JP7181526B2 - Pollution degree measurement system - Google Patents

Description

The present invention relates to a pollution degree measurement system. The present invention particularly relates to a contamination measurement system using a contamination measurement kit for measuring the contamination by at least one of ATP, ADP, and AMP.

In order to provide clean and hygienic food, it is necessary to control the hygiene of the food manufacturing and processing environment. For example, in a site such as a food factory where hygiene management is strict, the degree of contamination (that is, cleanliness) of machinery and equipment and workers' hands and fingers is measured after washing and sterilization for hygiene management. As a method for measuring the degree of contamination, Patent Document 1 (International Publication WO2018/147443A1) discloses a contamination measurement kit using the ATP+ADP measurement method or the ATP+ADP+AMP measurement method.

International publication WO2018/147443A1 (August 16, 2018)

In a site where hygiene management is strict as described above, bringing items into the site is restricted in order to prevent food from being contaminated with foreign substances. For this reason, all the required functions have been incorporated into the measuring device of the contamination measuring kit. As a result, the setting and operation of the measuring device become complicated, and there is a problem that the handling of the measuring device requires proficiency.

An object of one aspect of the present invention is to realize a pollution degree measurement system that can be easily handled.

In order to solve the above-mentioned problems, a contamination level measurement system according to aspect 1 of the present invention includes a contamination level measurement kit (2) for measuring the contamination level of an object to be measured by at least one of ATP, ADP, and AMP; a communication terminal (4) capable of communicating with the pollution degree measurement kit (2) and connectable to an external network (3); and a pollution degree measurement system (1) comprising: , the contamination measurement kit (2) can be operated.

According to the above configuration, the measurer can operate the pollution degree measurement kit from the communication terminal. Therefore, the measurer can easily handle the contamination degree measuring system. In addition, according to the above configuration, various functions can be incorporated into the communication terminal instead of the measuring device of the pollution degree measuring kit. Therefore, the measuring device is simplified, which facilitates cleaning and sterilization.

A pollution degree measurement system (1) according to aspect 2 of the present invention relates to aspect 1, wherein the communication terminal (4) instructs the pollution degree measurement kit (2) to start measuring the pollution degree. an instruction unit (S43); an acquisition unit (S46) that acquires the measurement result from the contamination measurement kit (2); a determination unit (S47) that determines the measurement result based on the reference value; and a storage of the reference value. and the contamination level measurement kit (2) may be configured to comprise a measurement part (2d) for starting the measurement of the contamination level according to the instruction of the instruction part (S43). .

A contamination level measurement system (1) according to aspect 3 of the present invention relates to the above aspect 2, wherein the communication terminal (4) includes an inspection point registration unit (S30) for registering an inspection point for measuring the contamination level. The configuration may further include a section (S2).

A contamination degree measuring system (1) according to aspect 4 of the present invention, according to aspect 3, further comprises a business type registration unit (S11) for registering a business type, and the inspection point registration unit (S30) registers an inspection point type. an inspection point type addition unit to be added (S33); for each inspection point, (i) an inspection point type corresponding to the registered business type and (ii) an inspection point type added by the inspection point type addition unit. An inspection point type registration unit (S32) for registering any one may be provided.

A contamination degree measuring system (1) according to aspect 5 of the present invention relates to aspect 4, wherein the inspection point registration unit (S30) sets the reference value according to the registered inspection point type for each inspection point. The configuration may further include a default value acquisition unit (S34) that acquires the default value.

A contamination degree measuring system (1) according to aspect 6 of the present invention relates to any one aspect of aspects 3 to 5, and the inspection point registration unit (S30) assigns a machine-readable code to each inspection point. The communication terminal (4) further includes a code assigning unit for reading the code, and based on the code read by the reading unit (4d), the measurement object from the registered inspection point The configuration may further include a first measurement target selection unit that selects the .

A contamination degree measuring system (1) according to aspect 7 of the present invention relates to any one aspect of aspects 3 to 6 above, and the inspection point registration unit (S30) provides an icon that assigns an item icon to each inspection point. The communication terminal (4) may further include a second measurement object selection unit that selects the measurement object from the registered inspection points based on the selection of the item icon.

A contamination degree measuring system (1) according to aspect 8 of the present invention relates to aspect 7, wherein the icon assigning unit creates the item icon for each inspection point from an image of the inspection point. good.

