This application claims the benefit of priority under 35 U.S.C. § 119 of European Application 17181340.5, filed Jul. 14, 2017, the entire contents of which are incorporated herein by reference.
The present disclosure relates generally to control systems for a plurality of pumps, in particular a plurality of speed-controlled wet rotor centrifugal pumps. Such a plurality of pumps may be used in a pump station of a water supply network.
Typically, a pump station of a water supply network may comprise a plurality of identical or different pumps installed in parallel to each other to provide a required fluid flow q and head Δp (pressure difference). Depending on the required flow and head, there are numerous possibilities for a control system to operate a multi-pump system with N pumps, wherein N≥2. The multi-pump system may have 2N−1 different options to run the system with different subsets of pumps. However, depending on the required flow and head, the overall power consumption is not the same for all subsets. Thus, in order to run the multi-pump system with the least energy consumption, the multi-pump control system may want to choose to run the system with the subset of pumps having the least power consumption. For instance, if half of the full load capacity of a system of four identical pumps is required, the control system has one option to run all four pumps at about half load, or six options to run two pumps at about full load, or 4 options to run three pumps at about ⅔ load. Depending on the pump characteristics, one of these options may be the subset with the least power consumption.
For instance, U.S. Pat. No. 7,480,544 B2 describes a system of energy-efficient and constant-pressure fluid transport machines coupled in parallel for supplying a pipe system with known nodes and pipe sections.
US 2003/0235492 A1 relates to a method and apparatus for automatic control of multiple pumps operated either in parallel or in series.
US 2015/0148972 A1 describes a device and a method for operating multiple centrifugal pumps with determined number of pumps with least energy consumption.
All of the known control systems or methods require stored pre-knowledge of the pump characteristics provided by the pump manufacturer. However, due to manufacturing tolerances, wear and/or fouling, the real current pump characteristics may be different from the stored information in the control logic. The pump characteristics may change over time and may be different between the pumps. Thus, the control system may consider pumps as identical where in fact their current pump characteristics differ significantly. Such a misinformation leads to wrong decisions about which subset of pumps is the most energy-efficient for supplying a required flow and head.
In case the control system is to be retro-fitted to an existing multi-pump system, there may even be none or insufficient information available on the pumps in the first place. The multi-pump system may comprise different sizes or kinds of pumps, where it can be assumed that the multi-pump system comprises subsets of at least two pumps providing the same flow at the same speed. It should also be noted that a flow measurement by sensors is in general not desired, because installation and maintenance of flow sensors is expensive. Thus, there is typically only one system flow measurement or no measured current flow value at all available.
Furthermore, cutting in or out a pump in a multi-pump system always represents a certain disturbance in the fluid network. Some fluid networks are sensitive to transients in flow or pressure having a high gradient, e.g. chilling circuits. Apart from that, high gradient transients in flow or pressure are generally more energy consuming than smooth transients. It is thus desired during normal operation of the multi-pump system to minimise the disturbances caused by cutting in and out pumps.
In contrast to known multi-pump control systems, embodiments of the present disclosure provide a control system and method to smoothly cut in or out pumps of a multi-pump system in order to save power consumption due to a system disturbance by cutting in/out pumps.
In accordance with a first aspect of the present disclosure, a multi-pump control system is provided comprising a control module, a processing module, a communication interface, and a storage module, wherein the control module is configured to
Optionally, the control module may be configured to keep the total head Δp constant while ramping up/down. Optionally, the control module may be configured to ramp up/down following at least one pre-determined model curve. Parameters a, b, c, x, y and z in polynomials
wherein the parameters are indicative of an approximated pump characteristic Δp=f(q, ωj) and/or power consumption P=f(q, ωj), may be determined during configuration cycle(s) as described below and used to determine the pre-determined model curve. The speed ω0 determined during a zero flow configuration cycle may be used to coordinate the ramping up (of the k added pumps or the residual subset r) and the simultaneous ramping down (of the running subset j or the k shut-down pumps) in such way that the combined flow and pressure of all running pumps during ramping up/down is essentially constant. It is thus not necessary to react to a sudden transient in flow and/or pressure after ramping up/down, because knowledge of the pre-determined model curve facilitates avoiding such a sudden transient in the first place and to establish the desired speed, flow and pressure at the end of ramping up/down.
