JP6748758B1 - Vehicle inspection fee providing system and vehicle inspection fee providing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a system for providing an actual cost for a vehicle inspection without having the owner bring the vehicle to the inspection site. A vehicle inspection cost providing system 1 directly or indirectly from a user terminal 2 connected via a network, provides vehicle information including at least the vehicle type, year, grade, and mileage of the user's vehicle. The vehicle information acquisition unit 11 for acquiring the parts, the replacement cost acquisition unit 12 for acquiring the replacement cost of each part when the parts are replaced from the parts database 21 in which the replacement cost of the parts is recorded, and each part. The maintenance cost calculation unit 13 that calculates the maintenance cost by multiplying the replacement cost by the replacement probability of replacing the parts determined based on the vehicle information, the maintenance cost for each part, the legal cost, and the basic inspection cost. It has a cost transmission unit 14 that transmits the total amount as a vehicle inspection cost to the user terminal. [Selection diagram] Fig. 1

Description

The present invention relates to a vehicle inspection cost providing system and a vehicle inspection cost providing method.

The automobile continuous inspection (hereinafter referred to as vehicle inspection) is stipulated by law. When carrying out this vehicle inspection, the owner of the vehicle brings the vehicle to a dealer or maintenance shop (hereinafter also referred to as an inspection station), undergoes a simple preliminary inspection and gets a quote, and after accepting this estimate, the official inspection To start. After the formal inspection, according to the proposal from the inspection site such as additional parts replacement, the cost will be added to the estimated amount and the cost will be paid.

JP, 2017-10134, A

As described above, when the vehicle inspection is performed, the actual cost can be estimated only after the actual inspection.
Patent Document 1 proposes to interact with parts dealers in real time, obtain answers to vehicle parts inquiries required as a result of inspection, and show a quote in which the results are reflected to the owner of the car in real time. doing. However, even with such a method, the owner cannot estimate the actual cost of the vehicle inspection unless the vehicle is brought into the inspection area.
Therefore, the present invention provides a system and a method for providing an actual cost for vehicle inspection without the owner bringing the vehicle to the inspection place.

In order to achieve the above object, the vehicle inspection cost providing system of the present invention is
There is a server connected to the user terminal via a network, wherein the server is
A vehicle information acquisition unit that acquires vehicle information including at least the model of the user's vehicle, new vehicle registration date, vehicle weight, and mileage directly or indirectly from the user terminal,
A replacement cost acquisition unit that acquires each replacement cost required for replacing a part from a parts database in which the replacement cost of the part is recorded,
For each of the parts, a maintenance cost calculation unit that calculates a maintenance cost by multiplying the replacement cost by a replacement probability of replacing the part determined based on the vehicle information,
There is a cost transmission unit that transmits the sum of the maintenance cost for each of the parts, the legal cost, and the basic inspection cost as a vehicle inspection cost to the user terminal.

In order to achieve the above object, the method of providing the vehicle inspection cost of the present invention is
A method for providing a vehicle inspection fee using a server connected to a user terminal via a network, wherein the server includes:
Directly or indirectly from the user terminal, the vehicle information including at least the model of the user's vehicle, new vehicle registration date, vehicle weight, and mileage is acquired,
Obtaining each replacement cost when replacing a part from the parts database in which the replacement cost of the part is recorded,
For each of the parts, the maintenance cost is calculated by multiplying the replacement cost by the replacement probability of replacing the part determined based on the vehicle information,
The sum of the maintenance cost of each of the parts, the legal cost and the basic inspection cost is transmitted to the user terminal as a vehicle inspection cost.

According to the present invention, there is provided a system and a method for providing an actual cost for vehicle inspection without the owner bringing the vehicle to the inspection area.

