JP6759284B2 - Processing equipment - Google Patents

Description

The present invention relates to, for example, a processing facility for managing agricultural work for producing agricultural products and processing agricultural products after harvesting.

Grains such as rice and wheat are harvested by agricultural machinery such as combine harvesters, and after the harvested grains are transferred to transport vehicles, they are transported to processing facilities such as rice centers and country elevators for shipping at the processing facilities. Will be processed. Patent Documents 1 and 2 disclose techniques for inspecting the quality of grains (grains) after drying and rubbing the grains (paddy) in a processing facility.
Patent Documents 1 and 2 disclose that information detected in each process (drying, storage, padding, preparation, weighing) of a processing facility is input to a data management device. In addition, it is shown that the producer information that identifies the grain producer and the measurement information (quality information) are associated and managed.

Japanese Unexamined Patent Publication No. 11-44649 Japanese Unexamined Patent Publication No. 11-281579

Patent Documents 1 and 2 describe that, in addition to inputting the detection information of each process into the data management device, the quality information and the producer information are managed in association with each other. However, the specific correspondence and processing between the quality information and the producer information are not described, and the actual situation is that the quality information and the like cannot be utilized in each processing.
The present invention is seen paragon of the above problems, and an object thereof is to provide a processing facility that performs processing on agricultural crops.

The technical means taken by the present invention to solve the above technical problems is characterized by the following points.
The processing equipment includes a dryer that dries the grain after harvesting , a preparation machine that prepares the grain dried by the dryer, and a crop management computer that manages information including at least operation information of the dryer. In the processing equipment provided, the crop management computer is a storage member that stores the dried grain, and has a consignment display unit that indicates storage identification information for identifying the storage member that stores the grain at the time of harvesting. The display device has a display device for displaying a management screen including a drying display unit for showing the status of the dryer and a preparation display unit for displaying the status of the color selection machine capable of color-sorting grains as the preparation machine. The apparatus causes the consignment display unit to display either the water content at the time of harvesting or the protein amount at the time of harvesting as the crop information of the grain contained in the storage member, and the crop management computer displays the drying. Based on the dry conversion amount, which is the weight of the grain after drying with the machine, the fine grain conversion amount that can be put into the color selector is obtained .
The processing equipment includes a dryer that dries the grain after harvesting, a cooling tank that releases the grain dried by the dryer, and crop management that manages information including at least operation information of the dryer. In a processing facility equipped with a computer, the crop management computer is a storage member for accommodating the dried grain, and a receipt display indicating accommodation identification information for identifying the storage member containing the grain at the time of harvesting. It has a display device for displaying a management screen including a unit, a drying display unit showing the status of the dryer, and a cooling display unit for displaying the status of the cooling tank, and the display device displays the receipt of goods. As crop information of the grain contained in the storage member, either the water content at the time of harvesting or the protein content at the time of harvesting is displayed on the unit, and the cooling display unit is dried by the dryer. The amount of dried grains, which is the weight of the grain after drying, the amount of water at the end of drying, and the amount of protein at the end of drying are displayed.

At the time of harvesting the grain, the crop management computer determines either the amount of water at the time of harvesting or the amount of protein at the time of harvesting when the grain is stored in the storage member from outside the processing facility in which the dryer is installed. Has a production information acquisition department to acquire
The display device displays either the water content at the time of harvest or the protein amount at the time of harvest acquired from the outside by the production information acquisition unit on the receipt display unit .

The crop management computer uses either the amount of water at the time of harvesting or the amount of protein at the time of harvesting of the grains contained in the storage member, and the amount of water at the time of harvesting and the amount of protein at the time of harvesting the grains placed in a plurality of dryers. By comparing with any of the protein amounts, it is determined whether or not the water content at the time of harvesting the grain and the protein amount at the time of harvesting match between the plurality of dryers and the accommodating member.
In the display device, when either the water content at the time of harvesting the grain and the protein amount at the time of harvest match with the consignment display unit, the water content at the time of harvesting or the water content at the time of harvesting of the matched grain is matched. Display the recommended destinations for grain stuffing in the dryer with the amount of protein .

In the display device, as the situation of the dryer, the display device has a capacity that allows the grain to be deposited in each dryer, and a maximum load amount that the dryer has. Both are displayed in a graph .

The processing equipment is equipped with a preparation machine that prepares grains dried by the dryer.
The management screen includes a preparation display unit as the preparation machine, which displays the status of a color selection machine capable of color-sorting grains after being padded with the paddy machine, and the crop management computer is the dryer. Based on the dry conversion amount, which is the weight of the dried grain, the fine grain conversion amount that can be put into the color sorter is determined . The processing equipment includes a measuring instrument for measuring the grain prepared by the preparing machine, and the management screen includes a preparation display unit for displaying the status of the measuring instrument.
The processing facility includes a cooling tank that cools the grains dried by the dryer, and the management screen includes a cooling display unit that displays the status of the cooling tank, and the cooling display is displayed. The unit displays the dry conversion amount, which is the weight of the grain after drying in the dryer, the water content at the end of drying, and the amount of protein at the end of drying .

By production management computer, it is possible to manage work information and crop information. On the other hand, the crop management computer can manage information including the operation information of the processing equipment that processes the crops after harvesting. In addition, the crop management computer can acquire the work information and the crop information managed by the production management computer. Therefore, work information and crop information can be reflected in the processing equipment.

For example, work information and crop information can be grasped when processing with a processing facility. That is, when processing with a processing facility, it is possible to trace back to the agricultural work when the crop was cultivated and the state of the crop at the time of harvest. Furthermore, processing equipment can be set based on work information and crop information.
In addition, management information such as a lot number assigned to each operation in the processing equipment can be associated with operation information, work information, and crop information of the processing equipment. Therefore, work information and crop information can be grasped for each operation of the processing facility. That is, each operation of the processing facility can be traced back to the agricultural work when the crop was cultivated and the state of the crop at the time of harvest.

In addition, the drying operation information, the work information, and the crop information can be associated with each operation of the dryer by the drying management information. Therefore, it is possible to grasp the result of the agricultural work and the state of the crop at the time of harvest as a result of drying with the dryer every time the dryer is operated. In addition, the preparation operation information, the work information, and the crop information can be associated with each operation of the preparation machine by the preparation management information. Therefore, it is possible to grasp the result of the preparation by the preparation machine, the result of the agricultural work, and the state of the crop at the time of harvest for each operation of the preparation machine.

In addition, a recommended dryer can be obtained based on the yield of grains and the amount of protein. Therefore, grains having a relatively similar amount of protein can be put into the dryer. In addition, the amount that can be easily put into the dryer can be determined based on the amount of grain harvested, the amount that can be put into the dryer, and the maximum amount that can be put into the dryer.

In addition, since the amount that can be stuffed is displayed, the worker can easily determine whether or not the grain can be stuffed into the dryer. In particular, when there are a plurality of dryers, the order of grain stuffing can be appropriately determined while observing the amount of stuffing possible. In addition, the weighing management information can be associated with weighing operation information, work information, and crop information for each operation of the measuring instrument. Therefore, it is possible to grasp the result of weighing with the measuring instrument, that is, the crop information at the time of farming and harvesting with respect to the shipment amount.

It is an overall view of the agricultural management system. It is an overall view of a tractor. It is an overall view of the combine. It is explanatory drawing of the main screen. It is a figure which shows the example which displayed the work plan. It is explanatory drawing which stores the harvested grain in a storage member. It is a figure which shows the example which displayed the selection screen. It is a figure which shows the association between the harvest management information and the machine identification information. It is a figure which shows the association between the harvest management information and crop information. It is a figure which shows the association of harvest management information, crop information and work information. It is a figure which shows the processing equipment and the crop management system. It is a figure which shows an example of the management screen. It is a figure which shows the association between the dryness management information and dryness information. It is a figure which shows the association between the preparation control information and the preparation information. It is a figure which shows the association between the measurement management information and measurement information. It is a figure which shows the association between the drying control information and the preparation control information. It is the whole view of the agricultural management system in 2nd Embodiment. It is a figure which shows the association of dryness management information, dryness information, harvest management information, production control information (work information, crop information). It is a figure which shows an example of the 1st input screen. It is the whole view of the agricultural management system in 3rd Embodiment. It is a figure which shows an example of the 2nd input screen. It is an overall view of the agricultural management system in 4th Embodiment.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[First Embodiment]
FIG. 1 shows an overall view of the agricultural management system.
The agricultural management system consists of a production management system that manages from planting of crops to harvesting of crops, and a crop management system that manages crops after harvesting.

First, the outline of the production control system will be described. Hereinafter, for convenience of explanation, the explanation will proceed assuming that the agricultural product is a grain such as rice or wheat. As a matter of course, agricultural products are not limited to rice and wheat.
The production control system is a system that manages various information (called production control information) from grain planting to grain harvesting. Here, the production management information is information about agricultural work (
It is roughly divided into information (called work information) and information on agricultural products (grains) (called crop information).

The work information is information including the results of agricultural work (agricultural results). For example, when the farming work is tillage, it is the place of tillage and the day of tillage. If the farm work is fertilizer application, the fertilizer application location, fertilizer date, fertilizer name, and fertilizer amount. If the agricultural work is pesticide spraying, the location of pesticide spraying, pesticide spraying date, pesticide name, and pesticide spraying amount. If the farming is a harvest
The place of harvest and the amount of harvest.

In addition, work information (agricultural results) includes information on workers who have performed agricultural work (worker names, number of people involved in the work, etc.), information on machines that have performed agricultural work (classification of agricultural machines, models, machine identification information, etc.). ) May be included. The work information is not limited to the above-mentioned contents as long as it includes the results of various agricultural works.
The crop information is information including the characteristics of the grain, for example, the variety of the grain, the characteristics of the grain (the amount of water at the time of harvest, the amount of protein at the time of harvest), and the amount of harvest. The characteristics of the grain (water content at harvest, protein content at harvest) and harvest amount may be treated as work results. Further, the crop information is not limited to the above-mentioned contents as long as it is information representing an agricultural product (grain).

As shown in FIG. 1, the production control system has a data collection device 5 capable of collecting production control information (work information, crop information). The data collecting device 5 is mounted on an agricultural machine such as a tractor, a rice transplanter, or a combine harvester. The data collecting device 5 can communicate with various devices mounted on the agricultural machine through an in-vehicle network or the like mounted on the agricultural machine. The data collecting device 5 collects (acquires) various data when the agricultural machine is operated.
In other words, the data collecting device 5 collects work information including the agricultural performance of the agricultural machine in the agricultural machine that has performed the agricultural work.