The approximation of the pump characteristic and/or power consumption by a second order polynomial is best around the operating points of highest efficiency, because the pump characteristic Δp=f(q, ωj) and the power consumption P=f(q, ωj) can be expected to be quite smooth around these preferred operating points. However, the approximation may be less accurate for operating points further away from the points of highest efficiency, in particular for a zero flow operation. However, a good approximation of the zero flow operation is useful for several reasons. Firstly, the approximations of the pump characteristic Δp=f(q, ωj) and/or the power consumption P=f(q, ωj) are more robust and more accurate if the points Δp=f(0,ω)≈cω02 and/or P=f(0,ω)≈zω03 are known. Secondly, as will be described below, the speed ω0 can be determined at which a pump being started up in addition to a running subset contributes to the total flow. Thirdly, knowing the parameters c and z is useful for a multi-pump system of two identical pumps, i.e. N=2, as there are only two options of running subsets with a different number of pumps i, i.e. j=1 (01 or 10) with i=1 and j=2 (11) with i=2.
Therefore, in order to determine a good approximation of the zero flow operation, the control module may be configured to
Optionally, the pressure is held essentially constant during the ramping up/down of the at least one pump. In option a), i.e. when at least one pump is ramped up in addition to an already running subset j, the subset j may provide an essentially constant pressure and the ramped-up pump does not contribute to the flow until the speed ω0 is reached, which is just sufficient to provide that constant pressure. Analogously, in option b), i.e. when at least one pump of a running subset j is ramped down, the subset j may provide an essentially constant pressure and the ramped-down pump still contributes to the flow until its speed falls below the speed ω0 which is at least necessary to provide that constant pressure. In both cases, this causes a sudden signal change that may show as a spike or steep drop in a diagram in which the speed, the pressure or the power consumption is recorded over the ramping time.
Optionally, the processing module may be configured to identify the received signal change by using a change detection algorithm, for instance a cumulative sum (CUSUM) algorithm. Optionally, the processing module may be configured to identify the received signal change by determining if the absolute value of the gradient in head Δp, speed ωj, and/or power consumption P is equal to or exceeds a pre-determined threshold value.
Thus, the parameters c and z as well as the speed ω0 may be determined by conducting one or more zero flow configuration cycles.
Optionally, the control module may be further configured to run n different subsets of i pumps of a multi-pump system comprising N pumps during n different configuration cycles at a speed ωj, wherein N≥2, 2≤n≤2N−1 and 1≤i≤N, wherein each configuration cycle j∈{1, . . . , n} is associated with a subset j∈{1, . . . , n} and a speed ωj. The communication interface may be configured to receive signals indicative of operational parameters from each subset j during the associated configuration cycle j. The processing module may be configured to determine an approximated pump characteristic Δp=f(q, ωj) based on the received signals for each subset j and under the assumption that the i pumps of each subset j share the same part q/i of a reference flow q. The storage module may be configured to store the approximated pump characteristic Δp=f(q, ωj) or parameters indicative thereof.
It should be noted that j is used herein as an index to distinguish different subsets and configuration cycles from each other. The number of pumps of a subset j is given by i. The number of configuration cycles is given by n. As the subset j changes between the configuration cycles, the same index j may be used to identify the subset and the configuration cycle. The following table may illustrate this by way of an example of a system of three pumps of the same type and size. The status of all pumps may be illustrated by a binary number with N bits, where each bit represents a pump, i.e. 0 means “off”, 1 means “on”, and the binary weight represents the number i of pumps in the running subset j:
The number n of configuration cycles depends on how precisely the pump characteristic Δp=f(q, ωj) is to be approximated. In the example of the above table, there are three options to run the first (j=1) configuration cycle with one (i=1) pump running. There are also three options to run the second (j=2) configuration cycle with two (i=2) pumps running. Preferably, the number i of running pumps may differ between the configuration cycles. In particular, if it can be assumed that all pumps have the same, but unknown pump characteristic, the following second-order polynomial may be used as an approximation:
where a, b and c are parameters indicative of the pump characteristic. The reference flow q may be a measured or a normalised value, i.e. it may be arbitrarily set to q=1. The speed ωj is an operational parameter received by the communication interface from each subset j during the associated configuration cycle j. The head Δpj may be measured by a pressure sensor and received by the communication interface as an operational parameter during the associated configuration cycle j. Alternatively or in addition, the speed ωj may be set to achieve a certain head Δpj and to keep the head Δpj=Δp constant for all n configuration cycles. Thereby, the configuration cycles allow an approximation of the current pump characteristic for determining which subset of pumps is the most energy-efficient to provide a required flow q and head Δp.
