction without being shaped in the y-axis direction, and a funnel having a coped exit end where the stream of bulk products exit the funnel assembly and enters a package, the funnel is configured such that bulk products travel through the funnel in the stream in the z axis direction and the stream is shaped in the y axis direction without being shaped in the x axis direction before exiting the funnel at the coped exit end and entering the package, wherein before the funnel completes the shaping of the stream in the y axis direction, the cross-sectional area of the coped exit end is substantially greater than the cross-sectional area of the package having an opening in a common plane.
In another construction, the disclosure provides a funnel for transferring bulk products in an x axis, y axis and z axis direction to a package in a manufacturing line comprising a first portion having an entry end wherein bulk products enter the funnel, the first portion configured such that bulk products travels in a stream through the first portion in the z axis direction and the stream is shaped in the x axis direction without being shaped in the y-axis direction, and a second portion having an exit end where the bulk products exit the funnel and enter a package, the second portion configured such that the stream of bulk products travels through the second portion and the stream is shaped in the y axis direction without being shaped in the x axis direction before exiting the second portion at the exit end and entering the package.
In another construction, the disclosure provides a method for transferring bulk products in an x axis, y axis and z axis direction into a package comprising the steps of providing a funnel into which bulk products enters, enabling the bulk products to travel in a stream through the funnel in the z axis direction, and shaping the stream of bulk products first in the x axis direction as the stream of bulk products travel through the funnel and thereafter in the y axis direction before the stream of bulk products enter the package.
Other aspects of the disclosure will become apparent by consideration of the detailed description and accompanying drawings.
Before any constructions of the disclosure are explained in detail, it is to be understood that the disclosure is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The disclosure is capable of other constructions and of being practiced or of being carried out in various ways.
With reference to
The funnel 20 includes an entry end 24, a coped exit end 26 and a conical portion 28 therebetween. The shredded cheese enters the funnel 20 at the entry end 24, commonly from a weight scaling system (not shown), travels in a stream through the conical portion 28 then exits the funnel at the coped exit end 26. The funnel 20 is supported by a support assembly 30 that moves the funnel 20 vertically for package filling. There are no moving parts on the funnel itself such that the funnel 20 does not include a duckbill.
The term coped means that the exit end 26 has at least one cutout portion in the wall or walls of the funnel 20 walls. As such, other coped designs for the exit end besides that shown in the figures can also be used. The shape of the exemplary embodiment of the coped exit end 26 is particularly shown in.
As shown in
In operation on a manufacturing line and with reference to
Using the funnel assembly 44, residual oxygen levels in the filled packages 38 is at or below 2% such that an Oxygen scavenger are not needed to attain an extended shelf life. With the lances 34 entering the interior 42 of the package 38, the Coanda effect is eliminated such that oxygen from outside of the package 38 is not pulled into the package interior.
Using a funnel with a coped exit end 26 eliminates the need for a duckbill. The funnel 20 with a coped exit end 26 naturally and consistently plows open the package 38 and contains the shredded cheese in the interior 42. of the package 38 while reducing funnel plugs. The funnel 20 enables bulk product losses and weight inaccuracies to be minimized and often eliminated since the coped exit end 26 enters the interior 42 of the package 38 prior to filling with shredded cheese. Without the duckbill and the mechanism to open/close it, the funnel assembly 44 is easier to clean and reduces food product safety risks.
Turning now to
The coped funnel 54 is of a similar design to the funnel 20 described above and will use common reference numerals. The gas lances 56 share a common wall 60 with the coped funnel 54 as best shown in
The intermediate funnel 52 is positioned above the coped funnel 54 in communication with. the weight scaling system (not shown). As shown in the drawings, the intermediate funnel 52 and the coped funnel 54 are two separate funnels, however, it should be noted that the intermediate funnel 52 and the coped funnel 54 could be two portions of one funnel.
Using a Cartesian coordinate system, shredded cheese falls downwardly in a stream through the intermediate funnel 52 and then the coped funnel 54 in a z axis direction. As particularly shown in
In operation on a manufacturing line and with reference to
When the set quantity of shredded cheese has entered the package 38, the coped funnel 54 and the lances 56 are moved vertically upwardly, along the vertical path 59, out of the interior 42 of the package 38. With this funnel assembly 50 arrangement, the complexity, increased cost and food safety challenges of moving the lances 56 independent of the coped funnel 54 is eliminated. It should be noted that, in an alternate embodiment, the package 38 is moved upwardly to insert the coped funnel 54, the intermediate funnel 52 and the lances 56 into the interior 42 of the package 38 then downwardly to remove the coped funnel 54 and lances 56 from the package 38.
Using a common wall 60 between the coped funnel 54 and lances 56 increases the cross-sectional area of both coped funnel 54 and the lances 56. More specifically, and referring back to
As shown in
Various features and advantages of the invention are set forth in the following claims.