JP6856951B2 - Mixer control system and mixer control method - Google Patents

Description

The present invention relates to a mixer control system, and more specifically, a mixer control system and a mixer control method for controlling each mixer device so that an edible dough in an optimum mixing state for each product can be stably produced by each mixer device. Regarding.

In the manufacturing process of mixing that manufactures bread etc. using flour as the main raw material, the finished temperature of the dough is adjusted regardless of the environmental conditions at the time of manufacturing such as the temperature of the main raw material, the temperature of the charged water, the room temperature and the humidity, and the amount of the raw material charged. It is not easy to keep it constant at all times. Therefore, even under different environmental conditions, automatic control of mixing is required to keep the finished temperature of the edible dough constant by adjusting the rotation speed, rotation time, and the like of the mixer device.

As a prior art, for example, Patent Document 1 uses a relational expression between the rotation speed of a mixer obtained in advance, the mixing end time of bread dough, and the average value of the absolute temperature of bread dough until the end of mixing. , A mixing management method for managing the mixing using the obtained relational expression to be carried out thereafter is disclosed. However, in this method, the rotation speed and the rotation time of the mixer are not adjusted according to the amount of bread dough charged. In addition, in response to changes in the manufacturing environment, only the average temperature of the bread dough during mixing is captured, and other measures against the water temperature, room temperature, humidity, etc. are not taken, so the finished temperature of the bread dough varies. Includes problems that arise.

On the other hand, Patent Document 2 describes a technique in which the mixing bowl is cooled before the start of kneading so that the dough temperature at the end of kneading is close to the target dough temperature, and the temperature control of the mixing bowl after the start of kneading is not required. However, while the amount of heat generated during kneading is calculated from the active power for driving the mixer, the rotation speed and rotation time of the mixer are not optimized for changes in the amount charged and environmental conditions. .. Therefore, although the dough temperature at the end of kneading is close to the target dough temperature, there is a problem that the elasticity and elongation of the dough are not constant.
Further, in these prior arts, the problem that the finished state of the dough differs for each mixer device due to the characteristic difference and the performance variation of the mixer device itself has been overlooked.

Japanese Unexamined Patent Publication No. 2001-275550 Japanese Unexamined Patent Publication No. 2011-62113

The present invention has been made in view of the above-mentioned conventional problems, and an object of the present invention is to ensure that edible dough in an optimum mixed state for each product is reproducibly produced by individual mixer devices. Mixer control that controls each mixer device by generating mixer control data corresponding to each mixer device based on the fabric manufacturing designation data of the product to be manufactured input from each mixer device and the environmental data at the time of manufacturing. To provide the system.

The mixer control system according to one aspect of the present invention, which has been made to achieve the above object, manufactures the dough of the product to be manufactured so that the edible dough in the optimum mixing state for each product can be manufactured with good reproducibility by each mixer device. A mixer control system that controls the individual mixer devices based on instruction data and environmental data at the time of manufacture.
The mixer control system is connected to a mixer device for producing the edible dough of the product to be manufactured and the mixer device, and the mixer device executes a mixing operation optimized for the edible dough of the product to be manufactured. A mixer management device that generates mixer control data corresponding to the mixer device and transmits it to the mixer device, and a standard of edible dough for each product name connected to the mixer management device and associated with the mixer device. The mixer device includes a database in which mixing control information and mixing condition correction information are stored, and the mixer device has an instruction input unit for receiving production instructions for edible dough of the product to be manufactured, and raw materials including powder material and charged water. A mixing unit to be mixed, a control unit that controls the mixing operation of the mixing unit based on the mixer control data generated for the edible dough of the product to be manufactured, and the mixing unit as environmental data at the time of manufacturing. A sensor unit that acquires the room temperature, humidity, and temperature of the raw material in the ambient environment using various sensors, and monitors the rotation speed and torque value of the mixing unit at the time of manufacture using a predetermined sensor, and the instruction. The dough manufacturing instruction data including the product name and the amount to be charged received by the input unit and the environmental data acquired by the sensor unit are transmitted to the mixer management device, and the mixer management device sends the dough for the edible dough of the product to be manufactured. The mixer management device includes a data communication unit that receives the generated mixer control data, and the mixer management device is associated with the mixer device from the database based on the dough production instruction data received from the mixer device. The mixing condition acquisition unit that acquires the standard mixing control information and the mixing condition correction information of the edible dough of the product to be manufactured, the environmental data at the time of manufacturing received from the mixer device, and the acquired mixing condition correction information. A control data generator that generates mixer control data for the mixer device that optimizes the target value of the rotation speed of the mixing section of the mixer device included in the acquired standard mixing control information, and includes Based on the monitoring data of the rotation speed of the mixing unit sequentially received from the sensor unit, the control unit of the mixer device sets the rotation speed of the mixing unit to the target value of the rotation speed specified by the mixer control data. Control the mixing unit so as to maintain It is characterized by that.

