JP2003186986A - Reproduction processing system for organic waste - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a system for carrying necessary kinds of food or manure to necessary places as necessary by realizing the organic connection of an agent which discharges organic wastes, an agent which works the organic wastes into food or manure, and an agent which wants the worked food or manure. <P>SOLUTION: This system is provided with a server 20 communicatively connected through a communication line 8 to a waste generator 9 and a user 10, and the server 20 is provided with a first storing means 32 for storing waste data when the kinds or generation quantity of organic wastes to be discharged are transmitted as waste data from the waste generator 9 and a control means 24 for reading the waste data from the first storing means 32 when the kinds or necessary quantity of the organic wastes are transmitted as demand data from the user 10, and for comparing the read waste data with the demand data, and for instructing the waste generator 9 who has transmitted the waste data adapted to the demand data to provide the waste to the user 10. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an organic waste reprocessing system for designing, blending, or delivering instructions for fertilizers or feeds using wastes discharged from food related industries.

[0002]

2. Description of the Related Art Large amounts of organic waste are discharged from food-related businesses involved in food production. Conventionally, such wastes have been reduced in volume by performing various treatments such as dehydration, drying, fermentation and carbonization on a business unit basis, and then discarded. For example, in organic waste,
Includes things like food sludge. In the conventional treatment of food sludge, it is dehydrated by adding a settling accelerator or a coagulant and finally disposed of in landfill. However, there is a limit to the size of the landfill disposal site, and this type of treatment cannot be allowed forever.

Incidentally, the above organic wastes are also treated as feeds. Organic wastes, such as beer slag, are already used as feed for cattle. In this case, there is also an example in which the slag is transported directly from the beer maker to the barn. However, most livestock farmers generally use compound feed as feed. Since most of the ingredients of compounded feed depend on imports, price fluctuations were significant and there was concern about safety.

On the other hand, a large amount of organic waste is also discharged as livestock waste from the livestock industry. Conventionally, such waste has been disposed of by composting in the vicinity of a livestock house by a method such as a deposition method. Disposal of waste by such composting is not only carried out individually for each livestock farmer, but also at facilities such as a compost center jointly established by multiple livestock farmers for composting. There is also. The compost produced in this way is provided to and used by neighboring farmers.

[0005]

[Problems to be Solved by the Invention] Despite the possibility that organic wastes discharged from food-related businesses can be effectively used as feed, they are disposed of by each business unit, which is a wasteful act. At the same time as the problem of continuing, it was a factor that made environmental damage worse. Also,
Despite the fact that there are livestock farmers who want feed that is cheap, safe, and can be supplied in a stable manner, the fact that organic waste that can be used as feed is discarded is the reason The cause is that there was no system to connect livestock farmers.

[0006] Organic wastes are also discharged from the livestock industry, and even if an attempt is made to produce compost from this, there are many complaints from the neighboring residents due to the problem of bad odor. In particular, it is difficult for small-scale livestock farmers to prepare deodorant equipment for the production of compost, and there is also a problem that compost production cannot be done without a place with deodorant equipment. Moreover, even if compost is produced, if there is no system that connects the farmer who wants the compost and the livestock industry, the compost may be piled up as it is.

[0007] Therefore, the present invention has been made to solve the above problems, and its object is to provide a supplier of organic waste, a supplier of organic waste into feed or compost, a processed feed or It is to provide a system that can organically connect with a company that wants compost and can bring the required kinds of feed and compost to the place where it is needed.

