This application claims priority from Japanese Patent Application No. 2017-219707 filed on Nov. 15, 2017 and Japanese Patent Application filed on Nov. 14, 2018, the entire subject matters of which is incorporated herein by reference.
The present disclosure relates to a chromatographic data system processing apparatus, and particularly to a quantitative analyzing apparatus for searching a separation condition of a liquid chromatography.
Literature 1: Masahito ITO, Katutoshi SHIMIZU, and Kiyoharu NAKATANI, “ANALYTICAL SCIENCE”, The Japan Society for Analytical Chemistry, February 2018, Vol. 34, p. 137-141
Literature 2: Stephen. R. Groskreutz, and Stephen. G. Weber, “Analytical Chemistry”, ACS Publications, 2016, Vol. 88, p. 11742-11749
In order to understand a relationship between an analysis time and separation performance of HPLC (High Performance Liquid Chromatography), the shown-above Literature 1 based on WO 2014/030537 1 can be cited. A pressure drop ΔP (Pa) and a hold-up time t0 (s) are input as two independent variables, and a number of theoretical plates N is output as one function of N (ΔP, t0) or N (Π, t0). Essentially, ΔP corresponds to a next velocity length product Π (m2/s) (represented by Cf in WO 2014/030537).
Here, KV (m2) represents a column permeability, ρ (Pa·s) represents a viscosity, u0 (m/s) represents a linear velocity of a non-retaining component, and L (m) represents a column length.
There is the shown-above Literature 2 for the same purpose. As shown in FIG. 1, the above function N on a z axis is expressed as N (u0, L) by another basal plane.
An HPLC user generally determines the column length L and then searches for the separation condition by a manipulation of changing the flow rate F. The pressure drop ΔP and the hold-up time t0 are obtained as measurement results reflecting F and L of the segregation condition searched. It is considered that this separation condition F and L is a cause system. Compared to the separation condition of F and L, ΔP and t0 are considered to be result indexes obtained therefrom. As described in WO 2014/030537, for example, an analytical operator firstly expects to grasp a relationship between the result indexes ΔP and t0 and the number of theoretical plates N obtained at that time. In other words, the analytical operator expects to analyze at what degree of ΔP, N indicating a high speed t0 and separation performance can be obtained.
For another example, when identifying each separated analyte for the property of HPLC, since a retention time after establishing the separation condition is used, in actual examination of the separation condition, t0 and the retention time of each analyte are verified.
In addition, a method of searching for a condition by three-dimensional graphing ΔP, t0 and N is proposed (WO 2014/030537). As factors of the separation condition search, ΔP and t0 can be direct judgment factors, as described above. However, as a related condition examination method, quantitative analysis is difficult for the HPLC user familiar with the column length L and the flow rate F. F is a speed related index that is proportional to the aforementioned u0, and ΔP is an intensity related potential capability index that is proportional to the aforementioned velocity length product Π.
In JP-A-2009-281897, transfer methods on how to transfer from HPLC to UHPLC or vice versa are described. Although only ΔP is considered by an optimization method of L and F, there was a problem that t0 is not sufficiently considered and N cannot be calculated either.
There is also a problem that ΔP, to and N cannot be quantitatively grasped to a physiographic profile of the three-dimensional graph.
In order to solve the above problems, a chromatographic data system processing apparatus is provided, which can quantitatively analyze ΔP, t0 and N by introducing an efficiency which is a new dimensionless index on a slope of a three-dimensional space representing a column length L, a linear velocity u0 and a number of theoretical plates N, and applying standardization based on an optimum linear velocity u0,opt, in other words, which can easily obtain a separation condition for obtaining performance from a three-dimensional graph including ΔP, t0 and N.
In order to solve the above problems, a chromatographic data system processing apparatus according to the present disclosure includes:
a liquid feeder configured to feed a mobile phase;
a sample injector configured to inject a sample into a mobile phase flowing path into which the mobile phase is fed;
a column configured to separate the injected sample;
a detector configured to detect the separated analytes;
a controller configured to process a detected result of the detector;
a data processor configured to examine and set operations of the liquid feeder, the column and the detector, and a measurement condition,
in which the data processor generates a three-dimensional graph having three axes related to a pressure, a time, and a number of theoretical plates based on data or variables indicating a relationship between the number of theoretical plates and a flow rate, and data or variables indicating a relationship between the pressure and the flow rate to analyze a separation condition from the generated three-dimensional graph.