1 is an overall configuration diagram of a vehicle inspection cost providing system according to an embodiment of the present invention. It is a flow chart of processing which a system concerning an embodiment of the present invention performs. It is a figure showing an example of information acquired from a user terminal. It is a figure for explaining the classification of a course. It is an example showing the mileage and the number of replacements for a certain replacement part of a vehicle of a certain model number. It is an example showing a mileage and a replacement rate for a certain replacement part of a vehicle of a certain model number. It is a figure for demonstrating the user attribute used for calculation of vehicle inspection cost. It is a figure which shows an example of the output screen of vehicle inspection cost.

A vehicle inspection fee providing system 1 (hereinafter simply referred to as system 1) and a method according to an embodiment of the present invention will be described with reference to the drawings.
As shown in FIG. 1, the system 1 has a main server 10 and a data server 20. The main server 10 and the data server 20 are communicably connected. The main server 10 and the data server 20 may be configured integrally or separately.

The main server 10 is connected to a plurality of user terminals 2 via a network. The user terminal 2 is a terminal operated by the user. The user in the present embodiment is the owner of the vehicle that uses the system 1. The user terminal 2 and the main server 10 may be connected by a dedicated line or may be connected by an internet line. The user terminal 2 has a display device integrally or separately. The terminal is an information processing device such as a computer, a tablet terminal, or a mobile phone owned by the user. Further, the terminal may be an information processing device not owned by the user. For example, it may be an information processing device to which the user has logged in. The information processing device includes a processor, a storage unit that stores computer-readable instructions, and a display device.

The main server 10 may be composed of a single server or plural servers. The main server 10 includes a processor and a storage unit that stores computer-readable instructions. The processor reads the computer-readable instructions stored in the storage unit and executes the vehicle inspection cost providing method described in detail below.

The main server 10 includes a vehicle information acquisition unit 11, a replacement cost acquisition unit 12, a maintenance cost calculation unit 13, and a cost transmission unit 14. The vehicle information acquisition unit 11 acquires vehicle information from the user terminal 2. The replacement cost acquisition unit 12 identifies a replacement part based on the vehicle information acquired by the vehicle information acquisition unit 11, and refers to the parts database 21 to acquire the replacement cost. The maintenance cost calculation unit 13 calculates the replacement probability by referring to the probability database 22 based on the vehicle information, and multiplies the replacement probability by the replacement cost to calculate the maintenance cost. The cost transmitter 14 sums up the maintenance cost, the legal cost, and the basic inspection cost to calculate the total vehicle inspection cost, and transmits the total vehicle inspection cost to the user terminal 2.

The data server 20 is composed of a recording device such as a hard disk. The data server 20 records various databases such as a parts database 21, a probability database 22 and a user database 23. Each information recorded in the data server 20 will be described later.

FIG. 2 is a flowchart of processing executed by the main server 10. As shown in FIG. 2, the vehicle information acquisition unit 11 of the main server 10 first acquires information including vehicle information from the user terminal 2 (step S01).
FIG. 3 is a diagram showing an example of information acquired from the user terminal 2. As shown in FIG. 3, the main server 10 receives, from the user terminal 2, vehicle information such as selected course name, mileage, vehicle type, new vehicle registration date (vehicle age), vehicle weight, place of residence/use, and purpose of use, Get the name and address of the user who owns the car. In the examples described below, the vehicle information includes the selected course name, mileage, vehicle type, new vehicle registration date (vehicle age), vehicle weight, place of residence/use, and intended use. It is not limited to this. It is preferable that the vehicle information includes at least a mileage, a new vehicle registration date, a vehicle manufacturer, and a prefecture name of a vehicle owner.

In the example shown in FIG. 3, the configuration in which the vehicle information is directly acquired from the user terminal 2 has been described, but the present invention is not limited to this. The vehicle information is stored in the user database 23 in association with the user ID, and the main server 10 acquires only the user ID and the password from the user terminal 2, and refers to the user database 23 based on the acquired user ID. The vehicle information may be acquired from the user database 23. Obtaining the vehicle information via the user database 23 by the main server 10 based on the user ID in this manner is referred to as indirectly obtaining the vehicle information from the user terminal 2.