The mixer control method according to one aspect of the present invention made to achieve the above object is to manufacture the dough of the product to be manufactured so that the edible dough in the optimum mixing state for each product can be manufactured with good reproducibility by each mixer device. A mixer control method for controlling the individual mixer devices based on the instruction data and the environmental data at the time of manufacturing.
A mixer device for producing edible dough for each product to be manufactured, and the mixer device connected to the mixer device so that the mixer device executes a mixing operation optimized for the edible dough of the product to be manufactured. A mixer management device that generates mixer control data corresponding to the above and sends it to the mixer device, and standard mixing control information and mixing of edible dough for each product name connected to the mixer management device and associated with the mixer device. In a mixer control system including a database in which condition correction information is stored, the mixer device receives a manufacturing instruction for edible dough of the product to be manufactured, and a product name and preparation specified in the received manufacturing instruction. The step of transmitting the dough production instruction data including the amount and the environmental data acquired by the sensor unit to the mixer management device, and the dough production instruction data received from the mixer device by the mixer management device. From the database, the step of acquiring the standard mixing control information and the mixing condition correction information of the edible dough of the product to be manufactured associated with the mixer device, the environmental data at the time of manufacturing received from the mixer device, and the environment data at the time of manufacturing. Using the mixing condition correction information, the mixer control data for the mixer device that optimizes the target value of the rotation speed of the mixing unit of the mixer device included in the acquired standard mixing control information is generated. The rotation of the mixing unit is based on the steps, the stage of transmitting the generated mixer control data to the mixer device, and the monitoring data of the rotation speed of the mixing unit sequentially received by the mixer device from the sensor unit. The speed is characterized by having a step of controlling the mixing unit so as to maintain a target value of the rotation speed specified in the mixer control data.

According to the present invention, edible dough in an optimum mixing state for each product can be stably produced with good reproducibility by individual mixer devices even under different production environments.
Further, according to the present invention, the mixer control data optimized for each mixer device is generated based on the monitoring data of the charged amount of the product and the manufacturing environment, and the mixer device is automatically controlled. The work is streamlined, and edible dough with little quality variation can be manufactured regardless of the skill of the craftsman.

It is the schematic which shows the structure of the mixer control system by one Embodiment of this invention. It is a block diagram which shows the structural example of the mixer apparatus by one Embodiment of this invention. It is a block diagram which shows the structural example of the mixer management apparatus by one Embodiment of this invention. It is a figure which shows an example of the standard mixing condition table in this embodiment. It is the schematic which shows the structure of the mixer control system by another embodiment of this invention. It is a flowchart which shows the processing procedure of the data transmission | transmission between the mixer apparatus and the mixer management apparatus in the mixer control method by one Embodiment of this invention. It is a figure which shows an example of the manufacturing instruction input screen transmitted to the mixer apparatus by one Embodiment of this invention. It is a flowchart which shows the processing procedure which generates the mixer control data of a mixer apparatus in the mixer control method by one Embodiment of this invention.

Hereinafter, specific examples of embodiments for carrying out the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic view showing a configuration of a mixer control system according to an embodiment of the present invention.

As shown in FIG. 1, in the mixer control system 1 according to the embodiment of the present invention, the mixer device 10 for producing the edible dough used for the bread product and the edible dough produced by the mixer device 10 are in the optimum finished state. In order to generate the mixer control device 20 for controlling the mixing operation of the mixer device and provide the mixer device 10 with the mixer control device 20 and the mixer control data provided to the mixer device 10 so as to be It is provided with a database 30 in which various necessary information is stored. The mixer management device 20 is communicably connected to the mixer device 10 and the database 30. The mixer management device 20 according to the embodiment of the present invention is configured to be connectable to one or a plurality of mixer devices 10, and the number of connected mixer devices 10 is not particularly limited. Further, the database 30 may be provided in the mixer management device 20 or may be built in an individual storage device or server computer.

FIG. 2 is a block diagram showing a configuration example of a mixer device according to an embodiment of the present invention.

As shown in FIG. 2, the mixer device 10 according to the embodiment of the present invention includes an instruction input unit 11, a mixing unit 12, a control unit 13, a sensor unit 14, a data communication unit 15, a display unit 16, and a storage unit 17. Including.

The instruction input unit 11 includes input means (not shown) such as a keypad and a touch panel, and receives production instructions for edible dough of the product to be manufactured through such input means. The manufacturing instruction includes, for example, the product name and the amount (weight) of the product to be manufactured, and the selected or input information is transmitted to the mixer management device 20 as manufacturing instruction data (hereinafter referred to as dough manufacturing instruction data). Will be done. A voice input device or the like can also be applied to the input means.

The mixing unit 12 is a means for mixing the powder material and the raw material including the charged water. The mixing unit 12 includes a mixing bowl (hereinafter referred to as a bowl) 12a into which raw materials including powder material and charged water are charged, a hook 12b for mixing the raw material charged in the bowl 12a, and a motor for rotating the hook 12b. It includes 12c. In addition, a separate motor for rotating the bowl 12a may be included. The present invention is not limited to this, and the form and capacity of the mixing unit 12 are not particularly limited. Further, the shape and size of the hook and the bowl can be appropriately selected according to the raw material, the mixing ratio, the weight and the like of the edible dough to be mixed.

In one embodiment of the present invention, the motor 12c (and the motor that drives and rotates the bowl 12a) that drives and rotates the hook 12b changes the rotation speed and the driving force steplessly by, for example, inverter control. It is possible to control the rotation speed of the hook and the bowl so as to maintain a predetermined rotation speed preset according to the product to be manufactured, based on the mixer control data described later. The type of motor and the drive control method are not particularly limited as long as the rotation speed and the drive force can be changed steplessly.

The control unit 13 controls the mixing operation of the mixing unit 12 based on the mixer control data generated for the edible dough of the product to be manufactured. Specifically, the rotation speed and rotation time of each motor that drives the hook and the bowl are controlled. Further, the control unit 13 calculates a torque value from a predetermined detection signal (for example, drive current) indicating the drive state of each motor acquired by the sensor unit 14, which will be described later, and uses an impulse using the torque value to obtain a fabric. The mixing state of the above is determined, and a predetermined process is executed. The control unit 13 includes a CPU (central processing unit) (not shown) and a storage device such as a ROM and RAM, and controls the entire mixer device 10. However, the present invention is not limited to this, and may be configured by a so-called sequencer that does not have (does not include) a CPU.

