The present invention relates to a containerised system housing an array of modular electrochemical devices preferably, but not necessarily limited to electrolysers for the electrolytic production of hydrogen.
Hydrogen has a multitude of applications, ranging from energy storage to the production of fertilisers. Hydrogen can be derived from many sources. Some of these sources, such as fossil fuels, are undesirable for obvious ecological and environmental reasons. Therefore, there is a need to be able to produce hydrogen in a reliable and sustainable manner.
Electrolysers are devices used for the generation of hydrogen and oxygen by, essentially, splitting water molecules. It is possible to power such devices with renewable energy, including utilising excess energy, so that hydrogen can be used as a means for energy storage, complementary to batteries, for example. Electrolysers generally fall into one of three main technologies currently available, namely anion exchange membrane (AEM), proton exchange membrane (PEM), and liquid alkaline systems. Liquid alkaline systems represent the most established technology, with PEM being somewhat less so. In contrast, AEM electrolysers are derived from a relatively new technology. Other technologies, such as solid oxide electrolysis are available, but they will not be discussed further herein.
AEM and PEM electrolysers are reliant on the transfer of ions from one half-cell to the other for the generation of hydrogen. AEM systems rely on the movement of hydroxide ions, OH−, whilst PEM systems rely on the movement of hydrogen ions, H+ through the membrane.
Other electrochemical devices include fuel cells, electrochemical compressors, or electrochemical purification devices. Each of these may be used alone, but can also be found to form part of a single hydrogen solution.
At present, it is common practice to size a single electrochemical stack for a required purpose. However, a common drawback for such activity is the required activation energy for each stack, especially of such a size, means that when less power is available the stack is not operated. The result is underutilization of available energy, and a reduced ability to respond to power fluctuations.
An object of aspects of the present invention is to provide an improved means and method for the housing and operation of modular electrochemical devices capable of utilising as much power as is available.
According to one aspect disclosed herein, there is provided a containerised modular electrochemical cell system, comprising: a housing; and a plurality of electrochemical stacks removably mounted within said housing, each stack comprising: one or more electrochemical cells; one or more fluid inlet(s) for receiving feedstock; and one or more product outlet(s), wherein the stacks are arranged in at least one string, each string comprising two or more of the stacks, the stacks in each string being electrically connectable in series, and each string being connectable to a power source, and wherein each stack or string is configured to be independently activated; and wherein each string comprises: at least one feedstock inlet manifold fluidly coupled to the inlet(s) of the stacks of the string for distributing feedstock between the inlet(s) of the stacks, and at least one product outlet manifold fluidly coupled to the outlet(s) of the stacks of the string; and flow regulation means configured to regulate fluid flow through the inlet(s) and/or outlet(s).
According to another aspect disclosed herein there is provided a containerised modular electrochemical cell system, comprising:
wherein each string comprises at least one feedstock inlet fluidly coupled to the input(s) of the stack(s) thereof, and at least one product outlet fluidly coupled to each of the output(s) of the stack(s) thereof; the system further comprising
As used herein, the term “fluid” preferably connotes both liquid (e.g. a liquid water or electrolyte stream) and gas (e.g. a hydrogen or oxygen gas stream).
Whilst it is envisaged that any electrochemical device may be used, in a preferred embodiment the electrochemical devices may be electrolysers. It will be understood by a person skilled in the art, however, that the required inlets and outlets would vary depending upon the nature of the electrochemical device.
In an exemplary embodiment, control means may be provided, communicably coupled to said feedstock delivery means, and configured to cause said feedstock delivery means to deliver quantities of feedstock to the inlet(s) dependent on available energy and/ power fluctuations. In an exemplary embodiment, means are provided for circulating spent electrolyte for reuse.
As used herein, “electrolytic stack” and “electrochemical stack” and “electrolyser” are intended to include reference to modular electrolysers, and electrolyser stacks and other modular electrochemical devices such as but not necessarily limited to compressors, purifiers, fuel cells or sensors.
As used herein, a modular device generally includes more subsidiary components than a stack itself. For embodiments of the present inventions wherein stacks are utilised, it is intended that more of the balance of plant (BoP) will be shared between devices.