In order to solve the above problems, a chromatographic data system processing apparatus, includes:
a liquid feeder configured to feed a mobile phase;
a sample injector configured to inject a sample into a mobile phase flowing path into which the mobile phase is fed;
a column configured to separate the injected sample;
a detector configured to detect the separated analytes;
a controller configured to process a detected result of the detector; and
a data processor configured to examine and set operations of the liquid feeder, the column and the detector, and a measurement condition,
in which, in a process of selecting two variables for axes from four variables related to a linear velocity, a length, a pressure and a time to analyze a separation condition, the data processor transforms the axes of the selected two variables into axes of two variables not selected.
In order to solve the above problems, a chromatographic data system processing apparatus, which analyzes and processes data of an analysis condition and a detection result of a chromatograph, outputs a three-dimensional graph having three axes related to a pressure, a time, and a number of theoretical plates based on data or variables indicating a relationship between the number of theoretical plates and a flow rate, and data or variables indicating a relationship between the pressure and the flow rate to analyze a separation condition from the output three-dimensional graph.
The present disclosure provides the chromatographic data system processing apparatus for easily transforming a representation form from a three-dimensional graph T2 (Π, t0, N) representing a result requested as a performance by a user to a causal three-dimensional graph T1 (u0, L, N) to be searched for as a separation condition. This is an LRT (Logarithmically Rotational Transformation) transformation from (Π, t0) to (u0, L) of a basal coordinate (x, y). T1 and T2 represent three-dimensional partial spaces, where T1 represents a vector space expressed by (u0, L, N), and T2 represents a vector space expressed by (Π, t0, N).
Next, the chromatographic data system processing apparatus outputs an index PAE (Pressure-Application Efficiency) that a user can quantitatively grasp whether the performance to be obtained is the performance corresponding to application of pressure or whether the inefficient pressure increases. The Pressure-Application Efficiency μN/Π (Π, t0) is standardized to 1 when the linear velocity is an optimal u0,opt. μt/Π (Π, t0) is the PAE for t0 which divides μN/Π (Π, t0) by μN/t (Π, t0). Although on a slope on a higher pressure side, i.e., a higher flow rate side than the line of u0,opt, the efficiency is 1 or less, the efficiency gradually inclines (changes) and not largely decreases. That is, an increase in number of theoretical plates per pressure can be expected with a good efficiency that is almost equal to an ideal u0,opt. For example, as one of guidelines, it is possible to search for a separation condition as a practical range of μN/Π of 0.5 or more as a practical range as long as the constant separation performance is allowed in a high-speed analysis time area which is not ideal. This is an advantage of quantitatively overlooking μN/Π in all areas on a basal coordinate (Π, t0).
In the accompanying drawings:
Hereinafter, the Literature 1 and the Literature 2 will be mathematically unified, and disclosures according to an invention devised from the understanding based on the mathematical unification will be shown.
As one of the disclosures, Logarithmically Rotational Transformation (LRT) based on a logarithmic axis representation such as log Π.
t0 described above is expressed by Equation 2 using the variables u0 and L in the above Equation 1.
The Equations 1 and 2 are logarithmic representations and can be represented into Equations 3 and 4.
Equations 3 and 4 can be represented in a matrix notation and can be regarded as a kind of axis rotational transformation (Equation 5).
This means that N (u0, L) can rotate to N (Π, t0) through a logarithm, that is, coordinate conversion can be performed. Since the logarithm can be returned to an antilogarithm, it is a one-to-one mapping from a basal plane (u0, L) to a basal plane (Π, t0), and vice versa. Precisely, it is a bijective linear transformation that multiplies the rotational transformation by a scalar magnification √2. It is regarded that the three-dimensional graph of N (u0, L) is different from the three-dimensional graph of N (Π, t0) only in the axis to be expressed, and contents to be expressed are equivalent. However, this relationship is an intuitive representation for the first time being represented on the logarithmic axis. Mathematically, from an idea that links a relationship of a mathematical product and a quotient between u0 and L to a relationship of a sum and a difference between them through logarithm, a representation easy to understand can be obtained. In the Literature 1, a target is considered to be a five-dimensional space V (u0, L, Π, t0, N), but according to the present disclosure, the target is divided into two three-dimensional partial spaces T1 (u0, L, N) and T2 (Π, t0, N), as shown in
As for the way to see chromatography, T1 (u0, L, N) is a space represented by a three-dimensional graph showing N obtained by first fixing separation conditions such as a mobile phase, an analytical specie and a column temperature under a precondition of an optional column filler and freely changing u0 and L. In response to this, T2 (Π, t0, N) is a transformation destination from the basal coordinate of u0 and L to the basal coordinate Π and t0. That is, two-dimensional degrees of freedom of u0 and L are inherited to all degrees of freedom of Π and t0. If there is a certain column, L is constant but u0 is variable. It is understood that, if u0 is moved, not only to but also Π changes accordingly, so that all sets of u0 and L correspond to sets of Π and t0.