A contamination measuring system (1) according to aspect 9 of the present invention relates to any one aspect of aspects 6 to 8, and the communication terminal (4) is a mobile communication terminal having a camera function, good too.

A pollution degree measurement system (1) according to aspect 10 of the present invention relates to any one aspect of aspects 2 to 9, and the communication terminal (4) is configured to display graph and displays one or more of the measurement result from the contamination measurement kit (2), the determination result by the determination unit (S47), and the graph. The pollution degree measurement system according to any one of claims 1 to 10, characterized in that:

A pollution degree measurement system (1) according to aspect 11 of the present invention relates to any one aspect of aspects 1 to 10, wherein the communication terminal (4) includes a calendar unit having a calendar function; The configuration may further include a scheduling unit that sets the frequency or date and time; and a first alerting unit that calls attention to measure the degree of contamination according to the frequency or date and time set by the scheduling unit.

A pollution degree measurement system (1) according to aspect 12 of the present invention relates to any one aspect of aspects 1 to 11, wherein the communication terminal (4) acquires environmental information through the external network (3). The configuration may further include: an information acquiring unit; and a second alerting unit that alerts to measure the degree of contamination according to the environmental information.

A communication terminal program according to a thirteenth aspect of the present invention is a program for causing a computer (4b) to function as the communication terminal (4) included in the pollution degree measurement system (1) according to any one of the second to tenth aspects. The program for a communication terminal may be configured to cause a computer (4b) to function as the instruction section (S43), the acquisition section (S46), and the determination section (S47).

A computer-readable recording medium (4a) according to aspect 14 of the present invention may have a configuration in which the communication terminal program according to aspect 13 is recorded.

ADVANTAGE OF THE INVENTION According to one aspect of the present invention, it is possible to realize a contamination degree measurement system that is easy to set and operate by a user.

1 is a block diagram schematically showing an example of a pollution degree measurement system according to an embodiment of the present invention; FIG. FIG. 2 is a flow diagram schematically showing an example of the flow of an application executed by the communication terminal shown in FIG. 1; 3 is a flow diagram schematically showing an example of the flow of the setting mode shown in FIG. 2; FIG. 4 is a diagram schematically showing an example of a registration screen in user registration shown in FIG. 3; FIG. be done. FIG. 4 schematically shows an example of a set of business type icons in the business type registration shown in FIG. 3; 4 schematically shows an example set of member type icons in the member type registration shown in FIG. 3; FIG. 4 schematically shows an example of a set of inspection point type icons in the inspection point registration shown in FIG. 3; FIG. (a) is a diagram schematically showing an example of a selection table of inspection point type icons in the inspection point type registration shown in FIG. 3, and (b) is an acquisition of default values of reference values shown in FIG. is a diagram schematically showing an example of a default value table in . FIG. 3 is a flow diagram schematically showing an example of the flow of the measurement mode shown in FIG. 2; FIG. 10 is a diagram schematically showing an example of a result display screen in the result display shown in FIG. 9; FIG.

[Embodiment 1]
An embodiment of the present invention will be described in detail below.

FIG. 1 is a block diagram schematically showing an example of a pollution degree measurement system according to one embodiment of the present invention.

As shown in FIG. 1 , the pollution degree measurement system 1 includes a pollution degree measurement kit 2 and a communication terminal 4 capable of communicating with the pollution degree measurement kit 2 and connectable to an external network 3 . The pollution degree measurement system 1 may further include a management server 5 capable of communicating with the communication terminal 4 through the external network 3 .

(Pollution measurement kit)
The contamination level measurement kit 2 is a contamination level measurement kit for measuring the contamination level of an object to be measured by at least one of ATP, ADP, and AMP. Since the measurement principle for measuring the degree of contamination by at least one of ATP, ADP, and AMP is well known, detailed description thereof will be omitted.

