Patent Publication Number: US-11390537-B2

Title: System for controlling water used for industrial food processing

Description:
CLAIM OF PRIORITY UNDER 35 U.S.C. § 119 
     The present Application for Patent claims benefit of U.S. Provisional Patent Application Ser. No. 62/403,322 filed on Oct. 3, 2016, assigned to the assignee hereof and hereby expressly incorporated by reference herein. 
    
    
     BACKGROUND 
     Field of the Disclosure 
     The subject matter disclosed herein generally relates to food processing and, more particularly, to controlling water chemistry used for industrial food processing. 
     Description of Related Art 
     Water is used in many food processes. For example, water is often used to wash produce at different stages of processing. In many cases this water is recycled and used multiple times. This is particularly true of the wash processes including those used in the value added produce industry. It is important to assure that this water does not add to the food safety hazards that might be associated with the food being processed. Accordingly, the water is controlled and monitored using a number of different methods and system to try and reduce any food safety concerns. The control requirements will vary with the food product being processed and the process. 
     Water chemistry management has been evolving with increased automation and improvements in instrumentation. There are still operations that use test strips and manual wet chemistry methods but these are increasingly inadequate. To address these needs, more sophisticated controllers have come into play with more logic. Even with these developments, more efficient and reliable approaches are needed. It is also increasingly important to validate control. 
     SUMMARY 
     The systems, methods, apparatus, and devices of the disclosure each have several aspects, no single one of which is solely responsible for its desirable attributes. Without limiting the scope of this disclosure as expressed by the claims which follow, some features will now be discussed briefly. After considering this discussion, and particularly after reading the section entitled “Detailed Description” one will understand how the features of this disclosure provide advantages that include improved food safety. 
     Certain aspects provide a control system for controlling water used in a food processing system. The control system generally includes at least one sensor configured to collect a sensor signal from a produce handling device, a logic processor configured to receive the sensor signal collected by the at least one sensor and generate a control signal for controlling adding wash solution to the water used in the food processing system, and a human machine interface (HMI) configured to display information from the logic processor to a user. 
     Certain aspects provide a control system for controlling water used in a food processing system. The control system generally includes at least one processor configured to execute computer readable instructions. The computer readable instructions include collecting, using a sensor disposed at the food processing system, a sensor signal, generating one or more control signals for controlling one or more chemical pumps and one or more valves to provide a wash solution into the water of the food processing system based on the sensor signal, and transmitting the one or more control signals to the one or more chemical pumps and one or more valves. The control system may further include a memory coupled to the at least one processor and configured to store one or more of the computer readable instructions, the one or more control signals, and the sensor signal. 
     Certain aspects provide a non-transitory computer program product for controlling water used in a food processing system. The non-transitory computer program product generally includes a computer readable storage medium having program instructions embodied therewith. The program instructions, executable by a processor, cause the processor to collect, using a sensor disposed at the food processing system, a sensor signal, generate, using a processor, one or more control signals for controlling at least one of a fouling control device, one or more chemical pumps, and one or more valves of a control system to provide a wash solution into the water based on at least the sensor signal, and operate at least one of the fouling control device, the one or more chemical pumps, and the one or more valves based on the one or more control signals. 
     Aspects generally include methods, apparatus, systems, computer readable mediums, and processing systems, as substantially described herein with reference to and as illustrated by the accompanying drawings. Numerous other aspects are provided. 
     To the accomplishment of the foregoing and related ends, the one or more aspects comprise the features hereinafter fully described and particularly pointed out in the claims. The following description and the annexed drawings set forth in detail certain illustrative features of the one or more aspects. These features are indicative, however, of but a few of the various ways in which the principles of various aspects may be employed, and this description is intended to include all such aspects and their equivalents. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       So that the manner in which the above-recited features of the present disclosure can be understood in detail, a more particular description, briefly summarized above, may be had by reference to aspects, some of which are illustrated in the appended drawings. It is to be noted, however, that the appended drawings illustrate only certain typical aspects of this disclosure and are therefore not to be considered limiting of its scope, for the description may admit to other equally effective aspects. 
         FIG. 1  is a block diagram of a control system for water used in produce processing that includes a water control system and produce wash equipment, in accordance with certain aspects of the present disclosure. 
         FIG. 2  is a block diagram of a control system for water used in produce processing with examples of sensor placement, in accordance with certain aspects of the present disclosure. 
         FIG. 3  is a block diagram of a control system for water used in produce processing showing examples of network integration, in accordance with certain aspects of the present disclosure. 
         FIG. 4  is a block diagram of a control system for water used in produce processing with examples of data storage memory locations, in accordance with certain aspects of the present disclosure. 
         FIG. 5  is a block diagram of a control system for water used in produce processing with distributed processing control, in accordance with certain aspects of the present disclosure. 
         FIG. 6  is a block diagram of a control system for water used in produce processing including pumps controlled by control signals, in accordance with certain aspects of the present disclosure. 
         FIG. 7  is a block diagram of a control system for water used in produce processing that controls water pH for washing produce, in accordance with certain aspects of the present disclosure. 
         FIG. 8  is a block diagram of a pH Clean-In-Place (CIP) enclosure of a control system for water used in produce processing, in accordance with certain aspects of the present disclosure. 
         FIG. 9  is a block diagram of a control system for water used in produce processing that controls chlorine being added to the water for washing produce, in accordance with certain aspects of the present disclosure. 
         FIG. 10  is an illustration of a set of filters used in a control system for water used in produce processing, in accordance with certain aspects of the present disclosure. 
         FIG. 11  is a flow chart of a method for using a control system for water used in produce processing, in accordance with certain aspects of the present disclosure. 
