JP2002203101A - Control system and controller for garbage treatment equipment, and recording medium - Google Patents

Abstract

PROBLEM TO BE SOLVED: To accurately record and totalize a garbage decomposition treatment amount and a reduction rate in a form easily reported according to enforcement of a food recycle law. SOLUTION: This system is provided with a controller 15 for operation- controlling a garbage treatment equipment 100 for decomposition-treating the garbage and for collecting a contitional data of the garbage, and a user side personal computer 101 for outputting an operation signal to the controller 15 by information communication, for inputting a signal based on the conditional data of the garbage collected by the information communication via the information communication, and for displaying conditional data information in a prescribed period as a diagram submitted to notice in response to the signal.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a garbage disposer for decomposing garbage generated in restaurants, food processing companies, and the like, and more particularly, to a mode for easily reporting the amount of garbage decomposed and the reduction rate. The present invention relates to a management system, a control device, and a recording medium for a garbage disposer capable of accurately recording and counting data in a computer.

[0002]

2. Description of the Related Art Japanese Patent Application Laid-Open No. Hei 10 (1998) discloses a method for decomposing garbage generated in households, restaurants, food processors, and the like, including food waste including vegetables and fruit scraps, bones and shells of seafood, and the like.
A so-called garbage disposer (garbage disposer) as described in JP-A-216665 has been proposed.

The garbage disposer according to the prior art receives a medium (cultivation base material) carrying microorganisms in a container (treatment tank) and rotates a stirring means (stirring blade) to remove the garbage in the treatment tank. The garbage is decomposed into gas and water by the decomposing action of microorganisms in the cultivation substrate by stirring and mixing with the cultivation substrate, thereby reducing the volume and weight (or extinction) of the garbage. is there. During operation, heat required for the action of decomposing microorganisms is supplied by the heating means (heater), and gas and water vapor in the processing tank are exhausted to the outside by the exhaust means (exhaust fan).

In this prior art, the temperature in the processing tank of the garbage disposer and the operating time of the heater during the above operation can be measured, and the measured data can be transmitted to an external terminal by information communication via a telephone line. It has become.

[0005]

In the context of recent waste recycle (recycling), the so-called Food Recycling Law was promulgated in June 2000 in relation to foods.
It is expected to take effect within 2001. According to the Food Recycling Law, the amount of garbage generated is particularly high for restaurants and food processors that produce garbage for business use, especially for those who generate a large amount (for example, several tens tons to several hundred tons or more per year). It is surely required that a weight reduction rate of a predetermined ratio (for example, 20 to 30%) is required. Under such a trend, in the garbage disposal machine (especially for business use), the garbage decomposition processing amount (garbage reduction volume, garbage reduction) and the weight loss rate are managed and accurately recorded and counted. It is essential.

Here, in the above-mentioned prior art, the temperature in the processing tank and the operating time of the heater are transmitted to an external terminal through information communication, and the processing tank temperature and the heater operating time for a predetermined number of days are displayed in a list in a graph format. However, there is no means for detecting the amount of garbage decomposition processing, and the amount of garbage decomposition processing is not displayed on an external terminal. Therefore, it is difficult to respond to the enforcement of the Food Recycling Law.

The present invention has been made in view of the above-mentioned circumstances, and has as its object to cope with the enforcement of the Food Recycling Law and to accurately record and dispose of the amount of garbage decomposition treatment and the rate of weight loss in an easy-to-report manner. An object of the present invention is to provide a management system, a control device, and a recording medium for a garbage disposer that can be counted.

[0008]

Means for Solving the Problems (1) In order to achieve the above-mentioned object, the present invention controls the operation of a garbage disposal machine for decomposing garbage and collects state quantity data of the garbage. Control means, and output an operation signal to the control means by information communication, and input a signal based on the garbage state quantity data collected by the control means by information communication, and according to the signal, the signal for a predetermined period of time. And an operation terminal for displaying the garbage state quantity information as a list that can be viewed.