Hereinafter, the collection of agricultural results by the data collecting device 5 will be described by taking a tractor and a combine as an example. For convenience of explanation, the data collecting device 5 mounted on the tractor is referred to as a first data collecting device 5A, and the data collecting device 5 mounted on the combine is referred to as a second data collecting device 5.
It is called a data collection device 5B.
First, the configuration of the tractor will be described.

As shown in FIGS. 1 and 2, the tractor 10 includes a traveling vehicle (traveling vehicle body) 11, an engine 12, a transmission 13, a driver's seat 14, and a control device 15. Further, various work devices can be detachably connected to the rear portion of the traveling vehicle 11. For details, traveling vehicle 11
At the rear, a three-point link mechanism 16 is provided so as to be able to move up and down, and a PTO shaft for transmitting power from the engine 12 is provided. As a working device 17, for example, a fertilizer spraying device, a tilling device, a pesticide spraying device, a sowing spraying device, and a harvesting device can be attached to the three-point link mechanism 16. Note that FIG. 2 shows an example in which the fertilizer spraying device is attached to the three-point link mechanism 16.

The control device 15 is a device that controls the traveling system, the working system, and the like of the tractor 10. The control device 15 controls the operation of the engine 12, for example, as a traveling system control. Further, when the control device 15 receives an input from an operation tool such as an operation lever or an operation switch provided around the driver's seat 14 as a work system control, the control device 15 moves the three-point link mechanism 16 up and down according to the input value and the PTO axis. Controls operations such as the output (rotation speed) of. The traveling system control and the working system control by the control device 15 are not limited to the above-mentioned contents.

The control signal for controlling the traveling system and the working system, and the detection signal detected by various devices mounted on the tractor 10 are output to the in-vehicle network.
The data collecting device 5 (first data collecting device 5A) is connected to the control device 15 via an in-vehicle network or the like. The first data collecting device 5A acquires a control signal and a detection signal output to the in-vehicle network when the tractor 10 and the like are in operation.

For example, when the rotary tillage device connected to the rear part of the tractor 10 is operated (when tillage is performed), the first data collection device 5A uses the rotary rotation speed, the rotary load, the engine rotation speed, the vehicle speed, and the tillage. Data such as depth is acquired through the in-vehicle network. That is, the first data collecting device 5A acquires the rotation speed of the rotary, the load of the rotary, the engine rotation speed, the vehicle speed, and the cultivation depth, which are the agricultural results when tilling is performed as agricultural work.

In addition, when the fertilizer application device connected to the rear part of the tractor 10 is operated (when fertilizer is applied).
Acquires data such as vehicle speed, engine speed, and fertilizer application amount through the in-vehicle network. That is, the first data collecting device 5A acquires the vehicle speed, the engine speed, and the amount of fertilizer applied, which are the actual agricultural results when fertilizer is applied as agricultural work.
Alternatively, when the pesticide spraying device connected to the rear part of the tractor 10 is operated (when pesticide is sprayed), data such as vehicle speed, engine speed, and pesticide spraying amount are acquired through the in-vehicle network. That is, the first data collecting device 5A acquires the vehicle speed, the engine speed, and the amount of pesticide sprayed, which are the agricultural results when the pesticide is sprayed as agricultural work.

That is, when the agricultural machine is the tractor 10, the first data collecting device 5A is the tractor 1.
Collect the agricultural results of the agricultural work performed by the device connected to 0.
Next, the structure of the combine will be described.
As shown in FIG. 3, the combine 20 includes an airframe 21, a traveling device 22, a driver's seat 14, and the like.
The engine 12, the Glen tank 24, the cutting device 25, the measuring device 26, and the control device 27.
And a threshing device (not shown). The traveling device 22 is provided at the lower part of the machine body. The driver's seat 14, the engine 12, the threshing device, and the grain tank 24 are provided on the machine body 21. The cutting device 25 is provided at the front portion of the machine body 21. The reaping device 25 is a device for reaping grains. The threshing device is a device for threshing the cut grain. The grain tank 24 is a tank for storing threshed grains. The control device 27 is a device that controls the engine 12, the threshing device, and the reaping device 25.

The measuring device 26 is a device for measuring the water content, protein content, yield amount, etc. of the grain. Specifically, the measuring device 26 includes a water content measuring unit 26A for measuring the amount of water contained in the grain, a taste measuring unit 26B for measuring the amount of protein in the grain, and a yield measuring unit 26C for measuring the yield of the grain.
And have. The moisture measuring unit 26A and the taste measuring unit 26B are inside the grain tank 24.
Alternatively, it is provided around the Glen tank 24. The yield measuring unit 26C is provided at the lower part of the grain tank 24.

The taste measuring unit 26B irradiates the grain entering the grain tank 24 with near-infrared light, analyzes the absorption spectrum based on the spectral analysis of the transmitted light, and based on the analysis result, the protein and the like contained in the grain are analyzed. The amount of components (protein content), that is, the amount of protein is determined. Moisture measuring unit 2
6A is composed of a sensor that measures the water content of the grain using the dielectric constant of the grain or measures the water content (water content) of the grain using the electrical resistance of the grain. The yield measuring unit 26C is composed of a load cell or the like that measures the weight of the grain tank 24 and converts the weight of the grain tank 24 into the yield. The taste measuring unit 26B, the moisture measuring unit 26A, and the yield measuring unit 26C are not limited to those described above.

The data collecting device 5 (second data collecting device 5B) is a control device 27 or a measuring device 2.
It is connected to 6 (moisture measuring unit 26A, taste measuring unit 26B) and collects the amount of grain harvested, the amount of water at the time of harvesting, and the amount of protein at the time of harvesting.
That is, when the agricultural machine is the combine 20, the second data collecting device 5B collects the yield amount as the agricultural result, and collects the water content at the time of harvesting and the protein amount at the time of harvesting as the crop information. As described above, the amount of water at the time of harvest and the amount of protein at the time of harvest may also be treated as agricultural results.

As described above, according to the data collecting device 5, it is possible to collect the agricultural results of the agricultural work performed by the device connected to the tractor 10 and the agricultural results of the agricultural work performed by the combine 20. The above-mentioned agricultural achievements are an example, and the agricultural achievements are not limited to the above-mentioned contents.
The data collecting device 5 (first data collecting device 5A, second data collecting device 5B) includes a first storage unit 30 and a first communication unit 31. The first storage unit 30 primarily stores data including agricultural results. The first communication unit 31 is composed of a device that performs short-distance or long-distance communication, and can be connected to an external device (computer). For example, the first communication unit 31 is a device that performs wireless communication according to Wi-Fi (Wireless Fidelity, a registered trademark) of the IEEE802.11 series, which is a communication standard. The first communication unit 31 may be a device that performs wireless communication via a mobile phone communication network or a device that performs wireless communication via a data communication network.

In addition, the production management system includes a computer 33 for managing production management information (work information, crop information). The computer 33 can be connected to a worker computer 33A operated by a farm worker who performs farm work, an administrator computer 33B operated by an administrator who manages the farm worker, a worker computer 33A, and an administrator computer 33B. It can be roughly divided into the production management computer 33C.

In this embodiment, the worker computer 33A is a communication terminal (mobile terminal) assigned to the farm worker and possessed by the farm worker, and the administrator computer 33B is a personal computer (PC) or the like assigned to the administrator. The production management computer 33C is
It is a server.
The communication terminal (mobile terminal) 33A is composed of, for example, a smartphone (multifunctional mobile phone) or a tablet PC having a relatively high computing power. The communication terminal 33A is the second communication unit 35.
A second storage unit 36 and a display unit 56 are provided.

The second communication unit 35 is composed of a data collection device 5 and a communication device that wirelessly communicates with the production management computer. The second communication unit 35 is, for example, the communication standard IEEE802.11.
It is a device that performs wireless communication by Wi-Fi (Wireless Fidelity, registered trademark) of the series. Further, the second communication unit 35 is a device that performs wireless communication by, for example, a mobile phone communication network, a data communication network, or a mobile phone communication network.

Therefore, the first communication unit 31 of the data collection device 5 and the second communication unit 35 of the communication terminal 33A
When the communication terminal 33A is connected to, the communication terminal 33A can acquire data such as agricultural results collected by the data collecting device 5, that is, data including production management information (work information, crop information). ..
When the communication terminal 33A acquires the production management information (work information, crop information), the communication terminal 33A acquires the machine identification information that is the source of the production management information in association with the production management information. For example, the communication terminal 33A acquires machine identification information for identifying the tractor 10 and the work device 17, or machine identification information for identifying the combine 20 from the data collection device 5 together with production management information.

Therefore, it is possible to extract the production control information by using the machine identification information.
Further, if the second communication unit 35 of the communication terminal 33A and the production management computer 33C are connected, data including agricultural results, that is, production management information (work information, crop information) can be transmitted to the production management computer 33C. Can be done. In addition, various data can be transmitted from the production management computer 33C to the communication terminal 33A.

The communication terminal 33A may have a position detection unit 37. The position detection unit 37 receives signals (position of GPS satellites, transmission time, correction information, etc.) transmitted from positioning satellites (for example, GPS satellites), and based on the received signals, own position (for example, latitude, etc.). It is a device that detects (longitude). For example, if a farm worker gets on the tractor 10 and performs farm work, the position of the farm worker at the time of farm work, that is, the place at the time of farm work can be detected.

More specifically, for example, when cultivated with a tractor 10, the cultivated place (field position),
When harvested with the combine 20, the harvested place (field position) can be detected.
The position detection unit 37 described above may be provided in an agricultural machine such as a tractor 10 or a combine 20.
The second storage unit 36 stores data (work information, crop information, machine identification information, etc.) transmitted from the data collection device 5, and stores data transmitted from the production management computer 33C.

Next, the production management computer 33C will be described in detail.
The production management computer 33C has a cropping plan setting unit 40 for setting a cropping plan and a cropping plan storage unit 41 for storing the cropping plan. The planting plan setting unit 40 is composed of a program or the like stored in the production management computer 33C. The planting plan is a plan to set crops to be planted, fields to be planted, and the like.