         FIG. 12  is a block diagram of a control system with cleaning and calibration elements used in produce processing, in accordance with certain aspects of the present disclosure. 
         FIG. 13  is a block diagram of a control system with cleaning and calibration elements and a filter used in produce processing, in accordance with certain aspects of the present disclosure. 
     
    
    
     To facilitate understanding, identical reference numerals have been used, where possible, to designate identical elements that are common to the figures. It is contemplated that elements disclosed in one aspect may be beneficially utilized on other aspects without specific recitation. 
     DETAILED DESCRIPTION 
     Aspects of the present disclosure provide apparatus, methods, processing systems, and computer readable mediums for controlling water chemistry used for industrial food processing. 
     The following description provides examples, and is not limiting of the scope, applicability, or examples set forth in the claims. Changes may be made in the function and arrangement of elements discussed without departing from the scope of the disclosure. Various examples may omit, substitute, or add various procedures or components as appropriate. For instance, the methods described may be performed in an order different from that described, and various steps may be added, omitted, or combined. Also, features described with respect to some examples may be combined in some other examples. For example, an apparatus may be implemented or a method may be practiced using any number of the aspects set forth herein. In addition, the scope of the disclosure is intended to cover such an apparatus or method which is practiced using other structure, functionality, or structure and functionality in addition to or other than the various aspects of the disclosure set forth herein. It should be understood that any aspect of the disclosure disclosed herein may be embodied by one or more elements of a claim. The word “exemplary” is used herein to mean “serving as an example, instance, or illustration.” Any aspect described herein as “exemplary” is not necessarily to be construed as preferred or advantageous over other aspects. 
     As shown and described herein, various features of the disclosure will be presented. Various embodiments may have the same or similar features and thus the same or similar features may be labeled with the same reference numeral, but preceded by a different first number indicating the figure to which the feature is shown. Thus, for example, element “a” that is shown in FIG. X may be labeled “Xa” and a similar feature in FIG. Z may be labeled “Za.” Although similar reference numbers may be used in a generic sense, various embodiments will be described and various features may include changes, alterations, modifications, etc. as will be appreciated by those of skill in the art, whether explicitly described or otherwise would be appreciated by those of skill in the art. 
     Embodiments described herein are directed to a system and method for controlling a wash solution in a wash system for produce handling. For example, according to one or more embodiments, a system and method include data collection using one or more sensors and generating control signals, based on the collected data, to control chemical pumps that adjust the amount of one or more chemicals in water used to wash produce that is being processed. The system can also include user input data as well has historical databases and analysis that can be used to generate the control signals. The control signals can also be generated based on the collected data, stored data, analysis, user input, a combination of data types, and/or other related data. Further, the control signals can also be generated for fouling the sensors and related components based on the collected data, stored data, analysis, user input, a combination thereof, and/or other related data. Additionally, the control signals can further include scheduling the fouling based on the collected data, stored data, analysis, user input, a combination thereof, and/or other related data. 
     According to one or more cases, a number of elements are included in a control system for a value added produce wash system. Some of these elements relate to monitoring water attributes while others relate to the performance of the monitoring system itself. Other elements relate to monitoring the status of the food process. 
     For example, in some cases, the control system may include at least two channels of monitoring. These channels provide control to allow control of a primary stage and secondary stage present in many wash systems. In some cases, one or more pH monitoring devices for each stage may be provided. A pH monitoring device can include an electrode that is suitable for a food contact situation. One or more coulometric chlorine electrodes for each stage may be provided in some cases. The effluent from such electrodes is often dumped rather than returned to use. In some cases, temperature monitoring for correcting pH measurements and chlorine measurements based on projected values of both when at that temperature may be provided. 
     In some cases, another element that may be included in an apparatus, system, and/or method for controlling a wash solution in a wash system for produce handling includes a relay to stop product feed if chlorine is out of specification for either stage. Similarly, product feed may be halted if pH is outside of the desired range. In some cases, a wired or wireless full duplex data communication with basic trend monitoring and reporting may be provided. Further, in some cases, another element that can be included is a memory location for storing all or some of the collected data along with other indicators. The data stored can include a subset of select data that is being collected. For example, key data can be backed up locally with a USB flash drive. 
     According to one or more cases, an electrode fouling control system including filtration and specific fouling removal processes may be included. Fault trapping in data analysis, may be used to monitor the water flow by a pH electrode and a chlorine electrode. Additionally, in one or more embodiment, it may be useful to insure that a fouling control device, for example a Clean-In-Place (CIP) air pressure device, is present and that water is circulating in the wash system. 
     In other cases, other fouling control devices such as clean-in-place embodiments may be provided that include flushing an electrode/sensor with a liquid wash solution such as, for example, an acid solution or some other food safe cleaning agent. A single clean-in-place device may be provided that is connected to each electrode such that the device is able to provide the cleaning air/gas and/or liquid as described herein. In another case, the clean-in-place device may be configured such that it can be connected when needed and disconnected from each electrode/sensor when not needed. In another case, each electrode/sensor may have its own specific clean-in-place device connected to the electrode/sensor. The clean-in-place device may therefore contain cleaning solution that is specifically tailored for the electrode/sensor. Further the device may further provide the ability to also provide a calibration solution when selected. Additionally, in some cases, when the clean-in-place device provides pressurized air/gas for cleaning, the pressure can be tailored specifically for the electrode/sensor to which the device is connected. 