WO 2014/030537 describes KPA (Kinetic Plot Analysis), that is, KPL (Kinetic Performance Limit). KPL can be regarded as representing a cross section (t0, N) at a certain Π when T2 (Π, t0, N) is cut with the certain Π. When u0 is changed using a column of a certain L, the N (u0) curve at the certain L is drawn on a (u0, N) plane of the certain L. Further, a T1 (u0, L, N) space is obtained by sweeping the above L. Since it is a surjection from T1 (u0, L, N) to T2 (Π, t0, N), it is clearly determined that a set of (u0, L) to a set of (Π, t0) is a one-to-one correspondence. That is, a two-dimensional graph (t0, N) indicated by KPL is a cross section (t0, N) of a certain Π in the (t0, N) space, and each point indicated by a curve N (t0) or t0 (N) of the specific Π expressed by KPL always goes back to coordinates somewhere in the original T1 (u0, L, N) space. The mapping point of the T2 (Π, t0, N) space never goes out of the T1 (u0, L, N) space and never duplicates. KPL is a cross section in the T2 (Π, t0, N) space at a specific Π, and original elements thereof are necessarily provided in advance in the T1 (u0, L, N) space.
In
A circle shown on the three-dimensional graph in
It can be understood that this is a reversible relationship indicating a transfer from a resultant T2 representation form required as performance to a causal representation form of T1 to be answered as a separation condition or a transfer in a reverse direction. The LRT can easily provide the basal coordinates of Π and t0, which can be obtained as a result that an analysis operator cannot immediately estimate by just looking at the cause setting variables u0 and L. Here, the basal coordinate referred to corresponds to a basal plane of a three-dimensional graph. z on a vertical axis is set as N, and the basal coordinate (x, y) is (u0, L) or (Π, t0).
Further, since the column length L available to general users is discrete as 50 mm, 100 mm, and 150 mm, there is an advantage that a cause input L of T1 can be discretely expressed and u0 can be evaluated continuously can be evaluated. Since this T1 can be LRT-transformed to a three-dimensional graph of T2, a discrete representation can correspond to the T2 graph one-to-one, as a performance result. This is a very convenient representation for the users as a real solution. The operation and representation form of a chromatography data system (CDS) related to these three-dimensional graphs can correspond not only to a bidirectional transformation of LRT but also a bidirectional transformation between a logarithm and an antilogarithm and a discrete representation of L. In addition, when the user indicates an arbitrary point on the three-dimensional graph, three sets of values of (u0, L, N) and (Π, t0, N) can be shown. When arbitrary two points are indicated, a difference between the three axial directions can also be expressed. For example, an increment of N is an increment of Π and t0.
The logarithmically rotational transformation LRT is generalized and extended. Variables are generalized with xi and four variables of i=1, 2, 3, 4 are introduced when x1=u0, x2=L, x3=Π, and x4=t0. In the four variables, Equation 1 and Equation 2, that is, Equation 6 and Equation 7, have a subordination relationship, and since there are four variables and two equations, there two independent variables. The number of combinations of selecting two variables from the four variables is 6 of 4C2.
In addition, when making a three-dimensional graph, two independent variables can be assigned to a first dimension axis and a second dimension axis, such as a basal coordinate (xi, xj). At this time, if the order of the first dimension axis and the second dimension axis is distinguished, there are 12 combinations of the permutation number 4P2. As described above, a logarithmic representation such as log x1 can be used for the basal coordinate. Up to here, the z axis is discussed with respect to N, but other functions can be introduced as a similar basal plane approach. In order to extend to tE−1 and E−1 E−1, a zk representation wherein k=1, 2, 3, 4, . . . , etc., is introduced and it can be defined that z1=N, z2=tE−1, z3=E−1, and z4=tP−1. For example, it is represented that z1=N (x3, x4), and z2=tE−1 (x1, x2). The reason why there are indexes expressed by reciprocals is to unify and impress as an optimization problem that maximizes the axis above the objective function zk. As zk, H−1, H−2, H−3, . . . , etc., which are simply powers and reciprocals of H, H2, H3, . . . , etc., can also be adopted. Further, an arbitrary index that multiplies each of the basal coordinates xi, xj, . . . , etc., can also be adopted.