When the administrator computer 33B logs in to the production management computer 33C and the administrator computer 33B requests to create a cropping plan, the cropping plan setting unit 40 prepares the cropping plan in response to the request. A screen, that is, a planting plan screen for inputting a crop to be planted, a field to be planted, and the like is displayed on the administrator computer 33B. Further, when the crops to be planted, the fields to be planted, etc. are input to the cropping plan screen, the cropping plan setting unit 40 stores the input crops and fields as a cropping plan in the cropping plan storage unit 41.

Therefore, by connecting the administrator computer 33B to the production management computer 33C, it is possible to easily create a cropping plan in which the crops to be planted and the field are associated with each other, and the created cropping plan is stored in the cropping plan storage unit 41. can do.
Further, the production management computer 33C has a work plan creation unit 42 for creating a work plan and a work plan storage unit 43 for storing the work plan. The work plan creation unit 42 is composed of a program or the like stored in the production management computer 33C. The work plan is a plan to set a predetermined place (field), farm work, time for farm work (work time), farm worker who performs farm work, details of farm work, and the like. The work plan may include the crop name (type of crop) and the like.

Agricultural work includes, for example, floor soil preparation, ridge coating, tillage, sowing, rice planting, puddling, grooving, weeding, top dressing, harvesting and the like. The details of the agricultural work are the fertilizer name and the amount of fertilizer applied when the agricultural work is fertilizer application, and the pesticide name and the amount of pesticide applied when the agricultural work is pesticide application. Information about the machinery used to perform the farming work may be the details of the farming work.
When the administrator computer 33B logs in to the production management computer 33C and the administrator computer 33B requests to create a work plan, the work plan creation unit 42 responds to the request to create a work plan. Work plan setting screen for administrator computer 33B
Display on. The work plan creation unit 42 displays, for example, a work plan setting screen for inputting a crop name, a field, a farm work, a work time, a farm worker, details of the farm work, and the like. In addition, the work plan creation unit 42 stores the items (agricultural product name, field, agricultural work, work time, agricultural worker, details of agricultural work) input to the work plan setting screen in the work plan storage unit 43 as a work plan. ..

Therefore, by connecting the administrator computer 33B to the production management computer 33C, a work plan can be easily created, and the created work plan can be stored in the work plan storage unit 43.
Further, the production management computer 33C includes a work instruction unit 44. Work instruction unit 44
Is composed of a program or the like stored in the production management computer 33C. The work instruction unit 44 transmits a work plan to the worker computer (communication terminal 33A).

When the communication terminal 33A assigned to the farm worker logs in to the production management computer 33C and the communication terminal 33A requests transmission of the work plan, the work instruction unit 44 sends the communication terminal 33A to the communication terminal 33A in response to the request. A work plan including the assigned worker is extracted from the work plan storage unit 43, and the work plan is transmitted to the communication terminal 33A.
As described above, according to the production management system, the cropping plan can be created by the administrator computer 33B, and the cropping plan can be stored in the production management computer 33C. In addition, the work plan can be created by the administrator computer 33B, and the work plan can be transmitted to the communication terminal 33A assigned to the farm worker. The farm worker can carry out the farm work while looking at the transmitted work plan. In addition, the communication terminal 33
From A, work information including agricultural results and crop information, that is, production management information can be transmitted to the production management computer 33C.

Next, the transmission of the production control information from the communication terminal 33A to the production control computer 33C will be described in detail.
As shown in FIG. 4, the display unit 56 of the communication terminal 33A can display the main screen (first screen) Q1. A notification button 50 and a collection button 51 are displayed on the main screen Q1. The notification button 50 and the collection button 51 are selectable.

When the notification button 50 is selected, a login process is executed between the communication terminal 33A and the production management computer 33C. After logging in, the communication terminal 33A is the production management computer 33C.
Request to send the work plan to. The production management computer 33C transmits a work plan corresponding to the communication terminal 33A to the communication terminal 33A. The production management computer 33C is attached to the communication terminal 33A, for example, crop name, tillage place, tillage date, fertilizer application place, fertilizer application date, fertilizer name, fertilizer application amount, pesticide application place, pesticide application date, pesticide name, pesticide application. Send a work plan including quantity, harvest location, worker name, agricultural machinery, etc.

When the collection button 51 is selected, the communication terminal 33A connects to the data collection device 5 (first data collection device 5A, second data collection device 5B) and collects work information including agricultural results collected by the data collection device 5. get. The communication terminal 33A transmits the acquired work information and the like to the production management computer 33C. The communication terminal 33A manages production, for example, rotary rotation speed, rotary load, engine rotation speed, vehicle speed, cultivation depth, fertilizer application amount, pesticide application amount, harvest amount, water amount at harvest, protein amount at harvest, and the like. It is transmitted to the computer 33C.

Although the notification button 50 and the collection button 51 are separate, these notification buttons 5
0 and the collection button 51 may be combined. When the notification button 50 is selected, the communication terminal 33A may also acquire work information and the like from the data collecting device 5.
By the way, the work plan transmitted from the production management computer 33C is displayed on the work plan screen Q2 of the communication terminal 33A as shown in FIG. Further, in addition to the work plan, the communication terminal 33A can display a completion button 52 indicating the completion of the farm work. When the completion button 52 is selected, the communication terminal 33A converts the work plan shown on the work plan screen Q2 into agricultural results. Specifically, when the completion button 52 is selected, the communication terminal 33A converts the items shown in the work plan that cannot be obtained by the data collecting device 5 as agricultural results. For example
The work plan is "Crop name, tilling place, tilling date, fertilizer application place, fertilizer application date, fertilizer name, fertilizer application amount, pesticide application place, pesticide application date, pesticide name, pesticide application amount, harvest place, worker name In the case of "Agricultural machinery", items other than fertilizer application amount, pesticide application amount, and yield amount are converted into agricultural results. When converting the work plan into agricultural results, predetermined items can be modified by operating the communication terminal 33A. The communication terminal 33A transmits the converted agricultural results to the production management computer 33C.

That is, the communication terminal 33A has work information (cultivation location, tilling date, fertilizer application location, fertilizer application date, fertilizer name, fertilizer application amount, pesticide application location, pesticide application date, pesticide name, pesticide application amount, harvest location, The worker name, agricultural machine) is transmitted to the production management computer 33C. Further, the communication terminal 33A transmits crop information (crop name, harvest amount, water content at harvest, protein amount at harvest) to the production management computer 33C. The work information and crop information transmitted from the communication terminal 33A are stored in the management information storage unit 47 provided in the production management computer 33C.

When the grain is harvested, as shown in FIG. 6, the grain harvested by the combine 20 is put into the first accommodating member 55 of the truck which is the transport vehicle 53. The grain contained in the first storage member 55 is transported by the truck 53 to a processing facility 60 such as a rice center. The first accommodating member 55 is a container or the like.
In the production control system, it is possible to set which first storage member 55 contains the grain containing what amount of water and protein. That is, in the crop management system, it is possible to associate the crop information (crop name, harvest amount, water content at harvest, protein amount at harvest) with the first accommodating member 55.

Next, the correspondence between the crop information and the first accommodating member will be described.
The correspondence between the crop information and the first accommodating member 55 is performed using a communication terminal 33A or the like. The communication terminal 33A includes an identification acquisition unit 57 and an association unit 58.
As shown in FIG. 7, the display unit 56 of the communication terminal 33A can display the machine selection screen Q5 for selecting an agricultural machine such as a combine 20. On the machine selection screen Q5, a list of combine names corresponding to the owned combine 20 is displayed. When a predetermined combine name is selected on the machine selection screen Q5, the communication terminal 33A holds the machine identification information corresponding to the selected combine name.

The identification acquisition unit 57 acquires identification information (referred to as accommodation identification information) for identifying the first accommodating member 55. The accommodation identification information is composed of a unique number or the like. This accommodation identification information is attached to a QR code (registered trademark) attached to the first accommodation member 55. The identification acquisition unit 57 is composed of a camera or the like, and holds the accommodation identification information by reading the QR code (registered trademark) as an image. The association unit 58 includes machine identification information corresponding to the combine name selected on the machine selection screen Q5, and the first accommodating member 5 acquired by the identification acquisition unit 57.
Correspond with the accommodation identification information indicating 5.

When the machine identification information and the accommodation identification information are associated with each other, the association unit 58 also associates the harvest management information assigned for management. The harvest management information is an ID code or the like, and is composed of a unique number or the like. I used as harvest management information for convenience of explanation
The D code is called the consignment ID.
Therefore, as shown in FIG. 8, the combine 20 from which the grain was harvested, that is, the combine 2
The machine identification information for identifying 0 can be associated with the first accommodating member 55 containing the grain harvested by the combine 20, that is, the accommodating identification information. The relationship between the predetermined combine 20 and the predetermined first accommodating member 55 can be extracted by the consignment ID.

Further, the communication terminal 33A can associate the predetermined first accommodating member 55 with the amount of water and the amount of protein of the grain contained in the first accommodating member 55. This association is performed using various information. For convenience of explanation, the combine 20 selected on the machine selection screen Q5 is selected as the select combine, the machine identification information indicating the selected combine is selected as the identification information, and the predetermined first accommodating member 55 associated with the selected combine is referred to. The accommodation identification information indicating the determined accommodating member and the determined accommodating member is referred to as the determined accommodating member.

The association unit 58 refers to the second storage unit 36 of the communication terminal 33A, and determines whether or not there is crop information in the grain harvested by the selected combine. For example, when the second storage unit 36 has the crop information corresponding to the selective identification information indicating the selected combine, it is determined that the crop information in the grain harvested by the selected combine exists. Here, if crop information exists,
The association unit 58 includes items (field, harvest date, work time, worker, machine information, etc.) indicated in the agricultural results converted from the work plan and time information (year, month, year, month, etc.) previously possessed by the communication terminal 33A. Using (day, hour, minute, etc.), crop information (water content at harvest, protein content at harvest) in the grain contained in the determination containment member is extracted. For example, the association unit 58 extracts the agricultural record having the same harvest date as the date when the combine 20 and the first accommodating member 55 are selected on the machine selection screen Q5 in the second storage unit 36, and corresponds to the extracted agricultural record. It is assumed that the grain contained in the determination container has the amount of water and the amount of protein to be used. That is, the association unit 58 associates the extracted crop information, that is, the amount of water at the time of harvest and the amount of protein at the time of harvest with the storage identification information indicating the determined storage member.