The contamination measuring kit 2 may consist of a disposable consumable part 2a and a reusable measuring device 2b. The consumable part 2a includes a cotton swab for wiping an object to be measured, an extraction reagent for extracting dirt from the cotton swab, a luminescent reagent for reacting with the dirt in the extraction reagent, a container for containing them, and the like. The measuring device 2b includes a recess 2c into which the expendable portion 2a is inserted, a measuring portion 2d that measures the amount of emitted light from the inserted expendable portion 2a, a communication portion 2g that communicates with the communication terminal 4, a processor 2h, and the like. The measurement device 2b may further include a start button 2e for starting measurement by the measurement unit 2d, a display unit 2f for displaying the measurement results, a storage unit 2i, and the like. A specific configuration of the contamination measurement kit 2 can be appropriately designed by those skilled in the art, and thus detailed description thereof is omitted.

(communication terminal)
The communication terminal 4 includes a storage unit 4a that stores various data, a processor 4b that executes various programs, a display unit 4c, an input unit 4d, and a communication unit 4e that communicates with the communication unit 2g of the measuring device 2b. A communication terminal program according to an embodiment of the present invention is recorded in the storage unit 4a as an application program (hereinafter referred to as an application). The processor 4b can read an application from the storage unit 4a and execute the application. Thereby, the communication terminal 4 can automatically operate the pollution degree measurement kit 2 and functions as a user interface of the pollution degree measurement system 1 .

A CPU (Central Processing Unit), for example, can be used as the processor 4b. The storage unit 4a is a computer-readable recording medium. As the recording medium, a "non-temporary tangible medium" such as a ROM (Read Only Memory), a tape, a disk, a card, a semiconductor memory, a programmable logic circuit, or the like can be used. In addition, a RAM (Random Access Memory) for developing the application may be further provided. Also, the application may be supplied to the processor 4b via the external network 3 . The external network 3 may be any transmission medium (communication network, broadcast waves, etc.) capable of transmitting the application. Note that one aspect of the present invention can also be implemented in the form of a data signal embedded in a carrier wave in which the application is embodied by electronic transmission.

The communication units 2g and 4e may communicate with each other wirelessly by infrared communication or Bluetooth (registered trademark) communication, or by wired communication through a USB cable or the like. The communication terminal 4 may be a mobile communication terminal such as a smart phone and a tablet, or a fixed communication terminal such as a personal computer. Alternatively, communication terminal 4 may be a dedicated terminal. For the sake of simplicity, this specification exemplifies a case where the communication units 2g and 4e perform Bluetooth (registered trademark) communication, the communication terminal 4 is a smartphone, and an application is stored in the storage unit 4a.

(app)
FIG. 2 is a flow diagram schematically showing an example of the flow of an application executed by the processor 4b of the communication terminal 4 shown in FIG.

As shown in FIG. 2, in the processor 4b that executes the application according to one embodiment of the present invention, first, it is determined whether or not the initialization has been completed (step S1). It is determined whether or not to change the setting (step S5). If the initial setting has not been completed (step S1; No) and if the setting is to be changed (step S5; Yes), the setting mode is entered (S2). The communication terminal 4 can implement a setting unit that sets measurement points for measuring the degree of contamination by executing the setting mode by the processor 4b. The setting mode will be described later with reference to FIGS. 3 to 8. FIG.

Subsequently, as shown in FIG. 2, when the initial setting has been completed and the setting has not been changed (step S5; No), and when step S2 has been completed, it is determined whether to measure (step S3). If measurement is to be performed (step S3; Yes), the measurement mode is entered (S4). The communication terminal 4 has an instruction unit that instructs the pollution degree measurement kit 2 to start the pollution degree measurement by the processor 4b executing the measurement mode; and an acquisition unit that acquires the measurement result from the pollution degree measurement kit 2. ; and a determination unit that determines the measurement result based on the reference value. The measurement mode will be described later with reference to FIGS. 9-10.

Then, as shown in FIG. 2, when the measurement in the measurement mode is completed, it is determined whether to perform the measurement again (step S3). When not measuring (step S3; No), the process ends. Without being limited to this, an app according to an embodiment of the present invention may include other modes such as an analysis mode, a calibration mode, and a cleaning mode.

(setting mode)
(user registration)
FIG. 3 is a flow diagram schematically showing an example of the flow of the setting mode (step S2) shown in FIG. The flow exemplified in this specification does not limit the scope of the present invention, and a flow in which the order of processing steps is changed, added, or omitted as appropriate by a person skilled in the art is also included in the scope of the present invention. As shown in FIG. 3, first, user registration is performed (step S10). Here, various user information is input by the user, and the business type is registered (step S11, business type registration section).