The sensor unit 14 includes the air temperature and humidity as the ambient environment of the mixing unit 12, for example, the room temperature and humidity of the work room where the mixer device 10 is installed, and the temperature of the raw material (the temperature of the powder material and the temperature of the charged water). And are acquired using various corresponding sensors. The various sensors are arranged at predetermined positions at predetermined locations, and after the mixer device 10 is activated, the continuously acquired detection signals are sequentially transmitted to the sensor unit 14. Further, the sensor unit 14 acquires detection signals for monitoring the temperature of the edible dough, the rotation speed of the motor 12c of the mixing unit, and the torque value by using predetermined sensors, respectively. For example, a thermopile or the like is used as a sensor for measuring the temperature of edible dough, and an optical sensor is used for measuring the rotation speed of the motor. Further, a motor current sensor or a torque sensor may be used for measuring the torque value of the motor, but the measurement is not limited to this.

The sensor unit 14 has at least the room temperature and humidity of the ambient environment of the mixing unit 12 and the temperature of the raw material (the temperature of the powder material and the temperature of the charged water) among the numerical data obtained by digitally converting the detection signals received from the various sensors. ) As environmental data and is transmitted to the data communication unit 15. Further, during the mixing operation, a predetermined detection signal for measuring the rotation speed and torque value of the motor 12c of the mixing unit is monitored in real time and sequentially transmitted to the control unit 13.

The data communication unit 15 is connected to the mixer management device 20 by a predetermined wired or wireless communication method, and the dough production instruction data including the product name and the charge amount received by the instruction input unit 11 and the environment acquired by the sensor unit 14. The data is transmitted to the mixer management device 20, and the mixer control data generated for the edible dough for each product to be manufactured is received from the mixer management device 20. The communication method of the data communication unit 15 is not particularly limited.

The display unit 16 displays information related to the setting and control of the mixer device output from the control unit 13 on a display panel (not shown). The display panel may be built in or externally attached to the mixer device 10. The format of the display panel is not particularly limited, but it may be provided with a touch input function and also serve as an input means of the instruction input unit 11.

The storage unit 17 stores various programs and data used for controlling the mixer device, and a mixer device number for identifying the mixer device. Further, the storage unit 17 stores the mixer control data generated for the edible dough for each product to be manufactured received from the mixer management device 20.

FIG. 3 is a block diagram showing a configuration example of a mixer management device according to an embodiment of the present invention.

As shown in FIG. 3, the mixer management device 20 according to the embodiment of the present invention includes a system control unit 21 including a CPU, a main storage device, an auxiliary storage device, and the like (not shown), and an auxiliary of the system control unit 21. As a functional unit realized by executing a program or software installed in a storage device (not shown) on a CPU, at least a mixing condition acquisition unit 22 and a control data generation unit 23 are included. The system control unit 21 controls the entire mixer control system.

The mixer management device 20 can use a general PC (personal computer) or workstation, and is connected to or directly connected to one or more mixer devices 10 and the database 30 via a communication network. To. The mixer management device 20 includes a communication unit 25 that communicates with the mixer device 10 and the database 30, a display unit 26 that displays various information in a predetermined display format on a screen of a display or the like (not shown), and each functional unit. It further includes a data storage unit 27 that stores the result data processed in (22, 23), recipe information acquired from the database 30, and the like.

The mixing condition acquisition unit 22 sets the mixing conditions for the edible dough of the product to be manufactured associated with the mixer device based on the dough manufacturing instruction data of the product to be manufactured received from each mixer device 10. The standard mixing control information and the mixing condition correction information are acquired from the database 30. In addition, environmental data such as temperature, room temperature, and humidity of raw materials acquired by the sensor unit 14 are acquired from the mixer device 10.

The control data generation unit 23 has, for each mixer device 10, standard mixing control information and mixing condition correction information corresponding to the mixer device acquired by the mixing condition acquisition unit 22, and environmental data acquired by the sensor unit. Based on the above, a predetermined correction process is performed on the standard mixing control conditions to generate mixer control data corresponding to the mixer device. The details of the procedure for generating the mixer control data will be described later.

The communication unit 25 has a function of transmitting and receiving data to and from one or more connected mixer devices 10, and each mixer device 10 responds to a request or command from the respective mixer device 10 and / or the mixer management device 20. The dough production instruction data and the environmental data are received from the database 30, and the production recipe data corresponding to the mixer device is received from the database 30 and distributed to the mixing condition acquisition unit 22 and the data storage unit 27.

The display unit 26 causes a display device (not shown) to display information related to various settings and controls output from the system control unit 21.

The data storage unit 27 stores various programs and data used for controlling the mixer management device 20. Further, the data storage unit 27 stores the mixer control data generated by the control data generation unit 23 for the edible dough for each product to be manufactured corresponding to each mixer device 10.

The database 30 includes a mixer device ID table 31 in which identification information for identifying each mixer device 10 is registered, a standard mixing condition table 32 in which standard mixing control information associated with each mixer device 10 is registered, and the like. Mixing condition correction table 33, recipe table 34 in which data on the amount of powder material used and the amount of water charged corresponding to the amount charged for each product are arranged, and environmental data including various information during the mixing operation and information on room temperature and humidity. It is composed of a log table 35 that records in association with and.