[0008]

The present invention has the following constitution in order to solve the above problems. That is, according to the organic waste reprocessing system of the present invention, a waste person communication terminal that can be operated by a waste person who discharges the organic waste and a user who uses the organic waste as compost or feed can be operated. A user's communication terminal, and an organic waste recycling system comprising a server connected to each of the communication terminals by a communication line capable of mutually communicating with each other,
The server stores a first storage unit that stores the waste data when the type and the amount of the organic waste to be discharged are transmitted from the communication terminal for the waste as the waste data, When the type and required amount of the organic waste that the user wants to provide is transmitted as demand data from the user communication terminal, the waste data is read from the first storage unit, and the read waste data is read. And compares the demand data transmitted with the demand data, and instructs the communication terminal for the waste user who has transmitted the waste data matching the demand data to provide the waste to the user who has transmitted the demand data. And a control means for transmitting and controlling the instruction signal. By adopting this configuration, it is possible to connect the users of companies, etc. who want to use organic waste to those who want to use organic waste by connecting them to those who want to discharge organic waste. The organic waste can be effectively used without wasteful disposal.

Further, the server stores the demand data when the type and the required amount of the organic waste that the user desires to provide are transmitted from the user communication terminal as the demand data. The control means is provided with a storage means, and when the type and amount of the organic waste to be discharged are transmitted as waste data from the waste communication terminal, the control means causes the second storage means to operate. Read the demand data, compare the read demand data with the waste data,
Controlling by transmitting an instruction signal instructing the waste terminal communication terminal that has transmitted the waste data that matches the read demand data to provide waste to the user who has transmitted the demand data. Characterize. With this configuration as well, a waste person such as a company who wants to discharge organic waste is connected with a user such as a company who wants to use the organic waste, and the waste organic waste is discarded. The organic waste can be effectively used without causing it.

Further, the server is connected to a communication terminal for a processor, which can be operated by a processor such as a processor for processing organic waste into processed products such as compost and feed, through a communication line capable of mutual communication. And a third storage unit for storing inventory data such as an inventory quantity of the processed product owned by the processor, wherein the control unit is an organic waste that the user communication terminal desires to provide. When the kind or required amount of the object is transmitted as demand data, the inventory data is read from the third storage means, the read inventory data is compared with the demand data, and the inventory data has the inventory data matching the demand data. It is characterized in that an instruction signal for instructing to provide a suitable processed product to the user is transmitted to the communication terminal for the processor for control. According to this configuration, it is possible to promptly and appropriately provide the processed product possessed by the processor by immediately responding to the request of the person who wants to use the compost, feed or the like processed from the organic waste. .

The server is provided with a fourth storage means for storing processor data such as processing facility specifications of the processor.
The control unit reads the processor data from the fourth storage unit when the type and amount of the organic waste to be discharged are transmitted as waste data from the waste communication terminal. The read processor data is compared with the waste data, and the waste of the waste worker who has transmitted the waste data is received and processed to the processor communication terminal having the processor data matching the waste data. It is characterized by transmitting an instruction signal for instructing to control.
According to this, it is possible to promptly respond to a request from a company or the like who intends to discharge waste, and to promptly provide the organic waste to a processing processor suitable for the nature of the organic waste to be used as waste. it can.

Further, the server is used in the case where the user uses the organic waste or the processed product, or when the processor processes the organic waste, the mixing ratio of the organic wastes of different kinds and the component of the additive. , A fifth storage means for storing design data such as a processing method such as quantity or processing time, wherein the control means uses organic waste or processed material by the user, or When processing the waste, the design data suitable for the organic waste or the processed product used by the user or the processor is given in the fifth item.
It may be characterized in that it is read from the storage means and the read design data is transmitted to the user or the processor. According to this, the user and the processor can be instructed on the proper use and processing of the compost and the feed, so that the effect of increasing the production amount and improving the quality can be achieved.

Further, the server is connected to a communication terminal for a carrier that can be operated by a carrier such as a transportation company that transports organic waste by a communication line that can communicate with each other, and the number of vehicles carried by the carrier. And a sixth storage means for storing transportation data such as a transportation record. When the organic waste is transported from the waste person to the user, the control means processes the processed material from the processor to the user. When transporting the organic waste or transporting the organic waste from the waste to the processor, the transport data is read from the sixth storage means, and the transport data read from the transport data to the transporter communication terminal suitable for transport, It is characterized by transmitting and controlling an instruction signal instructing to carry a compatible organic waste or processed product. By adopting this configuration, it is possible to transport the organic waste to a more suitable transporter depending on the amount and components of the organic waste, so that the transport efficiency can be increased and the organic waste can be smoothly moved.