From Equation 8, N is a function proportional to L, and also from the Equations 1 and 2, Π and t0 are also functions proportional to L, respectively. That is, in the three-dimensional graph (Π, t0, N), L can be regarded as one of extensive variables.
tE is a time obtained by dividing t0 by N2, and represents an impedance time, and tP is a time obtained by dividing t0 by N and represents a plate time.
On the other hand, the slop in each direction of the basal coordinate axis, that is, the partial differential coefficient, when N (Π, t0) is represented by the curved surface of the three-dimensional graph can be taken as a specific determination evaluation index.
First, simply, the slope of N with respect to the change of Π when t0 is constant in the three-dimensional graph N (Π, t0) is a partial differential coefficient cN/Π (Equation 12). cN/Π (Π, t0) indicating a simple slop is set as a slope of the curved surface in the three-dimensional graph, which is a function in which t0 is fixed with a partial differential coefficient, an N increment per Π is denoted, and a dimension is included, and is defined over the entire basal coordinate.
A general mathematical representation can be made as shown in Equation 13 from the properties of partial differential coefficient.
Here, x, y, and z are variables, l, n, and m are constants, and can be similarly expanded to Equation 14.
According to the Literature 2 or the like, the impedance time tE can be introduced, and the reciprocal thereof is re-indicated here as Equation 15 as shown in Equation 9 above.
On the other hand, a theoretical plate equivalent height H (u0) is obtained from a minimum and best theoretical plate equivalent height Hmin=H (u0,opt) with the optimal linear velocity u0,opt. When u0=u0,opt, Equation 16 is obtained by using this constant Hmin.
Π=Hmin2N2t0−1 (Equation 16)
As compared Equation 16 with a general formula (Equation 14), a coefficient n=2 appears and a representation of Equation 17 is obtained. Equation 11 in which the coefficient n=2 has a feature is limited when u0=u0,opt, and Hmin is offset in the calculation process.
Here, cN/Π is a partial differential coefficient value defined by Equation 12. When cN/Π (Π, t0) is expressed as a function defined by the basal coordinates, the form of Equation 18 is obtained.
Here, since u0,opt constant conditions are imposed, in fact, Π and t0 cannot move on the basal plane of the whole coordinate area freely, and are constrained by the rule of Equation 19 by the L of a medium extensive variable by the Equations 1 and 2.
Πt0=L2 (Equation 19)
Up to here, although being limited to the constant Hmin under the optimal condition u0,opt, the basal coordinate must be extended to (Π, t0) the whole area in order to extend to the real solution. μN/Π as a kind of new adjustment factor devised from Equations 12 and 17 is introduced (Equation 20). μN/Π is equal to 1 for the optimal condition u0=u0,opt, but is standardized so as to be a value other than 1 in other basal coordinate areas. Accordingly, μN/Π can be used as an index such as efficiency. As a result, μN/Π is a dimensionless standardization factor and has the ability to adjust to obtain the value cN/Π of Equation 17 obtained by using Hmin only in the case of u0,opt.
The following function μN/Π (Π, t0) is defined as a Pressure-Application Efficiency (PAE) (Equation 20). By comparing the function with Equation 18, the position of μN/Π can be understood. μN/Π (Π, t0) is a function defined by basal coordinates.
Equation 18 is an ideal equation that holds only when u0=u0,opt. That is, although Equation 18 does not hold in the case of u0 other than u0,opt, Equation 21 having a form close to Equation 18 can be expressed by introducing an adjustment factor μN/Π as a transformation of ideas.
The way to obtain the actual μN/Π (Π, t0) is to first obtain the slope cN/Π (Π, t0) of the three-dimensional graph at each point of the basal coordinate (Π, t0), and multiply each by a coefficient 2. Next, μN/Π (Π, t0) is obtained by multiplying Π of the basal coordinate thereof and dividing by N (Π, t0) of the coordinate (Equation 21).
Similarly, the Time-Extension Efficiency (TE2) can also be defined as μN/t (Π, t0) (Equation 22).
It is described that the z axis is a special direction to the basal plane, but mathematically simply expresses the slope of the curved surface in the three-dimensional graph from a different perspective. Therefore, PAE for hold-up time t0 can also be defined as μt/Π (Π, t0) (Equation 23). In other words, the above PAE is considered to be PAE for the number of theoretical plates N (Equation 20).
