JP7182354B2 - How to provide the blending ratio of the base material - Google Patents

Description

The present invention relates to a method of providing a blending ratio of base stocks used to obtain fuel oils.

The octane number (research method) of regular gasoline is determined to be 89 or more (Non-Patent Document 1). Therefore, petroleum wholesalers blend base materials so that the octane number is 89 or more, and sell the obtained fuel oil as regular gasoline.
However, when a base material with an octane number of 88 and a base material with an octane number of 90 are mixed in equal amounts to obtain a fuel oil, the octane number is not always 89 (Patent Document 1). Therefore, primary oil distributors produce fuel oil with an octane number of 89 or more by blending base materials so that the octane number is 90, for example, according to simple calculation. However, the fuel oil thus obtained is overspec. If the base material can be blended aiming at the lower limit of the standard (for example, 89), resources can be used effectively, and fuel oil of appropriate quality can be provided to users at low cost.

JP 2014-25077 A

JIS K2202:2007

According to conventional methods, the variation in octane number of the obtained fuel oil differs depending on the base material blended as described above, and it is difficult to predict the octane number by simple calculation. In order to specify the blending ratio of the base material so that the fuel oil with the desired octane number is obtained, a trial is conducted by changing the blending ratio of multiple types of base materials and blending them multiple times, and examining the octane value of the resulting fuel oil. It would be necessary to repeat mistakes, and this would be a significant burden for oil wholesalers. Furthermore, even if it becomes possible to predict, to some extent, empirically the octane number variation of fuel oil when using only existing basestocks, new basestocks obtained from different It has been difficult to accurately predict the octane number of a fuel oil using rules of thumb for existing base stocks only.

SUMMARY OF THE INVENTION An object of the present invention is to provide a method of providing a blending ratio of a base stock that can obtain a fuel oil with a desired octane number before actual blending, even when a new base stock is used.

In order to achieve the above object, one aspect of the present invention provides the following.
A method for providing a blending ratio of base materials used to obtain a fuel oil by blending a plurality of base materials having different compositions,
The method is executed by a server connected to a user terminal via a network,
The method includes
acquiring substrate information including at least density, composition of paraffins, olefins, naphthenes and aromatic compounds, distillation properties and octane number for each of a plurality of user substrates from the user terminal;
With reference to a correction database in which reference information including density, composition of paraffins, olefins, naphthenes and aromatic compounds, distillation properties and octane number reference correction factors for each of a plurality of types of reference base materials is recorded, the user base material identifying a user correction factor for each of the plurality of user substrates from the reference correction factor for the octane number of the reference substrate having the closest reference information to the substrate information of
a step of calculating a blending ratio of the user base material so as to obtain a fuel oil having a predetermined octane number based on each of the specified user correction coefficients;
a step of transmitting the calculated blending ratio to the user terminal;
A method of providing the blending ratio of the base material, performing in this order.

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide a method of providing a blending ratio of a base material that enables obtaining a fuel oil with a desired octane number before actual blending, even when a new base material is used.

1 is an overall configuration diagram of a system that provides a blending ratio of base materials; FIG. 1 is a flow chart of a method of providing a base material blend ratio; It is an example of an input screen displayed on the display unit of the user terminal. FIG. 4 is a diagram showing information stored in a correction database; FIG. It is an example of an output screen displayed on the display unit of the user terminal. FIG. 10 is a flow chart illustrating an example method for identifying an octane correction factor for a user substrate; FIG. FIG. 10 is a flow chart illustrating an example method for identifying an octane correction factor for a user substrate; FIG.

The blending ratio providing system of this embodiment is used when a user blends a base material to obtain a fuel oil with a desired octane number.

FIG. 1 is an overall configuration diagram of a system for performing a method of providing a blending ratio of base materials according to an embodiment of the present invention. As shown in FIG. 1 , the providing system has a user terminal 10 , a server 20 having arithmetic processing means, and a correction database 30 . The user terminal 10 is configured to be able to communicate with the server 20 via the network 40 . The server 20 and the correction database 30 are configured to be able to communicate with each other. The server 20 may be composed of a single server, or may be composed of a plurality of servers.

The user terminal 10 has a display section. This display unit is, for example, a liquid crystal screen, or may be a touch panel display.
The correction database 30 records reference information including reference correction factors for density, composition of paraffins, olefins, naphthenes and aromatics, distillation properties and octane numbers for each of a plurality of types of reference base stocks.