Note that the user uses the organic waste or processed product provided by the user as a result of the agriculture, forestry and livestock business, and as a result, the effect of production amount, quality, etc. is used as the result data for the user. It is possible to transmit from the communication terminal to the server, and the server has a seventh storage means for storing the received result data. By adopting this configuration, when the next similar organic waste is used based on the data of the result of use, the usage method etc. can be devised based on the result of the previous use. Based on the result data, better compost mixing ratios and usage methods are established. Users participating in the system can improve the production efficiency and quality of agricultural products and livestock products based on the accumulated data.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the present invention will be described below with reference to the drawings. First, FIG. 1 shows an example of the present embodiment. In the system of this embodiment, each of a waste user, a user, a processor, and a carrier can register in the system for a server that integrally controls the entire system, and each can be operated by a telephone line or some other communication line. Connected to another communication terminal. In FIG. 1, as an example of a communication line, the server 8 and the communication terminals 5, 4, 3, 2 for each business operator of each business operator 9, 10, 11, 12 are connected by the Internet 8. There is. However, the server 20 and the communication terminals 5, 4 for each business operator
The communication line connecting 3 and 2 is not limited to the Internet 8 and may be a normal telephone line or a dedicated line.

Hereinafter, a business operator or the like who can use this system will be described. The term “disposal person 9” as used herein refers to a food-related company or the like that produces organic wastes secondarily in the food manufacturing process, and an agricultural, forestry or livestock industry person or the like that discharges organic wastes such as manure. It is a thing. Here, there are a plurality of disposers 9, each disposer 9 has a communication terminal 5 for the disposer, and the communication terminal 5 for the disposer has a communication line 8.
Are connected to the server 20 by.

The user 10 is an agricultural, forestry and livestock industry who uses organic wastes, and is a farmer or forestry worker who uses organic wastes as compost and a livestock industry who uses organic wastes as feed. Etc. There are also a plurality of these users 10, and each user 10 has a user communication terminal 4, and this user communication terminal 4 is connected to the server 20 by a communication line 8.

The processor 11 means that the organic waste is used by the user 1
0 is a processor that makes it easy to use,
Specifically, it refers to a business operator who possesses equipment and technology capable of mixing a plurality of types of waste discharged from a waste person and processing it into feed, or composting the waste. There are a plurality of these processors 11, and each processor 11 has a processor communication terminal 3, and the processor communication terminal 3 is connected to the server 20 via a communication line 8.

The carrier 12 is a transportation operator who owns vehicles for transportation, and includes the waste 9 to the processor 1
1. A trader who can transport waste, processed feed, compost, etc. between the processor 11 and the user 10, or between the waste operator 9 and the user 10. There are a plurality of carriers 12 as well, and each carrier has a carrier communication terminal 2, and the carrier communication terminal 2 is connected to the server 20 via a communication line 8.

As an example of the communication terminals 5, 4, 3 and 2 owned by each business operator as described above, computers installed in respective companies are shown, but communication with the server 20 is limited to computers. However, a normal telephone or facsimile may be used. Each business operator needs to be able to connect to the server 20 without registering for the system. This is because unless the operator is a registered operator, he / she cannot examine the business content of each operator and send appropriate instructions, and cannot provide any service to the operator.

