OPERATING METHOD FOR A BATCH PROCESS

Abstract

An operating method for a batch process, the batch process comprising a plurality of operating phases and within each phase there is provided at least one operating mode, one of the modes of each phase being a standby mode or its equivalent, wherein a transition from a first phase to a second phase requires that the first phase be initialised to its standby mode or equivalent and upon completion of the phase change the second phase enters its standby mode or equivalent.

Claims

1. An operating method for a batch process, the batch process comprising a plurality of operating phases and within each phase there is provided at least one operating mode, one of the modes of each phase being a standby mode or its equivalent, wherein a transition from a first phase to a second phase requires that the first phase be initialised to its standby mode or equivalent and upon completion of the phase change the second phase enters its standby mode or equivalent, the operating phases further comprising alternating phases of aerobic and anaerobic treatment conducted in a single reactor.

2. An operating method according to claim 1, wherein valve and drive configurations of the standby modes or their equivalent in phases between which a transition occurs are substantially similar, thereby allowing efficient progression from one phase to another.

3. An operating method according to claim 1, wherein the equivalent of the or each standby mode is a target configuration of valves and drives embedded within a distinct mode or within a sequence of modes or phases involved in a change from the first stage to the second stage.

4. An operating method according to claim 1, wherein the batch process is directed to the treatment of the organic fraction of mixed municipal solid waste.

5. An operating method according to claim 1, wherein the batch process is directed to the treatment of the organic fraction of mixed municipal solid waste, the plurality of operating phases comprising the following phases: a. Aerobic; b. Anaerobic; and c. Transition.

6. An operating method according to claim 5, wherein the Transition operating phase in turn comprises one of an Aerobic-to-Anaerobic-Transition phase, to remove oxygen from a headspace of the reactor vessel, or an Anaerobic-to-Aerobic-Transition phase, to remove methane from, and introduce oxygen into, the headspace of the reactor vessel while avoiding the formation of a flammable gas mixture.

7. An operating method according to claim 5, wherein the Aerobic phase comprises one or more of the following modes of operation: (i) Standby; (ii) Loading (draft); (iii) Loading & recirculate solids (draft); (iv) Recirculate solids (draft); (v) Unloading (draft); (vi) Recirculate solids (pressure vent); and (vii) Pressure vent.

8. An operating method according to claim 6, wherein the Aerobic-to-Anaerobic-Transition phase comprises the following modes of operation: (i) Standby; and (ii) Transition.

9. An operating method according to claim 6, wherein the Anaerobic phase comprises the following modes of operation: (i) Standby; (ii) Fill & recirculate liquid; (iii) Empty liquid; and (iv) Recirculate solids.

10. An operating method according to claim 6, wherein the Anaerobic-to-Aerobic-Transition phase comprises the following modes of operation: (i) Standby; (ii) Pressure vent; and (iii) Purge.

11. An operating method according to claim 10, wherein the purge of step (iii) of the Anaerobic-to-Aerobic Transition phase is a purge to an odour management system.

12. An operating method according to claim 6, wherein the Anaerobic-o-Aerobic-Transition phase comprises the following modes of operation: (i) Standby; (ii) Continuous purge of an inert or exhaust gas; and (iii) Purge.

13. An operating method according to claim 1, wherein there is further provided a safety instrumented system (SIS).

14. An operating method according to claim 13, wherein there is further provided a basic process control system (BPCS) that operates in accordance with, and is governed by, the safety instrumented system.

15. An operating method according to claim 14, wherein the SIS makes decisions regarding the granting of permission when it is requested by the BPCS based on a number of parameters at that time, including one or more of valve positions/settings, pressure, gas composition and flow rates.

16. An operating method according to claim 15, wherein the BPCS is set at a ‘lower’ or ‘earlier’ level thereby substantially avoiding circumstances in which the SIS needs to intervene and halt the process, and which would cause a failsafe state.

17. An operating method according to claim 14, wherein to initialise a change of phase the following steps are undertaken: (i) The mode for a current phase is set to a phase specific standby mode; (ii) The SIS confirms that it is safe to make the change of phase; (iii) The BPCS moves specific BPCS controlled valves to appropriate positions in preparation for the change of phase; (iv) The BPCS requests the SIS to make the change of phase; (v) The SIS moves SIS controlled valves to the appropriate valve states; (vi) The SIS sets its phase to the new phase; (vii) The SIS informs the BPCS of the new phase and monitors the BPCS movement to the new phase; (viii) The BPCS sets the phase to the new phase; (ix) The BPCS moves BPCS controlled valves into position to facilitate the change of phase to appropriate phase specific standby state; and (x) The BPCS mode is set to standby and provides confirmation to the SIS.