Here, an explanation of the doctrine of equivalents will be added. Since the pressure drop ΔP and the velocity length product Π or the general term pressure P are proportional to each other, it is considered that all the discussions around this, which are regarded as ratios, are equivalent. Similarly, the retention time tR and the hold-up time t0 have the same relationship, and can be used equivalently if careful consideration is given to the retention factor and the gradient elution. The flow rate and the linear velocity u0 can also be used equivalently as long as it is understood that the flow rate and the linear velocity u0 correspond to the porosity and cross-sectional area of the column, respectively.
In the context of the present disclosure, there is an abstract and ideal discussion modeling, and the present disclosure is built on a mathematical pressure driven HPLC model composed and defined only by H (u0) and KV.
Representations based on the following generalization are also possible. Equation 24 holds at the time of u0,opt.
Here, ck/j is predefined as Equation 25.
Next, a dimensionless efficiency μk/i is defined as Equation 26 as described above. At the time of u0,opt, μk/i is standardized to 1. The coefficient n is the degree derived from Equation 9.
Here, when obtaining a partial differential coefficient, the variable xj of a suffix j is fixed and Equation 27 can be represented.
In addition, μk/i is obtained in the entire area of the basal coordinate as Equation 28.
In terms of total differentiation, the function N can be represented by Equation 29 using partial differential coefficients.
Here, it is expressed as Equation 30, and n=½, and m=½.
Since μk/j is mathematically derived from the slope of the curved surface in the three-dimensional graph, there is a relationship of Equation 31. If two independent variables and the three axes of the function z are mathematically handled without distinction, μt/Π derived from the slope obtained by fixing N can also be calculated.
For example, if being locally constant, μt/Π can be integrated as shown in Equation 32.
Similarly, μt/Π can also be represented exponentially (Equation 33).
Further, it is expanded to a partial differential coefficient system as a series when k of zk equals to 5, 6, 7, . . . , cN/Π to z5, μN/Π to z6 can also be expanded sequentially as a three-dimensional graph.
The Van Deemter equation is used to demonstrate concrete calculations (Equation 34).
This obtains regression coefficients A, B, and C by curve-fitting several experimental values of an H-u0 plot. The H-u0 profile is generated due to factors such as physical diffusion, but in the present disclosure KV and Equation 34 are used as a curved surface profile generator for generating a three-dimensional graph.
As shown in
At the time of u0,opt, surely μN/Π=1.
On the other hand, PAE for t0 is shown in
At the time of u0,opt, similarly μt/Π=1.
All three-dimensional graphs in
μN/Π (Π, t0) is 1 at when the linear velocity is the optimal u0,opt. Although the slope of higher pressure is less than 1, it is not merely a gentle slope and not a large decrease in efficiency. That is, an increase in number of theoretical plates per pressure can be expected with a good efficiency that is almost equal to an ideal u0,opt. For example, as one of guidelines, it is possible to search for a separation condition as a practical range of μN/Π of 0.5 or more as a practical range as long as the separation is allowed in a high-speed analysis time area which is not ideal. This is an advantage of quantitatively overlooking using μN/Π in the basal coordinate (Π, t0).
On the other hand, the slope on the low pressure side of μN/Π (Π, t0)=1 is greater than 1, which seems to be efficient at first sight, but this is not necessarily the case. The reason for showing excessive efficiency means that it is easy to reach μN/Π (Π, t0)=1 by setting a better set of L and u0. In the case of one or more slopes, it is relatively easy to increase N more than u0,opt if it is a set of L and u0 which increases the pressure slightly.
An index such as μN/Π is a dimensionless ratio that standardizes a value at the time of u0,opt to 1. In addition, in the case of exceeding 1, it may be better to refer to a Pressure-Application Coefficient (PAC) rather than efficiency.
Examples of the present disclosure will be described in detail with reference to the drawings.
In
In the analytical column 1260, the sample is separated for each analyte and sent to a detector 1270. Light is irradiated in a cell 1280 of the detector 1270, and a waveform of the chromatogram is obtained from the signal intensity. The sample and the eluent are then sent to a waste liquid tank 1290.
As shown in
The data processor 1360 may not be connected with the controller 1350 to be independent from the liquid chromatography system. In a case where the data processor 1360 is independent, the data processor 1360 may perform processing based on the conditions input from an input unit 1370. The data processor 1360 corresponds to the chromatographic data system processing apparatus described in the claims.