In the present invention, when the garbage disposer is operated and the garbage is decomposed, the control means collects the garbage state quantity data such as content material quantity data and content moisture content data. . Then, the operation terminal inputs a signal based on the collected data by information communication, and in response thereto, outputs the garbage state quantity information (for example, garbage input amount, garbage reduction, garbage reduction rate, etc.) for a predetermined period. It is displayed as a list that can be listed (for example, a so-called daily report displayed every day). Thereby, the user can grasp at a glance the amount of the garbage decomposition treatment for a predetermined period and can manage them, and by appropriately arranging the aspects of the above-mentioned table, the amount of the garbage decomposition treatment can be reduced. And the rate of weight loss can be accurately recorded and counted in an easy-to-report manner.

(2) In the above (1), preferably,
The garbage disposer includes a processing container for receiving the garbage, and the control unit collects at least data on the amount of content in the processing container as the garbage state amount data.

(3) In the above (2), more preferably, the operation terminal is configured to input the amount of garbage, reduce the amount of garbage, At least one of the waste reduction rates is displayed in association with the predetermined period.

(4) In the above (2), preferably, the garbage disposer includes a processing container for receiving the garbage, and the control means includes at least a content substance amount data in the processing container. And the content moisture content data is collected as the garbage state quantity data, and the operation terminal uses the garbage solid content change amount based on the content substance quantity data and the content moisture content data as the garbage state quantity information. Display in chart.

(5) In order to achieve the above object, the present invention is also a control device for a garbage disposer for controlling the operation of a garbage disposer for decomposing garbage. Input means for inputting state quantity data, calculation means for generating a display signal for displaying the state quantity information of the garbage for a predetermined period as a listable table based on the input state quantity data, and generation thereof Output means for outputting the displayed display signal by information communication.

(6) In order to achieve the above object, the present invention provides a computer for inputting state quantity data of garbage to be processed by a garbage processing machine, and for a predetermined period based on the input data. Computer-readable recording of a program for generating a display signal for displaying the state quantity information of the garbage as a list capable of listing, and outputting the generated display signal by information communication Recording medium.

[0015]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing an embodiment of a garbage processing machine management system according to the present invention.

FIG. 1 is an overall schematic diagram showing an embodiment of a garbage processing machine management system according to the present invention, together with a garbage processing machine 100 to be controlled. In FIG. 1, 1
Reference numeral 01 denotes a personal computer as an operation terminal installed inside a building (for example, a cafeteria building, a management building, etc.) 102 in which a user (user) is present, and 15 denotes an Internet 103 via a telephone line or the like to the personal computer 101. Is a control device of the garbage disposal machine 100 arranged outdoors. The personal computer 101 includes a display unit such as a CRT and an LCD, and an input unit such as a keyboard and a mouse (details will be described later). Reference numeral 104 denotes a personal computer other than the personal computer 101, and may be, for example, a personal computer for a user (for example, a boss or an administrator) who does not actually operate the garbage processing machine 1 installed in another building. Or the manufacturer side (the nearest sales branch, service factory, production factory, etc.)
A personal computer may be used.

FIG. 2 is a front view showing the entire structure of a garbage disposer 100 to be controlled by the garbage disposer management system of the present invention, and FIG. 3 is a side sectional view from the right in FIG. It is.

2 and 3, reference numeral 1 denotes a refuse treatment machine main body, 2 denotes a processing container disposed in the refuse treatment machine main body 1, and 3 denotes a garbage or medium 4 (a well-known function of disassembling processing). , A loading lid for opening and closing the loading port 3, 6 a heater provided at the bottom of the processing vessel 2,
a and 7b are air exhaust ports and air intake ports provided on the upper part of the processing container 2, respectively, and 8a and 8b are for removing dust at the processing container 2 side entrance of the exhaust port 7a and the processing container 2 side exit of the intake port 7b. Filters provided respectively, 9 is a hose-shaped duct connected to the exhaust port 7a, 10 is an exhaust port 7a
An exhaust fan provided between the duct 9 and the duct 9
Device connected to the downstream side of the deodorizing device, 12 is the deodorizing device 1
1 is a chimney provided further downstream, 13 is a moisture content detecting means provided at a lower part on the inner peripheral side (may be a bottom part or a side part) of the processing vessel 2, 14 is an open / close detecting means provided near the charging lid 5, 15. Reference numeral 16 denotes a control device provided at the lower part of the main body 1 of the refuse treatment machine.