18. An operating method according to claim 17, wherein the BPCS and SIS perform a ‘handshake’ at steps (ii) and (iv), whereby the BPCS requests the permission of the SIS to make the phase change.

19. An operating method according to claim 17, wherein with regard to step (vii), if the BPCS is not set to the new phase within a specific time frame from the commencement of step (iii), the SIS reverts to the previous phase and will raise a phase change failure alarm.

20. An operating method according to claim 19, wherein the specific time frame is a period of about 2 minutes.

21. An operating method according to claim 6, wherein only the following phase changes are possible: (i) Aerobic phase to Aerobic-to-Anaerobic Transition phase; (ii) Aerobic-to-Anaerobic-Transition phase can change, depending upon process conditions, to either of Aerobic phase or Anaerobic phase; (iii) Anaerobic phase to Anaerobic-to-Aerobic-Transition phase; and (iv) Anaerobic-to-Aerobic-Transition phase can change, depending upon process conditions, to either of Aerobic phase or Anaerobic phase.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0080] The present invention will now be described, by way of example only, with reference to one embodiment thereof and the accompanying drawings, in which:

[0081] FIGS. 1(a) and 1(b) are to be read in conjunction and provide a diagrammatic representation of the several phases of the batch process for the treatment of organic waste material to which the method of the present invention is applied in accordance with one embodiment thereof, showing the several modes within each phase and the sequences in which the modes and phases may change;

[0082] FIG. 2 is a Table of desired Standby valve positions in each of the several phases of the batch process for the treatment of organic waste material to which the method of the present invention is applied, as shown in FIGS. 1(a) and 1(b);

[0083] FIGS. 3(a) and 3(b) are to be read in conjunction and provide a flowchart representing the integration of the SIS and BPCS of the batch process for the treatment of organic waste material to which the method of the present invention is applied, as shown in FIGS. 1(a) and 1(b); and

[0084] FIG. 4 is a diagrammatic/schematic representation of a Fail to Closed SIS controlled valve and its associated valve control function block.

BEST MODE(S) FOR CARRYING OUT THE INVENTION

[0085] As noted hereinabove, International Patent Application PCT/AU00/00865 (WO 01/05729) describes an improved process and apparatus in which aerobic and anaerobic processes are combined for the treatment of the organic fraction of MSW (OFMSW). The process and apparatus are characterised at a fundamental level by the sequential treatment of organic waste material in a single vessel or reactor, through an initial aerobic step to raise the temperature of the organic waste material, and a subsequent anaerobic digestion step. During the anaerobic digestion step a process water or inoculum containing microorganisms is introduced to the vessel to create conditions suitable for efficient anaerobic digestion of the contents and the production of biogas. The introduced inoculum also aids in heat and mass transfer as well as providing buffer capacity to protect against acidification. Subsequently, air is introduced to the residues in the vessel to create conditions for aerobic degradation. The entire content of International Patent Application PCT/AU00/00865 (WO 01/05729) is specifically incorporated herein by reference.

[0086] It is further described in PCT/AU00/00865 (WO 01/05729) that the water introduced during anaerobic digestion may be sourced from an interconnected vessel that has undergone anaerobic digestion.

[0087] The sequential treatment of organic waste material in a single vessel requires that the process be conducted as a batch process, albeit that multiple vessels may be utilised. In such an arrangement each vessel still houses the sequential treatment of organic waste material in a single vessel, through an initial aerobic step to raise the temperature of the organic waste material, and a subsequent anaerobic digestion step.

[0088] The single vessel process described in PCT/AU00/00865 (WO 01/05729) presents challenges in transitioning between the aerobic and anaerobic stages of treatment, and in turn from that anaerobic stage back to an aerobic stage of treatment.