Alternatively, by designating the respective coordinate axes, Π, and t0, for example, from a first axis and second axis setting unit (760) after transformation, an LRT transformer (730) executes the rotation of the logarithmic axis and the scaling transformation. The result is transferred via a three-dimensional graph generator (740) after transformation to generate a three-dimensional graph, and the three-dimensional graph of N (Π, t0) shown in
By specifying, for example, Π and N respectively from the a xi, zk setting unit (870), a partial differential coefficient ck/i calculator (830) calculates the partial differential coefficient. First, the result can be displayed from the output unit (1380) in a three-dimensional graph of cN/Π (Π, t0) as necessary. Next, the result is displayed as a three-dimensional graph of μN/Π (Π, t0) shown in
The flow rate F (ml/min) is proportional to the linear velocity u0 (mm/s). These correspond to a variable x1, and the cross sectional area (m2) of the inner diameter of the column is related to the porosity of the filled state. A variable x2 having a length dimension (m) is the column length L (mm). A variable x3 corresponding to the pressure is the column pressure drop ΔP (MPa), which is also proportional to Π (m2/s). Π is called the velocity length product or the pressure-driven strength. A time variable x4 is the hold-up time t t0 (s) or the retention time tR (min). The number of theoretical plates N is a variable or function of z1 and is inversely proportional to the theoretical plate equivalent height H (μm). The function z2 is the reciprocal of the impedance time tE, the function z3 is the reciprocal of the separation impedance E, and the function z4 is the reciprocal of the plate time tP.
The flowchart of
The flowchart of
The three-dimensional graph can also be expressed with a logarithmic axis. For example, a three-dimensional graph expressed by a logarithmic coordinate (log u0, log L) is expressed as (log Π, log u0) by LRT transformation. Further, a PAE based on the slope on N (log Π, log u0) can also be defined.
Alternatively, in obtaining a slope from the graph of function N (log Π, log u0) or defining some sort of efficiency, the PAE can be calculated on N (log Π, log u0) by LRT transformation.
In addition, these can also be generalized representation.
Next, an example of an analysis example of separation conditions using a three-dimensional graphic representation of the liquid chromatographic data system processing apparatus of the present disclosure will be described. As an example of the utilization shown in
Next, when transforming
This designated circle is also transformed into
μN/Π and μt/Π are called PAC (Pressure-Application Coefficient), and μN/t is called TEC (Time-Extension Coefficient). Equations 24 to 28 are the definition equations.
The application of PAC (Pressure-Application Coefficient) and TEC (time extension coefficient) is shown in detail in the case of six approaches.
The pressure upper limit approaches 20 MPa around N=5,000 or more and the u0,opt line cannot be climbed along. In order to further increase N from here, a KPL method is adopted which is a method of climbing a hill under a constant condition that the upper limit pressure is 20 MPa. However, it is understood that in the KPL method, the climbing method is comparatively gentle, and only about N=7,000 is obtained, so that the efficiency of increasing N is worse than the Opt method. PAC and TEC are introduced as coefficients quantitatively indicating this efficiency.
In addition, as shown in
In the Opt method, the u0,opt line or the vicinity thereof is selected as an optimal separation condition, but the minimum Hmin is obtained the u0,opt line. Therefore, if an arbitrary L column is attached, the maximum N at this L is inevitably obtained. At the same time, t0 and Π are unambiguously calculated. That is, in a five-dimensional space (Π, t0, N, u0,opt, L), a so-called straight line u0,opt line determined by a constant u0,opt is shown. For example, if a user requests N=5,000, he or she can see contour lines on a height surface of N=5,000, i.e., on hilly slopes (
Hereinafter, six approaches are shown.