In one embodiment of the present invention, the database 30 is constructed in a data server separate from the mixer management device 20, and is connected to the mixer management device 20 via a communication network such as the Internet, LAN, or WAN. The database 30 stores standard mixing control information of individual mixer devices 10 corresponding to the edible dough of the product for each product name, and mixing condition correction information based on past actual data of the mixer device 10. However, the present invention is not limited to this, and the database 30 may be composed of a storage device directly connected to the mixer management device 20 or a storage device provided in the mixer management device 20.

The mixer device ID table 31 records the registration information of each mixer device 10. The registration information includes a search key section consisting of a mixer device number, a user ID, and / or a password, which is identification information for each mixer device 10, a factory name belonging to the data section, a manager name, fabric manufacturing instruction data, and registration. Includes information such as date. For example, in the dough production instruction data, the product name to be manufactured, the name of the main raw material, the amount to be charged, and the like are set.

The standard mixing condition table 32 records standard mixing control information for generating mixer control data corresponding to each mixer device 10.

FIG. 4 is a diagram showing an example of a standard mixing condition table according to an embodiment of the present invention. As shown in FIG. 4, the standard mixing control information in the standard mixing condition table 32 includes a search key unit including a mixer device number, a product name, a main raw material name, and a charge amount thereof, and a plurality of search key units in the mixing process belonging to the data unit. Rotation speed (1), number of rotations (1), rotation speed (2), number of rotations (2), rotation speed (3), number of rotations (3), rotation speed (4), number of rotations ( 4) Information such as the target finished temperature of the finished product is stored.
Here, the numerical values in parentheses indicate the order of each stage included in the mixing process, and the rotation speeds (1) to (4) are different rotation speeds within a predetermined low-speed rotation to high-speed rotation range. Is set, and the number of rotations (1) to (4) is set to the number of rotations of the hook and / or the bowl at each stage. Therefore, the rotation time of each stage is a value obtained by dividing the number of rotations by the rotation speed.

The present inventor has found that the viscous elasticity (stickiness and elasticity) of an edible dough strongly depends on the rotational speed and impulse of the mixer device, and for this reason, it is generally used as a control item of the mixer device. The number of rotations (the number of rotations of the hook and / or bowl, in other words, the number of rotation counts) was used as the control item, not the rotation time. Further, in the mixer control method described later, whether or not the impulse of the force (motor driving force) applied to the fabric during the mixing process is integrated from the torque value of the motor of the mixer device and the predetermined target impulse value is reached. By monitoring the torque, the optimum mixing state can be determined. This target impulse value can be added to the standard mixing condition table as shown in FIG. The target impulse value can be set for each stage.

The mixing condition correction table 33 sets the rotation speed and / or the number of rotations at each stage included in the standard mixing control information for a predetermined amount of the main raw material for each product based on the past results of each mixer device 10. , The correction information for correction according to the room temperature and humidity of the ambient environment of the mixer device 10 and the temperature of the raw material (for example, the water temperature of the charged water) is recorded. As an example, the correction information is in each stage of the mixing process belonging to the search key unit consisting of the mixer device number, the product name, the main raw material name, the predetermined charge amount of the main raw material, and the water temperature of the charged water, and the data unit. Stores a calculation formula for calculating the corrected rotation speed and / or the corrected rotation number. The calculation formula is the mixing by the mixing unit of the mixer device 10, which is necessary for the finished temperature of the dough to reach a predetermined target temperature for each product, with the room temperature, the humidity, the charged amount, and the water temperature of the charged water as parameters (variables). It is a regression equation or a model equation for calculating the increase / decrease value of the rotation speed and / or the number of rotations at a predetermined step in the process.

The mixing condition correction table 33 may further have a correction coefficient for the mixing condition with respect to the hardness of the charged water and the amount of enzyme contained in the powder of the main raw material. It is known that the hardness of water varies from region to region and has a strong influence on bread making. For example, since there is a lot of hard water in Europe and most of it is soft water in Japan, in order to minimize the effect of water hardness on the finish of fabrics, based on the results of trial production of fabrics using water of different hardness, A correction coefficient applicable to the above-mentioned calculation formula may be obtained and added to the mixing condition correction table 33. In addition, the amount of enzyme contained in the powder of the main raw material also has a great influence on the finish of the dough in the mixing process. For example, it is known that the amount of enzyme contained in wheat changes depending on the weather at the time of growth. Therefore, as with the hardness of water, a correction coefficient applicable to the above-mentioned calculation formula may be obtained based on the trial result of fabric production and added to the mixing condition correction table 33.

The recipe table 34 records recipe information of raw materials used for each product in order to present to the user information of raw materials to be input to the mixer device 10 in manufacturing the product. The recipe information stores information such as a search key unit consisting of a product name and / or a mixer device number, a standard usage amount of raw materials belonging to the data unit, a standard humidity, and a standard charged water temperature. In addition, correction data of the amount of charged water based on humidity is stored. Main raw materials, sub-raw materials, charged water, etc. can be set as raw materials.

The log table 35 records log information created by adding environmental data transmitted from the mixer device 10 to the mixer control data created by the control data generation unit 23 described later. The log information stores information such as a search key unit consisting of a creation date, a mixer device number, and a creation time, sensor acquisition data belonging to the data unit, rotation speed, rotation time, and registration date. The temperature of the charged water, the temperature of the dough in the manufacturing process, the humidity, etc. are set in the sensor acquisition data.

The data stored in each table of the database 30 described above can be updated at a predetermined time or period according to the usage record of each mixer device 10. There are some individual differences in the characteristics and performance of mixer devices even if they are of the same manufacturer and with the same part number, and individual differences may occur in the degree to which the characteristics and performance of individual mixer devices change over time (aging deterioration). Found. Therefore, the mixer control system according to the present invention always provides a fabric in a stable finished state by reflecting the results of the mixing operation in the standard mixing condition table and the mixing condition correction table associated with each mixer device. be able to.