     According to one or more cases, one or more touch screen interfaces can be provided for user input in the wet environment of a plant and allows substantial flexibility in input locations. Alternatively, a traditional mouse and/or keyboard can be provided. Further, microphones could be provided to capture audio commands and/or cameras can be included to capture user gestures that can correspond to select inputs and defined by the user and understood by the system. 
     According to some cases, another element that can be included is a relay that stops chlorine addition of the pH exceeds a threshold. For example, a facility safety is enhanced if there is a relay provided that can stop chlorine addition if the pH exceeds 7, which can be defined as a domain outside of the normal operating conditions. Similarly, one can set a lower bound to prevent or reduce the hazards of chlorine outgassing. 
     Further, additional elements can be included in the system and/or method for controlling a wash solution in a wash system for produce handling. For example, in accordance with one or more embodiments, sensor data and analysis data generated using the sensor data can be stored in memory somewhere in or connected to the system. Further, control signals and operational parameters can be generated and stored in memory as well. In accordance with one or more embodiments, a firewall panel is included in the system to allow external systems to view what is stored in the memory or database such as operational parameters without access to control features. Accordingly, the firewall panel can prevent unauthorized changes in operating parameters. In one or more cases, a memory coupled to at least one processor may be configured to store one or more of computer readable instructions, one or more control signals, and one or more sensor signals. 
     A graphical user interface may be shown on a computer display that a user, such as a machine operator, plant supervisor, etc., uses to view the data from the database such as the sensor data and operational parameters. However, the firewall panel prevents the user from inputting control signals by discarding any input from the user that attempts to adjust the operational parameters and/or is detected by the firewall panel as a disallowed input. 
     A web portal interface that may be provided to a user that is off-site such as a customer or corporate company leadership. When the user connected using the web portal over the internet from a remote location in relation to the position of the system, the user is give certain privileges. For example, the user can be provided with access to view data stored in a database of the system. However, a firewall panel can be provided that disallows the user from inputting control commands that attempt to, for example, change the operational parameters of the system. Thus, the user is can be granted viewer rights only through the use of the firewall panel. According to another embodiment, the firewall panel can provide some control of certain select items such requesting that following of the sensors be executed, or that new data points be collected by the sensors and processed. In another embodiment, the firewall panel can prevent all action and only provide the user visual access. 
     A system and/or method for controlling a wash solution and pH deviations may be provided. A pH deviation includes using a pH sensor and a pH chemical pump. For example, a pH deviation to a desired value can be detected by the pH sensor. This data can then be analyzed to determine and generate a control signal that defines the operating parameters of a pH chemical pump. The signal is then transmitted to the pH chemical pump which adjusts the amount of chemical based on the reviewed data in order to balance out the data from the sensor readings. 
     One or more sensors and controllers may be added to the product feed control loop to more stringently control the proceeding operations in accordance with one or more cases. Additionally, full feedback is reported to the controller about the status of product feed to assure that the control relay is not circumvented and prevent inappropriate processing. The controller assesses whether the product feed is as expected given the status of the water chemistry. 
     A split line control may be provided in accordance with one or more cases. This element may allow the two control channels to control either a two-stage wash line, a one-stage wash line or two one-stage lines. According to other embodiments, additional channels can be included in excess of two. 
     According to one or more cases, a proportional integral derivative (PID) controller with, for example 5 to 10 second control loops can be used to control the chemical pumps of the overall system. This allows the system to maintain the desired control and consistency in the water chemistry. The PID controller further allows for slow and fast acting sanitizer changes and better tuning of control. Further, according to one or more embodiments, controlling the speed of response provided the control system the ability to vary the degree of anticipation and response that corresponds with the produce wash equipment specification and/or produce characteristics. For example, cleaning carrots can sometimes be done with a longer respond time to chemical amount shifts while onions require a faster response to changes detected by one or more sensors. The control system can set the pump frequency and/or rate and stroke length to control the amount of chemical added as well as the timing. Further, a time interval may be selected for pumping based on the sensor provided information. 
     A redundant transient storage solution may be provided that can provide data integrity and protection, in accordance with one or more cases. For example, a two tiered backup solution can be implemented that uses local storage devices and a USB drive that can be plugged into any of the control system elements and then move and plugged into another element. 
     According to one or more cases, sensor fouling with limited interruption of data for cleaning may be provided that improves the fouling control system. According to one or more embodiments, a number of different elements can be provided that increase effectiveness. For example, switching from an elapsed time clock to a daily clock for chlorine electrode electrochemical cleaning can be provided. This change in clock cycle insures that the chlorine electrodes may start each day of production without fouling. According to another embodiment, another element that can be provided is adding feedback to the controller to confirm that chlorine electrode was cleaned allowing verification rather than assuming the cleaning cycle was complete. Further, according to another embodiment another element that can be included is cascading a designed for purpose filter. This may include a set of cascading filters that may include a first filter connected in parallel with a second filter. These filters may be of a tangential flow design to extend operating time. This allows greater tolerance for interfering materials including fats and oils that are present in meat and poultry operations. 
     According to other cases, to increase the utility of the system and the cloud based data, more powerful analysis tools may be added and calibration data collected. According to one or more embodiments, a calibration report is generated to statistically guide the decision to adjust the output from the chlorine system to accurately report chlorine concentration without correction that just add noise to the data stream. The cloud data from multiple plants and lines allows development of metric for performance comparisons such as degree of control, hours of in control operation and the absence of outliers. According to another embodiment, the cloud based data can be used to generate certificates of performance to demonstrate that the line was operating correctly. 