FIG. 4 is a perspective sectional view showing the entire structure of a garbage disposer 100 to be controlled by the garbage disposer management system of the present invention, viewed from the same direction as FIG. 2, and FIGS. 3 have the same reference numerals.

In FIG. 4, reference numeral 17 denotes a stirring means provided in the processing vessel 2 and having a stirrer 17b protruding from the rotation shaft 17a in a zigzag comb shape, and reference numeral 18 denotes a rotation shaft 1 of the stirring means 17.
7a is a pulley provided on the bottom of the refuse treatment machine main body 1, 19 is a drive device comprising, for example, an electric motor, 20 is a pulley provided on a drive shaft 19a of the drive device, 21 is a pulley 1
A chain (may be a belt) wound between the pulley 8 and the pulley 20 and connecting them, a supporting portion (supporting frame) 22 supports the processing vessel 1 and rotatably supports the rotating shaft 17a of the stirring means 17. Reference numerals 23 denote mass detecting means provided at the lower four corners of the support portion 22.

Returning to FIG. 2 and FIG.
Is a known electric heater, for example, and although not particularly illustrated in detail, has a structure that is appropriately divided into a plurality of blocks in a circumferential direction or an axial direction of the stirring unit rotating shaft 17a. ON / OFF is possible (details will be described later).

The mass detecting means 23 is composed of, for example, a known load cell, and the load of the processing vessel 2 and the stirring means 17 is applied via the support portion 22. The exhaust port 7a, the exhaust fan 10, the duct 9, the deodorizing device 11, the chimney 12, etc.
5 is separately supported by supporting means (not shown) so that a load is not applied. With such a configuration, the mass detection unit 23 measures (detects) the mass of the contents (the medium 4 and the garbage, and a mixture thereof after the start of operation) in the processing container 2,
The measurement signal is output to the control device 15. In this example, the mass detecting means 23 is provided at four positions, and
Although point support is used, the present invention is not limited to this.
May be set at only one of the four corners, and the other three may be supported by a bracket or the like. In short, it is sufficient if the arrangement is such that the mass of the medium (content) can be measured.

The moisture content detecting means 13 is, for example, a known microwave type, heat conduction type, dielectric constant type or the like sensor, and includes the contents (medium 4 after the start of operation and medium 4 in the processing vessel 2). Of water (mixture of garbage and garbage) (= mass of water / total mass, in other words, mass of water / (mass of solids + mass of water)) and control the measurement signal Output to the device 15. In this example, the moisture content detecting means 13 is mostly provided inside the processing vessel 2. However, the present invention is not limited to this. The moisture content detecting means 13 may be provided outside the processing vessel 2. It is sufficient if the arrangement is such that the moisture content can be measured. Further, a portion of the water content detection means 13 protruding into the processing container 2 may be provided with a cover or the like for protecting the medium 4 to be stirred and the flow of garbage or the like as appropriate.

The opening / closing detecting means 14 is, for example, a known contact-type limit switch, and detects (detects) the opening / closing movement (whether opened or closed) of the closing lid 5 and a detection signal thereof. Is output to the control device 15.

The operation panel 16 includes an operation section 16a for a user to perform an operation input, and a display section 16b as a display (notification) means for performing various displays (details will be described later).
The operation unit 16a includes at least a medium input switch 16a1 and a garbage input switch 16a2 for causing the control device 15 to recognize that the operation of inputting the medium 4 or the operation of inputting garbage is performed. Others
A switch for starting / stopping the heater 6, the exhaust fan 10, the deodorizing device 11, the driving device 19, and the like, and a switch for manually controlling the operation speed and the like are provided as needed. May be.

The details of the function of the control device 15 will be described later.

Next, the basic operation of the garbage disposer having the above configuration will be described.