Next, the configuration of the server will be described with reference to FIGS. The server 20 includes a control unit 24 including a CPU and a storage unit 26 such as a hard disk.
And a transmitter / receiver 22 capable of communicating with other devices. Various data are stored in the storage means 26, and a database is constructed. As shown in FIG. 1, as a database (hereinafter sometimes referred to as DB), the waste data DB 32 of the waste operator, the stock data DB 30 of the compost and feed stocked by the processor, and the user's request The demand data 33, the transporter's transportation data DB 34, the processor's processor data DB 35, the design data DB 36 of the compost and feed presented to the user and the processor, the production amount and quality of the result used by the user, etc. The result data DB 38 and the like are constructed.

As the waste data recorded in the waste data DB 32, the names of companies (including groups and individuals) who emit organic waste, product names, materials, properties, emissions, quality, components, safety Etc., and these are made into a database. The inventory data recorded in the inventory data DB 30 includes names of companies (including groups and individuals) who process waste, facility specifications, maintenance status, manufacturing record, manufacturing volume, shipping destination, inventory of compost and feed. Etc., and these are made into a database. As the demand data recorded in the demand data DB 33, there are companies (including groups and individuals) requesting compost and feed, their use, demand amount, time, place, etc., and these are made into a database. . The transportation data recorded in the transportation data DB 34 includes names of transportation companies (including groups and individuals), transportation results, the number of vacant vehicles, and the like, which are stored in a database. As the processor data recorded in the processor data DB 35, there are a processing company name, equipment specifications, maintenance status, manufacturing record, etc., which are stored in a database. The design data recorded in the design data DB 36 include product basic data, calculation formulas,
There are physical analysis information, design records, etc., and these are stored in a database. The result data recorded in the result data DB 38 includes the production amount or quality of the product based on the components of the used compost or feed, the use time, the use amount, etc., and these are made into a database.

Next, the operation of this system will be described with reference to FIGS. Although it may be explained that each business operator transmits each data, signal, etc. to the server 20 below, this is actually performed by each business operator via the communication terminal for each business operator. Therefore, the communication terminal is omitted in the description. FIG. 3 shows a block diagram of the operation of the system when the user is a farmer or the like and wants to provide compost.
First, when the user 10 runs out of compost, the user 10 uses the communication line 8 to connect to the server 20.
A request for the required type, amount, delivery date, etc. of the compost is transmitted as demand data.

The server 20 receives the demand data from the user 10 at the transmission / reception section 22, and the control means 24 analyzes the received data. The control means 24
When it is confirmed that the received data is demand data from the user 10, the stock data DB 30 of the storage means 26.
From the inventory data recorded in (1), it is searched which of the processors currently possesses compost that meets the conditions required by the demand data. As a result of searching the inventory data DB 30, when there is a corresponding processor, the control means 24 provides a supply instruction signal to the corresponding processor 11 so as to provide the compost that meets the conditions required by the demand data. To send.

Further, the control means 24 uses the transportation data recorded in the transportation data DB 34 of the storage means 26, and the user 1 who has transmitted the demand data from the corresponding processor.
To 0, it is searched whether or not there is a carrier who can carry the corresponding amount of compost on the specified date. When a carrier 12 that meets the conditions is found as a result of the search, the corresponding processor 1
A transport instruction signal is transmitted to the transporter 12 so as to transport the compost to the user 10 who has transmitted the demand data from 0.

The control means 24 sends to the user 10 the fact that the corresponding compost is found and the delivery will be made on time. At that time, if the user 10 is instructed how to use the corresponding compost, it is more convenient and suitable for the user (use method instruction signal). This usage method instruction signal is read out from among those recorded in the design data DB 36 and transmitted. That is, as a result of searching the design data DB 36, if there is a usage method corresponding to the compost to be provided to the user 10, the control means 24 gives the usage method to the user 10 as a usage method instruction signal. Send to user.