In the above-described embodiment, the determination accommodating member (accommodation identification information) and the crop information are associated with each other by referring to the second storage unit 36 of the communication terminal 33A, but the management information storage unit 47 of the production management computer 33C is used. By referring to it, the accommodation identification information and the crop information may be associated with each other.
For example, the association unit 58 is an item (field, field,) shown in the agricultural performance converted from the work plan.
Harvest date, working hours, information about workers, machines, etc.) and selective identification information as search keys
It is transmitted to the production management computer 33C. Then, the association unit 58 extracts the crop information harvested by the selected combine from the management information storage unit 47 using the search key. Then, the association unit 58 associates the crop information extracted from the management information storage unit 47 with the determined accommodating member (accommodation identification information).

Therefore, as shown in FIG. 9, by searching the second storage unit 36 or the management information storage unit 47, the accommodation identification information and the crop information (harvest amount, water content at the time of harvest, protein at the time of harvest). Amount) can be associated with. The associated crop information and accommodation identification information are stored in the harvest information storage unit 48 provided in the production management computer 33C together with the harvest management information.

In addition to the correspondence between the crop information and the predetermined first storage member 55, work information (agricultural results)
May also be associated. For example, the communication terminal 33A is connected to the production management computer 33C, and the agricultural results corresponding to the crop information (for example, the harvested field, the worker name, etc.) are extracted from the management information storage unit 47, and as shown in FIG. , The extracted agricultural record, crop information, accommodation identification information, and consignment ID may be associated and stored in the harvest information storage unit 48. Further, the association between the accommodation identification information and the crop information is not limited to the above-mentioned method.

As described above, according to the production management system, for example, it is possible to collectively manage crop cropping plans, agricultural work work plans, agricultural work results (work information), crop harvest information (crop information), and the like.
Next, the crop management system will be described. The crop management system is mainly a system for managing crops (grains) after harvesting. Specifically, the crop management system is a system that manages a processing facility 60 that processes agricultural products (grains) after harvesting.

First, the processing facility 60 will be described.
As shown in FIG. 11, the processing equipment 60 includes a dryer 61, a cooling tank 62, and a paddy machine 63.
The preparation machine 64 and the measuring instrument 65 are provided.
The dryer 61 is a device for drying grains. The dryer 61 is supplied with an input port 61A for charging grains (paddy), a storage section 61B for temporarily storing grains, and grains stored in the storage section 61B to dry the supplied grains. It has a drying unit 61C, a circulation unit 61D, and a control unit (referred to as a first controller) 66A. The circulation unit 61D transports the grain charged into the input port 61A to the storage unit 61B, and stores the grain dried in the drying unit 61C again in the storage unit 6.
It is a mechanism to return to 1B.

The first controller 66A is a device that controls the dryer 61, and the drying temperature of the drying unit 61C and the circulation unit 61D so that the water content and the protein content of the grain after the drying is set to preset target values. Controls the circulation speed of.
Further, the first controller 66A can output operation information (referred to as drying operation information) of the dryer 61. For example, the first controller 66A uses the operating state (during staking, drying, stopping, etc.), drying start time, drying end time, water content during drying (drying water content), drying temperature, and drying as drying operation information. Outputs the weight of grains (dry weight), etc.

Therefore, according to the dryer 61, the grain put in (filled in) the inlet 61A can be dried in the drying section 61C by temporarily storing the grain in the storage section 61B and supplying the grain to the drying section 61C. .. Further, by returning the grains dried in the drying section 61C to the storage section 61B, the grains can be dried while being circulated.
The cooling tank 62 is a tank that cools the grains dried by the dryer 61 by storing them in a predetermined time. The paddy machine 63 is a device for padding grains that have been cooled in the cooling tank 62.

The preparation machine 64 is an apparatus for preparing grains (crude brown rice or the like) obtained by padding grains with a padding machine 63. In other words, the preparation machine 64 is a device capable of preparing the dried grains in the dryer 61.
The preparation machine 64 is a device for performing color inspection and color selection, and is a color selection machine 67 for color selection of grains.
have. The preparation machine 64 also has an appearance quality meter 68 for performing a color inspection.

The color selector 67 includes a first hopper 67A, an imaging unit 67B, an injector 67C, and a control unit (second controller) 66B. The first hopper 67A is a member for putting grains and dropping grains. The imaging unit 67B is a device that images the falling grain, and the injector 67C separates the defective grain based on the color selection result.
The second controller 66B is a device that controls the color selector 67, for example, the imaging unit 67.
From the image of the grain captured in B, it is determined whether or not the color of the grain is defective. That is, the second controller 66B detects the damaged rice and the colored rice of the stink bug based on the color of the image of the captured grain, and determines that the grain corresponding to these is defective. The second controller 66B outputs a command to blow off the defective grain to the injector 67C when it is determined that the grain is defective.

Further, the second controller 66B is used for operation information of the color selector 67 (referred to as first preparation operation information).
Can be output. For example, the second controller 66B outputs a color selection result (color condition, good ratio, defective ratio), color start time, color end time, and the like as the first preparation operation information.
Therefore, according to the color sorter 67, by putting the grain in the first hopper 67A, the grain is imaged, and the color of the grain is selected based on the captured image. Can be sorted.

For the rate of defects, a waste rice measuring instrument is provided to measure the weight (emission weight) of the grains that are considered to be defective after color selection. Then, for example, from the discharged weight, the weight of the grain put into the color sorter 67 (
The percentage of defects can be obtained by dividing the input weight). Then, the ratio of good products (yield) can be obtained from the ratio of defective products. The method of obtaining the yield is not limited to this. Further, the good ratio and the defective ratio may be obtained by the operation management unit 74 described later. In this case, it is desirable to adopt the sizing conversion amount described later as the input weight.

The appearance grade meter 68 is a device that performs a color inspection of grains before being put into the color sorter 67 and a color inspection after discharge (after color selection) from the color sorter 67. The appearance quality meter 68 has a measurement unit 68A and a control unit (third controller) 66C. The measuring unit 68A is a device that measures the color of the grain by, for example, imaging the falling grain.
The third controller 66C is a device that controls the appearance quality meter 68, and performs processing such as obtaining a hue from the captured image. Further, the third controller 66C can output operation information (referred to as second preparation operation information) of the appearance quality meter 68. For example, the third controller 66C
Outputs the result of the color inspection, the measurement start time, the measurement end time, the measurement condition, etc. as the second preparation operation information.

Therefore, according to the appearance grade meter 68, the color tone of the grain can be grasped in advance before being put into the color selector 67, and the color tone of the grain after the color selection can be confirmed by the color selector 67.
The measuring instrument 65 measures the grain after the color selector 67 and the like are performed. The second hopper 65A for putting the grain, the pedestal 65B provided at the lower part of the second hopper 65A, and the measuring unit 6
It has a 5C and a control unit (fourth controller) 66D.

The second hopper 65A is a container for containing grains, and the pedestal 65B is a table on which the second accommodating member 69 for containing grains is placed. The second accommodating member 69 is a flexible container, a container, or the like. The measuring unit 65C is a device for measuring the weight of the grain contained in the second accommodating member 69.
The fourth controller 66D is a device that controls the measuring instrument 65, and performs processing related to the measurement result, measurement start, measurement end, and the like. Further, the fourth controller 66D can output operation information (measurement operation information) of the measuring instrument 65. For example, the fourth controller 66D outputs measurement results (for example, shipping amount, number of bags, amount of bags), measurement start time, measurement end time, and the like as measurement operation information.

By the way, as shown in FIGS. 1 and 11, the crop management system includes a crop management computer 70 composed of a server or the like. Crop management computer 70, first controller 66A,
The second controller 66B, the third controller 66C, and the fourth controller 66D are connected to each other by a network such as a LAN. Through this network, data can be transmitted and received between the crop management computer 70 and each controller. For example, the crop management computer 70 stores the operation information output from each controller and outputs various data to each controller. Further, the crop management computer 70 is a production management computer 33.
It is possible to connect to C through an external network.

The crop management computer 70 has a production information acquisition unit 71, an operation acquisition unit 72, an information output unit 73, and an operation management unit 74.
The production information acquisition unit 71 acquires the data stored in the production management computer 33C. For example, when the predetermined grain is dried by the dryer 61, the production information acquisition unit 71 accesses the production management computer 33C and refers to the harvest information storage unit 54. Then, the production information acquisition unit 71 acquires the accommodation identification information of the first accommodation member 55, the crop information associated with the accommodation identification information, and the consignment ID. In addition to the crop information, the production information acquisition unit 71 has
Information including agricultural performance (name of planting plan, field, etc.) may be acquired.

The operation acquisition unit 72 is composed of electronic parts, programs, etc., and includes the first controller 66A,
Various operation information is acquired from the second controller 66B, the third controller 66C, and the fourth controller 66D.
The information output unit 73 is composed of electronic components, programs, and the like, and includes the first controller 66A.
Various information is output to the second controller 66B, the third controller 66C, and the fourth controller 66D.

The operation management unit 74 performs processing related to the processing equipment 60. As shown in FIG. 12, the operation management unit displays the management screen Q8 on the display device connected to the crop management computer 70. The management screen Q8 is a screen for displaying information and the like regarding the operation of the processing facility 60. Management screen Q
Reference numeral 8 denotes a receipt display unit 75A, a dry display unit 75B, a cooling display unit 75C, and a preparation display unit 75.
It has D and a measuring instrument display unit 75E. The operation management unit 74 controls the display of the load receiving display unit 75A, the drying display unit 75B, the cooling display unit 75C, the preparation display unit 75D, and the measuring instrument display unit 75E.

The receipt identification information and crop information acquired by the production information acquisition unit 71 are displayed on the receipt display unit 75A. Specifically, the dry display unit 75B displays the name of the first storage member corresponding to the storage identification information and the crop information of the grain contained in the first storage member. The consignment display unit 75A can also display information including agricultural results acquired by the production information acquisition unit 71.

Specifically, as shown in FIG. 12, the consignment display unit 75A has a container name which is the name of the first accommodating member 55, a cropping plan name, a harvest amount, a water content (water content at the time of harvest), and a protein amount ( The amount of protein at the time of harvest), the field, and the recommended destination are displayed. The container name, the name of the cropping plan, the yield amount, the water content, the protein amount, and the field are information obtained from the production management computer 33C by the production information acquisition unit 71.