When performing the garbage disposal, first, the medium input switch 16a1 of the operation panel operation section 16a is turned on to make the control device 15 recognize that the medium is input (described later), and then the input cover 5 is opened and the input port is opened. From 3, a medium 4 supporting microorganisms is charged and accommodated in the processing container 2. Thereafter, the garbage input switch 16a2 is turned on and the control device 15 is turned on.
After recognizing the input of garbage (described later), garbage (not shown) is input from the input port 3 and the input lid 5 is closed. Thereafter, the medium 4 is electrically heated by the heater 6 via the processing container 2 to realize an optimal temperature environment for decomposing the microorganisms, and the driving force of the driving device 19 is transmitted through the chain 21 to stir the medium. The means 17 is rotated, and the inputted garbage and the medium 4 are stirred and mixed by the stirring rod 17b of the stirring means 17. Further, at this time, while the outside air is taken into the processing container 2 from the suction port 8b at the upper part of the processing container 2, the air in the processing container 2 is led out from the discharge port 8a, deodorized by the deodorizing device 11, and then discharged to the outside air through the chimney 12. By discharging the air, the air in the processing container 2 is circulated. As described above, the contact frequency between the microorganisms in the medium 4 and the garbage and the contact frequency between the microorganisms and the oxygen in the fresh air are increased, and the garbage is efficiently decomposed by the action of the microorganisms.

The garbage put into the processing container 2 is decomposed by such a basic operation, and when the garbage is decomposed and disappears or is reduced in volume to some extent, the garbage is sequentially removed by the same operation as described above. Additional input and further disassembly processing. Further, when the function of the microorganisms carried on the medium 4 is reduced (deteriorated) due to the repetition of the decomposition process, the medium 4 is appropriately replaced or the medium 4 is additionally charged by the same operation as described above.

A feature of the present invention is that, in the operation of the garbage disposer as described above, the user inputs an operation from the personal computer 101 in the building 102 and the control device 1 according to the operation signal.
5 controls the operation of the garbage disposal machine 100 (performs remote control by a personal computer), and collects the state quantity data of the garbage detected by the garbage disposal machine 100 with the control device 15,
The personal computer 101 displays the garbage state quantity information as a viewable table based on the collected data (performs a daily report display on the personal computer).

The contents are described below in order of FIGS.
This will be described below.

(A) Functional Configuration of Control Device FIG. 5 is a functional block diagram showing a functional configuration of the control device 15. In FIG. 5, reference numeral 15a denotes a central processing unit (CPU), and 15b denotes an R storing a control program.
OM, 15c is a RAM capable of storing and reading various data as needed, 15d is an A / D converter, 15e is a D / A converter, and 15f is capable of bidirectional data communication with the personal computer 101 via the Internet 103. Interface circuit (I / O) with built-in modem, 15g is timer,
15h is a communication control unit.

With the above configuration, the control device 15 inputs detection signals (garbage state quantity data) from the mass detecting means 23, the water content detecting means 13, and the open / close detecting means 14 of the garbage processing machine 100. A / D converter 15d
A / D conversion is performed, and at least a part of them is processed (primary processing) into predetermined weight reduction information (to be described later) based on those input signals by the CPU 15a, and stored in the RAM 15c. The weight reduction information (primary processing data) in the RAM 15c is returned to the RAM 15c by the communication control unit 15h at a predetermined timing (for example, when garbage is input as described later).
From the I / O 15f and the Internet 10
The information is transmitted to the weight reduction information processing unit 106 of the CPU 101b (described later) of the personal computer 101 via the PC 3 and is processed (secondary processing) into garbage state amount information. Information other than the weight loss information is also output as a display signal to the personal computer 101 via the I / O 15f and the Internet 103, and various numerical values and data including at least a part of the weight loss information are appropriately converted by the D / A converter. It is D / A converted at 15e and output as a display signal also to the display unit 16b of the operation panel 16 (details will be described later).

At this time, the control unit 15 receives an operation signal from the operation panel operation unit 16a, performs A / D conversion with the A / D converter 15d, and simultaneously executes the Internet 1
03 from the personal computer 101 via the I / O
O15f, and performs a predetermined calculation. Based on the calculation result, the driving device 19 and the exhaust fan 1
0 and a control signal for controlling the operation of the heater 6 (details will be described later).

(B) Functional Configuration of User-side Personal Computer FIG. 6 is a functional block diagram showing a functional configuration of the personal computer 101. 6, 101a is an input / output interface (I / O), 101b is a CPU, 101c is a RAM for temporarily storing data and the like, 101d is a ROM for storing control programs and the like, and 101e is a main memory for storing the database 104. Storage device, 101f is a keyboard,
The input unit 101 includes a mouse and the like, and 101g denotes a display unit including a CRT and an LCD.