The user 10, after using the provided compost,
It transmits to the server 20 as result data how the production quantity and quality were affected. When the server 20 receives the result data, the result data DB 38 of the storage means 26 is received.
And record it as a result data DB. The result data DB 38 is analyzed by an expert in agriculture, biology, or the like, and based on the result data, a better compost ratio and a method of using the compost are established. The mixing ratio and the method of use of the newly established compost studied here can be newly recorded in the design data DB of the design data DB 38. In this way, once a better formulation and method of use of compost is established, the compost can be prepared and used by the newly established method even when the next similar compost is used. The users of the system can improve the yield and quality by using it many times.

Next, the embodiment shown in FIG. 4 will be described. In the embodiment shown in FIG. 4, an example in which the user 10 is a cattle breeder or the like and wants feed, and directly receives the provision of waste products such as beer slag from food-related companies. Is shown. That is, the organic waste discharged from the waste user 9 reaches the user 10 without being processed. First, when the user 10 runs out of feed, a request for the required feed type, amount, delivery date, etc. is transmitted as demand data to the server 20 through the communication line.

The server 20 receives the demand data from the user 10 at the transmission / reception section 22, and the control means 24 analyzes the received demand data. Here, when the content of the demand data is such as beer slag that is used by directly receiving waste from the waste disposer 9, the control means 24 discards the storage means 26. Based on the discard data that the discarder intends to discard, recorded in the data DB 32, it is searched whether or not there is waste that meets the required conditions. As a result of searching the disposal data DB 32, the control means 24, if there is a corresponding wasteman, provides a disposal waste to the corresponding wasteman 9 so as to provide the waste material that meets the conditions required by the demand data. Send a signal.

Further, the control means 24, from the transportation data recorded in the transportation data DB 34 of the storage means 26, to the user who has transmitted the demand data from the corresponding discarder,
Search whether there is a carrier who can carry the corresponding amount of waste on the specified date. When a carrier 12 that meets the conditions is found as a result of the search, a transport instruction signal is sent to the carrier 12 so as to transport the waste from the corresponding waste user 9 to the user 10 who has transmitted the demand data. Send.

The control means 24 transmits to the user 10 that the corresponding waste is found and is delivered on time. At that time, if the user is instructed how to use the corresponding feed, it is more convenient and suitable for the user (usage instruction signal). This usage method instruction signal is read out from among those recorded in the design data DB 36 and transmitted. That is, as a result of searching the design data DB 36, if there is a usage method corresponding to the feed to be provided to the user 10, the control means 24 sends the usage method to the user 10 as a usage method instruction signal. Send to user.

After using the provided waste as feed, the user 10 transmits to the server 20 as result data how the production quantity and quality were affected. Server 2
When 0 is received, the result data is recorded in the result data DB 38 of the storage means 26 and constructed as the result data DB. The result data DB 38 is analyzed by an expert in agriculture, biology, or the like, and based on the result data, a better method of using feed or the like is established. The mixing ratio and the method of use of the compost newly studied here and newly established can be newly recorded in the design data DB 38.

In the embodiment of FIG. 4 as described above, the waste person 9 directly goes to the user 1 without the intervention of the processor 11.
It has only been shown that waste may be transported to zero. Therefore, when the user 10 wants to provide the feed, not all feeds are provided without passing through the processor, and there are feeds processed by the processor.
That is, as described above, when the processed feed is provided even for the feed, the system operates as shown in FIG.

Next, the operation in the case where the waste user requests the disposal of the waste will be described with reference to FIG. When the waste person 9 discharges the waste, the waste amount, component, discharge time, etc. of the waste are transmitted to the server 20 as waste data. The server 20 receives the discard data from the discarder 9 at the transmission / reception unit 22, and analyzes the discard data by the control means 24. Here, depending on the contents of the discard data,
It is decided what kind of feed and compost should be processed. The design data recorded in the design data DB 38 is used as a reference for the processing decision. Then, the control means 24 selects a processor having a feed to be processed, a processing facility capable of composting, etc. from the processor data DB 35 of the storage means 26.