FIG. 5 is a schematic view showing the configuration of a mixer control system according to another embodiment of the present invention.

In the mixer control system 1'shown in FIG. 5, a plurality of mixer management devices (20a, 20b) and a data server including the database 30 are communicably connected via the Internet 5, and each mixer management device (20a, 20b) is connected. A plurality of mixer devices are connected to 20b). Specifically, the mixer device A1 (10a) and the mixer device A2 (10c) are connected to the mixer management device A (20a), and the mixer device B1 (10b) and the mixer device are connected to the mixer management device B (20b). B2 (10d) is connected. Further, each mixer management device (20a, 20b) is configured to be accessible to each administrator of the corresponding mixer management device using the communication terminals (41, 42) via the Internet 5, and these communication terminals are configured. Information about the product dough mixing process executed by each mixer device (10a, 10b, 10c, 10d) via the corresponding mixer management device (20a, 20b) can be viewed from (41, 42). .. Since the configurations of the respective mixer management devices and the mixer devices are the same as those in the above-described embodiment, detailed description thereof will be omitted. Further, the communication terminals (41, 42) are composed of a smartphone, a tablet terminal, or a computer terminal.

According to the mixer control system shown in FIG. 5, since information that can be commonly used can be shared between each mixer management device and each mixer device, a user who has a plurality of factories and manages a large number of mixer devices Since the work efficiency is improved and more mixing performance data is collected, more detailed analysis and improvement for improving the mixing control can be performed.

Next, a mixer control method in the mixer control system according to the embodiment of the present invention will be described.

In the mixer control method according to the embodiment of the present invention, the processing procedure of data transmission / reception between the mixer device 10 and the mixer management device 20 and the mixer management device 20 responding to the manufacturing instruction input transmitted from the mixer device 10 Then, the processing procedure of acquiring the mixing control information corresponding to the manufacturing instruction input from the database 30 and generating the mixer control data is included.

FIG. 6 is a flowchart showing a processing procedure of data transmission / reception between the mixer device and the mixer management device in the mixer control method according to the embodiment of the present invention. Hereinafter, the operations of the mixer device 10 and the mixer management device 20 will be described with reference to FIGS. 6, 2 and 3.

First, when the mixer device 10 receives the input of the user ID and / or password from the instruction input unit 11 after the start-up, the mixer device 10 requests the mixer management device 20 to authenticate the user via the data communication unit 15 (step S100). Specifically, the mixer device 10 transmits the received user ID and / or password to the mixer management device 20, and the mixer management device 20 performs an authentication process of the received user ID and / or password (step S200). If the authentication is successful, the mixer management device 20 transmits a manufacturing instruction input screen to the requesting mixer device 10 (step S210).

The above-mentioned user authentication step may be omitted. In this case, when the mixer device 10 is started, the mixer device number of the mixer device 10 is transmitted from the mixer device 10 to the mixer management device 20, and the mixer management device 20 identifies the mixer device by the mixer device number. , The manufacturing instruction input screen is transmitted to the requesting mixer device 10.

FIG. 7 is a diagram showing an example of a manufacturing instruction input screen transmitted to the mixer device according to the embodiment of the present invention.

The mixer device 10 displays the received manufacturing instruction input screen on the display unit 16 of the mixer device 10 (step S110). After that, when the instruction input unit 11 receives the production instruction input of the edible dough including the product name to be manufactured and the amount of the product charged, the mixer device 10 receives the input instruction based on the production instruction input screen. The data (hereinafter referred to as dough production instruction data) is transmitted to the mixer management device 20 via the communication unit 15 (step S120).

The mixer management device 20 searches the recipe table 34 of the database 30 based on the received dough production instruction data, and acquires the recipe information corresponding to the product name (step S220). Then, based on the acquired recipe information, preparation condition setting data is generated (step S230), and based on the environmental data received from the mixer device 10, necessary correction processing, for example, the amount of charged water used and the target water temperature The calculation is performed (step S240), and the corrected preparation condition setting data is transmitted to the requesting mixer device 10 (step S250).

Hereinafter, the procedure for generating the preparation condition setting data by the mixer management device 20 will be described in more detail with reference to FIG. 7.
(1) In step S200, the mixer management device 20 searches the mixer device ID table 31 of the database 30 with the user ID and / or password received at the time of user authentication, and acquires the mixer device number of the corresponding mixer device.
(2) On the other hand, in step S120, the mixer device 10 receives an instruction to select a recipe of the product to be manufactured from the selection field A of the manufacturing instruction input screen shown in FIG. 7, and the recipe selected from the input field B. When the input of the charge amount (powder amount) of the main raw material corresponding to the product is received, the dough production instruction data including the product name and the charge amount (powder amount) of the received product to be manufactured is transmitted to the mixer management device 20.
(3) When the mixer management device 20 receives the dough production instruction data from the mixer device 10, the recipe of the database 30 is based on the product name and / or the mixer device number included in the received dough production instruction data in step S220. The table 34 is searched and the corresponding recipe information is acquired.
(4) After that, the mixer management device 20 reads out data such as the standard usage amount of the raw material corresponding to the charge amount of the dough production instruction data and the standard charge water temperature from the recipe information acquired in the process of (3). , (3), the preparation condition setting data for the requesting mixer device 10 is generated in association with the mixer device number acquired in the process (3) (step S230).

On the other hand, in parallel with the above-described procedure for generating the dough production instruction data, the mixer device 10 transmits the environmental data acquired by the sensor unit 14 to the mixer management device 20 (step S130).