[0089] The present invention provides a method of operating a batch process, such as the organic waste material treatment process described in PCT/AU00/00865 (WO 01/05729). The present invention will now be described with particular reference to the organic waste material treatment process and plant (hereinafter “the process” and “the plant”, respectively) as described in PCT/AU00/00865 (WO 01/05729) and for which additional aspects thereof are described in the Applicant's International Patent Applications PCT/AU2012/000738 (WO 2013/003883), PCT/2012/001057 (WO 2013/033772), PCT/AU2012/001058 (WO 2013/033773) and PCT/AU2012/000739 (WO 2013/003884).

[0090] In the process the environmental conditions to which the organic waste material, such as an OFMSW, is exposed are manipulated to facilitate the degradation thereof by a variety of microorganisms. These environmental conditions have been categorised by the Applicants as a number of, or series of, operating phases as follows: [0091] (i) Aerobic; [0092] (ii) Anaerobic; and [0093] (iii) Transition.

[0094] The Transition operating phase in turn comprises one or other of an Aerobic-to-Anaerobic-Transition phase, to remove oxygen from the vessel/reactor headspace, and an Anaerobic-to-Aerobic-Transition phase, to remove methane from, and introduce oxygen into, the vessel/reactor headspace whilst avoiding the formation of a flammable gas mixture.

[0095] Within each of the phases there are provided a number of operating activities, or modes. The modes of operation provided within each phase are set out, by way of example, in Table 1 below:

TABLE-US-00001 TABLE 1 Phase Modes within Phase Aerobic Standby Loading (draft) Loading & recirculate solids (draft) Recirculate solids (draft) Unloading (draft) Recirculate solids (pressure vent) Pressure vent Aerobic-to-Anaerobic-Transition Standby Transition Anaerobic Standby Fill & recirculate liquid Empty liquid Recirculate solids Anaerobic-to-Aerobic-Transition Standby Pressure vent Purge, for example to OMS

[0096] Each phase has provided therein a standby mode, or its equivalent, which places the plant or process in a defined idle state. Each phase is further defined by a set of valve configurations and motor states that are used to achieve the idle state. To change between two modes of operation within a specific phase the phase specific standby mode, or its equivalent, is entered before entering the required mode of operation. In case of fault or failure in the plant or process, the SIS/BPCS moves the process to the idle state.

[0097] The standby modes of the plant are states in which the plant may remain operable, in that the waste treatment process remains on-going, albeit in what may be termed a ‘parked’ state, or an ‘on-hold’ state.

[0098] It is envisaged that a number of the modes of operation noted above may be incorporated into one or more ‘consolidated sequences’ without departing from the spirit and scope of the present invention. Such a consolidated sequence is a predetermined combination of modes of operation.

[0099] It is further envisaged that the equivalent of the or each standby mode comprises a target configuration of valves and drives imbedded within a distinct mode or within a sequence of modes involved in a change from the first stage to the second stage.

[0100] In addition to the above, the method of the present invention comprises, as does the plant, both a Safety Instrumented System (SIS) and a Basic Process Control System (BPCS). The SIS sits above, or across the top of, the BPCS, thereby ‘governing’ the BPCS.

[0101] To initialise a change of phase the following steps are undertaken: [0102] (i) The mode for the current phase is set to the phase specific standby mode; [0103] (ii) The SIS confirms that it is safe to make the change of phase; [0104] (iii) The BPCS moves specific BPCS controlled valves to the appropriate positions in preparation for the change of phase; [0105] (iv) The BPCS requests the SIS to make the change of phase; [0106] (v) The SIS moves SIS controlled valves to the appropriate valve states; [0107] (vi) The SIS sets its phase to the new phase; [0108] (vii) The SIS informs the BPCS of the new phase and monitors the BPCS movement to the new phase; [0109] (viii) The BPCS sets the phase to the new phase; [0110] (ix) The BPCS moves BPCS controlled valves into position to facilitate the change of phase to appropriate phase specific standby state; and [0111] (x) The BPCS mode is set to standby and provides confirmation to the SIS.

[0112] As can be noted from the above, the BPCS and SIS perform a ‘handshake’ at steps (ii) and (iv). In effect, the BPCS is requesting the permission of the SIS to make the phase change. This is referred to as a ‘permissive’ at various points in the specification.

[0113] With regard to step (vii) above, if the BPCS is not set to the new phase within a specific time frame, for example two minutes, from the commencement of step (iii), the SIS will revert to the previous phase and will raise a phase change failure alarm.