The operation management unit 74 obtains a recommended stakeout destination based on the drying operation information obtained from the first controller 66A, and displays the stakeout destination on the consignment display unit 75A. For example, suppose that, of the four dryers, the third dryer (referred to as Unit 3) is stopped and the fourth dryer (referred to as Unit 4) is being loaded. In this case, the operation management unit 74 recognizes that Unit 3 is stopped and Unit 4 is being squeezed based on the drying operation information.

The operation control unit 74 has 7.2% of the grain protein loaded in Unit 3, and the container 01, container 03, container 04 and container 07 contain substantially the same protein as the grain protein loaded in Unit 3. Since it contains the grain it has, Unit 3 is recommended for container 01, container 03, container 04 and container 07. Then, the operation management unit 74 is the consignment display unit 75A, and displays the recommended destination, Unit 3, in the column of the container 01, the container 03, the container 04, and the container 07.

In addition, since the protein of the grain charged in Unit 4 is 6.3%, the operation management unit 74 has 4 relative to the container 02 and the container 05 containing the grain having this protein.
The unit is recommended for installation. Then, the operation management unit 74 is the consignment display unit 75A, and displays the recommended destination, Unit 4, in the column of the container 02 and the container 05. Note that the operation management unit 74 does not consider Unit 1 as the recommended destination because Unit 1 is drying and Unit 2 is waiting for discharge.

Therefore, since the recommended dryer 61 is obtained based on the amount of protein, grains having a relatively similar amount of protein can be put into the dryer.
As shown in FIG. 12, a decision button 78 for determining the stakeout is displayed at the stakeout destination of the consignment display unit 75A. When the decision button 78 is selected, the operation management unit 74 assumes that the container corresponding to the decision button 78 is loaded in the recommended destination, the harvest amount of the container is "filled amount", and the water content at the time of harvest is ". Set the amount of water at the time of staking (the amount of water squeezed) and the amount of protein at the time of harvesting to "the amount of protein at the time of staking (the amount of protein squeezed)".

The operation management unit 74 is based on the set stake amount, the set stake water amount and the set stake protein amount, the stake amount already in the dryer 61, the stake water amount and the stake protein amount. , Obtain the total amount of stake, the amount of stake water, and the amount of stake protein when stopped or during stake.
The information output unit 73 outputs the total filling amount, the filling water amount and the filling protein amount, the dryer number, and the container name (accommodation identification information) to the first controller 66A. The first controller 66A displays the total filling amount, the filling water amount and the filling protein amount, the dryer number, and the container name on the display device provided in the dryer 61.

The drying display unit 75B displays the status of the dryer 61 and the like. Specifically, the dry display unit 75
In B, as the situation of the dryer 61, the number of the dryer, the planting plan, and the operating state (during staking,
(Drying, stopped, etc.), remaining capacity that can be stuck in the dryer 61 (fillable amount), total sticking amount, water content (filling water content, dry water content), protein amount (filling protein) Amount, amount of dried protein), discharge destination is displayed. The operating state and the amount of dry moisture are drying operation information obtained from the first controller 66A by the operation acquisition unit 72. The planting plan is information acquired by the production information acquisition unit 71. The total filling amount, the remaining capacity, and the discharge destination are information shown based on the calculation result by the operation management unit 74. In this embodiment, the amount of protein to be squeezed is treated as the amount of protein in the grain being dried (the amount of dried protein).

The calculation of the remaining capacity by the operation management unit 74 will be described.
The operation management unit 74 obtains the remaining capacity by subtracting the total filling amount from the maximum filling amount of the dryer 61 corresponding to the dryer number. The maximum filling amount of each dryer 61 is stored in advance in the crop management computer 70. Further, operation management unit 74, the drying display unit 75B, the area for displaying the remaining capacity to display the vertical axis of the graph. Then, the operation management unit 74 displays the maximum amount of the dryer 61 corresponding to the number of the dryer at the upper end of the vertical axis, displays zero at the lower end of the vertical axis, and displays the remaining capacity along the vertical axis. indicate.

Therefore, the operation management unit 74 can determine the amount that can be charged into the dryer (remaining amount) based on the amount of grain harvested, the amount that can be charged into the dryer, and the maximum amount that can be charged into the dryer. it can. Then, since the stakeable amount and the maximum stake amount are displayed, the worker can easily determine whether or not the grain can be squeezed into the dryer. In particular, when there are a plurality of dryers 61, the order of grain loading can be appropriately determined while observing the amount of the dryers that can be loaded.

The operation management unit 74 obtains a discharge destination to be discharged to the cold discharge tank 62 based on the amount of protein of the grain stored in the cold discharge tank 62, and displays the discharge destination on the dry display unit 75B. For example
It is assumed that there are four cooling tanks 62. Here, the amount of protein in the grain (the amount of cold protein) in the second cooling tank 62 is 7.3%, and the amount of protein in the grain (dried protein) in the second dryer 61. When the amount) is 7.3%, the operation management unit 74 uses the second cold release tank 62 as the discharge destination because the amount of cold protein and the amount of dry protein are the same. The protein of the grain contained in the cooling tank 62 is obtained based on the crop information discharged from the dryer 61 to the cooling tank 62.

A decision button 78 for determining the discharge destination is displayed at the discharge destination of the dry display unit 75B. When the determination button 78 is selected, the operation management unit 74 determines that the grain is discharged from the dryer 61 corresponding to the determination button 78 to the cooling tank 62 at the discharge destination. Then, the operation management unit 74 obtains the weight of the dried grain (the amount of discharge discharged to the cooling tank 62), that is, the dry conversion amount, based on the total amount of stuffing, the amount of stuffed water, and the amount of dry water. .. For example, "dry conversion amount (
kg) = total amount of squeeze (kg)-(amount of squeezed water [%]-amount of dry water at the end of drying [%]) x total amount of stake [kg]) to determine the dry conversion amount.

Therefore, the weight of the dried grain (converted amount) can be obtained based on the amount of squeezed water and the amount of dry water (water amount after drying). That is, it is possible to grasp the grain to be put into the cooling tank 62 without providing a weighing scale or the like on the entry side of the cooling tank 62. Moreover, it is possible to obtain the amount of grain input to the paddy machine 63 and the amount input to the preparation machine 64 by using the conversion conversion amount.

In addition, the operation management unit 74 sets the water content (dry water content) at the end of drying as the water content (cooling water content) of the grains put in the cooling tank 62, and sets the protein amount at the end of drying to the cooling tank 62. Let it be the amount of protein in the grain (the amount of freezing protein).
The status of the cooling tank 62 is displayed on the cooling display unit 75C. Specifically, the cooling display unit 7
In 5C, as the status of the cooling tank 62, drying management information, planting plan, drying conversion amount, cooling water amount, cooling protein amount and the like are displayed. Further, the discharge destination is displayed on the cooling display unit 75C.

The preparation display unit 75D displays the status of the preparation machine 64 and the like. Specifically, the preparation display unit 75
In D, as the status of the preparation machine 64, drying management information, planting plan, grain conversion amount, color selection machine number, operating state (color selection in progress, stoppage, etc.), and color selection result are displayed. The number of the color selector, the operating state, and the color selection result are the first preparation operation information obtained from the second controller 66B by the operation acquisition unit 72.
Further, the discharge destination is displayed on the preparation display unit 75D. The dry conversion amount is information obtained by calculation by the operation management unit 74.

The operation management unit 74 obtains a sizing conversion amount that can be input to the color selector 67 based on the drying conversion amount. The operation management unit 74 obtains the sizing conversion amount by, for example, "grain size conversion amount (kg) = dry conversion amount (kg) x rice husk equivalent weight (rice husk removal rate) (%) with respect to the weight of coarse brown rice". Since the weight of rice husks is about 15% of the weight of crude brown rice, the rice husk removal rate is set to 0.85. The rice husk removal rate is not limited to the above-mentioned value.

Therefore, the weight of the grain (grain size conversion amount) that can be put into the preparation machine 64 prepared after the treatment of the paddy machine 63 can be grasped in advance. That is, it is possible to grasp the grain to be put into the preparation machine 64 without providing a weight scale or the like on the entrance side of the preparation machine 64.
The status of the measuring instrument 65 and the like are displayed on the measuring instrument display unit 75E. On the measuring instrument display 75E,
As the status of the measuring instrument 65, drying management information, cropping plan, total bagging amount, shipping result (shipping amount, number of bags, bagging amount) and the like are displayed. The shipping result (shipment amount, number of bags, bagging amount) is shown in the operation acquisition unit 72
Is the weighing operation information obtained from the fourth controller 66D.

As described above, the crop management computer 70 includes the operation information (drying operation information, the first preparation operation information, the second preparation operation information, the measurement operation information) obtained from each controller, and the production management computer 33.
Using the information obtained from C (harvest amount, water content at harvest, protein amount at harvest, planting plan), it is possible to manage the operation of the processing facility 60 and the like.
By the way, in performing each process in the processing facility 60, management information is assigned corresponding to each process. Specifically, in the drying process in the dryer 61, management information (drying management information) is assigned to each operation of the dryer 61. Further, in the preparation process of the preparation machine 64, management information (preparation management information) is assigned for each operation of the preparation machine 64, and in the measurement process of the measuring instrument 65, the management information (management information) is assigned for each operation of the measuring instrument 65. Measurement control information) is assigned.

The drying control information, the preparation control information, and the measurement control information are represented by, for example, a lot number or an ID. The crop management computer 70 assigns the drying control information, the preparation control information, and the measurement control information, and outputs the lot number and ID assigned to each controller.
The crop management computer 70 has an integrated association unit 80. Integrated association unit 80
Is associated with the operation information obtained from each controller, the result of calculation by the operation management unit 74, the information obtained by the production information acquisition unit 71, and the like. The integrated association unit 80 is composed of electronic components, programs, and the like.

As shown in FIG. 13, the integrated association unit 80 includes drying operation information (dry moisture content, dry protein amount, drying start time, drying end time, dry weight) obtained from the first controller 66A.
The drying information such as the result calculated by the operation management unit 74 (the amount of water to be charged and the amount of protein to be charged) and the information (planting plan) obtained by the production information acquisition unit 71 is associated with the drying management information.
Specifically, the crop management computer 70 automatically issues a lot number as drying management information before starting the operation of the dryer 61. Then, for example, when the number of the dryer is determined by the determination button 78 of the consignment display unit 75A and the dryer 61 corresponding to the number is started to operate from the first controller 66A, the integrated association unit 80 , The association between the issued lot number and the drying information in the dryer 61 that has determined the drying is determined.