Further, in the present embodiment, as shown in FIG. 3, a configuration may also be adopted in which the selected course is also acquired. The selected course indicates what kind of vehicle inspection the user desires when calculating the vehicle inspection cost. In this embodiment, as shown in FIG. 4, selection courses such as “minimum”, “firm”, “care”, “priority on price”, and “discerning” are prepared.

For example, there are cases where the user wants to undergo a vehicle inspection at an inspection site where cleaning of the interior of the vehicle and maintenance that can be expected to improve fuel efficiency can be performed in addition to the normal maintenance procedure. In such a case, the vehicle inspection will be requested to an inspection station that can provide high value-added services even if the basic fee is high.
Alternatively, the user may want to replace the vehicle parts as early as possible to extend the life of the vehicle in order to continue riding in the vehicle as long as possible. In this case, even if a general user considers that the replacement is unnecessary, the parts may be replaced, and the replacement frequency (replacement probability) of the parts increases.
Alternatively, some users think that it may not be a genuine replacement part but a general-purpose replacement part.
In consideration of such high and low basic fees, high and low replacement probability, and availability of general-purpose parts, in the present embodiment, each selection course is set as shown in FIG. The user selects one of the courses, and the main server 10 acquires information indicating the selected course. The choice of this course will affect the maintenance costs described below.

Next, the replacement cost acquisition unit 12 of the main server 10 refers to the parts database 21 based on the vehicle information, and acquires the replacement costs for the parts including the parts to be replaced (step S02).
In the parts database 21, the identification information of all parts to be replaced mounted on the vehicle of the model number and the replacement cost (parts cost and installation labor cost) are recorded in association with the model number. There is.

The main server 10 identifies all the replacement parts of the vehicle that match the model number of the vehicle information from the parts database 21 and extracts the replacement cost. For example, for a vehicle of model number ABC, the type of brake fluid to be replaced is specified and the replacement cost is extracted. In addition to brake fluid, the types and replacement costs of radiator fluid, flushing oil, wheel cylinders, and other parts subject to inspection/maintenance/replacement during vehicle inspection will be acquired.

In this way, the main server 10 may specify the type of replacement part based on only the model number in the vehicle information. Alternatively, the main server 10 may specify the type of replacement part based on the model number and other information. For example, the main server 10 may specify the replacement part in consideration of the selected course of the vehicle information. When “priority on price” is selected as the selected course, the main server 10 may be configured to select a general-purpose brake fluid instead of a genuine brake fluid when selecting the brake fluid type. Alternatively, when “feeling” is selected as the selected course, the main server 10 may be configured to select a tire having higher performance, instead of the default tire, as the tire.
The main server 10 may be configured to automatically select a genuine product, a general-purpose product, or a high-performance product. Alternatively, the main server 10 may be configured to display a selection screen on the user terminal 2 so as to allow the user to select a genuine product, a general-purpose product, or a high-performance product, and obtain the selection result from the user terminal 2. Good.

Next, the maintenance cost calculation unit 13 of the main server 10 calculates replacement probabilities for all replacement parts based on the vehicle information (step S03). In this embodiment, the main server 10 refers to the probability database 22 based on the vehicle and calculates the replacement probability for all replacement parts.

The concept of the exchange probability in this embodiment will be described with reference to FIGS. 5 and 6. The replacement probability is the probability of actually replacing the replacement part when the vehicle is inspected. It is the probability that a mechanic will determine that a replacement is required when inspecting the vehicle.

As an example, a method of calculating the replacement probability of the brake fluid mounted on the vehicle of model number ABC will be described. FIG. 5 is a graph showing the relationship between the distance traveled and the number of first-time replacements of a certain type of brake fluid in the vehicle of model number ABC. The number of replacements increases as the mileage increases, and the number of replacements gradually decreases after the peak.