FIG. 2 is a flow chart of a method of providing a base material blend ratio. As shown in FIG. 2, the server 20 acquires the target octane number from the user terminal 10 (step 01). The target octane number is the octane number of the blended oil (fuel oil) that the user intends to obtain as a result of blending the base material. In the present embodiment, the research octane number (RON) or the motor octane number (MON) may be obtained as the target octane number.

As shown in FIG. 2, following step 01, the server 20 acquires substrate information for each of a plurality of user substrates (step 02).
FIG. 3 is an example of a screen displayed on the user terminal 10 when the user is allowed to input information on the user base material. The user can use the input screen displayed on the display unit of the user terminal 10 to input information about the base material. The user terminal 10 causes the display unit to display a screen for inputting information including at least the density of a plurality of substrates, compositions of paraffins, olefins, naphthenes and aromatic compounds, distillation properties and octane numbers. In this specification, the term “distillation properties” refers to, for example, 10% by volume distillation temperature (T10) [° C.], 50% by volume distillation temperature (T50) [ °C], 90% by volume distillation temperature (T90) [°C].

As shown in FIG. 2, the server 20 refers to the correction database 30 based on the acquired base material information of a plurality of user base materials (step S03).
FIG. 4 is a diagram showing reference information of multiple types of reference substrates recorded in the correction database. The server 20 collates the reference information in the correction database with the input base material information of the user base material to identify the user correction coefficient of the user base material (step S04).

Here, in the blending ratio providing system of the present embodiment, the server 20 refers to the correction database 30 and specifies the user correction coefficients of the user base material α, the user base material β, and the user base material γ shown in FIG. We will explain the method in detail.

FIG. 6 is a flowchart of a method for server 20 to refer to correction database 30 to identify a user correction factor. As shown in FIG. 6, the server 20 refers to the reference information recorded in the correction database 30 shown in FIG. The reference information on the substrate that is closest to the user information on the user substrate is matched.

The server 20 determines whether there is reference information of a reference substrate that matches the substrate information of the user substrate in the correction database (step S41). If there is reference information of the reference base material that matches the base material information of the user base material, the server 20 identifies the reference correction coefficient of the reference base material that matches the base material information as the user correction coefficient of the user base material (step S42). If there is no reference information of the reference base material that matches the base material information of the user base material, the server 20 sets the reference correction coefficient of the reference base material having the reference information closest to the base material information of the user base material of the user base material. It is specified as a user correction coefficient (step S43). At this time, the server 20 compares the density of each of the user substrate and the reference substrate to determine the reference substrate having the reference information closest to the substrate information of the user substrate.

A specific description will be given. When the server 20 specifies the user correction coefficient of the user base material shown in FIG. (step S41). The reference information of the reference base material A matches the user information of the user base material α (step S41: YES). Therefore, the reference correction coefficient of the reference base material A that matches the base material information of the user base material α is specified as the user correction coefficient of the user base material (step S42). Subsequently, the server 20 determines whether or not there is reference information of a reference base material that matches the user information of the user base material β input by the user in the correction database (step S41). There is no reference information of the reference base material that matches the user information of the user base material β (step S41: NO). Therefore, the reference correction coefficient of the reference base material B having the density closest to the density of the user base material β is specified as the user correction coefficient of the user base material (step S43). Finally, the server 20 determines whether or not there is reference information of a reference base material that matches the user information of the user base material γ input by the user in the correction database (step S41). There is no reference information of the reference base material that matches the user information of the user base material γ (step S41: NO). Therefore, the reference correction coefficient of the reference base material F having the density closest to the density of the user base material γ is specified as the user correction coefficient of the user base material (step S43).

Returning to FIG. 2, once the octane number user correction factors for all of the plurality of user stocks have been identified, the server 20 is configured to obtain fuel oil of a given octane number based on the identified octane number user correction factors. A compounding ratio of the user base material is calculated (step S05). The octane number correction coefficient is a function of the blending ratio of the base material, and the octane numbers of the user base material α, the user base material β, and the user base material γ are respectively Xα, Xβ, and Xγ, the user base material α, and the user base material. Vα, Vβ and Vγ are the mixing ratios (% by volume) of β and user base material γ, respectively, and Fα (Vα) and Fβ (Vβ ) and Fγ (Vγ), the octane number X of the fuel oil is expressed by the following formula.
X=Fα(Vα)×Xα ×Vα×0.01 +Fβ(Vβ)×Xβ ×Vβ×0.01 +Fγ(Vγ)×Xγ ×Vγ×0.01