Then, after the start of drying by the dryer 61, the association and association between the drying information obtained by the end of drying and the rod number is continued. When the operation of the dryer 61 is completed, the associated drying information and drying management information are stored in the information storage unit 81 provided in the crop management computer 70. The associated drying information and drying management information are transmitted from the crop management computer 70 to the first controller 66A and displayed on the display device of the dryer 61.

Therefore, since the drying management information is associated with the drying information including the drying operation information,
The operation of the dryer 61 can be controlled by the operation unit (for each lot number) of the drying management information.
For example, the amount of dry water, the amount of dry protein, the start time of drying, the end time of drying, and the dry weight can be grasped for each operating unit, and these can be reflected in the regulator 64 and the measuring instrument 65 located downstream. ..

Further, as shown in FIG. 14, the integrated association unit 80 includes the first preparation operation information (operation state, color selection result, color selection start time, color selection end time) obtained from the second controller 66B, and the operation management unit. The preparation information about the preparation machine 64 such as the result calculated in 74 (dry conversion amount) is associated with the preparation management information.
Specifically, the crop management computer 70 automatically issues a lot number as preparation management information before starting the operation by the preparation machine 64 (color selection machine 67). For example, the cooling display unit 75
The number of the color selector is determined by the enter button 78 shown in C, and the color selector 67 corresponding to the number is determined.
When it is obtained from the second controller 66B that the unit has started operation, the integrated association unit 80
The association between the issued lot number and the preparation information in the color selection machine 67 that has determined the color selection is determined. Then, after the start of color selection by the color selection machine 67, the association and association between the preparation information obtained by the end of color selection and the rod number is continued. When the operation of the color selector 67 is completed, the associated preparation information and preparation management information are stored in the information storage unit 81. The associated preparation information and preparation management information are transmitted from the crop management computer 70 to the second controller 66B, and the preparation machine 64
It is displayed on the display device of (color selector 67).

Therefore, since the preparation control information is associated with the preparation information including the preparation operation information,
The operation of the preparation machine 64 can be controlled by the operation unit of the preparation management information. For example, the operating state, color selection result, color selection start time, color selection end time, etc. can be grasped for each operation unit, and these can be reflected in the measuring instrument 65 located downstream, or the dryer located upstream. It is possible to feed back to 61 and the like.

Further, as shown in FIG. 15, the integrated association unit 80 has measurement operation information (shipment amount, number of bags, bagging amount, measurement start time, measurement end time) and measurement management information obtained from the fourth controller 66D. To associate.
Specifically, the crop management computer 70 automatically issues a lot number as preparation management information before starting operation by the measuring instrument 65. Then, for example, after the decision button 78 shown on the measuring instrument display unit 75E is selected, when the crop management computer 70 acquires the operation information that has started operation from the third controller 66C, the integrated association unit 80 is issued. The association between the lot number and the weighing information is decided. Then, after the start of weighing by the weighing machine, the association and association between the weighing information obtained by the end of weighing and the rod number is continued. When the operation of the measuring instrument 65 is completed, the associated measuring information and measuring management information are stored in the information storage unit 81. The associated preparation information and preparation management information are transmitted from the crop management computer 70 to the fourth controller 66D and displayed on the display device of the measuring instrument 65.

Therefore, because the measurement control information is associated with the preparation information including the measurement operation information,
The operation of the measuring instrument 65 can be managed in the operation unit of the measurement management information. For example, shipping volume,
The number of bags, the amount of bags, the measurement start time, and the measurement end time can be grasped, and these can be fed back to the preparation machine 64 located upstream, the dryer 61 located upstream, and the like.
In the processing equipment 60, the dryer 61, the preparation machine 64 (for example, the color selector 67), and the measuring instrument 6
The processing of grains is executed in the order of 5. Here, the integrated association unit 80 associates the upstream management information of the device located on the upstream side with the downstream management information when the device located on the downstream side performs processing.

When the integrated association unit 80 prepares the grain dried by the dryer 61 corresponding to the drying management information by the preparing machine 64, the integrated association unit 80 adds the upstream management information to the preparation management information which is one of the downstream management information. The drying management information, which is one of the above, is associated.
As shown in FIG. 16, specifically, the crop management computer 70 has a lot number issued before the start of drying in the dryer 61 and a lot number in the dryer 61 for drying the grains to be put into the color sorter 67 ( It is associated with the lot number determined for each operation of the dryer 61).

As described above, after the predetermined drying is completed, the cold discharge tank 62 is used as the discharge destination by pressing the enter button 78.
Since the color selector 67 can be selected, the lot number determined for each operation of the dryer 61 can be easily associated with the lot number determined for each operation of the color selector 67. Then, the associated drying control information and preparation control information are stored in the information storage unit 81.
The associated drying control information and preparation control information can be displayed on the display device of the crop management computer 70.

Therefore, before the preparation, the drying management information can be used as a search key to obtain the drying information when the grain to be put into the preparation machine 64 is dried. Therefore, the preparation machine is based on the operation results of the dryer 61. It is possible to set 64 settings and the like. Further, when the preparation is performed by the preparation machine 64, it is possible to confirm how the dryer 61 was operating in units of operation.
When the integrated association unit 80 measures the grain dried by the operation of the dryer 61 corresponding to the drying management information with the measuring instrument 65, the integrated association unit 80 adds the measurement management information, which is one of the downstream management information.
Drying management information, which is one of the upstream management information, may be associated.

Specifically, the crop management computer 70 has a lot number issued before the start of drying in the dryer 61 and a lot number in the dryer 61 that has dried the grains to be put into the measuring instrument 65 (for each operation of the dryer 61). Associate with the lot number specified in. As described above, after the predetermined drying is completed, the cooling tank 62, the color selector 67, and the measuring instrument 65 can be selected as the discharge destinations by pressing the enter button 78. Therefore, it is easily determined for each operation of the dryer 61. The lot number to be determined can be associated with the lot number determined for each operation of the measuring instrument 65. Then, the associated drying management information and measurement management information are stored in the information storage unit 81. The associated drying management information and weighing management information can be displayed on the display device of the crop management computer 70.

For example, the measuring instrument 65 may be weighed and shipped in units of 30 kg, and the dryer 61 may be dried in several tons (for example, 6 tons). Therefore, the number of measuring instruments 65 is 200 lots for one lot of the dryer 61. In the present invention, since the drying control information and the measurement control information are associated with each other, it is possible to grasp the correspondence relationship even if the processing unit (number of lots) is different in each processing. That is, when measuring with the measuring instrument 65, it is possible to confirm how the dryer 61 was operating in units of operation.

Further, when the integrated association unit 80 measures the grain prepared by the preparation machine 64 corresponding to the preparation control information with the measuring instrument 65, the integrated association unit 80 adds the measurement management information, which is one of the downstream management information, to the measurement management information.
Preparation management information, which is one of upstream management information, may be associated.
Specifically, the crop management computer 70 has a lot number issued before weighing by the measuring instrument 65 and a lot number in the color selecting machine 67 that color-selects the grain to be put into the measuring instrument 65 (color sorting machine 67).
Associate with the lot number specified for each operation of. As described above, after the predetermined color selection is completed, the measuring instrument 65, which is the discharge destination of the grain of the color selecting machine 67, can be selected with the enter button 78, so that the lot number determined for each operation of the measuring instrument 65 can be easily obtained. , Can be associated with a lot number determined for each operation of the color selector 67. The associated preparation control information and measurement control information are
It is stored in the information storage unit 81. The associated preparation control information and measurement control information can be displayed on the display device of the crop management computer 70.

Therefore, when measuring with the measuring instrument 65, it is possible to confirm how the color selection 64 was operated in units of operation.
According to the above, the production management computer 33 can manage the production management information (work information, crop information), and the crop management computer 70 can manage the information related to the processing in the processing facility 60. By linking, production control information, especially
The crop information can be used for processing in the processing facility 60.

In the processing facility 60, at least the information in the dryer 61, the preparing machine 64, and the measuring instrument 65 can be shared with each other, and the information such as the operation in each processing can be reflected in other processing.
[Second Embodiment]
The second embodiment shows a modified example of the crop management computer 70. The same configuration as in the first embodiment will not be described.

As shown in FIG. 17, the crop management computer 70 has a comprehensive association unit 83 in addition to the integrated association unit 80. The integrated association unit 80 associates various information of each process of the processing equipment 60, and the comprehensive association unit 83 associates the production management information obtained from the production management computer 33C with various information of each process.
Specifically, the general association unit 83 associates the production management information (work information, crop information) with the management information (drying management information, preparation management information, measurement management information) assigned for each operation. The comprehensive association unit 83 is composed of electronic parts, programs, and the like.

The process of associating dryness management information, dryness information, work information and crop information will be described.
As described above, when the number of the dryer is determined by the determination button 78 of the consignment display unit 75A, the general association unit 83 enters the first accommodating member 55 and the first accommodating member 55 corresponding to the determination button 78. Holds the harvest management information (receipt ID) associated with the crop information of the grain.

Then, when the drying management information (lot number) and the drying information are linked by the integrated association unit 80, the harvest management information held in advance by the general association unit 83 separately from the integrated association unit 80. (Receiving ID), drying management information (lot number), and drying information are associated with each other.
In addition, the general association unit 83 connects to the harvest information storage unit 48 and uses the harvest management information (receipt ID) held as a search key to obtain work information and crop information including agricultural results associated with the receipt ID. Extract. Then, as shown in FIG. 18, the general association unit 83 associates the work information including the extracted agricultural results, the crop information, and the harvest management information (consignment ID) with the drying management information and the drying information. Then, the associated drying management information, drying information, work information, crop information, and harvest management information are stored in the comprehensive information storage unit 84 provided in the crop management computer 70. The general association unit 83 may associate the harvest management information and the drying management information, and store only this association in the general information storage unit 84.

Therefore, since the drying operation information, the work information, and the crop information are associated with each operation of the dryer 61, the result of drying with the dryer 61, the result of the agricultural work, and the state of the crop of the crop at the time of harvest Can be compared. For example, it is possible to grasp the amount of dry water and the amount of dry protein relative to the amount of water and protein at the time of harvesting in the field.
The work information associated with the general association unit 83 includes the place of tillage, the date of cultivation, the place of fertilization, the date of fertilization, the name of fertilizer, the amount of fertilizer applied, the place of pesticide application, the date of pesticide application, the name of pesticide, the amount of pesticide applied, and the harvest. The location, worker name, agricultural machinery, or any other information. It is desirable that the work information includes at least the harvest location. Further, the crop information associated with the comprehensive association unit 83 may be any of the crop name, the yield amount, the water content at the time of harvest, and the protein amount at the time of harvesting, and may be other information.