1. Speeding-up of t0 under constant condition of N
(1) Extension to the high Π area
(2) Low Π area (movement to upper limit pressure Πmax)
2. High separation of N under constant condition of t0
(1) Extension to the high Π area
(2) Low Π area (movement to upper limit pressure Πmax)
3. Expansion under Πm upper limit pressure
(1) Speeding-up (reduction in t0)
(2) High separation (increase in N)
Approach 1-(1) is an optimization method that aims to realize high speeding-up while ensuring a constant N (
As shown in
Approach 1-(2) corresponds to a case where an arbitrary N is expected to be obtained, and the intersection point of the u0,opt line and the contour line of N is already above the upper limit pressure. The approach 1-(2) is a method of lowering the pressure, that is, making the pressure belongs to the low Π area and securing N along the contour line while extending the time, so as to obtain this N (
First, the method starts from the intersection point of the contour line of N=5,000 and the u0,opt line (Opt method). In a case where the upper limit pressure is 10 MPa, it is inevitable to lower the pressure to 10 MPa along the contour line of N=5,000. The fact that μt/Π is 1.39 means that at the intersection point of 10 MPa and the contour line, it is possible to speed up 1.39 times from the vicinity of the u0,opt line, by just increasing the pressure slightly, that is, increasing the Π increment. Conversely, the low Π area is an area where the high speed performance is inevitably extremely sacrificed when trying to obtain the high separation performance which is disproportionate. (
Approach 2-(1) is an optimization method that aims to realize high separation while ensuring a constant t0 (
Approach 2-(2) corresponds to a case where an arbitrary t0 is expected to be obtained, and the intersection point of the u0,opt line and the horizontal line of a constant t0 is already above the upper limit pressure. The approach 2-(2) is a method of lowering the pressure, that is, making the pressure belongs to the low Π area and reaching the upper limit pressure along the t0 horizontal line while dropping N, so as to obtain this t0 (
First, the method starts from an intersection point of the horizontal line projected on a basal plane with a constant t0=10 s and the u0,opt line (Opt method). In a case where the upper limit pressure is 10 MPa, it is inevitable to lower the pressure along the horizontal line of a constant t0=10 s, and the separation condition is moved to the left direction from the u0,opt line to 10 MPa.
It is means that at the time of 10 MPa, μN/Π is 1.16, and at the intersection point of 10 MPa and the horizontal line of t0=10 s, it is possible to perform high separation 1.16 times from the vicinity of the u0,opt line, by just increasing the pressure slightly, that is, increasing the Π increment. Conversely, in order to obtain the high speed performance of t0=10 s, the pressure is lowered, the pressure reduction rate is increased, and N gets worse. Therefore, the separation performance comes to be remarkably sacrificed. Since the approach 2-(2) uses the low Π area of barren area as in the approach 1-(2), it is inevitable to sacrifice the separation performance to a large extent when trying to obtain the extremely high speed performance (
Approach 3 is a so-called KPL method that ensures a constant pressure. First, the approach 3-(1) is a speeding-up method (
First, the method starts from an intersection point of a vertical line of ΔP=20 MPa and the u0,opt line (Opt method). At the intersection point, t0=11 s is obtained, and N=5,620 (
In a case where t0 is speeded up to 3 s, N=2,760, which is remarkably reduced, but μN/t remains at 1.18; if the sacrifice of N is acceptable, it can be said that the approach 3-(1) is a reasonable speeding-up method in which the coefficient value gets worse.
On the other hand, the approach 3-(2) is a high separation method (
The method starts from an intersection point of a vertical line of ΔP=20 MPa and the u0,opt line (Opt method). At the intersection point, t0=11 s is obtained, and N=5,620. In order to further increase N from here, the time is increased from the u0,opt line vertically upwards for 15 s or 20 s. Also in a case of 20 s, μN/t=0.92, it is considered that N can be increased by using time relatively efficiently, which is an example of an effective KPL method. (
In fact, as for the low Π area and the high Π area, the former is an area of u0 lower than u0,opt, and the latter is an area of u0 higher than u0,opt. On the contour plot, only the u0,opt line is expressed. Since u0 is not expressed positively, the low Π area is expressed for convenience. As described above, although the speeding-up is excellent in the area of high u0, the PAC such as μN/Π and μt/Π becomes 1 or less. On contrast, the PAC exceeds 1 in the low Π area. For example, in the low Π area, when the pressure is increased just little, this ratio increases and N increases greatly. Conversely, it means that even if N is lowered, there is no effect of lowering the pressure to such an extent.
First, a to constant transformation efficiency ηt is defined.
For preparation, the numerator and denominator of Equation 20 are turned over to obtain Equation 40.
Therefore, μΠ/N indicates a relationship between PAC μN/Π related to N and a reciprocal, as shown in equation 41.