FIG. 4 is a diagram schematically showing an example of a registration screen displayed on the display unit 4c by the communication terminal 4 in step S10 shown in FIG. The communication terminal 4 may display the "new member information registration" screen shown in FIG. 4 on the display unit 4c and request the user to input various user information.

FIG. 5 is a diagram schematically showing an example of a set of business type icons displayed on the display section 4c by the communication terminal 4 in step S11 shown in FIG. The icons shown in FIG. 5 represent (a) food factories, (b) medical facilities such as hospitals, (c) catering facilities and restaurants with kitchens, and (d) other business types. In the business type registration (step S11), the communication terminal 4 may present several business types to the user by displaying a set of business type icons shown in FIG. 5 on the display section 4c. The user may enter the business type by icon selection. Alternatively, communication terminal 4 may automatically select a business type based on user information such as company name or facility name. The user may or may not change the business type from the selected type.

(register to be a member)
Subsequently, as shown in FIG. 3, members are registered (step S20). Here, first, the identification name of the member is input by the user, and the identification name is registered (step S21). Then, the member type of the member is input by the user, and the member type is registered (step S22). In this specification, the person who performs the measurement in the measurement mode is called the "measurer", and the pre-registered person is called the "member". Members include potential measurers. In addition, members may include non-candidate measurers. A member's identification name may be anything, such as a real name, a nickname, or an employee number.

FIG. 6 is a diagram schematically showing an example of a set of member type icons displayed by the communication terminal 4 on the display section 4c in the member type registration shown in FIG. The icons shown in FIG. 6 are (a) the restaurant owner or manager, (b) a member of the hygiene management department, (c) a field employee, (d) a male chef, (e) a female chef, and (f). A male doctor, (g) a female doctor, (h) a nurse, (i) a patient, (j) a waiter, (k) a waitress, and (l) a pastry chef are shown. In step S22, the communication terminal 4 presents the member type to the user by displaying (i) a set of member type icons shown in FIG. 6 and (ii) an icon indicating addition of the member type on the display unit 4c. good too. The user may enter the member type for each member by icon selection. If member type addition is selected, the member type to be added is registered in the next step S23.

Preferably, the member type icon is selectively shown according to the registered business type. For example, in the case of a food factory, additional icons for (b) health department personnel, (c) field workers, and member types are selectively shown. For example, for a medical facility, additional icons for (f) male doctor, (g) female doctor, (h) nurse, (i) patient, (j) waiter, (k) waitress, and member types can be optionally selected. shown in For example, in the case of food service facilities and restaurants, (a) restaurant owner or manager, (d) male chef, (e) female chef, (j) waiter, (k) waitress, (l) pastry chef, and add member types. This makes it easier for the user to select the member type icon.

As shown in FIG. 3, when the user selects addition of member types in step S22, member types are added (step S23). Here, the user adds a desired member type and a member type icon indicating it, and the communication terminal 4 registers the added member type and member type icon. A new member type icon may be created from an image taken by the camera function attached to the communication terminal 4 or another digital camera, or an image prepared by other methods.

Then, when the user selects other than addition of the member type in step S22, and when addition of the member type is completed, detailed information or remarks regarding the member can be appropriately registered (step S24).

(Registration of inspection points)
Subsequently, as shown in FIG. 3, inspection points are registered (step S30, inspection point registration unit). Here, first, the user inputs the inspection point type of the inspection point, and the inspection point type is registered (step S31, inspection point type registration section). In this specification, the item to be measured in the measurement mode is called "measurement object", and the pre-registered item is called "inspection point". The inspection points include candidates for measurement targets.

FIG. 7 is a diagram schematically showing an example of a set of inspection point type icons displayed by the communication terminal 4 on the display section 4c in the inspection point registration shown in FIG. (00) to (21) in FIG. 7 indicate inspection point type icons of inspection point type IDs WO_POINT_00 to WO_POINT_21 in order. In step S31, the communication terminal 4 displays (i) a set of inspection point type icons shown in FIG. 7 and (ii) an icon indicating addition of an inspection point type on the display unit 4c, thereby prompting the user to select the inspection point type. may be presented. The user may enter the inspection point type for each inspection point by icon selection. This makes it easier for the user to understand what should be registered as an inspection point. If addition of an inspection point type is selected in step S31, the inspection point type to be added is registered in the next step S32. Also, the inspection point type added in step S32 is added to the list of inspection point types presented in step S31 from the next time onward.