Optionally, the processing module may be configured to determine an approximated pump power consumption P=f(q, ωj) based on the received signals for each subset j and under the assumption that the i pumps of each subset j share the same part q/i of the reference flow q, wherein the storage module may be configured to store the approximated power consumption P=f(q, ωj) or parameters indicative thereof. Analogously to the pump characteristic Δp=f(q, ωj), in particular if it can be assumed that all pumps of a subset have the same, but unknown power consumption, the following second-order polynomial may be used as an approximation:
where x, y and z are parameters indicative of the power consumption. Thus, the approximated power consumption may be used as an alternative or in addition to the approximated pump characteristic for determining which subset of pumps is the most energy-efficient to provide a required flow or head.
Thus, optionally, the processing module may be configured to determine a subset k with the least power consumption for a required load based on the approximated power consumption P=f(q, ωj) and/or the approximated pump characteristic Δp=f(q, ωj) stored in the storage module. Consequently, the control module may be configured to operate the multi-pump system with the determined subset k having the least power consumption for a required load.
Optionally, the control module may be configured to run the i pumps of a subset j with the same speed ωj during a configuration cycle j, wherein the speed ωj of the i pumps of subset j in configuration cycle j differs from the speed (Ok of s pumps of a subset k in another configuration cycle k, wherein j≠s, wherein a total head Δp generated by the multi-pump system is essentially the same for both configuration cycles j, k. In other words, the speeds ωj and Wk may be set to achieve a certain constant head Δpj=Δpk=Δp for all n configuration cycles.
Optionally, the processing module may be configured to determine the approximated pump characteristic Δp=f(q, ωj) and/or power consumption P=f(q, ωj) by a least squares method if the number n of configuration cycles is equal to or exceeds the number of parameters to be determined. Thus, if the parameter set is overdetermined, “averaged” parameters may be found by a polynomial regression analysis or a similar statistical technique to exploit the redundant information from the configuration cycles. Thereby, wear, fouling, other forms of efficiency degradation or differences between the pumps due to manufacturing tolerances may be smoothed and thereby taken in consideration.
Furthermore, outliers may be determined during redundant configuration cycles in order to neglect those in the averaging and/or to identify and ban low efficiency pumps of the multi-pump system. Such identified low efficiency pumps may be indicated for service, repair or replacement.
In accordance with a second aspect of the present disclosure, a method for controlling a multi-pump system is provided comprising
Optionally, the method may comprise keeping the total head Δp constant while ramping up/down. Optionally, the ramping up/down follows at least one pre-determined model curve.
For instance, in option a), the head may be parametrised for the subset j with i running pumps before the k pumps have reached the speed ωm as follows:
wherein qj is the flow provided by the subset j before the k added pumps contribute to the flow. The pressure differential provided by the k added pumps may be parametrised as
wherein qk is the flow provided by the k added pumps before they contribute to the flow. It is most likely that only one pump is desired to be added to the subset j such that k=1 and Δp1=aq12+bq1ω1+cω12. After the ramp-up, the subset j is expected to provide
of the total flow q, whereas the added pump is expected to provide
of the total flow q. However, before the added pump has reached the speed ωm, the subset j is expected to provide all of the total flow q, whereas the added pump is expected to provide none of the total flow q. This may be displayed as:
wherein qjs is the flow contribution of the subset j at the start of the ramp-up, qje is the flow contribution of the subset j at the end of the ramp-up, q1s is the flow contribution of the added pump at the start of the ramp-up, and q1e is the flow contribution of the added pump at the end of the ramp-up. The rate of change between qjs and qje may be set to the same rate of change as the rate of change between q1s and q1e by following the conditions:
qj=qjs+(qje−qjs)α
q1=q1s+(q1e−q1s)α,
wherein the ramping parameter a ranges from 0 at the start of the ramp-up to 1 at the end of the ramp-up. The combined total flow q is always the sum of qj and q1 and thus constant during the ramp-up for all values of a. Also the total head Δp is constant during the ram-up for all values of a. The corresponding speeds ωj and ω1 may be determined as follows:
wherein both final speeds ωje and ω1e are the same and equal ωm at the end of the ramp-up, i.e. when α=1, wherein the subset m with i+1 pumps is running after the ramp-up. The above example is analogously valid for option b), in which one or more pumps of the subset j are ramped-down.