As used herein feedstock generally refers to any input to the electrochemical cell. In embodiments using electrolysers this will generally be an electrolyte such as KOH for AEM electrolysers or deionised water for PEM. For embodiments with fuel cells this may be a predominantly hydrogen-based feed and a feed with significant amounts of oxygen. Electrochemical oxygen or hydrogen compressors will generally be fed with streams containing a substantial amount of either gas. The present invention is not necessarily intended to be limited by such parameters.
Whilst it is envisaged the housing may be a container, as used herein housing is intended to cover any arrangement including a baseplate upon which modules are located, or a general location. Said baseplate or equivalent may or may not include external walls and/or roof.
It is envisaged that the means for circulating feedstock may include, but is not necessarily limited to pumps, fans, or pressurised storage and associated valves for a regulated release. Circulating and distributing being used interchangeably, with circulating including embodiments wherein there is a closed loop for the electrolyte or equivalent used in embodiments with electrolysers.
Whilst it is envisaged that each string shares a power source, in the preferred embodiment the power source for within each string is in series. Alternatively, the power may be supplied to each stack withing a string in parallel. The strings themselves being supplied by distinct power supplies, parallel, or multiple in series. Regardless of power supply being in series or parallel, each stack is envisaged to have a front end or terminal and back end or terminal, the front end being adapted to receive either a positive or negative power supply and the back end having a negative or positive supply. In embodiments using fuel cells, where power is generated it is envisaged that each string supplies power with the power being provided in series by each stack in said string.
Fluid connections for the present invention are present for both inlets and outlets. The fluid connections may be supplied from a shared manifold and are also envisaged to be in series or in parallel. In the preferred embodiment parallel means for supply and removal of fluids are provided to ensure the requisite pressures are maintained.
Whilst it is envisaged that a variety of housings may be used, in the preferred embodiment a shipping container is used.
In the preferred embodiment, the flow regulating means are provided on the outlet, but may also or alternatively be provided on the or each inlet. Whilst it is envisaged any flow regulating means may be used, normally check or control valves are utilised.
In the preferred embodiment, the electrochemical stacks comprise at least an anodic and cathodic half-cell, preferably separated by a polymeric ion exchange membrane, more preferably still an anion exchange membrane. It is envisaged that the inlet will be for the introduction of a fuel, oxidant, water or equivalent. Such fluids can include any one or more of hydrogen, oxygen, methanol, methane, carbon dioxide, carbon monoxide or DI (deionised) water.
Whilst it is envisaged that each stack may be provided with its own power source forming a string of one electrochemical device, in the preferred embodiment a string comprises upwards of 2 electrochemical devices. Preferably a string has in the range of 2 and 20 electrochemical devices, more preferably still between 2 and 10 devices and yet even more preferably still between 4 and 6 electrochemical devices.
Whilst the feedstock may be discarded after use, in some embodiments, e.g. those using an electrolyser, the electrolyte or DI water feedstock is preferably recirculated, with means being provided for this.
Whilst it is possible for the present invention to be used with electrochemical devices of any size, preferably the power consumption is in the range of 1 kW-200 kW, more preferably still between 1 kW-100 kW, even more preferably still between 1 kW-20 kW, more preferably still between 1 kW-10 kW and more preferably still between 1.5 kW and 5 kW and even more preferably still between 2 kW and 3 kW. Devices at the smaller end of the spectrum allow for better utilisation of available power, and responses to power fluctuation. The ability to respond well to power fluctuations being desirable especially when the devices are intended for coupling to renewable energy sources.
It is envisaged that the system may have a total power consumption of between 0.5 MW and 200 MW, more preferably still substantially 1 MW or between 50 MW and 150 MW. In embodiments of the present invention wherein more MW are used, it may be more practical to use larger stacks, such as those in a 10 kW to 100 kW range in strings, or 50 kW to 500 kW or 50 kW to 250 kw or 100 kW to 200 kW.
Alternatively, it is envisaged that each stack has a power consumption that is a fraction of the overall system capacity such as between 1/100th and 1/1000th, or 1/50th and 1/500th, or 1/50th and 1/1000th. Preferably each stack will be between 1/200th and 1/600th or 1/50th and 1/100th. Normally the fraction is excluding the power requirements of the BOP.
In the preferred embodiment, the system is adapted to allow hot swapping of electrochemical components. Each string being provided with means enabling the electrical and fluid isolation of the string such as valves and switch(es) for controlling the power source. Once isolated, one or more stack in the isolated string can be replaced. This mitigates the need for down time, further improving the power utilisation of the system. It is further envisaged that stacks or strings not meeting expected performance characteristics, such as output values, may be adapted to be isolated by the computing means and a prompt sent indicating maintenance is required.