The input / output interface 101a inputs weight reduction information from the machine-side control device 15 of each garbage disposal machine 100 via the Internet 103. The CPU
101b stores and accumulates the input information in the database 104 of the main storage device 101e, and processes the information stored in the database 104 into garbage state quantity information such as garbage input amount, garbage reduction, and garbage reduction rate. (Secondary processing) to create a daily report (described below) and the like, and display them on the display unit 101g.

(C) Remote operation by personal computer Next, referring to FIGS.
A remote operation control operation of the user of the garbage disposal 100 by the user will be described.

FIG. 7 shows an initial display screen 20 on the display unit 101g immediately after the program relating to the management system of the garbage disposer of the present embodiment is started on the personal computer 101.
1 is shown. In FIG. 7, reference numeral 202 denotes “setting” for shifting to a stage for setting each control condition for operation.
Operation setting screen 222 that appears on the display unit 101g when the “setting” button 202 is clicked.
Is shown in FIG.

In FIG. 8, reference numeral 206 denotes a stirring setting display area, 207 denotes an air volume setting display area, and 208 denotes a heater setting display area.

The stirring setting display area 206 is an area for displaying various settings of the stirring means 17. That is, in this example, the stirring means 17 is first rotated for a predetermined initial rotation time after the start of operation, and then stopped, and thereafter,
Intermittent operation in which rotation and stationary are alternately repeated is performed. Then, on this screen 222, it is possible to set the initial rotation time after the start of the operation, the rest time and the rotation time of the intermittent operation thereafter, and the rotation speed (rotation speed) at the initial rotation time and the rotation time. And an initial rotation time display area 206a and a stationary time display area 206b.
, Rotation time display area 206c, and rotation number display area 20
The setting of each time and the number of rotations is performed with 6d. In the initial state where the operation setting screen 222 is displayed, these areas 206a
For example, -d is displayed as 0 or the value at the time of the previous operation setting is displayed.

The air volume setting display area 207 is an air volume setting display area for displaying the air volume setting of the exhaust fan 10. In the initial state in which the operation setting screen 222 is displayed, the display is 0 or the previous operation. The value at the time of setting is displayed.

The heater setting display area 208 is an area for displaying the setting of the number of heating blocks of the heater 6.
That is, in this example, as described above, the heater 6 is configured to be capable of being turned on / off for each of a plurality of blocks. It is divided into two stages of “all” to be turned on. In the initial state where the operation setting screen 222 is displayed, for example, “all” is displayed or the value at the time of the previous operation setting is displayed.

Then, each of the regions 206a-d, 20
7 and 208, a display value change button 209 is provided, and when this button is clicked, each area 206 is changed.
The numerical values or display of a to d, 207 and 208 can be increased or decreased or changed.

Reference numeral 210 denotes a completion button. When this button 210 is clicked, each control value is determined by the display value at that time, and the operation control is performed based on that value. When the “Complete” button 210 is clicked, the setting confirmation window 211 is interrupted and opened (FIG. 8 shows a state in which this window 211 is open), and only when the “Yes” button 211 a of this window 211 is clicked will be described later. The screen shifts to the operation display screen 212.

FIG. 9 is a diagram showing an operation display screen 225 displayed by clicking the "Yes" button 211a of the setting confirmation window 211 of the operation setting screen 222.

In FIG. 9, reference numeral 220 denotes a “start operation” button, 221 denotes a “stop operation” button, and 226 denotes a “garbage disposal detailed display” button. "Start operation" button 220
By clicking, the control device 15 controls the stirring means 17, the heater 6, the exhaust fan 10, and the like of the garbage disposal machine 100 in accordance with the settings on the operation setting screen 222, and Start the operation (if the operation has already been started with another setting, change to the new setting this time and continue the operation). In addition, by clicking the “stop operation” button 221, the control device 15 stops the operations of the stirring means 17, the heater 6, the exhaust fan 10, and the like of the garbage disposal machine 100 to operate the garbage disposal machine 100. Stop.