Optionally, the method may further comprise
Optionally, the total head and/or flow may be held essentially constant during the ramping up/down of the at least one pump. In option a), i.e. when at least one pump is ramped up in addition to an already running subset j, the subset j may provide an essentially constant pressure and the ramped-up pump does not contribute to the flow until the speed ω0 is reached, which is just sufficient to provide that constant pressure. Analogously, in option b), i.e. when at least one pump of a running subset j is ramped down, the subset j may provide an essentially constant pressure and the ramped-down pump still contributes to the flow until its speed falls below the speed ω0 which is at least necessary to provide that constant pressure. In both cases, this causes a sudden signal change that may show as a spike or steep drop in a diagram in which the speed, the pressure or the power consumption is recorded over the ramping time.
Optionally, the received signal change may be identified by determining if the absolute value of the gradient in head Δp, speed ωj, and/or power consumption P is equal to or exceeds a pre-determined threshold value. Optionally, a change detection algorithm, for instance a cumulative sum (CUSUM) algorithm, is used for identifying the received signal change.
A CUSUM algorithm is particularly useful for detecting changes in the mean value of a signal. For instance, in view of a signal diagram over time, wherein the speed, the pressure or the power consumption is the signal, the positive and negative signal differences from its mean may be summed up to a monitored quantity. If the monitored quantity is equal to or exceeds a certain threshold, the mean value can be interpreted to have changed. In order to allow for some signal noise without exceeding the threshold by noise, a constant amount may be subtracted/added from the monitored quantity for each sample. The CUSUM logic for each signal may be described be the following equations:
wherein Jω is the monitored quantity for the speed ω, and JΔp is the monitored quantity for the head Δp. The signals are here normalised as well as the constant amounts γω and γΔp. The difference in sign between Jω and JΔp is due to the fact that the speed co is expected to suddenly decrease when the ramped-up pump starts contributing to the flow q, whereas the head Δp is expected to suddenly increase by this disturbance. Thresholds βω and βΔp may be defined to check if either Jω<−βω and/or JΔp>βΔp, and, once this is the case, to use the current values of ω and Δp to solve the following equations for determining parameter c:
The determination of parameter z may analogously be based on the second order polynomial approximation of the power consumption.
Optionally, the method may further comprise
Optionally, the method may comprise determining an approximated pump power consumption P=f(q, ωj) based on the received signals for each subset j and under the assumption that the i pumps of each subset j share the same part q/i of the reference flow q, and storing the approximated power consumption P=f(q, ωj) or parameters indicative thereof.
Optionally, the method may comprise determining a subset k with the least power consumption for a required load based on the approximated power consumption P=f(q, ωj) and/or the approximated pump characteristic Δp=f(q, ωj) stored in the storage module. Optionally, the method may comprise operating the multi-pump system with the determined subset k having the least power consumption for a required load.
For instance, once the approximated pump characteristic Δp=f(q, ωj) is determined, it may be used to determine the most energy efficient number of pumps for operating the multi-pump system. This may even be independent of the required load, i.e. required flow and pressure. The flow can in principle be determined from either the approximated pump characteristic Δp=f(q, ωj) or the approximated power consumption P=f(q, ωj), however each may yield two solutions due to quadratic terms if a second order polynomial is used as approximation. It is thus preferred to use a combination of Δp=f(q, ωj) and P=f(q, ωj) so that quadratic terms cancel out and leave only a single solution. This is shown in equations:
As all subsets j with the number of i pumps may be considered equivalent to each other, the speed ωj is denoted here as ωi, i.e. the speed of any subset j with i pumps. The flow q in the last equation can potentially be undefined if xb=ay, which would mean that Δp=f(q, ωi) and P=f(q, ωi) both have their maximum at the same flow q. This is generally not the case, as the power consumption tends to have its maximum at high flows, whereas the head Δp is usually maximal at low flows. Once q is determined by the equation above, it may be calculated whether it is more energy efficient to run the multi-pump system with one more or one less pump. In order to do this comparison, the resulting speed may be determined for both cases by:
Which may have two solutions, of which one can be ruled out, so that:
In order to obtain the expected speed ωi+1, i.e. the speed of any subset j with i+1 pumps, and the expected speed ωi−1, i.e. the speed of any subset j with i−1 pumps, the parameter i is replaced by i+1 and i−1, respectively, in the above equation.