The procedure of the environmental data transmission process by the mixer device 10 executed in step S130 will be described below.
(1) When the mixer device 10 receives the input of the user ID and / or password, the room temperature, humidity, and raw materials (for example,) of the work room in which the mixer device 10 is installed are transmitted from various sensors connected to the sensor unit 14. , Powder material and charged water). The temperature of the raw material may be obtained by using a digital thermometer connected to the mixer device 10 or may be received from a thermometer provided in the storage facility of the raw material.
(2) Environmental data including the temperature, humidity, and the temperature of the charged water acquired in the process of (1) and the mixer device number of the mixer device is generated and transmitted to the mixer management device 20.

If the step of inputting the user ID and / or the password described above is omitted, the mixer device 10 is the work in which the mixer device 10 is installed from various sensors connected to the sensor unit 14 after the start-up. The room temperature, humidity, and raw material temperature are acquired, and environmental data in which the acquired temperature, humidity, and raw material temperature are associated with the mixer device number of the mixer device is generated, and the mixer management device 20 is used. It may be configured to transmit.

When the mixer management device 20 receives the environmental data from the mixer device 10, if the received environmental data includes the humidity and the temperature of the charged water, the mixer management device 20 acquires the mixer device number included in the environmental data and the procedure for generating the charging condition setting data. Information on the charged water is acquired from the recipe information corresponding to the product name to be manufactured, and the humidity data included in the received environmental data is substituted into a predetermined correction formula to calculate the amount of charged water to be charged. At this time, the mixer management device 20 calculates the humidity difference by subtracting the humidity of the received environmental data from the standard humidity of the recipe information, and divides the calculated humidity difference by a predetermined humidity to obtain the database 30. The corresponding correction data is obtained from the recipe table 34 of the above, and is added to the standard usage amount of the charged water in the recipe information. Further, the mixer management device 20 substitutes the room temperature data included in the received environmental data into a predetermined calculation formula to calculate the target water temperature of the charged water so that the finished temperature of the dough becomes a predetermined target value (step). S240).

After that, the mixer management device 20 transmits the charging condition setting data including the amount of charged water used after addition and the calculated target water temperature of the charged water corresponding to the room temperature of the working room to the mixer device 10 (step S250). The mixer device 10 causes the display unit 16 to display the amount of charged water used and the target water temperature included in the charging condition setting data received from the mixer management device 20 in the setting confirmation field C of the manufacturing instruction input screen shown in FIG. 7 ( Step S140), waits until there is an instruction input from the user to start manufacturing.

Next, the processing procedure in which the mixer management device 20 acquires the mixing control information corresponding to the dough manufacturing instruction data from the database 30 based on the dough manufacturing instruction data transmitted from the mixer device 10 and generates the mixer control data. explain.

FIG. 8 is a flowchart showing a processing procedure for generating mixer control data of the mixer device in the mixer control method according to the embodiment of the present invention.

After the dough production instruction data is transmitted from the mixer device 10 in step S120, the mixing condition acquisition unit 22 of the mixer management device 20 includes the mixer device number, product name, main raw material name, and main material included in the dough production instruction data. The database 30 is searched based on the charge amount of the raw material, the standard mixing control information corresponding to the requesting mixer device 10 is acquired from the standard mixing condition table 32, and the correction information for each charge amount is obtained from the mixing condition correction table 33. Acquire (step S260).

Next, the control data generation unit 23 of the mixer management device 20 substitutes the environmental data received from the mixer device 10 into the calculation formula included in the correction information for each charge amount acquired by the mixing condition acquisition unit 22, and corrects the rotation. The speed and / or rotation speed is calculated and applied (added or subtracted) to the rotation speed and / or rotation speed of the standard mixing control information to generate mixer control data (step S270).

Specifically, the control data generation unit 23 acquires a calculation formula for calculating the correction rotation speed corresponding to the charged amount of the product to be manufactured, which is included in the dough manufacturing instruction data, from the mixing condition correction table 33, and uses the calculation formula. , The room temperature and humidity included in the environmental data received from the mixer device 10 are substituted, and the mixer control data in which the rotation speed of the standard mixing control information is corrected is generated by the calculated corrected rotation speed. Here, the calculation formula is set for each step in the mixing process, for example, and a multiple regression formula is used in which room temperature and humidity are the explanatory variables and the corrected rotation speed and / or the number of rotations is the objective variable, and each variable is set. On the other hand, the regression coefficient obtained based on the past performance is set. Further, a correction coefficient based on the hardness of the charged water and the amount of enzyme contained in the powder of the main raw material may be further applied to this calculation formula.

After that, the mixer management device 20 transmits the generated mixer control data to the requesting mixer device 10 (step S280). Further, the mixer management device 20 generates log information in which environment data is added to the generated mixer control data, and registers the log information in the log table 35 of the database 30.

When the mixer device 10 receives the mixer control data from the mixer management device 20 (step S150), the mixer device 10 stores the data in the storage unit 17.

After that, when the instruction input unit 11 receives an instruction to start the mixing operation (step S160), the mixer device 10 reads the mixer control data stored in the storage unit 17 into the mixer control data. The mixing unit 12 is controlled based on this.