     Given the importance of particle removal to fouling control of the electrodes, it is instructive to examine the filtration in greater detail that can be provided in accordance with one or more embodiments. For example, according to one or more embodiments, the filter housing and design look familiar but the fluid flow has been changed to provide by-pass flow to continuously clear the faces of the screens and filters as shown in  FIG. 10  below. According to one or more embodiments, when filters of this type are cascaded they are even more effective and provide longer operating windows before cleaning is necessary. This filtration coupled with Clean-In-Place (CIP) airflow, or another clean-in-place device, is enough to maintain the pH electrodes. The coulometric chlorine electrode requires electrochemical cleaning. 
     In accordance with one or more embodiments, the improved calibration process uses a calibration and verification process to assure the accuracy of the sensor electrodes. Further, according to one or more embodiments, a new controller can be put into service when the electrode response has drifted to outside of the acceptable range as determine by the verification process which utilizes a t-test as a decision making tool (the ratio of the difference to variance corrected for the number of measurements). This data can be manually entered into the cloud data system where the reporting decision reports the results reducing the human decisions. 
     Plumbing and electrical layout of one or more cases are illustrated in  FIGS. 7, 8, and 9 . These diagrams assist in organizing the flow of information and data in this complex system. 
     Turning now to  FIG. 1 , as shown,  FIG. 1  is a block diagram of a control system  100  for water used in produce processing, which may be called a water control system or an Automated Smart Wash Analytical Platform (ASAP)  100 , and a produce wash equipment  150 , which may also be referred to herein as a produce handling device  150 , in accordance with one or more embodiments. As shown a control system  100  includes a logic processor  110  that can also be called a controller  110 . The logic processor  110  is provided such that is can communicate and receive data from all the other elements of the control system  100 . The logic processor  110  can also take the received data from other elements of the control system (such as the HMI  140 , sensor  120 , and pump  130 ), or from devices as location outside the control system  100  (such as the produce handling equipment  150  or other external devices or databases). In accordance with one or more embodiments, the logic processor/controller  110  can take any of the received data or subset thereof and process the data to generate analysis output that can be provided to the HMI  140  for display to a user. Additionally the data can be used by the controller  110  for generating control signals for controlling elements connected to the controller  110 . 
     For example, according to one or more embodiments, the logic processor  110  receives sensor data from at least the sensor  120 , user input from the HMI  140  from one or more users, and data from the pump  130 . The logic processor  110  can also receive data from the produce handling equipment  150 . Further the logic processor  110  can also receive data from other control systems, or other databases. The logic processor  110  then takes all or part of this received data and generates control signals that can be transmitted to one or more of the other elements of the control system  100 . 
     Physically, the logic processor  110  can be implemented using a select number of logic circuit elements that can be integrated into one or more other physical devices in the overall control system  100  or even within an element of the produce handling equipment  150  or combination thereof. For example, a physical processing core can be integrated into the sensor  120  or in the HMI  140  that serves as the logic processor  110 . In another example, a processing core can be provided in the pump  130  or in the produce handling equipment  150 . In another embodiment the logic processor  110  can be a stand-alone computing system. This can include but is not limited to an on-site server, an off-site server, a distributed server arrangement, a cloud computing system, a portable electronic device, and/or a combination. 
     The control system  100  also include a human machine interface (HMI)  140  that is connected to the logic processor  110  such that the HMI  140  can receive and provide data to and from a user and the logic processor  110 . The HMI  140  can be for example, but is not limited to, a touchscreen, a monitor, a speaker system, a combination thereof, and/or any other device capable of transmitting and receives data from a user. For example, the HMI  140  can be a stationary computer station, a mobile computing device such as a tablet, cellular phone, laptop, and/or wearable electronic. The HMI  140  can also be a speaker system such as a stationary speaker system mounted in a facility or an integrated speaker system in an electronic device. Further, the HMI  140  can be a combination of electronic display, sound, and camera devices. An HMI  140  that includes one or more camera devices can receive inputs from a user in the form of gestures or movements. Also the HMI  140  can include a microphone so that is can receive audio input from a user. Further, the HMI  140  can receive input from the user using a keyboard, mouse, or touchscreen as well. The HMI  140 , when implements as a mobile device, can also receive input in the form of a movement, such as a shake or waving of the device by a user, that is detected by movement sensors in the mobile device. The HMI  140  can then provide one or more of the received inputs to the logic processor  110 . Further, in another embodiment, the HMI  140  can process the data and provide the results of the processing to the logic process  110  in an effort to alleviate the processing load on the logic processor  110 . 
     The control system may include at least one sensor  120 . As shown, in other embodiments the control system  100  can include a plurality of sensors. In one embodiment, the sensor  120  can be a pH sensor that can detect a pH level in a fluid that is run through the sensor. The fluid can be the wash solution that includes water and possibly other chemical and debris from the produce handling equipment  150 . In another embodiment, the sensor  120  can be a chlorine sensor that detects a chlorine level in the fluid that is run through the sensor. Further, in other embodiments, the sensor  120  can be a temperature gauge, a microphone, an imaging device such as a camera or video camera, or other known sensors. Further, a plurality of sensors can be included that can all be providing collected data to the logic processor  110 . The sensor  120  can be provided elsewhere, near, adjacent to, attached to, and/or within the produce handling equipment  150 . For example, the sensor  120  can be located at a distance from the produce handling equipment  150  while being connected using a sampling hose that transports the fluid to be tested to the sensor  120 . In another embodiment, the sensor can be provided connected to or within the produce handling equipment  150 . 
     Additionally, the control system  100  may include at least one pump  130 . In other embodiments, the control system  100  and include a plurality of pumps. The pump  130  can be a chemical pump that pumps a select wash solution into the water of the produce handling equipment that is being used to wash produce being processed. For example, the pump  130  can be a pH solution pump, or in another embodiment a chlorine pump. The pump  130  can also pump a wash solution that includes a number of chemical. The pump  130  receives control signals from the logic controller  110  that indicate to the pump when to pump, for how long to pump, and how fast the pump should operate. 
