This invention relates to bulk fluid container bags, and methods to empty filled bulk fluid container bags.
Many fluids are transported in bulk containers, such as ISO tanks and shipping containers, railcar containers, 55 gallon drums and other bulk containers. Highly viscous fluids and fluids high in solids content present particular transportation problems, such as ease of discharge of a filled container.
Examples of high solids content fluids include pepper mash, fruit pulps, grape mash/musk, drilling muds, clay slurries, fish slurries, tomato products, inks, and paints. During transportation, a high solids content fluid can separate into a fluid portion and a solids portion. Upon arrival at the discharge location, the solids separation must be addressed. If the solids portion is dense, the solids will settle to the bottom of the container, requiring removal of the fluids from the top portion of the container and solids removal later. If the solids portion is light, the solids will float to the top and create a solids cap. While the liquid portion is easily discharged from the bottom of the container, the solids cap will remain and must be physically unloaded later. Unloading of the solids can be labor intensive, such as physically breaking up and shoveling the solids cap or solids bottom. To assist in unloading containers filled with high solids content, mechanical agitation has been utilized, such as by placing rotors, vanes or other types of mechanical agitators in the transport tank, or even rotating the entire container (see U.S. Pat. No. 3,132,846, incorporated herein by reference).
Air injection has also been a method of mixing (see U.S. Pat. No. 4,595,296 to Parks, incorporated herein by reference). In the Parks patent, a fluid filled tank has a gas injector (or injectors) fixed to the bottom of the tank connected to a distribution manifold within the tank. The injectors are attached to a source of suitable gas (air, nitrogen or other inert gas), and the gas pulsed into the injectors assist in fluidizing and homogenizing the liquid/solids stored in the tank. The gas injector generally includes a feed line and an accumulator plate positioned at the exit of the feed pipe to assist in shaping the released bubble shape.
Examples of highly viscous fluids include oils/lubricants, syrups, and resins. These types of fluids present discharge problems due to the inability of these fluids to easily flow, resulting in long discharge times. Discharge times can be decreased by heating the fluid, thereby lowering the viscosity and increasing the fluid flows. Generally, either the bottom of the container or the entire container will be heated. However, heat transport in a viscous fluid can be slow and inefficient, and hence, smaller containers, such as a 300 gallon container, are used to reduce the fluid volume to be heated. Even with these smaller containers, heat times and discharge times can still be excessive.
In certain circumstances, it is desirable to transport fluids in flexible bags in a fixed wall container. A disposable bag prevents damage/contamination to the transport container from the fluid and eliminates the need to clean the container after each use. For instance, transport bags are used to reduce the potential for tank contamination of the product when the transported fluid is food stuffs or food grade materials. In these instances, a transport bag can be constructed of food grade plastics and if needed, can be pre-sterilized prior to use. Additionally, transport bags can be used when transporting hazardous materials, thereby preventing contamination of the tank by the fluid. Bag transport of high solids fluids or viscous fluids, however, presents problems, as prior art mechanical agitation or air injection is generally not feasible due to the inability to position the agitation device into the interior of the bag.
A liquid transport system includes a bag adapted to hold fluids, the bag being constructed of a flexible fabric. The bag has a top portion, a bottom portion and a sidewall portion forming an interior and exterior. The system includes a discharge port, a fill port and a series of injector ports on the bag providing fluid access to the interior of the bag from the exterior, where each of the ports are sealingly closable. The discharge port and the fill port are adapted to allow product to flow into and out of the bag, and the injector ports are adapted to accommodate an injector probe. The system includes injector probes and an air injector controller to control the timing/sequence and duration of the injected sequence.
It is an object of the invention to provide a mixing system for transport containers that allows mixing internal to the container without a mechanical agitator.
It is an object of the system to provide a disposal bag for use in transport containers that provides a liner or bag and a means of mixing within the liner or bag.
It is an object of the invention to provide for transporting and discharging high solids content and high viscosity fluids.