Whilst any type of electrochemical device may be used with the present invention, in the preferred embodiment the present invention is preferably coupled with AEM technology as opposed to PEM. More preferably still, when the electrochemical devices are electrolysers, AEM electrolysers with a substantially dry half cell, and more preferably still a dry cathode. A dry cathode, or anode, meaning a device where no electrolyte or equivalent is introduced to the cathodic, or anodic, half-cell.
Due to the nature of the required electrolyte, AEM devices are not reliant upon PGM catalysts, and also do not require materials resistant to the caustic conditions required by PEM devices.
Each string may be provided with a shared connection to the power source, or alternatively each device within said string may have its own device power source connection. In the preferred embodiment wherein more BOP is shared the power supply is in series and feedstock is in parallel via inlet manifold(s). Products of the process may be fluidly connected in parallel by outlet manifolds.
It is envisaged that strings of devices may be provided with means for temperature control, such means including but not necessarily limited to heat exchangers, air cooling, or liquid cooling. In the preferred embodiment, waste heat utilisation is employed using the heat emitted from the devices to preheat the electrolyte or other feedstock such as but not necessarily limited to water. Alternatively, waste heat may be utilised by providing heat to nearby housing, water or other industrial processes.
Whilst is it envisaged that the electrochemical cells may operate at a variety of temperatures in the preferred embodiment the temperature of the feedstock is not intended to surpass 100° C. More preferably still within the range of 40° C. and 80° C. and even more preferably still substantially 60° C. Preheating, and heat exchangers for waste heat utilisation may be employed to minimise energy waste.
In some embodiments using modules it is envisaged that means for ventilation or air cooling will be provided to the or to each module. However, this is not present for variants using stacks. In any case, even in variants wherein modules have means for ventilation, ventilation is preferably provided for the housing as a whole. Ventilation is provided to ensure that the ratio of hydrogen and oxygen does not pass the potentially hazardous levels.
Alternatively, in the preferred embodiment, ventilation means are provided for the system as a whole in the housing said ventilation being preferably controlled by the computing means, said computing means having one or more hydrogen sensors situated within the housing. By default, the ventilation means are quiescent which beneficially does not dilute any potential leak allowing the hydrogen sensors detect a leak more rapidly, and accurately. Location may be determined by using a plurality of sensors. If hydrogen is detected, the computing means are adapted to activate the ventilation means. This has the added benefit of maintaining the temperature within the housing, drastically reducing waste heat. Therefore, in the preferred embodiment it is desired that the means for ventilation is adapted to handle in the range of 10x-1000x the hydrogen produced, more preferably still between 25x and 200x, more preferably still 50x and 150x and even more preferably still substantially 100x.
In other embodiments using fuel cells or compressors as the electrolytic stack the ventilation means may be sized in accordance with the input of hydrogen or other feedstock in the ranges disclosed above
In embodiments where modules are used, said modules comprising a housing, the housing may further act as insulation preventing the entire container from reaching the temperature of the stack, rendering the system more readily serviceable without the need for ventilation.
The ventilation means may be further controlled by automated readings from alternative sensors, such as the computer means triggering ventilation when an unexpected pressure drop is measured on a fluid pipeline.
As a further means for safety measurement, the preferred embodiment comprises at least one sensor for hydrogen, and/or other gas(es) which may pose a safety concern. Whilst one sensor may be sufficient, the size of the housing may be sufficiently large that a plurality of sensors is desired, placed throughout the stack or housing. Said sensors may be passive, such as visual colour changing tape, however, in the preferred embodiment the sensors are adapted to trigger an alarm and preferably increase the ventilation flowrate before potentially hazardous levels are reached to minimise risk. Other means such as a mobile sensor may be used to detect a leak alone, or in combination with pressure readings from sensors placed on each stack or string, a drop in pressure being indicative of a leak.
In one embodiment of the present invention electrochemical hydrogen sensors may be employed in each column of stacked cells, or each string. Due to the nature of hydrogen gas, sensors are preferably placed substantially at the top of the housing, at least in the upper half. This is not intended to exclude sensors in the bottom half.