FIG. 6 is a diagram showing the mileage and the first replacement probability for the brake fluid of the vehicle of model number ABC. FIG. 6 is a graph obtained by integrating FIG. 5 and adjusting the vertical axis. FIG. 6 shows how much the brake fluid has been replaced by a certain mileage. In addition, the vertical axis of FIG. 6 converts the actual number of exchanges into the exchange probability. That is, it indicates a value obtained by dividing the number of exchange records up to a certain mileage by the total number of exchange records. For example, when the total number of exchange records is 100,000 and the exchange record up to a certain mileage is 20,000, the exchange probability up to that mileage is 20%. ..

In addition, in the example shown in FIG. 6, an example in which the replacement probability continuously changes according to the traveling distance is shown, but the present invention is not limited to this example. For example, the probability is set to 10% at a mileage in which the probability of actual replacement obtained as shown in FIG. As described above, the replacement probability may be configured as a function that changes stepwise according to an index such as a mileage.

In the data server 20, as the probability database 22, a function indicating the exchange probability as shown in FIG. 6 (hereinafter, also referred to as an exchange probability function) is recorded. The probability database 22 records the model number, the type of replacement part, and the replacement probability function.

The main server 10 reads out the replacement probability function corresponding to the part from the probability database 22 for all the parts that may be replaced and is installed in the user's vehicle, and obtains the read replacement probability function from the user terminal 2. By applying the traveled distance, the probability of replacing each part when the user's vehicle is inspected is calculated.

In addition, in the example shown in FIGS. 5 and 6, an example in which the replacement probability is determined only from the traveling distance is shown for simplification of description, but the present invention is not limited to this.
As shown in FIG. 7, the replacement probability may be determined according to the mileage, the new vehicle registration date (vehicle age), the vehicle weight, the replacement history, and the like. Further, the replacement probability may be determined in consideration of the usage condition of the vehicle, such as the usage of a short distance, the usage in a cold region, and the usage in a crowded condition. As the travel distance, the travel distance from the new vehicle registration date may be counted, or the travel distance from the time of the previous replacement may be counted. Further, when a course with a high exchange probability (for example, a firm course or a care course) is selected in the selected course described with reference to FIG. 4, 20% is uniformly added to the exchange probability calculated as described above. You may perform processing, such as.

Next, the maintenance cost calculation unit 13 of the main server 10 calculates the maintenance cost by multiplying the replacement cost by the replacement probability for all replacement parts (step S04).
The maintenance cost is a value obtained by multiplying the replacement part identified based on the vehicle information by the replacement probability calculated as described above. For example, if the replacement cost of the brake fluid is 10,000 yen and the replacement probability is 20%, the maintenance cost of the brake fluid is 20,000 yen. If the replacement cost of the wiper is 70,000 yen and the replacement probability is 50%, the maintenance cost of the wiper is 0.35 million yen.

Next, the main server 10 calculates the total vehicle inspection cost by summing up the legal cost, basic inspection cost, and maintenance cost of all replacement parts (step S06). FIG. 8 shows the total amount of (d) vehicle inspection costs together with (a) legal costs, (b) basic inspection costs, and (c) maintenance costs. The total vehicle inspection cost is calculated as the sum of the legal cost, basic inspection cost, and maintenance cost for all replacement parts (d=a+b+c).
The main server 10 calculates the legal cost and the basic inspection cost based on the vehicle information. The legal cost is the cost required for legal vehicle inspection. The legal cost depends on the weight of the vehicle. The weight of the vehicle is acquired as vehicle information from the user terminal 2 (step S01).
The basic inspection cost is a basic fee set for each inspection site. The basic inspection cost depends on the course selected by the user and the area where the user lives. Information such as the selected course and the residence of the user is also acquired as vehicle information from the user terminal 2 (step S01).

