This disclosure is directed to container rinsing systems and, more particularly, to air rinsing apparatus and systems for rinsing containers.
In food packaging and other types of packaging plants, containers or packaging may require cleaning prior to having food items or other products introduced to the packaging. Conventional packaging cleaning systems required inversion of the packaging to enable removal of any particulate matter from the packaging via gravity.
Methods and systems are provided for providing a consistent electrode state for welding, substantially as illustrated by and described in connection with at least one of the figures, as set forth more completely in the claims.
Limitations and disadvantages of conventional approaches to providing terminal inputs and outputs for industrial devices will become apparent to one of skill in the art, through comparison of such approaches with some aspects of the present apparatus and system set forth in the remainder of this disclosure with reference to the drawings.
The figures are not necessarily to scale. Where appropriate, similar or identical reference numbers are used to refer to similar or identical components.
Disclosed example air rinsing apparatus and container rinsing systems provide improved elimination of particulate matter from packaging such as containers, while being capable of elimination of the particulate matter in any orientation of the packaging, including orientations in which an opening of the packaging is facing upwards. Disclosed example air rinsing apparatus may be used with a single air mover to provide both blowing of air (or other gas) into the container and suction for removal of the air and particulate matter from the container.
Disclosed example air rinsing apparatus include: a first enclosure having a first inlet port and a first output port; a second enclosure within the first enclosure, the second enclosure comprising a second inlet port and a second output port, the second output port disposed on a same face of the first enclosure as the first inlet port; and one or more air movers. The air movers are configured to: urge first air into the second inlet port, the second enclosure configured to direct the first air from the second inlet port to the second output port; and pull second air from the first output port, the first enclosure configured to direct the second air from the first inlet port to the first output port.
In some example air rinsing apparatus, the first enclosure includes a plurality of first inlet ports including the first inlet port, and the second enclosure includes a plurality of second output ports including the second output port and equal to the number of first inlet ports, in which the first enclosure is configured to direct the second air from the plurality of first inlet ports to the first output port, and the second enclosure is configured to direct the first air from the second inlet port to the plurality of second output ports. In some examples, the plurality of second output ports include corresponding nozzles that extend through respective ones of the plurality of first inlet ports. In some examples, the plurality of first inlet ports and the plurality of second output ports are arranged in a single row. In some examples, the plurality of first inlet ports and the plurality of second output ports are arranged in two rows.
In some example air rinsing apparatus, the first inlet port includes a frustum-shaped opening configured to accelerate the second air entering the first inlet port. In some examples, the second output port includes a nozzle extending through a smaller base of the frustum-shaped opening of the first inlet port. In some examples, the first enclosure includes a first face, in which the first inlet port and the second output port are on the first face, and the air rinsing apparatus further includes an extension plate positioned co-planar with the first face. In some examples, the second output port includes an air knife.
Some example air rinsing apparatus further include an ionizer disposed within the second enclosure and configured to generate positive and negative ions, in which the second enclosure is configured to direct the first air from the second inlet port to the second output port such that the first air entrains the positive and negative ions. In some examples, the one or more air movers are configured to urge the first air by providing positive air pressure to the second inlet port. In some examples, the one or more air movers are configured to pull the second air by providing negative air pressure to the first output port.
Disclosed example container rinsing systems include a feed line and an air rinsing apparatus. The feed line is configured to direct containers having openings in a first number of rows of containers transverse to a direction of travel of the containers. The air rinsing apparatus is disposed adjacent the feed line, and includes: a first enclosure having a number of first inlet ports equal to the first number of rows of the containers, and a first output port; a second enclosure within the first enclosure, the second enclosure comprising a second inlet port and a number of second output ports equal to the first number of rows of the containers, the second output ports disposed on a same face of the first enclosure as the first inlet ports; and one or more air movers configured to: urge first air into the second inlet port, the second enclosure configured to direct the first air from the second inlet port to the second output ports and into the containers; and pull second air via the first output port, the first enclosure configured to direct the second air from the first inlet ports to the first output port to pull air and particulates from the containers.
In some example container rinsing systems, the number of second output ports is equal to the number of first inlet ports, the first enclosure is configured to direct the second air from the first inlet ports to the first output port, and the second enclosure is configured to direct the first air from the second inlet port to the second output ports. In some examples, the second output ports include corresponding nozzles that extend through respective ones of the first inlet ports. In some examples, the first inlet ports and the second output ports are arranged in a single row. In some examples, the first inlet ports and the second output ports are arranged in two rows.