Next, the control means 24 conveys the corresponding amount of waste to the processor 11 selected from the corresponding waste persons based on the transportation data recorded in the transportation data DB 34 of the storage means 26 on the designated deadline. Search for possible carriers. When the carrier 12 that meets the conditions is found as a result of the search, a transportation instruction signal is transmitted to the carrier 12 so that the waste is transported from the corresponding wasteman 9 to the processor 11. The control means 24 transmits the design data obtained by searching the design data 36 to the processor 11 as a processing instruction signal to the processor 11.

Next, a description will be given of the operation in the case where the waste user requests the disposal of the waste, different from the case of FIG. 5 described above. When the waste person 9 discharges the waste, the waste amount, component, discharge time, etc. of the waste are transmitted to the server 20 as waste data. The server 20 is the discarder 9
The discard data is received by the transmission / reception unit 22, and the control unit 24 analyzes the discard data. Here, the control means 24 reads the demand data DB 33 when the waste should be directly used as feed without being processed according to the content of the waste data, and uses the desired waste. Search whether there is a person. When there is a corresponding user as a result of searching the demand data DB 33, the control means 24 transmits a provision instruction signal so that the corresponding waste person 9 is provided with waste.

Next, the control means 24 can carry the corresponding amount of waste to the user selected from the corresponding waste from the transportation data recorded in the transportation data DB 34 of the storage means 26 on the designated deadline. Search whether there is a proper carrier. As a result of the search, when a carrier 12 that meets the conditions is found, a transportation instruction signal is transmitted to the carrier 12 so as to transport the waste from the corresponding wasteman 9 to the user 10.

The control means 24 sends to the user 10 the fact that the corresponding waste is found and is delivered on time. At that time, if the user is instructed how to use the corresponding feed, it is more convenient and suitable for the user (usage instruction signal). This usage method instruction signal is read out from among those recorded in the design data DB 36 and transmitted. That is, as a result of searching the design data DB 36, if there is a usage method corresponding to the feed to be provided to the user 10, the control means 24 sends the usage method to the user 10 as a usage method instruction signal. Send to user. After using the provided waste as feed, the user 10 transmits to the server 20 as result data how the production amount and quality were affected.

When the transportation data of the carrier 12 and the stock data and the processor data of the processor 11 become the latest data, the contents of each database in the server 20 need to be updated at any time. That is, as shown in FIG. 7, the carrier 12 uses the server 2 to update the transportation data.
Send haul data to 0. The server 20 which has received the transportation data in the transmission / reception unit 22 uses the control means 24 to store the transportation data in the transportation data DB 34 of the storage means 26.
Try to write in. Thereby, the transportation data DB 34
Will be updated with the latest information.

Similarly, the processor 11 transmits the inventory data and the processor data to the server 20 in order to update the processor data and the stock data of the processor. The server 20 which has received the inventory data and the processor data in the transmitter / receiver 22 writes the inventory data into the inventory data DB 30 by the control means 24 and stores the processor data in the processor data D.
Make sure to write to B35. This allows inventory data D
B30 and processor data DB35 are updated to the latest information.

It is preferable that the server 20 has an electronic bulletin board function (not shown). The electronic bulletin board has a function similar to that of the electronic bulletin board on the homepage of the Internet which is usually seen. Any of the registered companies can connect to this electronic bulletin board. Each company will access the electronic bulletin board and the feeding effect when using this system and other comments will be described, and it will be a place for each company to exchange opinions. Since each company connected to this electronic bulletin board is not the only one of the same company, it is possible for each company to hear opinions from the other parties with whom it does not have direct transactions, which can be useful for each company activity.

Furthermore, it is preferable that the server 20 has a library function (not shown). The library function stores and registers necessary information about the feed and compost of the present system. It is a function that allows each company to search and retrieve when they want. The library function is actually performed by securing a part of the storage means 26 of the server. The library information includes a glossary of terms necessary for the design and calculation of feed, main pig feed ingredients, a numerical table of feeding standards, and regulated values such as restrictions on the addition of additives. Further, the library information is not limited to such technical information regarding the reproduction processing, and may include company information such as profiles of participating companies.