μΠ/N=(μN/Π)−1 (Equation 41)
The t constant transformation efficiency ηt should have a value from 0 to 1 in order to position the efficiency. Therefore, the high Π area corresponds to μN/Π, and the low Π area corresponds to μΠ/N. It is requested that the maximum efficiency value 1 on the u0,opt line. In this way, the t constant transformation efficiency ηt can be expressed by one equation using PAC μN/Π related to N (Equation 42).
log ηt=−|log μN/Π| (Equation 42)
The above is the t0 constant transformation efficiency ηt. Similarly, an N constant transformation efficiency ηN can also be defined using PAC μt/Π related to t0 (Equation 43).
log ηN=−|log μt/Π| (Equation 43)
In addition, a Π constant transformation efficiency ηΠ can also be defined using TEC μN/t (Equation 44).
log ηΠ=−|log μN/t| (Equation 44)
Here, the meanings of the x constant transformation efficiencies ηN, ηt and ηΠ are looked back. The contour plot is a graph expressing three variables Π, t0, and N. Each constant transformation efficiency keeps one of the three variables constant and corresponds to the partial differential coefficient of the remaining two variables. In the high Π area, a short t0 as high speed performance or high separation performance N can be obtained under specific transformation efficiency by applying a pressure.
In contrast, in
Similarly in
However, efficiency η system is ideal for searching for maximum value 1. To analyze the vicinity of boundary line such as the u0,opt line, the efficiency η becomes an index not monotonically increase or decrease, which is also inconvenient. Hereinafter, it returns to practical PAC and TEC.
With reference to
In
Next, when an arbitrary t0 is to be obtained, first, a point B is found on the u0,opt line in
Quantitative optimization on the above KPL straight line, that is, the upper limit pressure will be described in detail.
If an arbitrary N is specified and a point C having a longer time than the vertex (intersection) of the previous triangular region is found, the separation condition is adopted. Here, if N is to be increased, t0 is further extended, so that the effectiveness of time extension can be measured with reference to TEC μN/t. Even when seeing a state of TEC μN/t by adding or subtracting t0, if the interval is longer than the intersection point, the effectiveness can be grasped as TEC of 1 or less.
In a case where an arbitrary t0 is specified and a point C having a longer time than the vertex (intersection) of the above triangular region is found, it is possible to further perform the speeding-up if it is determined that N is sufficiently large. It is possible to define the time reduction coefficient in the case of moving on the KPL straight line or define the N consumption coefficient as the reciprocal of μN/t, i.e., μt/N. In a case where N is sufficiently large, first, the contour plot is referred to again with the specified N.
If it is a coefficient of the same point such as point A, the following relationship (Equation 45) holds from the definition.
μN/Π=μN/tμt/Π (Equation 45)
As can be seen, since TEC μN/t is greater than 1 at a point slightly coming into the high Π area from the point A for example, μN/Π is larger than μt/Π, and PAC is 1 or less in this high Π area. Therefore, it is more effective and easier in high separation under a constant t than the speeding-up under a constant N. On the u0,opt line including the intersection above the triangular region, μN/Π=μN/t=μt/Π=1.
As described above, in a case where the point A (or the point B) is found on the u0,opt line by specifying N or t0, it is significant to search the separation condition for the triangular region up to the upper limit pressure. In this case, the pressure effectiveness in the triangular region can be quantitatively understood using each PAC.
In a case where the separation condition is searched on the KPL straight line of a constant pressure above the triangular region as the point C, the separation condition is adopted. If there is room to add or subtract N or t0, it is possible to quantitatively examine the effectiveness of the action t0 given to N using TEC.
In order to make it easier to understand mathematical representations and graphs, the square theoretical plate number Λ and an inverse hold-up time v0 are introduced.
Λ=N2
v
0
=t
0
−1
Π=H2Λv0=L2v0=u0L
As can be seen from the equations, by expressing with v0, the power of Π is divided by the product of Λ and v0. Since H2 is not a constant, but a ridge line is generated on the curved surface. By using the square theoretical plate number Λ instead of N on the vertical axis of the three-dimensional graph, the KPL curved surface can be expressed almost like a plane. In contrast, with respect to high speed performance, the larger the numerical value of the reverse hold-up time v0, the larger the high speed performance can be obtained.
The three-dimensional graphs are Λ (Π, t0) in
Commercial columns have discrete L such as 50 mm, 100 mm, and 150 mm. The variable of the present disclosure is a continuous real number representation, but in reality will be optimized with discrete L. However, the basic idea will follow even in practical application.
The present disclosure is not limited to the above embodiments, but it goes without saying that it extends to various modifications and equivalents included in the spirit and scope of the present invention.
Number | Date | Country | Kind |
---|---|---|---|
2017-219707 | Nov 2017 | JP | national |