It is an object of the system to provide a system for mixing with injected air within a mixing bag.
Shown in
Bag 1 has a top portion 2, a bottom portion 3, and side walls portion 4. In construction, bag 1 can be a cylinder shaped container manufactured from a blown plastic cylinder with the ends sealed. Alternatively, bag 1 can be manufactured from a single sheet that is rolled into an open cylinder with the seam sealed, and the cylinders ends subsequently closed and sealed, such as by heat welding, solvent welding, or other means known in the art. The bag 1 could also be constructed from multiple sheets welded into a rectangular shape or other shape, but such is not preferred as the additional welds or joints present additional potential leakage points.
Located on the top portion of bag 1 is at least one injection port 10. Injection port 10 is a location (port) on the top portion of the bag that can be opened after the bag has been filled and is adapted to sealingly accommodate an air or gas injection means (the injected gas can also vary depending on the application; inert gases, such as nitrogen, could be used when contact with oxygen could promote unwanted bacterial growth). A suitable injection port 10 includes an opening in the bag 11 sealed with a fitting 20. One type of an injection port 10 used is shown in
This injection port 10 is located at opening 11 in the bag 1. Positioned around the bag opening 11 is a seal member 12. As shown, seal member 12 is a 90 mil circular sheet of polyethylene heat welded to the bag material. Seal member 12 strengthens the area of the bag in surrounding the opening 11. If the bag is sufficiently tear resistant, the seal member 12 can be eliminated. Seal member 12 has an opening 13 which aligns with the bag opening 11. As shown in
One embodiment of the fitting 20 is two inter-mating parts; here a male and female threaded fitting with a passageway through the fittings, more fully described in U.S. Pat. No. 3,531,142 (incorporated herein by reference). As shown in
Other types of fitting connectors could be used in the injector port, such as compression or quick connect fittings. Also, instead of a two piece fitting, the fitting could be a one piece closure, designed to mate with a structure molded onto the seal member 12 (such as an upstanding treaded cylinder molded onto the seal member 12). However, a two piece fitting 20 is preferred for disposable bags, as such a fitting 20 can be removed from the bag to be cleaned and re-used on another bag. With a two piece fitting, the fittings should be installed onto the bag material prior to closing the ends of the bag because the interior is not easily accessed after bag assembly.
The bag 1 can have a series of injection ports 10. Bag 1 also includes a sealable fill port 30, and can include a sealable vent port 35 and a sealable discharge port 40. The fill port 30 is generally positioned on the top portion of the bag 1, such as the center of the top portion, while the discharge port 40 is generally located on the sidewall near the bottom portion of the bag. The discharge port 40 and fill port 30 can be the same port, but this is not preferred when it is desired to re-circulate product prior to or during discharge of product from the bag, as later described. The fill port 30 and discharge port 40 are generally larger than the injection port 10 in order to accommodate product flows. For instance, for a bag designed for a 20 foot ISO container used to transport pepper mash product, a three inch diameter fill and discharge port have been used. If desired, the bag 1 could be equipped with several fill 30 or discharge ports 40. These ports can be constructed similarly to an injection port 10 or with other designs known in the art.
During filling, the fill port 30 is coupled to a product feed line, and product is pumped through the line and into the bag through the fill port 30. Once the bag 1 is suitably full, the product feed line is removed and the fill port 30 is sealingly closed. Feed lines and discharge lines can be attached to the appropriate port with clamps, quick connects, threaded fittings, or other connectors know in the art.
Discharge port 40 is a sealable port on the bag 1 that couples to a discharge line to allow product to be removed from the bag through the discharge port 40. The discharge port 40 may be attached to the discharge line through a valve body or a fitting incorporating a valve body 41, such as a gate valve, to allow controlled release of product. An appropriate valve can be built into the discharge port 40. Additionally, a “T” or “Y” type splitter fitting 43 may be coupled to the discharge port 40, as shown in
Positioned on the top of the bag 1 is a vent port 35 (an injection port 10 could be used as a vent port 35). Vent port 35 allows the user to bleed off unwanted gas pressure within the bag during filling, discharging or mixing. The vent port 35 may be constructed similarly to an injection port 10 or of other construction known in the art. Vent port 35 may be coupled to a pressure actuated device, such as a spring loaded check valve, to keep the air pressure within the bag 1 at or below a predetermined maximum value.