In the above-described embodiment, each business operator has registered a plurality. However, each operator does not necessarily have to be plural, and may be singular.

Although the present invention has been variously described with reference to the preferred embodiments, the present invention is not limited to this embodiment, and many modifications can be made without departing from the spirit of the invention. Of course.

[0045]

The organic waste recycling system according to the present invention connects a waste person who wants to discharge the organic waste with a user who wants to use the organic waste, The organic waste can be effectively used without wastefully discarding the organic waste. For this reason, the waste owner can fulfill the social responsibility of considering the environment in the disposal of the organic waste, while the user plays a role of promoting the proper treatment of the organic waste. It is expected that the roles of waste users and users will be shared and the local community will be activated.

Further, according to the organic waste reprocessing system of claim 2, the user who wants to use the organic waste is provided to the waste person who wants to discharge the organic waste. It is possible to effectively use the organic waste without tying it up and wastefully discarding the organic waste. And, like the effect of claim 1, the waste holder can fulfill the social responsibility of considering the environment in the disposal of the organic waste, while the user plays a role of promoting the proper treatment of the organic waste. . Therefore, it is expected that the roles of waste users and users will be shared and the local community will be activated.

According to the organic waste reprocessing system of claim 3, the processor promptly responds to the request of the user who wants to use the compost, feed or the like processed from the organic waste. The processed product can be provided.

According to the organic waste reprocessing system of claim 4, the organic waste can be immediately provided to the processor in response to the request of the waste producer who intends to discharge the waste. it can.

According to the organic waste recycling system of claim 5, the user and the processor can receive the instruction of proper use and processing, so that the production effect of agriculture, forestry and livestock can be further enhanced. can do.

[0050] According to the organic waste recycling system of claim 6, depending on the amount and components of the organic waste,
Since it can be transported to a more suitable transporter, the transport efficiency can be increased, the organic waste can be transported quickly and accurately, and the efficiency of the entire recycling process of the organic waste can be increased. .

According to the organic waste reprocessing system of claim 7, when the next similar organic waste is used based on the data of the result of use, it is used based on the result of the previous use. Since the method etc. can be devised, based on this result data, a better compost mixing ratio and usage method etc. can be established. Users participating in the system can improve the production efficiency and quality of agricultural products and livestock products based on the accumulated data.

[Brief description of drawings]

FIG. 1 is an explanatory view showing the overall structure of an organic waste recycling system according to the present invention.

FIG. 2 is a block diagram showing an internal structure of a server.

FIG. 3 is an explanatory diagram showing the operation of the server when the user requests a processed product of processed waste.

FIG. 4 is an explanatory diagram showing the operation of the server when the user requests waste.

FIG. 5 is an explanatory diagram showing the operation of the server when the waste user requests the discharge of the organic waste and transports the organic waste to the processor.

FIG. 6 is an explanatory diagram showing the operation of the server when the waste user requests the discharge of the organic waste and transports the organic waste to the user.

FIG. 7 is an explanatory diagram when a carrier or a processor updates the transportation data, the processor data, or the inventory data.

[Explanation of symbols]

Communication terminal for 2 carriers 3 Communication terminal for processors Communication terminal for 4 users Communication terminal for 5 waste 8 communication lines 9 waste 10 users 11 Processor 12 Carrier 20 servers 22 Transmitter / receiver 24 Control means 26 storage means 30 Inventory data DB 32 Discarded data DB 33 Demand data DB 34 Transportation data DB 35 Processor data DB 36 Design data DB 38 Result data DB

Front page continuation (51) Int.Cl. ⁷ Identification code FI theme code (reference) B09B 5/00 B09B 5/00 M Z

Claims (7)