[0114] In general terms, the SIS makes decisions regarding the granting of permission when it is requested by the BPCS based on a number of parameters within the plant at that time, including but not necessarily limited to valve positions/settings, pressure, gas composition and flow rates. Importantly, the BPCS is set at a ‘lower or’ earlier level in an effort to avoid circumstances in which the SIS may need to intervene and halt the process, causing a failsafe state, to be defined hereinafter. The failsafe state is very similar to the standby states defined herein.

[0115] Only the following phase changes are possible under the method of the present invention: [0116] (i) Aerobic phase to Aerobic-to-Anaerobic Transition phase; [0117] (ii) Aerobic-to-Anaerobic-Transition phase can change, depending upon process conditions, to either of Aerobic phase or Anaerobic phase; [0118] (iii) Anaerobic phase to Anaerobic-to-Aerobic-Transition phase; and [0119] (iv) Anaerobic-to-Aerobic-Transition phase can change, depending upon process conditions, to either of Aerobic phase or Anaerobic phase.

[0120] The method of operating a batch process of the present invention will now be described, and may be better understood, with reference to the following non-limiting example.

Example

[0121] This Example describes the functional requirements in relation to integration of the SIS and BPCS for the purposes of vessel mode/phase change. The Example can be read in conjunction with FIGS. 1(a) and 1(b) which show each of the phases of the batch process, and each of the modes within each phase.

[0122] Each vessel has a group of valves to control gases flowing in and out of the vessel headspace. These valves control purge gas (air/nitrogen) entering the vessel and biogas (approx. 50% CH.sub.4), transitional gas (0.1-50% CH.sub.4) and odorous gas (<1% CH.sub.4) exiting the vessel. There are two valves per line, one controlled by the BPCS and one controlled by the SIS.

[0123] As described above, there are four defined phases for each vessel (“Aerobic”, “Aerobic-to-Anaerobic-Transition”, “Anaerobic” and “Anaerobic-to-Aerobic-Transition”) which require the SIS (and BPCS) valves to be in certain positions to maintain a safe state during normal operation. The BPCS valve positions required for normal operation in each phase are as shown in the table of FIG. 2. The SIS valve positions required for normal operation in each phase are as shown in Table 2 below.

TABLE-US-00002 TABLE 2 Aerobic-to- Anaerobic-to- Anaerobic- Aerobic- SIS Valve Aerobic Transition Anaerobic Transition Description Phase Phase Phase Phase Biogas CLOSED CLOSED OPEN CLOSED Supply Valve Transition Line CLOSED OPEN CLOSED OPEN Supply Valve OMS Supply OPEN CLOSED CLOSED CLOSED Valve Air Blower OPEN CLOSED CLOSED OPEN Supply Valve OMS Bypass CLOSED OPEN CLOSED OPEN Valve Nitrogen OPEN OPEN OPEN OPEN Supply Valve

[0124] The following conditions trip the SIS valves to the CLOSED position to create a failsafe state. In each case the BPCS will act, at a lower value, on the corresponding BPCS controlled valves to initiate a BPCS equivalent failsafe state.

[0125] Transition Line Supply Valve: [0126] Anaerobic-to-Aerobic-Transition: [0127] If the methane concentration is greater than the lower explosive limit (LEL) for methane in air less a safety margin, for example 3%. [0128] Anaerobic-to-Aerobic-Transition: [0129] If the methane concentration is greater than the LEL for methane in air, for example 4%, and the oxygen concentration is greater than the minimum oxygen concentration (MOO) for methane less a safety margin, for example 5%; or [0130] If the oxygen concentration is less than the MOO for methane, for example 11%, but greater than a safety margin, for example 5%, and the methane concentration is greater than the LEL for methane in air less a safety margin, for example 3 to 4%; or [0131] If the oxygen concentration is greater than the MOO for methane, for example 11%, and methane is greater than the LEL for methane in air less a safety margin, for example 3%.

[0132] OMS Supply Valve: [0133] If the Odour Management System (OMS) is Off; or [0134] If the methane concentration is greater than the Lower Explosive Limit (LEL) for methane in air less a safety margin, for example 1%; or [0135] Vessel Pressure is nearing the vessel under-pressure relief valve relieving pressure, for example between about −5 kPa to −0.4 kPa.