Injection ports 10 are adapted to accommodate an injector probe 50 at time of product discharge. Injector probes 50 are pipes, tubes or other air passageways with suitable fittings to sealingly couple to the injection port 10. Air injector probes 50 are inserted into the injection ports 10, and connected to a source of suitable gas for injection into the product, generally through an air injection line. The fully installed probe 50 will be almost as long as the bag is high, as the distal end of the probe 50 should be located near the floor of the bag (for pepper mash, 4-12 inches off the floor, with 6 inches being preferred).
Installation of a full length injection probe 50 in the closed environment of a transport container containing a filled product bag can be difficult, and hence, the injector probe 50 may be assembled in sections joined with suitable couplings 52, such as a threaded coupling. One embodiment of an injector probe 50 is shown in
An alternative design for the injector probe 50 is to build the probe into the injector port 10. For instance, a flexible tubing slightly longer than the bag height could be utilized as the injector probe. One end of the flexible tubing would be fixedly connected to the interior floor portion of the bag and the other end of the tube would be connected to a corresponding injection port 10, such as through an injector fitting 20. The flexible tubing may be opened at (B) 8 the bottom, or closed with an opening in the side of the tubing at a desired height above the bottom of the floor portion. In this fashion, the bag 1 could be shipped with injector probes 50 installed, and it is only necessary to connect an air line to the injection ports at the discharge site to initiate mixing.
The following operation will be described using a bag 1 having a single injection port, vent port, discharge port and fill port. For small bags, a single injection port may be suitable (for instance, a 300 gallon bag) but for larger bags, multiple injection ports are preferred. It is preferred that an injection port 10 be located near the discharge port 40.
The bag 1 is shipped empty to the fill location. The empty bag is collapsed, and is generally flat or may be folded to create a smaller footprint for shipping. At the fill location, the bag 1 is positioned within the transport container with all ports. The bag 1 is generally still in a collapsed state, but pick up loops may be attached to the exterior of the bag 1 to allow for attachment of the bag 1 onto the transport container. A fill line is attached to the fill port 30, and product then released or pumped through the fill line into the bag 1. The vent port 35 may need to be opened to allow venting of gases in the bag 1 while filling. Alternatively, prior to filling the bag 1 with product, the bag could be “inflated” by attaching a gas injector line to an injection port 10 and filling the bag with a suitable gas to ease the filling process. Once the bag is suitably full, filling stops, the fill line removed, and all ports sealed closed for transport. If the shipping container is a closed container where the top is not removable, it is preferred that either the bag height be less than that of the container height, or alternatively, that the filling stop before the bag is full. Space is required between the container top and bag top to allow an operator to climb into the transport container onto the top portion of the filled bag to access the ports on top of the bag, for instance, to remove and attach hoses, close ports, or other desired actions.
At the discharge facility, the container is opened and an operator climbs onto the bag 1 and opens the fitting 20 at the injection port 10 and inserts an injector probe 50. For a multi-piece injector probe (for instance a two section probe), the operator would insert the bottommost section into the injector probe 50, and the top section would then be threaded onto the bottom section, and the top section also inserted. The threaded coupling on the top section of the injector probe 50 is then treaded onto the fitting 20 at the injection port 10, sealing the probe 50 into the port opening. If the liquid phase of the product is in the top portion of the bag 1, it may be desired to inflate the bag prior to installation of the injector probes to avoid loss of fluid. This may be accomplished by attaching an air line (without a probe) to an injection port 20, injecting air and hence inflating any slack in the bag (keeping the vent port closed). If the solids have formed a cap on top of the liquids, the operator will have to force the probe 50 through the solids layer. To assist, the probe's distal end may be shaped to assist in piercing a solids cap.