[Claims] 1. A waste communication terminal for a waste operator that discharges organic waste, a user communication terminal for a user who uses the organic waste as compost or feed, and each of the communication terminals. And a server connected to each other via communication lines capable of communicating with each other, wherein the server is a type of organic waste discharged from the waste communication terminal. The first storage means for storing the waste data when the amount of waste, the amount of generation, etc. are transmitted as waste data, and the type and need of the organic waste that the user communication terminal desires to provide. When the quantity is transmitted as demand data, the waste data is read from the first storage means, the read waste data is compared with the transmitted demand data, and the demand data is matched. Control means for transmitting and controlling an instruction signal instructing to provide waste to the user who has transmitted the demand data, to the communication terminal for waste that has transmitted the waste data. Recycling system for organic waste. 2. The server stores the demand data when the type and the required amount of the organic waste desired to be provided are transmitted from the communication terminal for user as the demand data. The storage unit may include a storage unit, and the control unit may output from the second storage unit when the type and amount of the organic waste to be discharged are transmitted as waste data from the waste communication terminal. Read demand data,
To compare the read demand data with the waste data and provide the waste to the user who has transmitted the demand data to the waste communication terminal that has transmitted the waste data that matches the read demand data. 2. The recycling system for organic waste according to claim 1, wherein the system is controlled by transmitting an instruction signal to instruct. 3. The server is connected to a communication terminal for a processor, which can be operated by a processor such as a processor that processes organic waste into processed products such as compost and feed, through a communication line capable of mutual communication. And a third storage unit for storing inventory data such as an inventory quantity of the processed product owned by the processing unit, wherein the control unit is an organic waste that the user communication terminal desires to provide. When the kind or required amount of the object is transmitted as demand data, the inventory data is read from the third storage means, the read inventory data is compared with the demand data, and the inventory data has the inventory data matching the demand data. The system for recycling organic waste according to claim 1 or 2, wherein the communication terminal for a processor is controlled by transmitting an instruction signal instructing to provide a suitable processed product to the user. . 4. The server includes a fourth storage unit for storing processor data such as specifications of processing facilities of the processor, and the control unit is an organic substance discharged from the waste communication terminal. When the type and generation amount of waste are transmitted as waste data, the processor data is read from the fourth storage means, the read processor data and the waste data are compared, and the waste data It is characterized by transmitting an instruction signal for instructing to accept and process the waste of the waste person who has transmitted the waste data to the communication terminal for the processor having the processor data that conforms to The recycling system for organic waste according to claim 3. 5. The server uses the organic waste or the processed product when the user uses it, or when the processor processes the organic waste or the processed product, the ratio of the mixture of the organic wastes of different types and the component of the additive. , A fifth storage means for storing design data such as processing method such as quantity or processing time, wherein the control means uses organic waste or processed material by the user, or When processing waste, the design data suitable for the organic waste or the product used by the user or the processor is read from the fifth storage means, and the read design data is read by the user or the processor. 5. The recycling system for organic waste according to claim 1, 2, 3 or 4, which is transmitted. 6. The server is connected to a communication terminal for a carrier that can be operated by a carrier such as a transportation company that transports organic waste by a communication line capable of mutual communication, and the number of vehicles carried by the carrier. And a sixth storage means for storing transportation data such as a transportation record, wherein the control means, when transporting the organic waste from the waste user to the user, the processed product from the processor to the user. When transporting the organic waste or transporting the organic waste from the waste to the processor, the transport data is read from the sixth storage means, and the transport data read from the transport data to the transporter communication terminal suitable for transport, The system for recycling organic waste according to claim 3, 4 or 5, wherein an instruction signal for instructing to carry a compatible organic waste or processed product is transmitted and controlled. 7. The user uses the organic waste or processed material provided by the user as a result of an agricultural, forestry and livestock business, and as a result, effects such as production amount and quality are used as result data for the user. The transmission is possible from a communication terminal to the server, and the server has a seventh storage means for storing the received result data. Recycling system for organic waste.