       FIG. 2  is a block diagram of a control system  200 , or ASAP  200 , for water used in produce processing with examples of sensor placement in accordance with one or more embodiments. As shown, the control system  200  includes a logic processor  210  that is connected to a human machine interface  240  as well as a plurality of sensors  221 ,  222 ,  223 , and  224 . The sensors  221 ,  222 ,  223 , and  224  are each shown at a different representative location in relation to produce handling equipment  250  that the sensors  221 ,  222 ,  223 , and  224  are monitoring. The sensors  221 ,  222 ,  223 , and  224  can be placed as shown at all different locations, all at any one positions, or a combination thereof. 
     Looking specifically at each of the sensors, a sensor  221  can be provided away from the produce handling equipment  250 . For example, a pH or chlorine sensor can be placed at a location and be connected to the equipment  250  using a sampling hose that carries water from the equipment  250  to the sensor  221 . In another embodiment, the sensor  221  can be a camera or microphone. This arrangement allows for the control system  200  to be provided at a central testing location to be installed in a plant setting away from any of the produce handling equipment lines in the plant. Sensor  222  can be placed adjacent to or connected to the produce handling equipment  250 . For example, a sensor can be mounted on the outside of the produce handling equipment were the sensor  222  can be directly provided samples or inputs for testing. The sensor  223  is provided such that part of the sensor can extend into the produce handling equipment  250 . For example, sensor  223  can be mostly mounted to an outer surface of the produce wash equipment with a probe extending into the equipment  250 . Further, sensor  224  shows that a sensor can be provided completely within or submerged in the produce handling equipment  250 . 
       FIG. 3  is a block diagram of a control system  300 , or ASAP  300 , for water used in produce processing showing examples of network integration in accordance with one or more embodiments. As shown the control system  300  includes a logic processor  310 , a HMI  340 , and sensors  321 ,  322 ,  323 , and  324  provided to collected data from produce handling equipment  350 . The HMI  340  is similar to the above discussed HMI  140  of  FIG. 1 . Similarly, sensors  321 ,  322 ,  323 , and  324  are similar to sensors  221 ,  222 ,  223 , and  224  of  FIG. 2 . Further, the control system now includes one or more networks  361  and  361  that can be used to connect elements of the control system  300  that are no longer directly connected with the logic processor  310 . Specifically, as shown a network  361  can be used to connect sensors  321 ,  322 ,  323 , and  324  to the logic processor  310 . For example, the network  361  can include a local area network (LAN) and associated device resources that provide a communication path for the sensors to communicate with the logic processor. The network  361  can be a wired system, a wireless system, or a combination thereof. The network  361  can also be a wide area network (WAN) or even can represent a connection through the internet that would traverse a number of network elements now included in the network  361 . This allows for the placement of the logic processor  310  to effectively be placed anywhere. 
     Further, the system  300  includes a network  362  as well that connects the HMI  340  and the logic processor  310 . The network  362  can include a local area network (LAN) and associated device resources that provide a communication path for the HMI  340  to communicate with the logic processor. The network  362  can be a wired system, a wireless system, or a combination thereof. The network  362  can also be a wide area network (WAN) or even can represent a connection through the internet that would traverse a number of network elements now included in the network  362 . This allows for the placement of the logic processor  310  and the HMI  340  to effectively be placed anywhere. For example, the HMI  340  could be a portable electronic device that the user carries with them within the plant or even outside the plant. Similarly, the logic processor  310  can be located on-site, off-site, or a combination thereof. 
       FIG. 4  is a block diagram of a control system  400 , or ASAP  400 , for water used in produce processing with examples of data storage memory locations in accordance with one or more embodiments. The control system  400  includes a HMI  440 , a logic processor  410 , sensors  421 ,  422 ,  423 , and  424 , and networks  461  and  462  that are similar to the similar elements in  FIGS. 2 and 3 . Specifically, the HMI  240 , logic processor  210 , sensors  221 ,  222 ,  223 , and  224  from  FIG. 1  and networks  361  and  362  from  FIG. 2 , respectively. 
     Further, the control system can include one or more of the shown memory devices or locations. The memory devices can be provided in the form of integrated random access memory (RAM), read-only memory (ROM), a cache, or any other known memory arrangement. These integrated memory elements can be provided as, for example, a static integrated circuit, a hard drives, floppy disc, optical drive, or any other known memory type. Further, the memory devices can also be stand along memory devices in the form of USB data drives or external hard drives or even distributed cloud computing storage solutions. For example, looking specifically at  FIG. 4 , the HMI  440  can include a memory device  440 . 1 . This memory device  440 . 1  can be a universal serial bus (USB) thumb drive, an integrated or external hard drive, or any other memory device and/or combination thereof. Additionally, according to one or more embodiments, control system  400  elements can include a plurality of memory devices. For example, the logic processor  410  can include a first memory device  410 . 1  and can also include a second external memory device  410 . 2 . The first memory device  410 . 1  can be an internal form of memory while the second memory device  410 . 2  can be an external memory device such as a USB thumb drive. Further, according to one or more embodiments, any one of the sensors  421 ,  422 ,  423 , and  424  can each also include one or more forms of memory devices  421 . 1 ,  422 . 1 ,  423 . 1 , and  424 . 1  as shown. Further, according to one or more embodiments, an external detachable memory element, such as a USB thumb drive  421 . 1 , can be detached from a sensor  421  and can then be directly connected to another device such as the logic processor  410  transferring the data from the memory device  421 . 1  to the logic processor  410 . This process can also be done in the reverse carrying data such as control signals to a sensor or other device in the system. 