In some example container rinsing systems, each of the first inlet ports includes a frustum-shaped opening configured to accelerate the second air entering the first inlet port. In some example container rinsing systems, each of the second output ports includes a nozzle extending through a smaller base of the frustum-shaped opening of a respective one of the first inlet ports. In some examples, the first enclosure comprises a first face, the first inlet ports and the second output ports being on the first face, and the air rinsing apparatus further comprising an extension plate positioned co-planar with the first face.
The system 100 includes an air rinser 108 positioned adjacent a path of travel of the applications 104 as the applications 104 are moved along the feed line 102. The air rinser 108 blows air into the applications 104 while simultaneously providing suction adjacent the application 104. The suction removes particulate matter from the applications 104, which is loosened from the interior surfaces of the applications 104 and entrained within the air stream created in the applications 104 by the blown air from the air rinser 108.
In some examples, the air rinser 108 generates and directs positive and negative ions at the applications 104 via the blown air. To this end, the example system 100 may include a high voltage power supply 110 electrically coupled to the air rinser 108 to enable generation of positive and negative ions, as described in more detail below.
An air mover 112 provides positive air pressure to the air rinser 108 for blowing the air at the applications 104 and provides negative air pressure to the air rinser 108 for removing the air containing particulate matter from the applications 104. By using a single air mover 112, the complexity and maintenance costs of the system 100 are reduced. Additionally, using the single air mover 112 enables the flow rates of the air blown at the applications 104 and the air removed from the applications 104 to be consistently equal. One or more filters 114 are provided between the air rinser 108 and the negative pressure source in the air mover 112 to filter the particulate matter removed from the applications 104.
In other examples, a first air mover may be used to provide the positive pressure to the air rinser 108 and a second air mover may be used to provide the negative pressure to the air rinser 108.
The first enclosure 202 is connected to a negative air pressure source (e.g., the air mover 112 of
The example second enclosure 204 is connected to a positive air pressure source (e.g., the air mover 112 of
The second output ports 212 include nozzles 214 that protrude at least partially through respective ones of the first inlet ports 208. Accordingly, the first inlet ports 208 and the second output ports 212 are disposed on a same face 216 of the first enclosure 202. For example, as illustrated in
The example second enclosure 204 of
As shown in
While the example second enclosure 204 of
While the example air rinser 200 of
A first airflow 610 is generated by positive pressure from the air mover 112 of
A second airflow 614 is generated by negative pressure from the air mover 112 via the first output port 206. The second airflow 614 contains substantially the same air as the first airflow 610, and has entrained loosened particulate matter 612. The second airflow 614 flows from the containers 602-608 and through the first inlet ports 208 into the first enclosure 202. From the first enclosure 202, the negative pressure causes the second airflow 614 to flow from the first enclosure 202 through the first output port 206 to the air mover 112.
As an alternative to the extension plates 702, 704, the dimensions of the first enclosure 202 may be adjusted to extend the face 216 of the first enclosure 202 to cover a similar area as the extension plates 702, 704.
As utilized herein, “and/or” means any one or more of the items in the list joined by “and/or.” As an example, “x and/or y” means any element of the three-element set {(x), (y), (x, y)}. In other words, “x and/or y” means “one or both of x and y”. As another example, “x, y, and/or z” means any element of the seven-element set {(x), (y), (z), (x, y), (x, z), (y, z), (x, y, z)}. In other words, “x, y and/or z” means “one or more of x, y and z”. As utilized herein, the term “exemplary” means serving as a non-limiting example, instance, or illustration. As utilized herein, the terms “e.g.,” and “for example” set off lists of one or more non-limiting examples, instances, or illustrations.
While the present apparatus and/or system has been described with reference to certain implementations, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted without departing from the scope of the present apparatus and/or system. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the present disclosure without departing from its scope. Therefore, the present apparatus and/or system are not limited to the particular implementations disclosed. Instead, the present apparatus and/or system will include all implementations falling within the scope of the appended claims, both literally and under the doctrine of equivalents.
This patent claims priority to U.S. Provisional Patent Application No. 62/680,796, filed Jun. 5, 2018, entitled “Air Rinsing Apparatus and Systems for Rinsing Containers.” The entirety of U.S. Provisional Patent Application No. 62/680,796 is incorporated herein by reference.
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