By the way, the general association unit 83 also associates the preparation information, the preparation management information, the work information, and the crop information. For example, when associating the drying management information with the preparation management information, the comprehensive association unit 83 takes over the work information and the crop information associated with the drying management information in advance.
The inherited work information and crop information are also associated with the preparation management information. Then, the associated preparation information, preparation management information, work information, and crop information are stored in the comprehensive information storage unit 84.

Therefore, since the preparation operation information, the work information, and the crop information are associated with each operation of the preparation machine 64, the result of color selection by the preparation machine 64, the result of the agricultural work, and the state of the crop of the crop at the time of harvesting are associated. Can be compared with. For example, it is possible to grasp the color selection result (ratio of good products, ratio of defective products) with respect to the field, the amount of fertilizer applied and the amount of pesticide sprayed.
In addition, the comprehensive association unit 83 also associates measurement information, measurement management information, work information, and crop information. For example, when associating the drying management information with the measurement management information, the general association unit 83 takes over the work information and the crop information associated with the drying management information in advance.
Associate the inherited work information and crop information with the measurement management information. Then, the associated measurement information, measurement management information, work information, and crop information are stored in the comprehensive information storage unit 84.

Therefore, since the weighing operation information, the work information, and the crop information are associated with each operation of the measuring instrument 65, the result of weighing with the measuring instrument 64, the result of the agricultural work, and the state of the crop of the crop at the time of harvest Can be compared. For example, it is possible to grasp the measurement results (shipment amount, number of bags, amount of bags) for the field, the amount of fertilizer applied, and the amount of pesticide sprayed.
In the above-mentioned agricultural management system, various information of each processing of the processing facility 60 can be associated with the production management information obtained from the production management computer 33C. Therefore, the production of agricultural products can be reviewed and improved by comparing the two. It can be carried out. That is, it is possible to trace back to the farming work when the crop was cultivated and the state of the crop at the time of harvest. In addition, the processing equipment can be set with reference to the work information and the crop information obtained when the processing equipment 60 is in operation. Every time the processing equipment is operated, it is possible to trace back to the farming work when the crop was cultivated and the state of the crop at the time of harvest.

By the way, in the processing facility 60, before the grain color selection is performed by the color selection machine 67, or before the color selection machine 6 is used.
After the grain color is selected in No. 7, a color inspection is performed with an appearance grade meter 68. Specifically, a grain sample is taken before the grain is put into the color selector 67, and a color inspection is performed with an appearance grade meter 68.
The operation acquisition unit 72 acquires the color result (referred to as the preliminary result) of the color inspection (referred to as the preliminary inspection) performed before the color selection of the grain. In addition, the operation acquisition unit 72 performed a color inspection after the grain color selection (
Acquire the color result (post-inspection result) of (called post-inspection). For example, the operation acquisition unit 72 acquires an image of the grain captured as a color result, or the ratio of damaged grains, dead rice, colored grains, heterogeneous grains, and foreign substances to the sample.

The crop management computer 70 displays the preliminary result on the display device. Further, the crop management computer 70 associates the post-inspection result with the first adjustment operation information including the preparation management information and the color selection result. The first adjustment operation information including the associated post-inspection result, preparation control information, and color selection result is stored in the quality control storage unit 85.
Therefore, for example, since the color result by the appearance grade meter 68 can be obtained before the color selection is performed by the color selection machine, the color selection machine 67 can be set based on the color result. Further, after the color selection is performed by the color selection machine 67, the color result by the appearance grade meter 68 can be obtained.
It becomes possible to feed back the color result, which can be useful for the setting of the next color selector 67.

The crop management computer 70 has a grade acquisition unit 87 and a grade association unit 88. The grade acquisition unit 87 obtains the grade of the grain after the color inspection. The grade acquisition unit 87 acquires the grade (1st grade, 2nd grade, 3rd grade, non-standard) performed after weighing with the measuring instrument 65. For example, as shown in FIG. 19, the grade acquisition unit 87 causes the display device 89 connected to the crop management computer 70 to display the first input screen Q4 for inputting the measurement management information (lot number) and the grade. The grade can be obtained by inputting the grade in the portion corresponding to the measurement management information on the first input screen Q4.

The grade association unit 88 associates the grade acquired by the grade acquisition unit 87 with the first adjustment operation information including the color selection result. For example, the grade association unit 88 extracts the preparation control information associated with the measurement control information, and further extracts the first adjustment operation information including the color selection result associated with the preparation control information. Then, the grade association unit 88 associates the first adjustment operation information including the extracted color selection result with the grade.

Here, since the color selection result and the post-inspection result (color result by the appearance inspection meter) are associated with each other, the grade association unit 88 uses this to perform the grade and color selection result (first adjustment operation information). ,
Associate each of the post-test results. That is, the grade associating unit 88 performs a process of associating the grade with the color selection result (first adjustment operation information), the post-inspection result, and the preparation management information associated in advance. Then, the grade, the post-inspection result, the color selection result and the preparation control information are stored in the quality control storage unit 8.
It is stored in 5.

Therefore, it is possible to grasp the color result and the color selection result for the grade. for that reason,
If the color result is obtained in advance before the color selection is performed by the color selection machine 67, the color selection can be performed in consideration of which grade is to be obtained from the color result. For example, since the worker obtains the color result in advance, he / she can grasp the situation of the grain (brown rice) before the color selection. Here, it is possible to compare the grade and color result obtained in advance with the color result obtained in advance, and perform a simulation before processing the current grain at which grade to be shipped by the sorter 67. it can. For example, before sorting the sorter 67, it is possible to control the grade such that the shipment amount is increased although the grade is lowered, or the grade is increased although the shipment amount is decreased.

By the way, as described above, the preparation control information is associated with the production control information (work information, crop information) by the general association unit 83. Therefore, the grade association unit 88 refers to the comprehensive information storage unit 84, uses the preparation control information as a search key, and extracts the production control information (work information, crop information) associated with the preparation control information. The grade association unit 88 associates the extracted production control information (work information, crop information) with the grade, the post-inspection result, and the color selection result associated in advance. In particular, it is preferable that the grade associating unit 88 extracts the agricultural results related to the field and agricultural work where the harvest was performed from the production management information, and associates the fields and agricultural results, grades, color selection results, and color results. The grade, post-inspection result, color selection result, preparation control information, field and agricultural record are stored in the quality control storage unit 85.

Therefore, it is possible to grasp the grade, the color result, and the color selection result for the field, and it is possible to confirm what grade of rice (brown rice) was obtained in the predetermined field. In addition, it is possible to grasp the grade, color result and color selection result for the field and agricultural performance, and to confirm what grade of rice (brown rice) was obtained by what kind of agriculture in which field. it can.
[Third Embodiment]
FIG. 20 shows the agricultural management system of the third embodiment. The same configurations as those of the first embodiment and the second embodiment will not be described.

As shown in FIG. 20, the agricultural management system includes a production management computer 33C and a crop management computer 70. The production management computer 33C is a management information storage unit 47.
It is possible to output the production management information (work information, crop information) stored in the management information storage unit 47 to the outside. The production control information includes, for example, the place of tillage, the day of cultivation, the place of fertilization, the date of fertilization, the name of fertilizer, the amount of fertilizer applied, the place of pesticide application, the date of pesticide application, the name of pesticide, the amount of pesticide applied, and the harvest It remembers the location, worker name, and agricultural machinery. As the crop information, for example, the crop name, the yield amount, the water content at the time of harvesting, and the protein amount at the time of harvesting are stored. The work information and the crop information are data obtained by changing the data transmitted from the communication terminal 33A and the work plan to the agricultural results, as in the first embodiment.

The crop management computer 70 has a quality control storage unit 85, and the quality control storage unit 85.
It is possible to output the data stored in to the outside. The quality control storage unit 85 stores the grade, the post-inspection result (color inspection performed after the grain color selection), the color selection result, and the preparation control information. The association of the grade, the post-inspection result, the color selection result and the preparation control information is the same as the method shown in the first embodiment.

The agricultural management system has an information acquisition computer. This information acquisition computer is a computer capable of acquiring production control information and quality information. Specifically, the information acquisition computer is a communication terminal 33A (computer for farm workers) assigned to the farm worker and possessed by the farm worker. The information acquisition computer may be a personal computer (administrator computer 33B) assigned to the administrator.

The acquisition of production control information and quality information by the information acquisition computer will be described below.
The explanation will proceed assuming that the information acquisition computer is the communication terminal 33A.
The information acquisition computer (communication terminal) 33A has an information acquisition unit 90. The information acquisition unit 90 is composed of electronic parts, programs, and the like. The information acquisition unit 90 acquires quality information.

As shown in FIG. 21, specifically, the information acquisition unit 90 causes the communication terminal 33A to display a second input screen Q7 for inputting necessary items for obtaining quality information. Information such as measurement control information (lot number) and manufacturing control number can be input to the second input screen Q7.
When the information acquisition unit 90 determines the necessary items input on the second input screen Q7, the communication terminal 3
Requests 3A to connect to the production management computer 33C. The communication terminal 33A connects to the production management computer 33C in response to the connection request of the information acquisition unit 90. After the communication terminal 33A connects to the production management computer 33C, the information acquisition unit 90 requests the production management computer 33C for quality information and transmits the necessary items input on the second input screen Q7 to the management computer.

By the way, the production management computer 33C has a quality acquisition unit 91. Quality acquisition department 91
Is composed of electronic parts, programs, and the like. The quality acquisition unit 91 acquires quality information stored in the crop management computer 70.
When the quality information acquisition unit 91 (communication terminal 33A) requests the quality information, the quality acquisition unit 91 receives.
Based on the necessary items transmitted from the communication terminal 33A, the quality information corresponding to the necessary items is acquired from the crop management computer 70.