[0136] Air Blower Supply Valve: [0137] Aerobic Phase: [0138] Vessel Pressure is nearing the vessel relief valve relieving pressure, for example between about 30 kPa and 1000 kPa, [0139] Anaerobic-to-Aerobic-Transition: [0140] Vessel Pressure is nearing the vessel relief valve relieving pressure, for example between about 20 kPa to 1000 kPa; or [0141] If the methane concentration is greater than the LEL for methane in air, for example 4%, and the oxygen concentration is greater than the MOO for methane less a safety margin, for example 5%; or [0142] If the oxygen concentration is less than the MOO for methane, for example 11%, but greater than a safety margin, for example 5%, and the methane concentration is greater than the LEL for methane in air less a safety margin, for example 3 to 4%; or [0143] If the oxygen concentration is greater than the MOO for methane, for example 11%, and methane is greater than the LEL for methane in air less a safety margin, for example 3%.

[0144] OMS Bypass Valve: [0145] Aerobic-to-Anaerobic-Transition and Anaerobic-to-Aerobic-Transition Phases: [0146] Vessel Pressure is nearing the vessel under-pressure relief valve relieving pressure, for example between about −5 kPa to −0.4 kPa; or [0147] If the methane concentration is greater than the LEL for methane in air less a safety margin, for example 2%; or [0148] If the OMS is off.

[0149] Nitrogen Supply Valve: [0150] Aerobic and Anaerobic: [0151] Vessel Pressure is nearing the vessel relief valve relieving pressure, for example between about 30 kPa and 1000 kPa. [0152] Aerobic-to-Anaerobic-Transition and Anaerobic-to-Aerobic-Transition Phases: [0153] Vessel Pressure is nearing the vessel relief valve relieving pressure, for example between about 20 kPa to 1000 kPa.

[0154] In addition, the SIS valves may be required to change position in the event of a Safety Instrumented Function (SIF) being activated, so as to bring the process back to a safe state. The valve positions during activation of process SIFs take precedence over those defined for normal operation, such as described and set out in Table 2 above.

[0155] Each vessel has 16 modes of operation, these modes being defined and controlled in the BPCS. The SIS sets the phase of the vessel and the BPCS then aligns with the assigned phase. The modes and phases are listed in Table 3 below and accord with those set out hereinabove at Table 1.

TABLE-US-00003 TABLE 3 Vessel Mode (BPCS) Vessel Phase (SIS) Aerobic Standby (Draft) Aerobic Phase Aerobic Loading (Draft) Aerobic Phase Aerobic Loading and Recirc Solids Aerobic Phase (Draft) Aerobic Recirc Solids (Draft) Aerobic Phase Aerobic Unloading (Draft) Aerobic Phase Aerobic Recirc Solids (Pressure Vent) Aerobic Phase Aerobic Pressure Vent Aerobic Phase Aerobic-to-Anaerobic-Transition Aerobic-to-Anaerobic-Transition Standby Phase Aerobic-to-Anaerobic-Transition Aerobic-to-Anaerobic-Transition Phase Anaerobic Standby Anaerobic Phase Anaerobic Fill & Recirc liquid Anaerobic Phase Anaerobic Empty liquid Anaerobic Phase Anaerobic Recirc Solids Anaerobic Phase Anaerobic-to-Aerobic-Transition Anaerobic-to-Aerobic-Transition Standby Phase Anaerobic-to-Aerobic-Transition Anaerobic-to-Aerobic-Transition Pressure Vent Phase Anaerobic-to-Aerobic-Transition Anaerobic-to-Aerobic-Transition Purge, for example to OMS Phase

[0156] An operator is able to initiate a mode change (subject to their operating schedule and mode change permissives). Each mode change is realised through completion of a BPCS mode change sequence. To initiate a change of mode, away from the phase specific Standby mode, a BPCS START sequence is run and to return to the phase specific Standby mode a BPCS STOP sequence is run.

[0157] Phase changes require a controlled change of SIS (and BPCS) valve positions during normal operation of the plant. This will be required when changing between any of the “Standby” modes, for example when changing from Aerobic Standby (Draft) to Aerobic-to-Anaerobic-Transition Standby.