In FIG. 9, reference numeral 214 denotes an input lid open / close display area, 215 denotes a content substance amount display area, 216 denotes a content moisture content display area, 217 denotes a fan operation display area, and 21 denotes a fan operation display area.
Reference numeral 8 denotes a heater operation display area, and reference numeral 219 denotes a stirring operation display area, each of which displays the operation status of each device that has started operation by clicking the “operation start” button 220 as described above.

The opening / closing opening / closing display area 214 indicates the opening / closing detecting means 1 of the garbage processing machine 100 at this time.
The open lamp 214a or the close lamp 214b is illuminated and displayed according to the open / closed state of the input lid 5 detected in step 4.

The content substance amount display area 215 indicates the mass detection means 2 of the garbage disposal 100 at this time.
The mass value of the contents in the processing container 2 detected at 3 is displayed.

The water content display area 216 indicates the water content detection means 13 of the garbage disposal 100 at this time.
The moisture content of the contents in the processing container 2 detected by the above is displayed.

The fan operation display area 217 monitors a control signal from the control device 15 to the exhaust fan 10 based on the setting on the operation setting screen 222 (or the actual rotation speed of the exhaust fan 10 is not shown). (It may be monitored by the detecting means), and the rotation speed [rpm] of the exhaust fan 10 at that time and the air flow [m ³ / m
in] is the rotation number display section 217a and the air volume display section 2 respectively.
17b.

The heater operation display area 218 monitors a control signal from the control device 15 to the heater 6 based on the setting on the operation setting screen 222 (or the actual power amount of the heater 6 is not shown). The number of heating blocks of the heating heater 6 and the corresponding power consumption [W] at that time may be monitored by the number of heating blocks. The information is displayed on the display unit 218a and the electric energy display unit 218b.

The stirring operation display area 219 monitors a control signal from the control device 15 to the stirring means 17 based on the setting on the operation setting screen 222 (or the actual rotation speed of the stirring means 17 is not shown). (It may be monitored by the detection means.)
The rotation display lamp 219a / stationary display lamp 219b is lit and displayed according to the rotation / stationary state of, and the set rotation number [rpm] at that time is displayed on the set rotation number display section 219c.

The above-mentioned “display garbage processing details” button 22
6, when this button is pressed, a new garbage processing detail display window 227 is interrupted and displayed. FIG.
It is a figure showing the state where the window 227 was interrupted and displayed.

In FIG. 10, reference numeral 228 denotes a medium input button (switch) corresponding to the medium input switch 16a1 of the operation panel operation section 16a, and 229 denotes the operation panel operation section 16a.
A garbage input button (switch) corresponding to the medium input switch 16a2 of a, 230 is a content substance / moisture content display area, 231 is a mass / moisture content display area at the time of additional medium input, 2
Reference numeral 32 denotes a mass / moisture content display area after the input of garbage, 233 denotes a mass / water content display area before the input of garbage, 234 denotes a garbage input count display area, and 235 denotes a medium exchange display window. These buttons 16a1, 16a2, display areas 231 to
234 and the window 235 will be described later in detail.

Although not described in detail, at least a part of the operation for the operation performed from the personal computer 101 is performed by the operation panel 16 provided in the garbage processing machine 100.
By operating corresponding switches, dials and the like (details not shown) on the operation unit 16a of the personal computer 1,
The same operation as that from the 01 side is possible.

Next, the control device 15 in the present embodiment
Among the control (calculation) contents described above, a control procedure related to remote operation from a personal computer will be described with reference to FIGS.

FIG. 11 is a flowchart showing the entire control performed by the control device 15 with respect to remote control from a personal computer. In FIG. 11, this flow is started when the operation start button 220 on the operation display screen 225 shown in FIG. 10 is clicked (or when an operation start switch (not shown) provided in the operation panel operation unit 16a is turned on). First, in step 10, an index i indicating the number of times of adding garbage, an index j indicating the number of times of adding the medium 4, the integrated amount H of the medium 4, the input solid mass Hd, and the input water mass Hw.
Are all initialized to zero.

Thereafter, in step 20, it is determined whether or not the medium input button 228 (or the medium input switch 16a1 of the operation panel operation unit 16a) of the personal garbage processing detailed display window 227 has been turned ON. When the determination is satisfied, the process proceeds to Step 30.

In step 30, the index i representing the number of garbage throws is set to 1, and the routine proceeds to step 100.