       FIG. 5  is a block diagram of a control system  500 , or ASAP  500 , for water used in produce processing with distributed processing control in accordance with one or more embodiments. The control system  500  includes a HMI  540 , and sensors  521 ,  522 ,  523 , and  524 . In other embodiments the control system  500  can have more or less sensors and their placement can also vary as well as their type. In this embodiment the logic processor/controller is explicitly show has a distributed system. Specifically the control system  500  can include a number of logic processors  511 ,  512 , and  513 . As shown the logic processor  512  for example can handle a subset of the sensors. For example, the logic processor  512  can be connected to chlorine sensors  523  and  524  in the system and can therefore conduct all the specific data processing associated with the type of sensor data. The logic processor  513  is show to connect with a different subset of sensors. For example, the logic processor  513  can connect to pH sensors  522  and  521  found in the system. The logic processors  512  and  513  can then send specifically processed data to the logic process  511  which can conduct additional overarching processing and send that to be displayed to a user using the HMI  540 . 
     According to other embodiments, there can be include more or less logic processors than those shown. For example each sensor can have its own logic processor or any variation thereof can be provided. Further, according to other embodiments, the logic processor  512  and logic processor  513  may connect to sensors not based on their type but rather another characteristic such as location or processing requirements to produce a specifically desired output. 
       FIG. 6  is a block diagram of a control system  600 , or ASAP  600 , for water used in produce processing including control signals and pumps that are controlled by the control signals in accordance with one or more embodiments. Specifically, as shown, the control system  600  includes one or more pumps  631 ,  632 ,  633 , and  634 . According to one or more embodiments, the chemical feed pump  631  can be provided away from, adjacent to, partially within, or totally within the produce handling equipment  650 . Further, according to other embodiments, the pumps  632 ,  633 , and  634  can be provided at different location as well. One or more of the chemical pumps  631 ,  632 ,  633 , and  634  can pump produce wash chemicals such as chlorine and/or a combination of chemicals that make up a was solution. For example, a commercial system for a two stage leafy green wash line might include six pumps to allow control of chlorine in each stage, and two additional pumps to control an acid wash adjuvant that is suitable for organic or conventional production allowing for ease in line conversion from organic to conventional production. The reverse conversion can also be done but it is less useful because a full wash down is required to prevent carry over into the organic production. 
     Further the control system  600  includes a logic processor  610  that receives data from one or more sensors  621 ,  622 ,  623 , and  624 . The logic processor  610  can also receive data from a HMI  640 . Further, the logic processor  610  can receive data from one or more of the chemical feed pumps  631 ,  632 ,  633 , and  634 . The logic processor  610  can then take all or part of the received data and process the data to come up with control signals. The control signals can then be transmitted to, for example, the chemical feed pumps instructing the pump on when and how much to pump. For example, consider a leafy green processing line operating at a 15 ppm setpoint. As the chlorine levels begin to fall due to product flow and reaction, the controller will activate the chlorine pump. As the demand grows, the PID will begin anticipating the demand prompting greater and/or longer activation of the pump with the goal of maintaining a stable chlorine concentration in the wash system. Similar control will be exercised to control the pH. 
       FIG. 7  is a block diagram of a control system  700 , or ASAP  700 , for water used in produce processing that controls water pH for washing produce in accordance with one or more embodiments. The control system  700  includes a wash solution  781  reservoir that contains chemicals for washing produce such as sodium hypochlorite or SmartWash Solutions SW™ or any other materials that needs to be dosed into the line in a controlled manner. The control system  700  also includes a primary pH pump  721 . 1  that pumps the wash solution  781  into the produce handling equipment  750  and specifically into the water being using in the produce handling equipment  750  to wash the produce. The control system  700  also includes a secondary pH pump  721 . 1  that can also pump wash solution  781  into the produce handling equipment. Additional pumps can be added if wash solutions  781  is to be added at other locations in the produce handling equipment  750 . Further the control system  700  can further include a second wash solution  782 . This wash solution can be, for example, an organic wash solution. The control system can further include a primary organic pH pump  722 . 1  and a secondary organic pH pump  722 . 2  that are each able to pump the wash solution  782  into the produce handling equipment at different points and at different timing and amounts as indicated by received control signals generated by the control system. 
     Specifically, the control system  700  further includes a first sensor pHE- 1   725 . 1  and a second sensor pHE- 2   725 . 2  that are sensors that can detect and provide pH sensor data to a logic processor of the control system  700 . The control system  700  can then take these sensor data and generate control signals for controlling the pumps  721 . 1 ,  721 . 2 ,  722 . 1  and  722 . 2 . As shown, water samples from the produce handling equipment  750  are drawing into and through the sensors  725 . 1  and  725 . 2  that then output the pH sensor data for processing and/or storage. Further, the control system  700  includes a pH clean-in-place (CIP) enclosure  770 . The CIP enclosure  770  is connected to the first and second sensors  725 . 2  and  725 . 2  and facilitates and conducts cleaning of itself and the sensors which is specifically described in  FIG. 8 . 