The computing means is intended to be controllably connected to the power supply for each device, or string thereof. In a preferred embodiment of the present invention, the computing means is also operably connected to any one or more sensors, for each device or string thereof, sensors including but not limited to: leak detectors, pressure sensors, temperature sensors, humidity sensors, flowrate sensors, level sensors, pH sensors, conductivity sensors, oxygen sensors, hydrogen sensors, electrolyte sensor, gas sensors for other feedstock such as but not limited to carbon monoxide.
The operable connection may be wired, or wireless such as by WiFi or Bluetooth®. It is envisaged that readings from the sensors may be rendered available to a user by another computing device, with access being secured by known means.
Whilst it is envisaged that a variety of power sources may be utilised, such as from a national grid, in the preferred embodiment energy is utilised from renewable sources, and more preferably excess renewable sources. Renewable sources include but are not limited to, solar, wind — onshore or offshore, tidal, hydro or a combination thereof. It has been found that AEM electrolysers are particularly well suited to cycling compared to other relatively established electrochemical processes.
It is envisaged that means may be provided for the treatment of spent electrolyte or feedstock for reuse in the system.
It is envisaged that one or more rectifiers may be used to convert incoming power such that it may be supplied as AC, DC or reverse pulse. The same applies for power output for embodiments of the present invention utilising fuel cells. The modular nature of the present invention renders it better suited to any known or employed technology for the utilisation of as much power as possible. To allow for this, strings of varying lengths may be provided in a single housing to allow for a more tailored control by the computing means. Strings of fewer devices being better suited to address fluctuations in loads. Strings with more units have a longer response time but can act as a buffer for larger fluctuations in energy supply more efficiently, due to better amplitude matching but decreased frequency matching. Shorter strings allow for faster response times, but decreased buffer capacity, due to better frequency matching and lower amplitude matching ability.
In embodiments of the present invention wherein the electrolytic stacks are fuel cells, the strings may be more responsive to required energy demands from the loads drawing on the system. The same may be applied to compressors as well.
In accordance with the present invention, it is envisaged that a variety of electrochemical devices may be housed together to form a hydrogen battery. The electrochemical devices in such a variant would include at least electrolysers and fuel cells. Electrochemical compressors may also be provided, or more traditional mechanical compressors. More preferably still AEM electrochemical compressors would be used to allow for the simultaneous compression, drying and/or purification of the produced hydrogen. BOP such as power supply and computing means may be shared between each type of electrolytic device. In order to function as a hydrogen battery, preferably storage means are provided within the housing.
In embodiments utilising electrochemical compressors, it is possible to compress either Hydrogen or Oxygen. Said compression may occur with optional purification. Hydrogen is preferably derived from a green source, such as water electrolysis, but a feed stock may be from a steam reformation or other non-renewable source of hydrogen, wherein simultaneous purification is certainly preferred. Where oxygen is to be compressed it may be derived from the outlet of one or more electrolysers, housed within the container or equivalent, or stripped from atmospheric air. The simultaneous purification can allow for medical or industrial use. However, means for drying may also be required prior to storage.
In lieu of fuel cells, such a hydrogen battery could be coupled to a refuelling station, or industrial process for the in-situ creation of required fuel stock.
It is envisaged that the layout of the housing will have the devices arranged in columns and rows. In embodiments utilising more than one type of electrochemical device, each group will preferably be situated in close proximity to devices of a similar type. For ease of access, it is envisaged that the devices will be situated allowing for three walkways, a central walkway between two walls of devices, said walls comprising a plurality of stacks. Additional walkways are envisaged to the rear of each wall, as shown in the figures. Alternatively, in order to save space, a central walkway only will be provided, with means for accessing the rear of stack modules including access doors/removable walls behind the stacks, or rendering the array of stacks moveable, such as by guide rails.
In a preferred embodiment, the walkway incudes a raised platform allowing for a clearance between 1 cm and 20 cm, or more preferably between 3 and 15 cm between the floor of the housing and the walkway platform upon which the stacks are mounted to allow for a clearance in which some BOP may be placed, and optional drainage for any condensation or other liquid to collect, and optionally air inlets. In such embodiments, drainage means may also be provided.
Additionally, it is envisaged that the walkway may be electrically insulated from the housing either by material selection, coating or other suitable means. The walkway may be the same or different material to the chassis of each stack, module or device.