The server 20 calculates Vα, Vβ, and Vγ, which are blending ratios (% by volume) of the user base material α, the user base material β, and the user base material γ, so that the octane number X of this fuel oil has a predetermined value. and transmitted to the user terminal 10 (step S06). FIG. 5 is an example of a screen showing the blending ratio of the user base material displayed on the display unit of the user terminal 10, and is provided by the method according to the present embodiment when the target research octane number of fuel oil is 89. 4 shows the compounding ratio of user base material α, user base material β, and user base material γ shown in FIG.

If you want to obtain a fuel oil with a research octane number of 89 using the research octane numbers of user base material α, user base material β, and user base material γ shown in FIG. By blending 18% by volume of the user base material β and 27% by volume of the user base material γ, it is calculated by simple calculation that a fuel oil having an octane number of 89.1 can be obtained. However, the actual octane number of the fuel oil obtained with this blending ratio was 88.1, which was below the standard of 89 for regular gasoline.
On the other hand, when fuel oil is obtained at the blending ratio of user base material α, user base material β, and user base material γ calculated according to the present embodiment shown in FIG. 5, the research octane number is 89.1, and regular gasoline was able to meet the standards of At this time, the user correction coefficient for the user base material α was 1.03, the user correction coefficient for the user base material β was 1.12, and the user correction coefficient for the user base material γ was 0.92.

According to the present embodiment described above, whether a new base material is used or an existing base material is used, the base material to be blended is adjusted so as to obtain a fuel oil with a desired octane number before actual blending. Blending ratios can be provided. At the site where the base material is actually blended to obtain fuel oil, even if the information on the base material used when starting a new refinery is known, the octane number of the fuel oil cannot be predicted based on the octane number and the blending ratio alone. Instead, the mixture ratio was intentionally increased so as not to fall below the specified standard. However, in this case, the obtained fuel oil is often over-specified, and it is difficult to say that resources are being used effectively. According to the above embodiment, it is possible to provide the user with fuel oil of appropriate quality at low cost.

Further, in the above-described embodiment, as shown in FIG. 7, if there is no reference information of the reference base material that matches the base material information of the user base material, the server 20 selects reference information close to the base material information of the user base material. A user correction factor for a user substrate may be predicted and identified based on the reference correction factors for a plurality of reference substrates (step S143). FIG. 7 is a flow chart showing a modified example of a method for server 20 to refer to correction database 30 and specify a user correction coefficient.

In this modification, the server 20 determines whether or not there is reference information of a reference base material that matches the user information of the user base material α in the correction database (step S41). The reference information of the reference base material A matches the user information of the user base material α (step S41: YES). Therefore, the reference correction coefficient of the reference base material A that matches the base material information of the user base material α is specified as the user correction coefficient of the user base material (step S42). Subsequently, the server 20 determines whether or not there is reference information of a reference base material that matches the user information of the user base material β input by the user in the correction database (step S41). There is no reference information of the reference base material that matches the user information of the user base material β (step S41: NO). Therefore, the user correction coefficient is predicted and identified based on the reference correction coefficients of the reference base material B, the reference base material C, and the reference base material D having densities close to the density of the user base material β (step S143). Finally, the server 20 determines whether or not there is reference information of a reference base material that matches the user information of the user base material γ input by the user in the correction database (step S41). There is no reference information of the reference base material that matches the user information of the user base material γ (step S41: NO). Therefore, the user correction coefficient is predicted and specified based on the reference correction coefficients of the reference base material E and the reference base material F having densities close to the density of the user base material γ (step S143). Prediction of the user correction factor can use, for example, interpolation, extrapolation, and/or Newton's method.

According to this modification, it is possible to predict the user correction coefficient of the user base material with high accuracy based on the reference information of the reference base material and the reference correction coefficient of the octane number stored in the correction database 30, and a new base material can be obtained. Even when using raw materials, it is possible to provide the blending ratio of the bases to be blended so as to obtain the desired octane rating of the fuel oil prior to the actual blending.

In the above embodiment, the research method octane number is input, and the mixture ratio is calculated by referring to the correction coefficient so as to achieve the target research method octane number. The blending ratio may be calculated by referring to the correction coefficient so as to obtain the normal octane number. Moreover, when the target octane number is determined in advance, the step of obtaining the target octane number may be omitted.