Once the probe 50 is inserted, an air line or gas line 70 is attached to the injector probe 50. Each air line is connected to a valve, and the valves are connected to an air distribution manifold, and gas injection is begun. The values are operated by a controller 60 to control the cycling and duration of the air pulses to the injection ports 10. Suitable controllers are available from Pulsair Systems, Inc. in Bellevue Wash. To bleed off excess gas pressure, the vent port 30 is opened. While gas injection can be continuous, it has been found that pulsing gas into the system is generally more efficient. Further, while all injection ports/probes could be pulsed simultaneously (such as by having the air feeder lines tie into a common air distribution line) it is preferred to pulse each probe sequentially. For instance, a preferred pulsing pattern is to pulse from the back of the bag (furthest from the discharge port) to the front of the bag.
Gas is pulsed into the bag through the probe, and enters the product near the bottom of the bag. The rising air mixes the product and will break up the solids layer. After a suitable mixing period, a fairly homogeneous mixture is obtained, and the discharge port 40 can be opened, and product removed. Air injection may continue or cease during product discharge, dependent upon the product's characteristics. For instance, it may be advantageous to continue air injection for product which quickly separates, particularly injecting air near the discharge port 40 to avoid clogging of the discharge port.
Product fluids may also be re-circulated during mixing and/or discharging. Recirculation pumps product about the system to speed the mixing of the product to more rapidly achieve a fairly homogeneous product. Recirculation can be achieved by attaching a fluid recirculation line to a port on the bag. Generally, the recirculation line has one end attached to the discharge port 40, and the other end attached to a fill port 30 or an injector port 20 (henceforth referred to as a recirculation port). The recirculation line may be attached to the discharge port 40 by coupling to one end of a splitter fitting positioned on a discharge port 40. It is preferred that a gate valve or other valve is used to control flows through the two available paths in a splitter fitting. A pump then is actuated to draw product through recirculation system.
The bag 1 shown in
The controller 60 can be configured to accommodate a variety of pulse durations and cycle times. For instance, a Pulsair PLC controller system was used for air injection of pepper mash in a 20 foot ISO bag container configured similarly to that shown in
Injected air creates rising bubbles in the product, inducing a current in the fluid, thereby locally mixing the product. Each injector site will have a local area of influence that is the volume surrounding the injection site affected by the induced current, as depicted in
For mixing viscous fluids, current techniques include heating the product container. Air injection increases the speed of heat transport in the fluid, and hence, decreases the time to raise the temperature of the product to the desired temperature. In fact, if the injected air is heated prior to injection, the current method of directly heating the container can be eliminated.
The bag, injector probes, transport container and air injection system provide a fluid transport system capable of dealing with high solids or high viscosity fluids. Although the present invention has been described in terms of specific embodiments, it is anticipated that alterations and modifications thereof will no doubt become apparent to those skilled in the art which are intended to be included within the scope of the following claims.
This application is a continuation of U.S. application Ser. No. 13/449,928 filed on Apr. 18, 2012, which was a continuation of Ser. No. 12/825,029 filed on Jun. 28, 2010, which was a divisional of U.S. patent application Ser. No. 11/326,738, filed on Jan. 6, 2006, which was a continuation application claiming the benefit of and priority to PCT/US2005/021567 filed on Jun. 17, 2005 and U.S. Provisional Patent Application Ser. No. 60/616,691 filed on Oct. 7, 2004, which are incorporated by reference herein in their entirety.
Number | Date | Country | |
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Parent | 11326738 | Jan 2006 | US |
Child | 12825029 | US |
Number | Date | Country | |
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Parent | 13449928 | Apr 2012 | US |
Child | 13925310 | US | |
Parent | 12825029 | Jun 2010 | US |
Child | 13449928 | US |