Whilst it is envisaged that each module or stack may be provided with all of the required BOP, in the preferred embodiment BOP is shared as much as possible. This includes, but is not necessarily limited to power supply, water purification/feedstock treatment, feedstock circulation/distribution, sensors as described above, pressure regulating means, HVAC/ventilation means, safety system, product treatment.
In order to allow for the handling of large power supplies, it is envisaged that at least 10 of such modules will be used, but preferably over 20. For larger scales over it is envisaged a single container may house between 100 and 1000 modular devices, more preferably between 200 and 500 modular devices and more preferably still between 300 and 450 modular devices.
It is envisaged that the pressure regulating means on the outlet from the or each device are adapted to maintain a pre-determined threshold. This may vary depending on the device, but for the preferred embodiment wherein the electrochemical devices are electrolysers, the preferred pressure rating is between 1 and 50 bar, more preferably between 20 and 40 bar, and more preferably between 30 and 40 bar. In the most preferred embodiment it is substantially 35 bar. This may be limited to lower pressures in certain jurisdictions, such as 8 bar in Japan. Fuel cells may require considerably lower regulating means, whereas electrochemical compressors will naturally have higher means, normally in steps. An electrochemical compressor may eventually compress the target gas up to 2000 bar, or anywhere in the range of 30 bar to 2000 bar, 100 bar to 1500 bar or 500 bar to 1000 bar. In line with end usage for vehicles 350 bar, or 750 bar may be desired.
In embodiments using electrochemical compressors, each string may form a single stage, with a first stage feeding a second stage from P1 to P2 and so on to a final nth stage of Pn.
It is envisaged that the present invention may include means for electrically insulating or optionally fluidly isolating each stack from other stacks, strings of stack and or the optional chassis for each stack. The insulation may be provided by any reasonable means including electrically insulating materials or isolation can be done intermittently by adding circuit breakers, switches, and/or relays. It is envisaged that the means for intermittent isolation may be operably connected to computing means within the housing, or manually controlled/overridden, this includes flow regulation means disposed on said feedstock inlet and/or said outlet(s) of each stack, said flow regulation means being configured to selectively open and close the respective inlet(s) and/or outlet(s), as well as electrical connections.
Each stack or string thereof may be held within a chassis, said chassis comprising some BoP such as, but not necessarily limited to sensors (pressure, temperature etc.), electronics compartments, check valves and more. Additionally, ports may be provided for the inlet(s) and outlet(s). Furthermore, the chassis may also be provided with reinforcing support brackets, and compression means, said compression means being a spring or equivalent suspension to ensure sealing remains constant within the stack for its life span. Alternatively it is envisaged that the chassis may house more than one stack, such as 2 or more, a string of stacks or even multiple strings.
It is also envisaged that means for in-situ diagnostics may also be provided, said in-situ diagnostics being provided on a single device, or string of such devices, or a block of strings. A block of strings being two or more strings. Such diagnostics may be used to alert the user of required maintenance, pre-emptive or otherwise. Preferably the in-situ diagnostics may be used by the computing means to control the load distribution of the power supply to prioritise stacks with a better state of health (SoH). SoH may be determined using actual output compared to theoretical output and runtime of the devices.
In a preferred embodiment the in-situ diagnostics are coupled to the computing means and used to determine one or both of: power supply to the stack or string thereof, and how much feedstock should be made available to the stack or string thereof.
It is envisaged that means for determining in-situ diagnostics may include the ability to measure any one or more of the following:
The above list is not necessarily exhaustive, any reasonable performance or operating condition from which the status of a component may be determined or inferred may be used, in addition or alternatively.
It is envisaged that, based on the previously mentioned monitored operating conditions, inputs and outputs, means are provided to predict outputs extrapolated from the previous operating conditions. This would allow the overall system to operate at a desired capacity or requirement. Where appropriate, such measurements may be taken at pre-determined intervals by the in-situ diagnostic means, which may optionally be altered by the user. Additionally, triggers may be given for the instigation of diagnostics. Such triggers could be a change of power supply, forecast change of conditions or any other conceivable trigger.
It is envisaged that the above information may be used by a control system or computing means according to an aspect of the invention to determine a “weighted run time” (WRT) for each device or string thereof, the WRT taking into account factors such as, but not limited to run time, power supplied whilst running, anticipated vs actual measured performance and down time.