Finally, the cost transmission unit 14 of the main server 10 transmits at least the total amount of the vehicle inspection cost to the user terminal 2 (step S07). In the present embodiment, the main server 10 transmits information including the total amount of vehicle inspection costs to the user terminal 2. The screen shown in FIG. 8 may also be transmitted to the user terminal 2 and displayed on the display device. It should be noted that a vehicle inspection application button may be displayed on the screen displayed on the user terminal 2.

As described above, according to the vehicle inspection cost providing system and method according to the present embodiment, it is possible to receive the vehicle inspection cost via the network without bringing the vehicle to the inspection site.

Conventionally, a vehicle is brought to an inspection site, actually inspected, and then a replacement cost is charged when the replacement is necessary, and is not charged when the replacement is unnecessary. However, in such a method, the cost is not fixed unless the vehicle is brought to the inspection site.
On the other hand, the inventor has realized that the replacement probability can be estimated to some extent by using the replacement record and the vehicle information. Therefore, I came up with the idea of letting the user bear the cost according to the replacement probability, and fixing the vehicle inspection cost without performing the inspection.

For example, when there are two users who have an exchange probability of 50%, conventionally one person may exchange and another person may not exchange. The cost of exchanging the parts from the two persons by the conventional cost calculation method is the same as the maintenance cost received from the two persons in the present embodiment. Therefore, the operator of the inspection site is not burdened.
In addition, even for a user who needs to exchange, since the exchange probability is 50%, the exchange can be performed at half the original cost. For users who did not need replacement, there is a point that they have to pay the cost even if they did not actually replace it, but they are relieved that the cost will be charged at the face value of the cost notified in advance. There is. Even if it is necessary to replace parts such as batteries or parts with high labor costs, the mental burden of suddenly incurring large expenses after the inspection is reduced.

Although the embodiments of the present invention have been described above, it goes without saying that the technical scope of the present invention should not be limitedly interpreted by the description of the present embodiments. It is understood by those skilled in the art that the present embodiment is merely an example, and various modifications can be made within the scope of the invention described in the claims. The technical scope of the present invention should be determined based on the scope of the invention described in the claims and the equivalent scope thereof.

1 Vehicle Inspection Cost Providing System 2 User Terminal 10 Main Server 11 Vehicle Information Acquisition Unit 12 Replacement Cost Acquisition Unit 13 Maintenance Cost Calculation Unit 14 Cost Transmission Unit 20 Data Server 21 Parts Database 22 Probability Database 23 User Database

Claims (2)

There is a server connected to the user terminal via a network, wherein the server is
A vehicle information acquisition unit that acquires vehicle information including at least the model of the user's vehicle, new vehicle registration date, vehicle weight, and mileage directly or indirectly from the user terminal,
A replacement cost acquisition unit that acquires each replacement cost required for replacing a part from a parts database in which the replacement cost of the part is recorded,
For each of the parts, a maintenance cost calculation unit that calculates a maintenance cost by multiplying the replacement cost by a replacement probability of replacing the part determined based on the vehicle information,
A vehicle inspection cost providing system, comprising: a cost transmission unit that transmits the sum of the maintenance cost for each of the parts, the legal cost, and the basic inspection cost to the user terminal as a vehicle inspection cost. A method for providing a vehicle inspection fee using a server connected to a user terminal via a network, wherein the server includes:
Directly or indirectly from the user terminal, the vehicle information including at least the model of the user's vehicle, new vehicle registration date, vehicle weight, and mileage is acquired,
Obtaining each replacement cost when replacing a part from the parts database in which the replacement cost of the part is recorded,
For each of the parts, the maintenance cost is calculated by multiplying the replacement cost by the replacement probability of replacing the part determined based on the vehicle information,
A method of providing a vehicle inspection cost, in which the sum of the maintenance cost of each of the parts, the legal cost, and the basic inspection cost is transmitted to the user terminal as the vehicle inspection cost.

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