Preferably, the inspection point type icon is selectively shown according to the registered business type. For example, as shown in FIG. 8(a), an inspection point type icon is selectively shown. This makes it easier for the user to select the inspection point type icon. Furthermore, it is easier for the user to understand what should be the inspection points.

As shown in FIG. 3, when the user selects addition of an inspection point type in step S31, an inspection point type is added (step S32, inspection point type addition unit). Here, the user adds a desired inspection point type and an inspection point type icon indicating it, and the communication terminal 4 registers the added inspection point type and inspection point type icon. A new inspection point icon may be created from an image captured by a camera function attached to the communication terminal 4 or a digital camera, or an image prepared by another method.

Preferably, the inspection point icon indicates a portion of the consumable portion 2a to be wiped with a cotton swab. For example, a knowledgeable (or researched) user may mark a wipe location on an image and an inspection point icon created from the image. Also, for example, a typical inspection point may have a wiping site indicated in its inspection point icon from the beginning. This makes it easier for the measurer to understand what should be wiped, so that even an unskilled measurer can appropriately perform the wiping test. This not only reduces the burden on the measurer, but also reduces errors and variations caused by the measurer.

Then, if the user selects anything other than adding an inspection point type in step S31 and if step S32 is completed, the default name of the identification name of the inspection point is acquired according to the registered inspection point type (step S33). For example, if the inspection point type is kitchen knife, default names such as "kitchen knife 1" and "kitchen knife 2" may be obtained. Then, identification name registration is performed (step S34). Here, for example, the communication terminal 4 may display on the display unit 4c a screen in which the default name obtained in step S33 is provisionally entered in the identification name input field, and the user can edit the identification name. . The user may or may not change the identification name from the default name. As a result, it is possible to reduce the effort of the user to input the identification name. In addition, since even a user who has no knowledge of inspection points can appropriately name them, it becomes easier for other personnel to identify inspection points from identification names. In addition, since a user who has knowledge about inspection points can customize identification names, convenience is improved.

Further, according to the registered inspection point type, the default value of the reference value of the degree of contamination at the inspection point is obtained (step S35, default value obtaining unit). For example, there are three levels of judgment results based on the degree of contamination: "pass", "caution", and "fail". A case where there is a "criterion 2" between "needs attention" and "failed" is exemplified. For example, as shown in (b) of FIG. 8, default values of "reference 1" and "reference 2" are acquired according to the inspection point type.

Note that the table shown in FIG. 8 may be stored in the storage unit 4a of the communication terminal 4. FIG.

Then, as shown in FIG. 3, reference value registration is performed (step S36). Here, for example, the communication terminal 4 may display, on the display unit 4c, a screen in which the default value obtained in step S35 is provisionally entered in the reference value input field, and the user can edit the reference value. . The user may change the reference value from the default value or leave it at the default value. As a result, it is possible to reduce the user's labor for inputting the reference value. In addition, even a user who has no knowledge about the degree of contamination can manage hygiene based on the degree of contamination. After that, detailed information or remarks regarding inspection points can be appropriately registered (step S37). For example, in step 37, the user may save an image of the area to be wiped marked with a marker.

Step S30 may further include a step (not shown, icon giving unit) of giving an item icon to each inspection point. The item icon for each inspection point is preferably created from the image of that inspection point. This makes it easier for the measurer to understand what the inspection points are.

Step S30 may further include a step (code assigning unit) (not shown) of assigning a machine-readable code such as a QR code (registered trademark), and the communication terminal 4 is a reading unit capable of reading the assigned code. may be provided. By marking the assigned code on the inspection list and/or the physical object of the inspection point, it is possible to easily select the measurement object from the inspection points. In addition, it is possible to confirm whether the object to be measured is correct or not. Assignment of this code may be performed automatically. For example, a screen for printing a code on a seal may be automatically opened, or a list of inspection points may be automatically printed.