There are a variety of ways in which the WRT may be used to control the operation of the system as a whole. Priority may be given to the device or string with the lowest WRT, however it may be preferable to prioritise another device or string depending on the State of Health (SoH), which may be determined by the in-situ diagnostics, should the in-situ diagnostics show or indicate an issue with a device having a lower WRT than other devices. This may be supplemented by polarisation curve measurements or other diagnostic techniques. A device may have reduced priority even with a lower WRT if in need of maintenance, or a potential issue has been detected.
Other methods of determining a stack's SoH, a supplement or alternative to the WRT, generally include fitting the stack to an equivalent circuit model. In the simplest cases said model including resistor and capacitor components, but generally also adapted to include mass transport contributions as well. An example being Randles circuit, which includes a Warburg element to represent mass transport effects. Additionally, constant phase elements, a more general kind of capacitor element, to reflect porous electrodes may be included.
Equivalent circuit fitting of impedance spectra is possible for electrochemical stacks, but to obtain more useful data it is envisaged that fitting such a stack to equivalent circuits either requires electrochemical impedance spectroscopy (EIS) or another circuit through which the stack can passively charge/discharge. The passive charge/discharge circuitry having requisite switches and resistors to allow passive charging and discharging of the stack. Upon charging and discharging, the resulting voltage transience can be used, with a sufficient sampling rate, wherein said sampling rate is pre-determined, to fit the stack to an equivalent circuit. For the avoidance of doubt, the measured voltage transience may be combined with means for using said transience for fitting pre-determined equivalent circuit parameters. Characteristics of the stack voltage transience can be directly correlated with performance parameters that need to be identified (i.e. ohmic resistance, kinetic activity characteristics, and even mass transport/low frequency behaviour). This arguably increases the hardware complexity but allows for specific determination of parameters associated with individual cell components. EIS generally requires potentiostats which are expensive, however, one such potentiostat may be used to a plurality of electrolysers or strings of electrolysers. A DC bias is applied to the stack with an AC component (+/−1% of the DC bias) such that the frequency of the AC perturbation is swept from kHz to mHz—the impedance is measured at each frequency and this data can be used to fit the stack to an equivalent circuit model. If using a potentiostat, it would be connected to the electrochemical cell, stack or string by known means not described herein.
The ideal case, simplifying the hardware requirements while still obtaining useful information, involves simply looking at the changes in polarization curve data where the below equation separates the three dominating sources of losses: kinetic, ohmic, and mass transport.
In this equation:
Yet another diagnostic method includes measuring ΔV, or the change of polarization curve diagnostic. The polarization curve, or voltage versus applied current graph, gives information of the different kinds of efficiency losses in an electrolyser cell/stack — kinetic, ohmic, and mass transport. Nominally, electrolysers are dominated by kinetic and ohmic losses, the former being a logarithmic V vs I relationship, and the latter being linear between V and I. Though mass transport losses are present in the worst cases, generally it can be taken as the difference between the raw polarization curve data and the kinetic+ohmic fitting data. The kinetic part having two fitting coefficients, these being Tafel slope and exchange current density, which are dependent on the electrochemical reactions of the cell and reflect the state of health of each electrode's catalyst layer. The ohmic part only has one fitting coefficient, this being DC resistance, factors impacting this including membrane state of health and increasing contact resistance due to corrosion. Lastly, mass transport generally has two fitting coefficients, a logarithm prefactor, and the limiting current density, both of which give us an idea of the degree of “resistance” of water getting to the catalyst layer and/or gases leaving the electrodes — mass transport losses mainly arise from the gas diffusion layer (GDL), catalyst layer, and/or the membrane.
Consider that nonlinear curve fitting with five free parameters is practically rather difficult in the presently described invention and there are time constraints if done too regularly, although improved processing power may go some way to mitigating this—with an associated cost. Ignoring mass transport fitting now and focusing on the kinetic and ohmic losses allows for simplification. For the fitting procedure and improving accuracy and stability, the ohmic part may be measured and fixed such that the nonlinear curve fitting is only correcting for the two kinetic parameters in the first and only logarithmic term. In embodiments wherein one of the fitting parameters is stable, say the Tafel slope, this may be set at a fixed point in the control software/methodology reducing the variable. However, it is preferred to fix something that can be measured quickly such as the DC resistance or other suitable parameter. Deviation from the fitted polarization curve of purely ohmic+kinetic contributions with respect to the measured values can be attributed to mass transport limitation onset, which can also be used to properly define a maximum capacity value.