Specifically, when the control unit 13 of the mixer device 10 starts the mixing operation, the rotation speed of the motor 12c of the mixing unit is acquired from the sensor unit 14 at each stage in the mixing process (step S170). The rotation speed monitoring data is compared with the rotation speed set at each stage of the mixing step included in the mixer control data, that is, the target value (step S180). Then, the output of the motor 12c of the mixing unit is controlled so that the actually measured rotation speed falls within a predetermined allowable value with respect to the target value. When all the steps of the mixing step are completed (step S190), the control unit 13 acquires the temperature of the completed edible dough from the sensor unit 14, displays it on the display unit 16, and transmits it to the mixer management device 20. The mixer management device 20 registers the temperature of the received edible dough of the finished product in the log table 35 as log data of the mixer device 10 in addition to the log information including the mixer control data and the environmental data described above (step S290). ..

In one embodiment, the mixer device 10 may monitor the torque value together with the rotation speed of the motor 12c of the mixing unit after the mixing operation is started. In the mixer device, a torque value is obtained as a resistance that transmits the driving force (mixing force) applied to the dough being manufactured to the motor, and the impulse using this torque value is used to judge the finish of the dough. be able to. Specifically, based on the mixing results tried in advance, the value of "impulse using torque value" that gives the optimum finish (mixing state) is obtained as one item of the standard mixing control information for each product, and this value is obtained. The impulse value may be stored in the standard mixing condition table 32 shown in FIG. 4 as the target impulse value. In this case, the control unit 13 of the mixer device 10 integrates the impulse value from the monitored torque value and determines whether or not the impulse value during the mixing process has reached the target impulse value. An alert notification instructing the end or extension of the mixing operation may be displayed on the display unit 16. Further, the target impulse value in the mixing process may be set at each stage of the mixing process, and the control unit 13 compares the impulse value monitoring result with the target impulse value of each stage for each stage. , The rotation time of the mixing unit at each stage may be adjusted (that is, increased or decreased).

Further, as another embodiment, "impulse using torque value" can be used to determine the degree of aging deterioration of consumable members such as belts of the mixer device 10 itself. For example, the mixer device 10 transmits the output data of the motor and the "force product using the torque value" data at a predetermined stage in the mixing process to the mixer management device 20, and the mixer management device 20 transmits these data. Is included in the log information and recorded in the log table 35 of the database 30. At the time of generating the mixer control data, the mixer management device 20 converts the motor output data and the "force product using torque value" data included in the log information of the mixer device 10 at a predetermined time in the past into the mixer control data. In addition, the data is transmitted to the mixer device 10, and the mixer device 10 determines the degree of deterioration over time by comparing the motor output data, the force product data, and the actual measurement data included in the received mixer control data at the time of mixing. Can be determined. Further, in the determination, when the degree of deterioration with time is small, the mixer device 10 provides feedback to the target value of the rotation speed, and when the degree of deterioration with time is large, an alert notification prompting the replacement of consumable parts is displayed on the display unit 16. You may let me. A program for executing the above-mentioned aged deterioration determination process in the mixer device 10 and the mixer management device 20 is created in advance and stored in the corresponding storage unit 17 and data storage unit 27, respectively.

According to the mixer control system of the present invention described above, each of the plurality of mixer devices can stably produce edible dough in a mixed state optimized for each predetermined product even under different manufacturing environments. Can be provided. In addition, the mixer control data optimized for each individual mixer device is automatically generated based on the monitoring data of the product charge amount and the manufacturing environment, and the mixer device is automatically controlled by the generated mixer control data. The work is streamlined, and edible dough with little quality variation can be manufactured regardless of the skill of the craftsman.

Although the embodiments of the present invention have been described in detail with reference to the drawings, the present invention is not limited to the above-described embodiments and is variously modified within a range that does not deviate from the technical scope of the present invention. It is possible to carry out.

1, 1'Mixer control system 5 Internet 10, 10a, 10b, 10c, 10d Mixer device 11 Instruction input unit 12 Mixing unit 12a Bowl 12b Hook 12c Motor 13 Control unit 14 Sensor unit 15 Data communication unit 16, 26 Display unit 17 Storage Units 20, 20a, 20b Mixer management device 21 System control unit 22 Mixing condition acquisition unit 23 Control data generation unit 25 Communication unit 27 Data storage unit 30 Database 31 Mixer device ID table 32 Standard mixing condition table 33 Mixing condition correction table 34 Recipe table 35 Log table 41, 42 Communication terminal

Claims (8)