(measurement mode)
FIG. 9 is a flow diagram schematically showing an example of the flow of the measurement mode (step S3) shown in FIG. As shown in FIG. 9, first, a person to be measured is designated from the registered members (step S40), and a measurement target is designated from the registered inspection points (step S41). When step S30 includes the step of giving an item icon to each inspection point, step 41 may display the item icon on the display unit 4c by the communication terminal 4 and select the measurement target from the inspection points by icon selection (second measurement target selection section). Step 41 inspects the measurement object by reading the code marked on the inspection list and/or the physical object of the inspection point with a reader, if step S30 includes applying a machine-readable code to each inspection point. It may be selected from points (first measurement target selection unit).

Then, the communication terminal 4 displays measurement guidance on the display section 4c (step S42), and the subject prepares for measurement according to the measurement guidance. Specifically, the measurer removes the cotton swab of the consumable part 2a from the container, applies it, wipes the object to be measured with the cotton swab, returns the cotton swab to the container, shakes the consumable part 2a well, and then places it on the concave part 2c of the measuring device 2b. insert.

During or after the measurement guidance, the measurer instructs the communication terminal 4 to start measurement through the input unit 4d. Then, the communication terminal 4 instructs the measurement device 2b to start measuring the degree of contamination through the communication section 4e and the communication section 2g (step S43, instruction section).

When the communication terminal 4 instructs the measurement device 2b to perform measurement, the measurement unit 2d starts measurement (step S50). Upon starting the measurement, the measurement device 2b notifies the communication terminal 4 of measurement parameters such as the time required for measurement through the communication units 4e and 2g (step S51), and the communication terminal 4 acquires the measurement parameters. Then, the communication terminal 4 and the measurement device 2b count down the time required for measurement (steps S45 and S52).

After the countdown, the measuring device 2b notifies the communication terminal 4 of the contamination degree measurement result through the communication unit 4e and the communication unit 2g (step S54), and the communication terminal 4 acquires the contamination degree measurement result (step S46, acquisition unit ). Then, the communication terminal 4 determines the measurement result based on the reference value registered in step S35 (step S47, determination section). The communication terminal 4 further generates a graph based on the history of the measurement result of the measurement target (step S48, graph generating section).

FIG. 10 is a diagram schematically showing an example of the result display screen displayed by the communication terminal 4 on the display unit 4c in the result display (step S493) shown in FIG. The communication terminal 4 may display one or more of the measurement result, the determination result, the graph, etc., as shown in FIG. 10 (step S49).

The measurement mode (step S<b>4 ) may further include a step of storing the measurement result in the storage unit 4 a of the communication terminal 4 , although illustration is omitted.

(Measurement frequency setting)
In addition, the application according to the present embodiment is preferably software capable of realizing a calendar section having a calendar function and a scheduling section for setting the frequency or date and time of measuring the contamination level of the object to be measured. In this case, it is more preferable to implement a first alerting unit that alerts the user or measurer to measure the contamination level according to the frequency or date and time set by the scheduling unit.

In addition, the application according to the present embodiment includes an environmental information acquisition unit that acquires environmental information such as temperature and humidity through the external network 3, and alerts the user or measurer to measure the degree of pollution according to the environmental information. It is more preferable to be able to implement a second alerting unit that According to this, for example, the user will pay attention to hygiene management during the rainy season, summer, or warm winter.

Further, it is more preferable that the application according to the present embodiment can implement a measurement frequency recommendation unit that presents the user with the recommended measurement frequency at the location (store, facility, factory, etc.) according to the registered business type. . The higher the measurement frequency, the higher the standard of hygiene control, but the higher the cost. Also, different standards of hygiene control are required depending on the type of business. For this reason, it is beneficial that this application enables measurement at an appropriate frequency according to the type of business, even if the user does not have any knowledge about it.

(Hardware implementation example)
An example in which the various functions of the pollution degree measurement kit 2 and the communication terminal 4 are realized by the processors 4b and 2h executing applications has been described above. Not limited to this, some or all of the various functions of the pollution degree measurement kit 2 and/or the communication terminal 4 may be implemented by a logic circuit (hardware) formed on an integrated circuit (IC chip) or the like. .

(cloud system)
In the pollution degree measurement system 1 , the processor of the management server 5 may execute some of the functions executed by the processor 4 b of the communication terminal 4 instead, and the results may be provided to the communication terminal 4 via the external network 3 . And/or, part of the information stored in the storage unit 4 a of the communication terminal 4 may be stored in the storage unit of the management server 5 instead, and the information may be provided to the communication terminal 4 through the external network 3 .