Having determined the expected speeds ωi+1 and ωi−1, the corresponding power consumption P=f(q, ω1) may be calculated. It is then possible to determine which of the following options consumes least power: 1. continuing running with the i pumps of subset j as is, 2. adding another pump to the subset j, or 3. switching off one pump of subset j. The decision logic for finding the optimal number i of running pumps may be summarised as follows:
Herein, P(q, i, ωi) may be the current power consumption of the running subset j of i pumps so that it may be received as a current measured value, whereas the predicted values P(q, i−1, ωi−1) and P(q, i+1, ωi+1) may be determined from the approximated power consumption P=f(q, ωi).
The above determination of whether it is more energy-efficient to run with one more or one less pump than with the current number of running pumps is a simple example for making use of the approximated pump characteristics and the approximated power consumption in order to run the multi-pump system more energy-efficiently. However, the configuration cycles also allow recording of parameter sets for any subset j, so that it is possible to determine the exact subset of pumps which consumes least power for a required load. For instance, one of the four options of running a subset of three out of four pumps may have shown to consume less power than the other three options. Therefore, not only the optimal number of running pumps may be determined, but also which exact subset to choose for it. However, this may change over time and with operating hours due to wear. In order to take such changes into account, regular runs of configuration cycles allow updating the approximated pump characteristics and/or the approximated power consumption.
Optionally, the above algorithm may comprise two constraining criteria, of which one avoids exceeding the maximum power of a pump and the other prevents a violation of minimum flow. In regard of the first constraint, some pumps may be equipped with a variable frequency drive (VFD) that cannot drive the pump at full speed under all conditions without violating the VFD's maximum power. If the above algorithm finds that a subset of i−1 pumps consumes less power, the remaining i−1 pumps must not exceed the VFD's maximum power, which is sometimes not known beforehand. In case the VFD's maximum power is not known, it can be determined in one or more of the configuration cycles by recording the power consumption the first time the actual speed of a pump does not follow the set speed, because the VFD's maximum power is reached. The decision algorithm may thus take the recorded maximum power into account by not ramping down a pump if the residual subset of i−1 pumps would exceed the maximum power per pump.
Regarding the second constraint, the fluid in some pumps, in particular multistage centrifugal pumps, i.e. so-called CR pumps, must not become too hot and thus a minimal flow is required. However, the flow may be an unknown quantity in an arbitrary unit in the above process and may be cut in half per pump if a pump is added to a running subset of one pump, or reduced by a third per pump if a pump is added to a running subset of two pumps. Therefore, it may not be guaranteed that sufficient flow is available for each pump. However, the flow may be “calibrated” to the unit m3/s by estimating it in a conservative way, i.e. a minimum flow may be estimated that lies below the real flow. This can be done by fairly assuming that the efficiency is above 50% at the maximum of the power consumption. At the maximum of the power consumption, the normalised flow can be deduced from the parameters as follows:
This flow may be fed into the equations for Δp and P, wherein the efficiency e is conservatively assumed to be 50% and a scaling ratio α is introduced as follows:
which yields the following calibrating conditions:
a=α2a
b=αb
c=c
x=α2x
y=αy
z=z
Under these conditions, if the efficiency was 50% at the point of maximum power, the approximated flow would be given in the unit m3/s. If the real efficiency is higher, the real flow is also higher. In case the point of maximum power violated the VFD's maximum power, the VFD's maximum power may be used yielding two solutions for the flow of which the lower solution may be conservatively chosen to be fed into the equations for Δp and P as above. Thereby, the algorithm may ensure that always a sufficient flow is available per pump.
Optionally, the method may comprise running the i pumps of a subset j with the same speed ωj during a configuration cycle j, wherein the speed ωj of the i pumps of subset j in configuration cycle j differs from the speed (Ok of s pumps of a subset k in another configuration cycle k, wherein j≠s, wherein a total head Δp generated by the multi-pump system is essentially the same for both configuration cycles j, k.