       FIG. 8  is a block diagram of a pH Clean-In-Place (CIP) enclosure  770  of a control system/ASAP, for water used in produce processing in accordance with one or more embodiments. As shown the CIP enclosure  770  is connected to both pH sensors  725 . 1  and  725 . 2 . The CIP enclosure  770  includes internal solenoids  774  and  776  that are configured to control a flow path using valves  775  and  777  respectively. A cleaning air blast can be used to clean out either of the flow paths  775  and  777 . Particularly, according to one or more embodiments, solenoids  774  and  776  control the valves  775  and  776  respectively when a cleaning event is triggered. The signal to command the solenoids to open the valves comes from the PLC. In some cases, an air blast device may be configured to deliver a filtered and oil free burst of air to dislodge adhering material on at least one sensor. 
     The CIP enclosure  770  further includes a Pressure Transmitter (PT)  773  that sends a signal to the PLC with the measurement of the air pressure in the CIP system. This measurement can be used to send an alarm that there is too much or too little air to function correctly. Further, the CIP enclosure  770  includes a filter  771  that protect an air regulator  772 . The air regulator  772  regulates the air pressure to the desired operating pressure. 
       FIG. 9  is a block diagram of a control system  900 , or ASAP  900 , for water used in produce processing that controls chlorine being added to the water for washing produce in accordance with one or more embodiments. The control system  900  includes a sensor enclosure  926  that includes a primary flow cell  926 . 1  sensor and a secondary flow cell  926 . 2  sensor. The control system  900  further includes a primary filter  991  and a secondary filter  992  that is connected to the sensor enclosure  926 . These filters  991  and  992  are connected to the produce handling equipment  950 . The filters  991  and  992  pull water from the produce handling equipment  950  and filter the water discarding of some while passing the filtered water into the sensor enclosure  926  and into the primary and secondary flow cell sensors  926 . 1  and  926 . 2 . The sensors  926 . 1  and  926 . 2  can then process the provided water, generate a sensor signal, and transmit that sensor signal out to a controller of the control system  900 . The sensor signals can indicate the amount or lack thereof, of chlorine present in the water. The controller can generate control signals based on this sensor data and can provide those control signals to the primary and secondary chlorine pumps  923 . 1  and  923 . 2 . The chlorine pumps include a primary chlorine pump  923 . 1  and a secondary chlorine pump  923 . 2 . The primary chlorine pump  923 . 1  and the secondary chlorine pump  923 . 2  pull the chlorine solution  983  in accordance with the control signals each receive and provide that chlorine solution into the water in the produce handling equipment  950 . 
       FIG. 10  is an illustration of a set of filters  1090  used in a control system for water used in produce processing in accordance with one or more embodiments. For example, the set of filters  1090  can be as one or both of the filters  991  and  992  as shown in  FIG. 9 . The set of filters  1090  include at least two sub-filters  1098  and  1099  that are connected in series with the output of a first filter  1098  feeding into the input of the second filter  1099 . Initially, process water  1090 . 1  is input into the first filter  1098  as shown. Particles and water return  1090 . 2  that are collected by the filtering agent within the filter  1098  are discarded. Next, a stream of partially filtered water  1090 . 3  is output from the first filter  1098  and into the second filter  1099 . The second filter again filters out particles and water and discards of the second set of particles and water  1090 . 4 . What is left is prepared process water  1090 . 6  that is passed to one or more filters for testing of the water for chemical composition. 
       FIG. 11  is a flow chart of operations  1100  for using a control system for controlling water used in produce processing in accordance with one or more embodiments. The operations  1100  includes collecting, using a sensor disposed at the food processing system, a sensor signal (operation  1102 ). The operations  1100  also includes generating one or more control signals for controlling one or more chemical pumps and one or more valves to provide a wash solution into the water of the food processing system based on the sensor signal (operation  1104 ). The operations  1100  further include transmitting the one or more control signals to the one or more chemical pumps and one or more valves (operation  1106 ). 
     In spite of recent advances in wash process control as discussed herein, there are still challenges. Oft times, the control systems as described herein may be operated in cold and/or wet environments. Such environments may be deleterious to the performance of electronic components. Failure of these potentially critical electronic components may present a potential food safety hazard. The control of wash process is critical to many food processing operations. Manual control is increasingly inadequate. Therefore wash process control is increasingly handled by control systems such as described herein in one or more disclosed embodiments and examples. Further, additional features may be provided that may further improve and care for instrumentation as described herein that is used to manage wash processes. 
     In accordance with one or more cases, chlorine monitoring and maintenance may be improved through the implementation of, for example, calibration and/or electrode cleaning. The importance and mechanics of chlorine electrode calibration are described herein. However, chlorine electrodes and flow cells can be fouled by deposits that can tan to black in color. These deposits can be cleaned manually by disassembly and manual scrubbing with an acid cleaner. Although this may be an adequate way to end up with a clean sensor, the process and need to stop the produce processing, remove, disassemble, reassembly, and reinstall the sensor. This is not only time consuming but also costly and imposes both wear and tear on the sensor parts such as the electrodes as well as provides a complex disassemble/assemble procedure that may lead to erroneous implementation leading to sensor damage and possible food safety concerns. 
     According to one or more cases, a feature that may be provided is a clean-in-place option that avoids the disassembly and manual scrubbing. For example, a general example of this is shown in  FIG. 7  element  770 . A specific implementation is further shown in  FIG. 8 . Other cases are shown in  FIGS. 12 and 13  that include other specific examples that include passing a liquid cleaning and/or calibration solution through the electrodes/sensors. An oxidizing acid solution will rapidly dissolve deposits that may be found on or near an electrode flow cell. Many oxidizing acids are known including but not limited to nitric acid, chromic acid, and peroxy acids of various organic acids. In some cases, a peroxy acetic acid for cleaning may be selected because the acid is commercially available in food grade qualities making it highly compatible with use in a food processing environment. 