Preferably, by updating the app, it is possible to add or delete business types, inspection point types, member types, etc., and modify default values for reference values and recommended frequency for measurement frequency. As a result, it is possible to appropriately reflect the spread of user business types, market research results, and changes in sanitary control standards.

Moreover, preferably, the management server 5 can be connected to a plurality of communication terminals 4 . As a result, the measurement results obtained by the plurality of communication terminals 4 can be synchronized and immediately compared in time series.

(effect)
Since conventional contamination measurement kits require skill, it is difficult to introduce contamination measurement kits in places where it is not expected, such as general grocery stores and restaurants where multiple part-time workers work in shifts. rice field. For this reason, there has been a social problem that hygiene management is insufficient and food poisoning is likely to occur. On the other hand, the pollution degree measuring system 1 according to this embodiment can be easily handled by the user. For this reason, in addition to operation in food factories where conventional contamination measurement kits are operated, the contamination measurement system 1 can be used in food service facilities provided in general restaurants, hospitals and schools, hospitals, etc. It is suitable for use in welfare facilities such as medical facilities and nursing homes. Therefore, it is possible to solve social problems such as improvement of sanitary management and suppression of food poisoning in general grocery stores and restaurants.

In the conventional contamination measurement kit, the information of the object to be measured and the reference value are stored inside the contamination measurement kit. For this reason, when the contamination degree of a measurement target is measured with a plurality of contamination degree measurement kits, it is necessary to collect the measurement results in an information terminal such as a personal computer in order to compare the measurement results. On the other hand, in the pollution degree measuring system 1 according to one embodiment of the present invention, the information of the measurement target and the reference value are stored in the storage unit 4a of the communication terminal 4, and the communication terminal 4 automatically displays the measurement result. to acquire For this reason, by connecting a plurality of pollution degree measurement kits 2 to one communication terminal 4, the measurement results from the plurality of pollution degree measurement kits 2 can be immediately compared in chronological order without any aggregation work. can be done.

In the conventional contamination measurement kit, the measurement person manually operates the measurement device at the time of measurement. Specifically, after inserting the consumable part into the concave portion of the measuring device, the measurer manually starts the measurement by pressing a decision key or the like provided on the measuring device. This requires skill because conventional contamination measurement kits are complicated. Then, the measurement results were manually recorded, and the measurement results were aggregated by connecting the measurement device to an information terminal. This also takes a lot of time and effort, so I needed to get used to it. On the other hand, in the pollution degree measurement system 1 according to one embodiment of the present invention, the communication terminal 4 automatically operates the pollution degree measurement kit 2 . Specifically, the communication terminal 4 displays a screen for starting measurement on the display unit 4a, receives an instruction from the measurement person, instructs the measurement device 2b to start measurement, and then automatically acquires the measurement result. do. The screen for starting measurement is simple and does not require skill. In addition, since the start of measurement and a series of subsequent operations are automatically operated by the communication terminal 4, it does not take time and effort and does not require skill.

The present invention is not limited to the above-described embodiments, but can be modified in various ways within the scope of the claims, and can be obtained by appropriately combining technical means disclosed in different embodiments. is also included in the technical scope of the present invention.

1 Pollution degree measurement system 2 Pollution degree measurement kit 2a Consumable part 2b Measuring device 2c Concave part 2d Measuring part 2e Start button 2f, 4c Display part 2g, 4e Communication part 2h, 4b Processor 2i, 4a Storage part 3 External network 4 Communication terminal 4d input unit 5 management server

Claims (14)