Also, in the above embodiment, the server 20 collated the density of the user substrate when determining the reference substrate having the closest reference information to the substrate information of the user substrate, but at least the density, paraffin , composition of olefins, naphthenes, and aromatic compounds, distillation properties, and octane number are collated to determine a reference base material having the closest reference information to the base material information of the user base material. may decide. Likewise, when the server 20 determines a reference base material having reference information close to the base material information of the user base material, at least density, composition of paraffins, olefins, naphthenes and aromatic compounds, distillation properties and octane number A single or multiple indicators selected from the group may be collated to determine the reference substrate having the closest reference information to the substrate information of the user substrate.

In the above description, in steps S43 and S143, the user correction coefficient of the user base material is specified even when there is no reference information of the reference base material that matches the base material information of the user base material. Therefore, the base material information of the user base material may be accumulated in the correction database 30 using the user correction coefficient of the specified user base material as a reference correction coefficient. As a result, reference information accumulated in the correction database 30 can be increased, and accuracy in specifying the user correction coefficients can be improved.

In the above embodiment, the correction database 30 stores density [g/cm ³ ], vapor pressure [kPa], distillation property [° C.], total calorific value [cal/ g], PRTR target substance concentration [vol%], paraffin concentration [vol%], olefin concentration [vol%], naphthene concentration [vol%], aroma concentration [vol%] Correction of physical properties including at least one correction coefficient The coefficient may be recorded, and based on the physical property correction coefficient, the server 20 stores the fuel oil density [g/cm ³ ], vapor pressure [kPa], distillation property [° C.], total calorific value [cal/g]. , PRTR target substance concentration [vol%], paraffin concentration [vol%], olefin concentration [vol%], naphthene concentration [vol%], aroma concentration [vol%]. , may be transmitted to the user terminal 10 . According to this configuration, it is possible not only to obtain the blending ratio for obtaining the fuel oil with the desired octane number, but also to predict the physical properties of the obtained fuel oil.

10: user terminal, 20: server, 30: correction database, 40: network

Claims (6)

A method for providing a blending ratio of base materials used to obtain a fuel oil by blending a plurality of base materials having different compositions,
The method is executed by a server connected to a user terminal via a network,
The method includes
acquiring substrate information including at least density, composition of paraffins, olefins, naphthenes and aromatic compounds, distillation properties and octane number for each of a plurality of user substrates from the user terminal;
Correction database containing reference information including reference correction factors for density, paraffin, olefin, naphthene and aromatic compound composition, distillation properties and octane number as a function of the mix ratio of the base material for each of a number of reference base materials. identifying a user correction factor for each of a plurality of user substrates from the reference correction factor for the octane number of the reference substrate having the closest reference information to the substrate information of the user substrate, with reference to
a step of calculating a blending ratio of the user base material so as to obtain a fuel oil having a predetermined octane number based on each of the specified user correction coefficients;
a step of transmitting the calculated blending ratio to the user terminal;
A method of providing the blending ratio of the base material, performing in this order. In the step of specifying the user correction coefficient, the correction database is referred to, and the reference correction coefficient of the octane number of the base material having reference information that matches the base material information acquired for each of a plurality of types is determined as the user base material. as a user correction factor for at least one octane rating of
A method for providing the blending ratio of the base material according to claim 1 . In the step of identifying the user correction coefficient, the reference correction coefficient of the octane number of the base material having the reference information closest to the base material information acquired for each of the plurality of types is determined by referring to the correction database. as a user correction factor for at least one octane rating of
A method for providing the blending ratio of the base material according to claim 1 . In the step of identifying the user correction coefficient, the correction database is referred to, and the user base is selected from the octane number reference correction coefficients of the plurality of base materials having reference information close to the base material information acquired for each of the plurality of types. predicting and identifying a user correction factor for at least one octane rating of the material;
A method for providing the blending ratio of the base material according to claim 1 . 5. The method of providing a mixture ratio of base materials according to claim 3, wherein the base material information is accumulated in the correction database using the specified user correction coefficient as the reference correction coefficient. 6. The method of providing the blending ratio of the base material according to any one of claims 1 to 5, comprising the step of obtaining a target octane number of fuel oil desired to be obtained from the user terminal.

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