Optionally, the method may comprise determining the approximated pump characteristic Δp=f(q, ωj) by determining parameters a, b and c of a second order polynomial
wherein ωj is the speed of the i pumps of a subset j. Alternatively or in addition, the method may comprise determining the approximated power consumption P=f(q, ωj) by determining parameters x, y and z of a second order polynomial
wherein ωj is the speed of the i pumps of a subset j.
Optionally, the method may comprise determining the approximated pump characteristic Δp=f(q, ωj) and/or power consumption P=f(q, ωj) by a least squares method if the number of configuration cycles is equal to or exceeds the number of parameters to be determined. Thus, if the parameter set is overdetermined, “averaged” parameters may be found by a polynomial regression analysis or a similar statistical technique to exploit the redundant information from the configuration cycles. Thereby, wear, fouling, other forms of efficiency degradation or differences between the pumps due to manufacturing tolerances may be smoothed and thereby taken in consideration. Furthermore, outliers may be determined during redundant configuration cycles in order to neglect those in the averaging and/or to identify and ban low efficiency pumps of the multi-pump system. Such identified low efficiency pumps may be indicated for service, repair or replacement.
The method described above may be implemented in form of compiled or uncompiled software code that is stored on a computer readable medium with instructions for executing the method on a computer or one or more processors including one or more processors as a part of the pump system and one or more cloud-based system processors. Alternatively or in addition, the method may be executed by software in a cloud-based system, i.e. one or more of the modules of the controls system, in particular the processing module may be implemented in a cloud-based system comprising one or more processors. The control system is implemented with one or more computers and/or circuitry comprising one or more processors and memory to provide the processing module, the communication interface, the storage module and the control module. The one or more processors and data storage (memory) may be at the location of the pump system or may be a part of a cloud-based system or may comprise processors at the location of the pump system and that are a part of a cloud-based system with communication between features at the pump system and at the cloud-based system.
The present invention will be described in detail below with reference to the attached figures. The various features of novelty which characterize the invention are pointed out with particularity in the claims annexed to and forming a part of this disclosure. For a better understanding of the invention, its operating advantages and specific objects attained by its uses, reference is made to the accompanying drawings and descriptive matter in which preferred embodiments of the invention are illustrated.
In the drawings:
A multi-pump control system 5, comprising a control module 7, a processing module 9, communication interface 11, and a storage module 13, is in direct or indirect, wireless or wired communication connection with the pumps 3a, 3b, 3c, 3d. The communication interface 11 is configured to send signals to and receive signals from the pumps 3a, 3b, 3c, 3d. The processing module 9 is configured to process received signals and to execute calculations based on the received signals. The storage module 13 is configured to store the results of the calculations. The control module 7 is configured to control the pump operation based on the stored results by commands via the communication interface 11 to the pumps 3a, 3b, 3c, 3d. It should be noted that the control module 7, the processing module 9, the communication interface 11, and the storage module 13 may be physically distributed over the system 5 which does not have to be physically comprised within a single unit. Two or more of the modules may be combined, so that the functionality of more than one module is provided by a combined module.
For instance, the multi-pump control system 5 may constantly, regularly or sporadically check if a currently running subset of pumps is the most energy efficient operating mode to provide a required total flow q and a required total head Δp to the fluid network 1. The required total flow q and the required total head Δp may be summarised by a required total load. For example, the four pumps 3a, 3b, 3c, 3d may be able to provide a certain maximum load, of which only 75% is currently required by the fluid network 1. The multi-pump control system 5 may thus run three pumps at maximum speed having four options which of the pumps to shut down, e.g. 3d. Another option would be to run all four pumps 3a, 3b, 3c, 3d at 75% of their maximum speed. Assuming that all pumps of a running subset should run at the same speed, the multi-pump control system 5 has now five options which all may show different power consumptions.
However, running the system most energy-efficiently is not a trivial task if there is no flow measurement available and the current pump characteristics are unknown. For instance, the pump characteristics may not be given if the multi-pump control system 5 is retro-fitted to an already installed multi-pump system 3. Even if they were originally known, they could show unknown manufacturing variances, or may have changed over time due to degradations, wear, or fouling. The trick is thus to identify the most energy-efficient subset for a required load in lack of information on the current flow and the current pump characteristics.