a contamination level measurement kit for measuring the contamination level of an object to be measured by at least one of ATP, ADP, and AMP;
A pollution degree measurement system comprising a communication terminal capable of communicating with the pollution degree measurement kit and connectable to an external network,
The above communication terminal
It is capable of operating the contamination measurement kit ,
an instruction unit for instructing the contamination measurement kit to start measuring the contamination;
an acquisition unit that acquires measurement results from the pollution degree measurement kit;
a determination unit that determines the measurement result based on a reference value;
a storage unit that stores the reference value;
a setting unit including an inspection point registration unit that registers inspection points for measuring the degree of contamination,
The contamination measurement kit includes a measurement unit that starts measurement of the contamination according to the instruction of the instruction unit,
The pollution degree measurement system , wherein the setting unit registers member types of members who are personnel who perform the measurement . The setting unit further comprises a business type registration unit for registering a business type,
The above inspection point registration unit
an inspection point type addition unit for adding inspection point types;
For each inspection point, an inspection point type registration unit that registers one of (i) an inspection point type corresponding to the registered business type and (ii) an inspection point type added by the inspection point type addition unit. 2. The pollution degree measurement system according to claim 1 , comprising: 3. The degree of contamination according to claim 2 , wherein the inspection point registration unit further comprises a default value acquisition unit that acquires a default value of the reference value corresponding to a registered inspection point type for each inspection point. measurement system. The inspection point registration unit further includes a code assigning unit that assigns a machine-readable code to each inspection point,
The above communication terminal
a reading unit for reading the code;
4. The method according to any one of claims 1 to 3 , further comprising a first measurement object selection unit that selects the measurement object from registered inspection points based on the code read by the reading unit. A pollution degree measurement system as described. The inspection point registration unit further includes an icon assigning unit that assigns an item icon to each inspection point,
The communication terminal according to any one of claims 1 to 4 , further comprising a second measurement target selection unit that selects the measurement target from registered inspection points based on selection of the item icon. The pollution degree measurement system described in . The above icon assigning unit
6. The pollution degree measuring system according to claim 5 , wherein for each inspection point, the item icon is created from the image of the inspection point. 7. The pollution degree measuring system according to claim 1 , wherein said communication terminal is a mobile communication terminal having a camera function. The communication terminal further includes a graph generation unit that generates a graph based on the history of measurement results of the measurement target,
8. Contamination according to any one of claims 1 to 7 , characterized in that any one or more of the measurement result from the contamination degree measurement kit, the judgment result by the judging section, and the graph are displayed. Degree measurement system. The above communication terminal
a calendar part with a calendar function;
a scheduling unit that sets the frequency or date and time of measuring the degree of contamination;
9. The method according to any one of claims 1 to 8 , further comprising a first alerting unit that alerts to measure the degree of contamination according to the frequency or date and time set by the scheduling unit. Pollution degree measurement system. The above communication terminal
an environment information acquisition unit that acquires environment information through the external network;
10. The pollution degree measuring system according to any one of claims 1 to 9 , further comprising a second alerting unit that calls attention to measure the pollution degree according to the environmental information. a contamination level measurement kit for measuring the contamination level of an object to be measured by at least one of ATP, ADP, and AMP;
A pollution degree measurement system comprising a communication terminal capable of communicating with the pollution degree measurement kit and connectable to an external network,
The above communication terminal
It is capable of operating the contamination measurement kit,
an instruction unit for instructing the contamination measurement kit to start measuring the contamination;
an acquisition unit that acquires measurement results from the pollution degree measurement kit;
a determination unit that determines the measurement result based on a reference value;
a storage unit that stores the reference value;
a setting unit including an inspection point registration unit that registers inspection points for measuring the degree of contamination,
The contamination measurement kit includes a measurement unit that starts measurement of the contamination according to the instruction of the instruction unit,
The setting unit further comprises a business type registration unit for registering a business type,
The above inspection point registration unit
an inspection point type addition unit for adding inspection point types;
For each inspection point, an inspection point type registration unit that registers one of (i) an inspection point type corresponding to the registered business type and (ii) an inspection point type added by the inspection point type addition unit. and
The inspection point registration unit selectively indicates an inspection point type icon indicating the inspection point type according to the registered business type,
When the addition of the inspection point type is selected, the selected inspection point type is registered, and thereafter, the inspection indicating the additionally registered inspection point type in the selectively displayed inspection point icon. A pollution degree measurement system comprising a point icon. 12. The contamination degree measurement system according to claim 2 or 11, wherein said inspection point registration unit selectively displays a member type icon indicating a type of member who is a person who performs said measurement according to said business type. A communication terminal program for causing a computer to function as the communication terminal included in the pollution degree measurement system according to any one of claims 1 to 12 ,
A communication terminal program for causing a computer to function as the instruction unit, the acquisition unit, and the determination unit. 14. A computer-readable recording medium recording the communication terminal program according to claim 13.

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