Some methods for measuring the ohmic part mentioned above include EIS or current interrupt which require a potentiostat or an impedance meter to read the impedance at a fixed high frequency (e.g. 1 kHz). As mentioned before a single potentiostat may be centralized and used for multiple stacks or strings thereof. It should be noted that distinguishing between a logarithm and a linear part of a curve is not easily done if there is not enough data, this is normally more pronounced especially at a very low current density which requires a long time to remove the capacitive contribution. It is envisaged that the means may be adapted to conduct more measurements at lower current densities to ensure adequate data, lower current densities being half or less than maximum operating capacity. Measuring the resistance by direct methods (e.g. EIS, current interrupt, impedance meter) removes this numerical issue allowing for a fast recording of the polarization curve, requiring less points for an accurate numerical fitting regardless of linear or logarithmic tendencies.
In a preferred embodiment of the present invention, the above described means and methods for conducting in situ diagnostics is used by the control means to determine the allocation and division of power and/or feedstock available.
It is envisaged that means for the determination of available power are provided, as well as means for forecasting available power based on known conditions.
In the preferred embodiment, flow regulating means may also be provided on the inlet, upstream of the stack or stream thereof. This also includes embodiments comprising a feedstock outlet, such as electrolyser embodiments with an outlet for the electrolyte, the feedstock inlet and outlet forming loop comprising the feedstock inlet and outlet. A pump or equivalent being placed on the upstream of the stack or strings thereof to minimise the presence of dissolved gases.
In the preferred embodiment of strings of electrolysers, flow regulating means or otherwise pressure such as a check valves are placed on at least the hydrogen outlet.
In accordance with a second aspect of the present invention, there is provided a method of controlling a plurality of electrochemical devices in a containerised modular electrochemical system, said method comprising:
In the preferred embodiment, the electrochemical system comprises primarily electrolyser stacks. Therefore, in accordance with the second aspect of the present invention there is provided a method of controlling a plurality of electrochemical devices in a containerised modular electrolyser system, said method comprising:
The method of operating the system as described above may be adapted to include any disclosed apparatus variant described above, including the utilisation of in-sit diagnostics, and other features.
The method may further comprise the step of providing means for controlling the outlet pressure from one or more outlet manifolds. Optionally, means may be provided for the purification of the contents of said outlet manifolds.
It is also envisaged that a walkway may be provided in the housing for access to each device. Said walkway may be provided centrally, but preferably rear access to each stack is also provided.
To help understanding of the invention, a specific embodiment thereof will now be described by way of example and with reference to the accompanying drawings, in which:
Referring to
As discussed above, the walls 20a and 20b of devices do not need to be electrochemical devices of the same type.
The container 2 has area 30 for the BoP such as water tanks, pumps, hydrogen storage etc. all not shown. Also not shown are components such as means for ventilation, sensors and more.
Referring to
Shown coupled to the string are sensors 32, and 42 for hydrogen and oxygen respectively. In order to ensure safety of outlets and ensure gases are not mixing above the lower explosive limit (LEL) the sensor for oxygen 32 may be placed on the hydrogen outlet manifold 30 and the hydrogen sensor 42 on the oxygen outlet manifold 40.
Graph 8b shows readings for the same setup with the Voltage being on the Y axis. Values must be multiplied by 5 due to the setup having 5 stacks, so a peak of approximately 210V is present. Surprisingly, the present configuration dampened the voltage swings allowing for more resilience in the system, a great benefit for a system coupled to inherently variable renewable energy sources.
In the present figures not all BoP is shown, and the present invention is not necessarily intended to be limited by such BoP.
The invention is not intended to be restricted to the details of the above described embodiment. For instance, a single system may house a variety of electrochemical stacks such as electrolysers, compressors and fuel cell. Additionally, the BoP not claimed may also vary without departing from the scope of the present invention. The feedstock or electrolyte may also differ without departing from the scope of the present invention. It will be apparent to a person skilled in the art, from the foregoing description, that various modifications can be made to the described embodiments without departing from the scope of the invention as defined by the appended claims.
Number | Date | Country | Kind |
---|---|---|---|
2103709.8 | Mar 2021 | GB | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/EP2022/057014 | 3/17/2022 | WO |