In order to approximate the pump characteristics, the control module 7 is configured to run a certain number, i.e. n, of different configuration cycles. Each configuration cycle may be labelled with the index j. Each configuration cycle is run with a different subset of the pumps 3a, 3b, 3c, 3d. As the subset should change between the configuration cycles to gain information, each subset may be labelled with the same index j. With N=4 being the total number of pumps in the multi-pump system 3 and i as the number of pumps in the subset j, the following conditions apply: N≥2, 2≤n≤2N−1 and 1≤i≤N. During each configuration cycle, the i pumps of the subset j are run at the same constant speed ωj. The speed is adapted between the configuration cycles to maintain the same total head, i.e. pressure differential Δp. The measured and monitored pressure differential Δpj and the recorded speed ωj is communicated to the control module 7 by the communication interface 11, which is configured to receive signals indicative of operational parameters from each subset j during the associated configuration cycle j. The processing module is configured to determine an approximated pump characteristic in form of a second order polynomial
based on the assumption that the i pumps of each subset j share the same part q/i of a reference flow q. The reference flow q may be a measured or a normalised value, i.e. it may be arbitrarily set to q=1. The storage module is configured to store the approximated pump characteristic or the parameters indicative thereof, i.e. a, b and c.
Furthermore, in each configuration cycle the power consumption Pj=f(q, ωj) is approximated by a second order polynomial
based on the assumption that the i pumps of each subset j share the same part q/i of a reference flow q. The parameters x, y and z are parameters indicative of the power consumption and stored in the storage module.
Thus, the six parameters a, b, c, x, y, and z can be determined from the six equations yielded by three configuration cycles with subsets of a different number of pumps. So, preferably, the number of running pumps i should change between the cycles. If the multi-pump system comprises only two pumps, i.e. N=2, a zero flow configuration cycle (further explained below) may be used to pre-determine the parameters c and z, so that the remaining four parameters are well determined by the four equations yielded by running a first configuration cycle with one pump and a second cycle with two pumps.
The following table may illustrate the options of running configuration cycles for the system 3 of four pumps 3a, 3b, 3c, 3d as shown in
Running more than three configuration cycles will over-determine the parameter set. The total number of permutations for running subsets is 2N−1, i.e. in this case 24−1=15. In order to take differences between pumps into account caused by manufacturing tolerances, wear or fouling, more than three configuration cycles allow an “averaging” over the pumps. Thereby, the approximation may be closer to the real pump characteristics of the pump system.
The simple case of running three configuration cycles, e.g. the first cycle (j=1) with one (i=1) pump, the second cycle (j=2) with two (i=2) pumps and the third cycle (j=3) with three (i=3) pumps, may be implemented as an algorithm (here as a c-style meta language) as follows:
More than three configuration cycles may be implemented as an algorithm (here as a c-style meta language) as follows:
In the above example for N=4 pumps, the algorithm would produce four cycles with one pump, six cycles with two pumps and four cycles with three pumps, i.e. in sum 14 cycles. A least squares method can be used to find average values for the parameters a, b c, x, y and z. Furthermore, outliers may be determined during redundant configuration cycles in order to neglect those in the averaging and/or to identify and ban low efficiency pumps of the multi-pump system 3. Such identified low efficiency pumps may be indicated for service, repair or replacement. It is preferred to run only subsets of three pumps, because cycles with subsets of many pumps only differ marginally from cycles with subsets of one more or less pump. In principle, however, the configuration cycles can be run with any number of pumps i N.
Before a zero flow configuration cycle of the multi-pump system 3 with the four pumps 3a, 3b, 3c, and 3d, only a subset of three pumps 3a, 3b and 3c may be running at a speed ωj while pump 3d is not running. During the zero flow configuration cycle, pump 3d is ramped-up in speed. As long as the pressure differential provided by the current speed of pump 3d is below the total head Δp, pump 3d does not contribute to the total flow. Once the communication interface 13 receives a signal change indicative of the at least one pump starting to contribute to the total flow, the current speed ω0 of pump 3d is recorded in the moment the pump 3d starts to contribute to the total flow. The parameter c can then be determined from Δp=cω02. The parameter c determined in the zero flow configuration cycle may be used to improve the polynomial approximations as shown by solid lines in
Optionally, the total head and/or flow may be held essentially constant during the ramping up/down of the at least one pump as shown in
Optionally, the received signal change is identified by determining if the absolute value of the gradient in head Δp, speed ωj, and/or power consumption P is equal to or exceeds a pre-determined threshold value. Optionally, a change detection algorithm, for instance a cumulative sum (CUSUM) algorithm, is used for identifying the received signal change.