     Turning now to  FIG. 12 , a block diagram of a control system  1200  with cleaning and calibration elements used in produce processing is shown. The control system  1200  includes a fluid receptacle that contains a cleaning solution connected to a primary cleaning solution dosing pump  1 . The dosing pump  1  is further connected to a multi-way selector valve  7 . The control system also includes a calibration solution connected to a calibration solution dosing pump  2 . The dosing pump  2  is further connected to the multi-way selector valve  7 . In addition to receiving cleaning solution and calibration solution, the selector valve  7  also receives sample water. The selector valve  7  can switch between any of these options and provide a selected flow to an electrode flow cell. In one or more cases, the control system  1200  may also include an optional dosing pump  3  and an optional multi-way valve  5  that provide cleaning solution to a secondary electrode flow cell. Further, the control system  1200  may include another optional dosing pump  4  and another optional multi-way valve  6  for providing calibration solution to the secondary electrode flow cell. 
       FIG. 13  is a block diagram of a control system  1300  with cleaning and calibration elements identical to  FIG. 12 . The control system  1300  may further include a filter that filters the incoming sample water that is then provided to the electrode flow cell. The filter may also include a return water path. In some cases, the water filter may be included that is configured to filter sample water provided to at least one sensor and return excess sample water when a multi-way valve is engaged to provide at least one of a cleaning solution or a calibration solution to the at least one sensor instead of the sample water. 
     In one or more cases, peroxy acetic acid is gentle enough that deleterious effects on the electrode and housing may not be apparent over a broad range of concentrations including up to 50%. However, 50% may be much more concentrated than necessary to achieve the cleaning of the electrode. At the lower end, the cleaning time begins to increase below about 2% when the electrode and housing are between 40 and 80 degrees F. At less than about 0.5% the cleaning is less complete in reasonable times. In accordance with one case, a recommended cleaning is therefore 2% peroxy acetic acid for 15 minutes to overnight. In other cases, time, temperature, and concentration can be adjusted against each other to generate other cleaning protocols. This embodiment is simple and effective for use in most process environments where chlorine monitoring is performed with the referenced automated system. 
     To gain further improvements in the maintenance process for such controllers, the use of a solution can be automated with robotic valves controlled by a controller such as a PLC or by manual selection. The ability to select between process water, no flow, cleaning solution such as the described 2% solution, and calibration solution may reduce the need for human intervention during the regular activities of cleaning and calibration. It accordance with one or more cases, control may be achieved through a series of binary valves or a single multichannel valve. The decision between options may be based on the cost and reliability of the components as well as sensor feedback values. 
     In one or more cases, in a steady state operation, the electrode and flow cell are placed in the cleaning solution for 15 minutes or more. The solution is made static but switched to no flow to allow cleaning to occur after about three volumes of solution have flushed the system. The solution could be allowed to flow continuously but this is not required. At start up the electrode and flow cell are reconnected to process water to flush the system. As the line systems all stabilize, the calibration solution is selected to confirm the calibration or initiate a calibration is needed. When this is completed, the flow of process water is restored to return to normal automation. These procedures may be implemented using the system  1200  presented in  FIG. 12 . 
     Additionally, the maintenance of these machines, devices, and systems takes people and scheduling. Time spent on maintenance is time a line is not producing product. Accordingly it can be appreciated that automation of the maintenance activities has impacts beyond just the labor savings. In one case, a robotic valve may used to select the delivery of process water, calibration solution, or electrode cleaning solution allowing increased automation in maintenance activities. 
     The environment where these control systems operate can be very challenging. The moist air, the changing temperatures, and the sanitary wash downs are threats to the reliability of the control system electronics. 
     Thus, in one or more cases, the electronics of the controller are held under pressure greater than ambient with dry air to retard water migration. Specifically, electronics may be housed in cabinets designed for this purpose with appropriate gasketed doors and cable openings to mitigate the entry of these environmental conditions. For example, in one or more cases, a small positive pressure, about 4 inches of water, with dry air may be provided which may mitigate threats to reliability by preventing the ingress of moisture and moist air. In accordance with one or more cases, adding air pressure to the electronic cabinets of an ASAP may help prevent moisture entry and prevent mold growth. For example, pressurized enclosure may be provide for logic processors/controllers  110 ,  210 ,  310 ,  410 ,  511 ,  512 ,  513 , and  610  as shown in  FIGS. 1-6 . Additionally, a pressurized enclosure may also be provided for the human machine interfaces as well as for any of the electronics of sensors as disclosed herein. Further, pressurized enclosures may be provided for memory devices as shown, for example, in  FIG. 4 . 
     These improvements can be used in tandem or individually to improve the reliability of wash process control equipment. 
     While the present disclosure has been described in detail in connection with only a limited number of embodiments, it should be readily understood that the present disclosure is not limited to such disclosed embodiments. Rather, the present disclosure can be modified to incorporate any number of variations, alterations, substitutions, combinations, sub-combinations, or equivalent arrangements not heretofore described, but which are commensurate with the scope of the present disclosure. Additionally, while various embodiments of the present disclosure have been described, it is to be understood that aspects of the present disclosure may include only some of the described embodiments. 
     The term “about” is intended to include the degree of error associated with measurement of the particular quantity based upon the equipment available at the time of filing the application. For example, “about” can include a range of ±8% or 5%, or 2% of a given value. 
     The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the present disclosure. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, element components, and/or groups thereof. 
     While the present disclosure has been described with reference to an exemplary embodiment or embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the present disclosure. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the present disclosure without departing from the essential scope thereof. 
     Therefore, it is intended that the present disclosure not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out this present disclosure, but that the present disclosure will include all embodiments falling within the scope of the claims.