[0158] The steps required when changing between Standby modes can be summarised below, with this example relating to the change between Aerobic Standby (Draft) and Aerobic-to-Anaerobic-Transition Standby for a first vessel. This description should be read in conjunction with the SIS/BPCS integration flowchart of FIGS. 3(a) and 3(b). This flowchart sets out which actions occur in the SIS, which occur in the BPCS, and the signal exchanges required between the two systems.

[0159] With reference to the flowchart of FIG. 3, this example begins in the step “Wait for Phase Change Request”, seen specifically at FIG. 3(a). [0160] 1. Initial state is SIS Phase=“Aerobic Phase” (flag “V-1101 A” active) and BPCS Mode=“Aerobic Standby (Draft)” [0161] 2. Operator initiates a mode change to “Aerobic-to-Anaerobic-Transition Standby” mode via the BPCS Human Machine Interface (HMI) [0162] 3. If the SIS phase change permissive “V-1101 A to AN Tran Per” is healthy (defined as: all Vessel pressures are within operational parameters; the methane concentration within the Transition Line is low; the OMS is on-line and the current Phase for V-1101 is Aerobic), then the operator can initiate a phase change. If the BPCS sequence permissives are healthy, the BPCS prepares for a phase change by initialising the relevant BPCS valves [0163] 4. The BPCS sets the “V-1101 A to An Tran REQ” flag, indicating the BPCS is requesting a phase change from the SIS. This flag remains latched until the BPCS confirms successful completion of a phase change or 2 minute timeout [0164] 5. If the SIS phase change permissive “V-1101 A to AN Tran Per” is healthy, the SIS valves change to the positions defined in Table 2 [0165] 6. If the “V-1101 A to An Tran REQ” flag is active AND all valves have successfully made their required positions, flag V-1101B is set and latched [0166] 7. Flag “V-1101 B” indicates the last known phase is now “Aerobic-to-Anaerobic-Transition Phase” [0167] 8. The BPCS sets the phase to Anaerobic-to-Aerobic-Transition Phase [0168] 9. The BPCS sets the BPCS valves to their new positions, as per FIG. 2 [0169] 10. The BPCS sets the mode to “Aerobic to Anaerobic Transition Standby” and sends a confirmation signal, V-1101 B PCS to the SIS. This flag remains latched until the next phase change

[0170] The request for a phase change by the BPCS can be removed at anytime during the phase change sequence. Upon removal of the request the SIS and BPCS will return to their previous phase and standby mode, and align their respective valves accordingly.

[0171] If the SIS and BPCS valves fail to make their required positions within, for example, 60 seconds during a phase change, the SIS and BPCS return to their previous phase and standby mode. In this example, Aerobic Phase and Aerobic Standby (Draft), respectively.

[0172] If the SIS valve position feedbacks go into an unexpected state during normal operation or there is a phase/mode mismatch between SIS and BPCS, an alarm is raised.

[0173] Following a cold start of the SIS, the SIS controlled valves remain in the positions defined for a cold start condition until a valid phase is manually selected by the operator. The operator is required to set the current phase of the vessel in the SIS to match the actual physical state of the vessel. Manual selection of phase requires a two-step process as follows: [0174] 1. Placing the SIS phase initialisation keyswitch into the initialise position if the SIS instrument override is required; and [0175] 2. Initialising the phase from the HMI using the phase change request (for example “V-1101 A REQ”)

[0176] Phase change permissives are checked prior to allowing the phase to be initialised. However, as indicated in FIGS. 3(a) and 3(b), certain parts of each phase change permissive can be overridden by the operator while the vessel is in the cold start phase (SIS Phase Flag=“V-1101 E”).

[0177] Following a cold start of the BPCS, the BPCS initialises its valve positions and mode flag based on the phase flag in the SIS. If the SIS phase is unavailable (for example communications not healthy) or in the cold start phase (SIS Phase Flag=“V-1101 E”), the BPCS controlled valves remain in the failed positions until the SIS phase flag is set (i.e. SIS Phase Flag=“V-1101 A, B, C or D”).

[0178] A communications ‘watchdog’ is provided in the software layer for communications between the SIS and BPCS. It requires that a communications healthy flag in each system will become false if either or both of the following conditions are true for more than 30 seconds: [0179] 1. The link between the SIS and BPCS is down: or [0180] 2. The other system (BPCS or SIS) stops processing logic (for example CPU state=stop)

[0181] All signals exchanged between the systems are acted on only if the communications healthy flag is true.