A CUSUM algorithm is particularly useful for detecting changes in the mean value of a signal. For instance, in view of a signal diagram over time, wherein the speed, the pressure or the power consumption is the signal, the positive and negative signal differences from its mean may be summed up to a monitored quantity. If the monitored quantity is equal to or exceeds a certain threshold, the mean value can be interpreted to have changed. Alternatively or in addition, the absolute value of the gradient in head Δp, speed ωj, and/or power consumption P may be measured and compared with a pre-determined threshold value. If the threshold value is reached or exceeded, the sudden signal change is indicative of the at least one pump starting to contribute to the total flow.
The disturbance is useful in the zero configuration cycle, but not desired for the normal pump operation when, for instance, the control unit decides that the system would consume less power with an additional pump, and therefore ramps up another pump. In this normal operation, optionally, the control module may be configured to ramp up the speed of the pump 3d in addition to the subset of the three pumps 3a, 3b, 3c running at speed ωj providing a total head Δp, and simultaneously to ramp down the three pumps 3a, 3b, 3c from the speed ωj to a lower speed ωm, wherein the speed ωm is the speed required for the new subset of four pumps to provide the total head Δp. Such a simultaneous convergence of speeds is shown in
Knowledge of the speed ω0 and the approximated power consumption P=f(q, ωj) and/or the approximated pump characteristic Δp=f(q, ωj) may allow for the control module to ramp up/down following at least one pre-determined model curve. Thereby, the time for convergence after the added pumps actively joins in contributing flow can be significantly reduced, because the final speed ωm can be predicted. Following the pre-determined model curve may automatically result in a constant total head Δp and/or the total flow for all values of a. Therefore, no feedback-loop for controlling based on monitored measured values may be needed.
If one or more pumps of a running subset are ramped down, the way back from parameter a at a value of 1 (start of the ramping) to 0 (end of the ramping) follows analogously. Similarly, also the zero flow configuration cycles may be run by ramping one or more pumps of a running subset down and recording the speed at which the ramped-down pump(s) suddenly stop contributing to the total flow.
The method as shown in
A subset k with the least power consumption for a required load is then determined (715) based on the approximated power consumption and/or the approximated pump characteristic stored in the storage module 13. The multi-pump system is then operated (717) by the determined subset k having the least power consumption for a required load. When it is energetically more efficient to change the running subset to i+1 or i−1 pumps, another pump may be smoothly cut in/out (719) by either:
Where, in the foregoing description, integers or elements are mentioned which have known, obvious or foreseeable equivalents, then such equivalents are herein incorporated as if individually set forth. Reference should be made to the claims for determining the true scope of the present disclosure, which should be construed so as to encompass any such equivalents. It will also be appreciated by the reader that integers or features of the disclosure that are described as optional, preferable, advantageous, convenient or the like are optional and do not limit the scope of the independent claims.
The above embodiments are to be understood as illustrative examples of the disclosure. It is to be understood that any feature described in relation to any one embodiment may be used alone, or in combination with other features described, and may also be used in combination with one or more features of any other of the embodiments, or any combination of any other of the embodiments. While at least one exemplary embodiment has been shown and described, it should be understood that other modifications, substitutions and alternatives are apparent to one of ordinary skill in the art and may be changed without departing from the scope of the subject matter described herein, and this application is intended to cover any adaptations or variations of the specific embodiments discussed herein.
In addition, “comprising” does not exclude other elements or steps, and “a” or “one” does not exclude a plural number. Furthermore, characteristics or steps which have been described with reference to one of the above exemplary embodiments may also be used in combination with other characteristics or steps of other exemplary embodiments described above. Method steps may be applied in any order or in parallel or may constitute a part or a more detailed version of another method step. It should be understood that there should be embodied within the scope of the patent warranted hereon all such modifications as reasonably and properly come within the scope of the contribution to the art. Such modifications, substitutions and alternatives can be made without departing from the spirit and scope of the disclosure, which should be determined from the appended claims and their legal equivalents.
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17181340 | Jul 2017 | EP | regional |
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Entry |
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Machine translation (generated Dec. 12, 2019) of EP 0735273A1 (Year: 1996). |
Machine translation (generated Dec. 17, 2019) of EP 2469094A2 (Year: 2012). |
Number | Date | Country | |
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20190017511 A1 | Jan 2019 | US |