The individual mixer device is controlled based on the dough manufacturing instruction data of the product to be manufactured and the environmental data at the time of manufacturing so that the edible dough in the optimum mixed state for each product is manufactured with good reproducibility by the individual mixer device. Mixer control system
The mixer control system
A mixer device that manufactures edible dough for the product to be manufactured, and
The mixer control data corresponding to the mixer device is generated and transmitted to the mixer device so that the mixing operation optimized for the edible dough of the product to be manufactured is executed by the mixer device connected to the mixer device. Mixer management device and
It is provided with a database connected to the mixer management device and storing standard mixing control information and mixing condition correction information of edible dough for each product name associated with the mixer device.
The mixer device
An instruction input unit that accepts manufacturing instructions for edible dough for the product to be manufactured, and
A mixing unit that mixes powder materials and raw materials including water to be charged,
A control unit that controls the mixing operation of the mixing unit based on the mixer control data generated for the edible dough of the product to be manufactured, and a control unit.
As the environmental data at the time of manufacturing, the room temperature and humidity of the ambient environment of the mixing unit and the temperature of the raw material are acquired by using various sensors, and the rotation speed and torque value of the mixing unit at the time of manufacturing are predetermined. The sensor unit that monitors using a sensor and
The dough production instruction data including the product name and the amount to be charged received by the instruction input unit and the environmental data acquired by the sensor unit are transmitted to the mixer management device, and the edible dough of the product to be manufactured is transmitted from the mixer management device. Including a data communication unit that receives the mixer control data generated for
The mixer management device is
Acquisition of mixing conditions for acquiring standard mixing control information and mixing condition correction information of the edible dough of the product to be manufactured associated with the mixer device from the database based on the dough manufacturing instruction data received from the mixer device. Department and
Using the manufacturing environment data received from the mixer device and the acquired mixing condition correction information, a target of the rotation speed of the mixing unit of the mixer device included in the acquired standard mixing control information. wherein the control data generating unit that generates a mixer control data for said mixer device with optimized value, a,
The control unit of the mixer device
Based on the monitoring data of the rotation speed of the mixing unit sequentially received from the sensor unit, the mixing unit is set so that the rotation speed of the mixing unit maintains the target value of the rotation speed specified in the mixer control data. A mixer control system characterized by control. The standard mixing control information includes a target value of the rotation speed of the mixing unit at each of the predetermined stages included in the mixing operation for each amount of the edible dough of the product to be manufactured.
The mixing condition correction information is included in the mixing operation so that the finished temperature of the edible dough reaches a predetermined target temperature for each product to be manufactured, with the room temperature and / or humidity of the ambient environment of the mixing unit as variables. Includes a calculation formula for correcting the target value of the rotation speed of the mixing unit in each of the predetermined stages.
The control data generation unit
The correction value calculated by substituting the environmental data received from the mixer device into the corresponding variable of the calculation formula, and is the target value of the rotation speed of the mixing unit in each of the predetermined stages included in the mixing operation. The mixer control system according to claim 1, wherein an optimization process for correcting the above is performed. The optimized mixer control data for the mixer device further includes a target impulse value of the mixing unit at a predetermined stage included in the mixing operation.
The control unit of the mixer device is characterized in that the rotation time of the mixing unit in the predetermined step is adjusted based on the impulse value calculated from the monitored torque value and the target impulse value. The mixer control system according to claim 2. The mixer control system
Including a plurality of the mixer devices,
The mixer management device is connected to each of the plurality of mixer devices.
Each of the plurality of mixer devices generates mixer control data for controlling each of the plurality of mixer devices so that a mixing operation optimized for the edible dough for each product to be manufactured is executed. The mixer control system according to claim 1, wherein the mixer control system is transmitted to each of the plurality of mixer devices. The individual mixer device is controlled based on the dough manufacturing instruction data of the product to be manufactured and the environmental data at the time of manufacturing so that the edible dough in the optimum mixed state for each product is manufactured with good reproducibility by each mixer device. It is a mixer control method to
The mixer device for producing the edible dough of the product to be manufactured and the mixer device connected to the mixer device so that the mixer device executes a mixing operation optimized for the edible dough of the product to be manufactured. A mixer management device that generates corresponding mixer control data and transmits it to the mixer device, and standard mixing control information and mixing conditions for edible dough for each product name connected to the mixer management device and associated with the mixer device. In a mixer control system including a database in which correction information is stored,
The mixer device
At the stage of accepting manufacturing instructions for edible dough for the product to be manufactured,
Dough preparation instruction data including the product name and charge amount specified in the accepted manufacturing instructions, as well as ambient room temperature environment of the mixing section of the mixer apparatus as environmental data at the time of the preparation obtained by the sensor portion of the mixer apparatus , Humidity, and temperature of raw materials are transmitted to the mixer management device, and
The mixer management device
A step of acquiring the standard mixing control information and the mixing condition correction information of the edible dough of the product to be manufactured associated with the mixer device from the database based on the dough manufacturing instruction data received from the mixer device. When,
Using the manufacturing environment data received from the mixer device and the mixing condition correction information, a target value of the rotation speed of the mixing unit of the mixer device included in the acquired standard mixing control information can be obtained. The stage of generating the mixer control data for the optimized mixer device, and
The stage of transmitting the generated mixer control data to the mixer device, and
Based on the monitoring data of the rotation speed of the mixing unit sequentially received from the sensor unit by the mixer device, the rotation speed of the mixing unit maintains the target value of the rotation speed specified in the mixer control data. A mixer control method comprising a step of controlling the mixing unit. The step of acquiring the standard mixing control information and the mixing condition correction information is
The mixer management device searches the database based on the dough production instruction data received from the mixer device.
The target value of the rotation speed of the mixing unit at each of the predetermined stages included in the mixing operation corresponding to the product name and the charging amount specified in the dough production instruction data, and
With the room temperature and / or humidity of the ambient environment of the mixing unit included in the environmental data at the time of manufacturing received from the mixer device as variables, the finished temperature of the edible dough reaches a predetermined target temperature for each product to be manufactured. 5. The fifth aspect of claim 5, further comprising a calculation formula for correcting a target value of the rotation speed of the mixing unit in each of the predetermined stages included in the mixing operation, and a stage for acquiring the data. Mixer control method. The stage of generating the mixer control data is
The correction calculated by the mixer management device by substituting the room temperature and humidity of the ambient environment of the mixing unit included in the environmental data at the time of manufacture received from the mixer device into the corresponding variables of the acquired calculation formula. The mixer control method according to claim 6, further comprising a step of performing an optimization process for correcting a target value of the rotation speed of the mixing unit in each of the predetermined steps included in the mixing operation. .. The stage of generating the mixer control data is
Further including a step of generating mixer control data for the optimized mixer device, including a target impulse value of the mixing unit at a predetermined step included in the mixing operation.
The stage in which the mixer device controls the mixing unit adjusts the rotation time of the mixing unit in the predetermined stage based on the impulse value calculated from the monitored torque value and the target impulse value. The mixer control method according to claim 7, further comprising a step of performing.

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