Specifically, when the quality acquisition unit 91 receives the request for quality information transmitted from the communication terminal 33A, the quality acquisition unit 91 requests the production management computer 33C to connect to the crop management computer 70. The production management computer 33C connects to the crop management computer 70 in response to the connection request of the quality acquisition unit 91. After the production management computer 33C connects to the crop management computer 70, the quality acquisition unit 91 requests the quality information from the crop management computer 70 and refers to the quality control storage unit 85. In addition, the quality acquisition unit 91 has necessary items (measurement management information,
Using the manufacturing control number, etc.) as a search key, quality information is extracted from the quality control storage unit 85 using the search key. Further, the quality acquisition unit 91 transmits the acquired quality information to the communication terminal 33A for which the quality information is requested. The information acquisition unit 90 acquires the quality information transmitted from the quality acquisition unit 91 (production control computer 33C). The acquired quality information is the communication terminal 33.
Display on A.

By the way, the information acquisition unit 90 can also acquire production management information (work information, crop information). In this case, at least the measurement control information and the manufacturing control number are input to the second input screen Q7. When the production control computer 33C receives the measurement control information and the production control number transmitted from the information acquisition unit 90 (communication terminal 33A), the production control computer 33C requests the receipt ID corresponding to the measurement control information and the production control number.

The crop management computer 70 refers to the information storage unit 81, uses the measurement control information and the production control number as a search key, and extracts the drying control information corresponding to the measurement control information and the production control number. Then, the crop management computer 70 refers to the comprehensive information storage unit 84 and extracts the consignment ID using the drying management information as a search key. The crop management computer 70 transmits the extracted consignment ID to the production management computer 33C. The production management computer 33C refers to the harvest information storage unit 48 and extracts production management information (work information, crop information) using the receipt ID as a search key. Management management computer The extracted production management information (work information, crop information) is transmitted to the communication terminal 33A.

Therefore, since the information acquisition computer can acquire production control information and quality information, for example, it is possible to grasp the relationship between the quality at the time of shipment of the grain and the production of the field where the grain is cultivated, agricultural work, etc. It is possible to analyze various matters from cultivation to shipping. That is, the production control information regarding grain production and the quality information regarding grain quality can be effectively utilized.

For example, if a producer of agricultural products (grains) obtains production control information and quality information using an information acquisition computer, the plan for production of agricultural products can be reviewed with reference to the quality information. In addition, consumers who have purchased agricultural products can confirm production and quality by obtaining production control information and quality information using an information acquisition computer.
By simply connecting the information acquisition computer to the production management computer 33, quality information that the production management computer does not have can be obtained. That is, quality information can be obtained without connecting the information acquisition computer to the crop management computer 70. Moreover, after the production control information and the quality information are acquired, the quality information corresponding to the production control information can be acquired without organizing the production control information and the quality information.
[Fourth Embodiment]
The fourth embodiment shows a modified example of acquisition of production control information and quality information. The same configurations as those of the first to third embodiments will be omitted.

The production management information is acquired by the production information acquisition unit 71 provided in the crop management computer 70. Specifically, when the necessary items input to the second input screen are determined, the information acquisition unit 90 requests the communication terminal 33A, which is the information acquisition computer, to connect to the crop management computer 70. The communication terminal 33A connects to the crop management computer 70 in response to the connection request of the information acquisition unit 90. In the information acquisition unit 90, the communication terminal 33A is the production management computer 3
After connecting to 3C, the crop management computer 70 is requested for production management information, and the necessary items entered in the second input screen are transmitted to the management computer.

Specifically, when the production information acquisition unit 71 receives the request for the production management information transmitted from the communication terminal 33A, the production information acquisition unit 71 refers to the information storage unit 81, and the necessary items (measurement management information and manufacturing) input on the second input screen. Using the control number) as a search key, the measurement control information and the drying control information corresponding to the manufacturing control number are extracted. The production information acquisition unit 71 refers to the general information storage unit 84 and extracts the receipt ID using the drying management information as a search key. The production information acquisition unit 71 connects to the production management computer 33C, refers to the harvest information storage unit 48, and extracts production management information (work information, crop information) based on the extracted consignment ID. The crop management computer 70 (production information acquisition unit 71) transmits the extracted production management information (work information, crop information) to the communication terminal 33A that requested the production management information. The information acquisition unit 90 acquires the production management information transmitted from the crop management computer 70 (production information acquisition unit 71). The acquired production management information is the communication terminal 3
Display on 3A.

Therefore, the production management information that the crop management computer 70 does not have can be obtained only by connecting the information acquisition computer to the crop management computer 70. That is, the production management information can be obtained without connecting the information acquisition computer to the production management computer 33.
In addition, the information acquisition unit 90 can also acquire quality information. The crop management computer 70
It has a quality output unit. The quality output unit is composed of electronic parts, programs, and the like.
When the quality output unit receives the request for quality information transmitted from the communication terminal 33A, the quality output unit refers to the quality control storage unit 85, and the necessary items (measurement control information and manufacturing control number) input on the second input screen.
Is used as the search key to extract quality information. The quality output unit transmits the extracted quality information to the communication terminal 33A for which the quality information is requested.

Therefore, after the production control information and the quality information are acquired, the quality information corresponding to the production control information can be acquired without organizing the production control information and the quality information.
[Fifth Embodiment]
The fifth embodiment shows a modified example of acquisition of production control information and quality information. The same configurations as those of the first to fourth embodiments will be omitted.

As shown in FIG. 22, the crop management computer 70 has a quality association unit 93. The quality association unit 93 is composed of electronic parts, programs, and the like. The quality association unit 93 associates the production control information with the quality information, and is substantially the same as the grade association unit 88. That is, the quality association unit 93 associates, for example, the place (field) where the harvest was performed and other agricultural achievements with the grade, color selection result, and color result as work information.

The information acquisition unit 90 requests the crop management computer 70 for quality information and work information associated with the quality information. The crop management computer 70 (quality output unit) refers to the quality control storage unit 85 and extracts quality information and work information using necessary items (measurement control information and manufacturing control number) as search keys. The quality output unit transmits the extracted quality information to the communication terminal 33A for which the quality information is requested.

Therefore, quality information corresponding to the production management information can be acquired only by connecting the information acquisition computer to the crop management computer 70. That is, the production control information and the quality information can be acquired without connecting the information acquisition computer to both the production control computer 33 and the crop management computer 70. Moreover, after the production control information and the quality information are acquired, the quality information corresponding to the production control information can be acquired without organizing the production control information and the quality information.

It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and it is intended that all modifications within the meaning and scope equivalent to the scope of claims are included.
In the above-described embodiment, the processing equipment 60 has been described by taking the dryer 61, the cooling tank 62, the paddy machine 63, the preparation machine 64, and the measuring instrument 65 as examples, but the present invention is not limited thereto. Processing equipment 6
0 may include, for example, a stone remover.

In addition, the controller of the waste rice measuring instrument was connected to the crop management computer 70, and the weighing result (
Emission weight) may be output to the crop management computer 70. In this case, the operation acquisition unit 72 may obtain the yield based on the input weight and the discharge weight.
It should be considered that the embodiments disclosed this time are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and it is intended that all modifications within the meaning and scope equivalent to the scope of claims are included.

1 Agricultural management system 33 Computer 33A Worker's computer 33B Administrator's computer 33C Worker's computer 60 Processing equipment 61 Dryer 62 Cooling tank 63 Paddy machine 64 Preparer 65 Weighing instrument 67 Color selector 68 Appearance grade meter 70 Crop management computer 71 Production information acquisition department 72 Operation acquisition department 74 Operation management department 83 Comprehensive association department 84 Comprehensive information storage department

Claims (6)

A processing facility equipped with a dryer for drying grains after harvesting , a preparation machine for preparing grains dried by the dryer, and a crop management computer for managing information including at least operation information of the dryer. In
The crop management computer is an accommodating member for accommodating the grain to be dried, and displays a consignment display unit for identifying the accommodating member accommodating the grain at the time of harvesting, and a status of the dryer. It has a display device for displaying a management screen including a dry display unit for showing and a preparation display unit for displaying the status of a color selection machine capable of color-sorting grains as the preparation machine .
The display device causes the consignment display unit to display either the water content at the time of harvesting or the protein amount at the time of harvesting as crop information of the grain contained in the storage member.
The crop management computer is a processing facility that obtains a grain conversion amount that can be put into the color selector based on a drying conversion amount that is the weight of grains dried by the dryer . It is equipped with a dryer that dries the grain after harvesting , a cooling tank that releases the dried grain by storing the dried grain in the dryer, and a crop management computer that manages information including at least operation information of the dryer. In the processing equipment
The crop management computer is a storage member that stores the grain to be dried, and displays a receiving display unit that indicates storage identification information for identifying the storage member that stores the grain at the time of harvesting, and the status of the dryer. It has a display device for displaying a management screen including a drying display unit for showing and a cooling display unit for displaying the status of the cooling tank .
The display device causes the consignment display unit to display either the water content at the time of harvesting or the protein amount at the time of harvesting as crop information of the grain contained in the storage member, and displays the cold release. A processing facility that displays the amount of grains converted to drying, which is the weight of grains after drying with the dryer, the amount of water at the end of drying, and the amount of protein at the end of drying . At the time of harvesting the grain, the crop management computer obtains either the amount of water at the time of harvesting or the amount of protein at the time of harvesting when the grain is stored in the storage member from outside the processing facility in which the dryer is installed. Has a production information acquisition department to acquire
The processing equipment according to claim 1, wherein the display device displays either the amount of water at the time of harvest or the amount of protein at the time of harvest acquired from the outside by the production information acquisition unit on the receipt display unit. The crop management computer uses either the amount of water at the time of harvesting or the amount of protein at the time of harvesting of the grains contained in the storage member, and the amount of water at the time of harvesting and the amount of protein at the time of harvesting the grains placed in a plurality of dryers. By comparing with any of the protein amounts, it is determined whether or not the water content at the time of harvesting the grain and the protein amount at the time of harvesting match between the plurality of dryers and the accommodating member.
In the display device, when either the water content at the time of harvesting the grain and the protein amount at the time of harvest match with the consignment display unit, the water content at the time of harvesting or the water content at the time of harvesting of the matched grain is matched. The processing equipment according to claim 1 or 3 , wherein a dryer in which the amount of protein is charged is displayed as a recommended destination for grain. In the display device, as the situation of the dryer, the display device has a capacity that allows the grain to be deposited in each dryer, and a maximum load amount that the dryer has. The processing equipment according to claim 3 or 4 , wherein both of the above are displayed in a graph. A measuring instrument for measuring grains prepared by the preparation machine is provided.
The processing equipment according to claim 1 , wherein the management screen includes a preparation display unit for displaying the status of the measuring instrument.