[0182] If communications are lost, no further action is required. The last latched phase (“V-1101 A, B, C or D”) represents the safe state for the vessel.

[0183] Table 4 below sets out and summarises the signals exchanged between the two systems for the purposes of co-ordinating a mode/phase change. The signals are replicated for each vessel by replacing ‘x’ in the table with the vessel number.

[0184] All signals in the table below are logged in a BPCS event log.

TABLE-US-00004 TABLE 4 Signal Direction Purpose V-1x01 A SIS->BPCS Indicates SIS valves have moved to their correct positions for Aerobic Phase (as confirmed by limit switches) following a phase change request from the BPCS. This signal is latched in the SIS to indicate the last confirmed phase. V-1x01 B SIS->BPCS As above, for Aerobic-to-Anaerobic-Transition Phase V-1x01 C SIS->BPCS As above, for Anaerobic Phase V-1x01 D SIS->BPCS As above, for Anaerobic-to-Aerobic-Transition Phase V-1x01 E SIS->BPCS Indicates SIS has been subjected to a power cycle and is waiting for the operator to manually set the current phase. V-1x01 A PER SIS->BPCS Indicates SIS Permissive for changing to Aerobic Phase is healthy V-1x01 A to An Tran SIS->BPCS As above, for Aerobic-to-Anaerobic-Transition Phase PER V-1x01 An PER SIS->BPCS As above, for Anaerobic Phase V-1x01 An to A Tran SIS->BPCS As above, for Anaerobic-to-Aerobic-Transition Phase PER V-1x01 A REQ BPCS->SIS Indicates the BPCS is requesting the SIS valves to change to their required positions for Aerobic Phase. This signal is latched in the BPCS until confirmation is received that the SIS Phase Change Flag has been set, or a timeout has occurred, whichever occurs first. V-1x01 A to An Tran BPCS->SIS As above, for Aerobic-to-Anaerobic-Transition Phase REQ V-1x01 An REQ BPCS->SIS As above, for Anaerobic Phase V-1x01 An to A Tran BPCS->SIS As above, for Anaerobic-to-Aerobic-Transition Phase REQ V-1x01 A PCS BPCS->SIS Indicates BPCS valves have moved to their correct positions for Aerobic Standby (Draft) Mode (confirmed by limit switches) following a mode change request from the operator. This signal is latched in the BPCS to indicate the last confirmed mode. V-1x01 B PCS BPCS->SIS As above, for Aerobic-to-Anaerobic-Transition Standby Mode V-1x01 C PCS BPCS->SIS As above, for Anaerobic Standby Mode V-1x01 D PCS BPCS->SIS As above, for Anaerobic-to-Aerobic-Transition Standby Mode

[0185] Each SIS controlled valve has an associated valve control function block, an example of which is shown in FIG. 4, to carry out the latching function required above.

[0186] Operation occurs as shown in FIG. 4 and Table 5 below, and provides certain functionality as set out immediately below: [0187] (i) Once a valve position is requested, the valve control function block will latch this position and drive the valve accordingly; [0188] (ii) A SIS trip will override the latched state and force the output to the tripped state for the duration of the SIS trip remaining active; [0189] (iii) Once the SIS trip has cleared, the output of the function block will remain in the tripped state until the SIF has been reset at which time it will return to its previously latched state.

TABLE-US-00005 TABLE 5 COMMAND OPEN CLOSED Set (S) 1 0 Reset (R) 0 1

[0190] Control of Fail Last (FL) valves will be similar to that described above. However, the function block will be required to drive two solenoids as shown in Table 6 below. On a cold start, the outputs of both solenoids remain off until an Open/Close command is received.

TABLE-US-00006 TABLE 6 Required Valve Position Close Solenoid Open Solenoid Closed On Off Open Off On

[0191] As can be seen with reference to the above description, the present invention provides an operating method for a batch process, the batch process in one form being provided as a process for the treatment of the organic fraction of mixed municipal solid waste (“OFMSW”), that process including alternating phases of aerobic and anaerobic treatment conducted in a single reactor vessel.

[0192] Modifications and variations such as would be apparent to the skilled addressee are considered to fall within the scope of the present invention.