In step 100, prior to the start of the garbage decomposition processing operation, control for the operation preparation processing is performed. FIG. 12 is a flowchart showing a detailed procedure of the operation preparation processing.

In FIG. 12, first, at step 101,
It is determined whether or not the open / closed state of the input lid 5 is detected by the opening / closing detection unit 14. When the determination is satisfied, it is considered that the loading lid 5 is opened and the loading of the medium 4 is performed, and the process proceeds to step 102 to determine whether the closing state of the loading lid 5 is detected. When the determination in step 102 is satisfied, the process proceeds to step 103.

In step 103, the measured value by the mass detecting means 23 at this time is inputted, and the mass ki of the medium 4 into which the value is input (in this case, i = 1, which is k1) [k
g] in the RAM 15c, and outputs the value as a display signal to the personal computer 101 (or the operation panel 16).
Is displayed on the content substance amount display section 230a (or the operation panel display section 16b) of the content substance content / water content display area 230. At this time, a value measured by the water content detection means 13 is input, and this value is stored in the RAM 15c as the water content ai (a1 in this case) [%] of the inserted medium 4, and the value is stored in the personal computer 101 ( Alternatively, it is output to the operation panel 16 as a display signal, and is displayed on the content water content display section 230b (or the operation panel display section 16b) of the content substance / water content display area 230.

Note that the mass ki of the medium 4 is not detected by the mass detecting means 23 but is detected by another detecting means outside the garbage processing machine before being charged, and the detection signal is transmitted to the control device 15. May be automatically imported to
Alternatively, the user may manually input the detected value to input means provided in the garbage processing detailed display window 227 (or the operation panel operation unit 16a), and may input the input signal to the control device 15. . Furthermore, when the mass (or the average value) of the medium 4 is generally known statistically or empirically, or when the medium is charged with a fixed-capacity container, the charged volume can be kept constant every time. In such a case, the user manually inputs the mass value to the input means provided in the garbage processing detailed display window 227 (or the operation panel operation unit 16a) without performing detection. Alternatively, if there is little change, the setting may be stored in the RAM 15c of the control device 15 in advance. In any case, the detection is not necessarily performed as long as the mass ki of the medium 4 to be charged can be given to the control device 15.

The water content ai of the medium 4 is not detected by the water content detection means 13 but, for example, when the user opens the charging lid 5, the garbage processing machine is placed in the processing container 2 from outside. A separate detection means is inserted and inserted into the medium 4 to perform the detection, or the detection is performed by another detection means outside the garbage processing machine before the input, and the detection signal is transmitted to the control device 1.
5, or the user manually inputs the detected value to input means provided in the garbage processing detailed display window 227 (or the operation panel operation unit 16a). The input signal may be taken into the control device 15. Further, when the value of the water content of the medium 4 (or the average value thereof) is statistically or empirically known, the user can use the value of the water content without detecting the garbage without performing detection. It may be manually input to an input means provided in the processing detail display window 227 (or the operation panel operation unit 16a), or may be set and stored in the RAM 15c of the control device 15 in advance if there is little change. . In addition, a plurality of moisture content values corresponding to a plurality of types of media 4 are set and stored in the RAM 15c, and the type of the media 4 or the moisture content value corresponding to each of the media 4 is displayed in the garbage processing detailed display window 227 (or A list is displayed on the display unit 16b of the operation panel 16), and a user is provided with a selection means (not shown) separately provided in the garbage processing detailed display window 227 (or the operation panel operation unit 16a). May be selected and input. In any case, as long as the water content ai of the medium 4 to be charged can be provided in the control device 15, the detection is not necessarily performed.

Thereafter, the process proceeds to step 104, where the mass ki of the input medium 4 and the water content ai input in step 103 are used to calculate the solid content mass kdi of the medium 4 (in this case, kd
1) and the water mass kwi (kw1 in this case) are calculated. That is, the mass kdi of the solid content is obtained by: kdi = (1-ai / 100) × ki, and the water mass kwi is obtained by: kwi = ai × ki / 100.

The solid content mass kdi and the water content kwi of the medium 4 thus determined are stored in the RAM 15c, and their values are output as display signals, and the content solid content mass display portion 230c of the garbage processing detailed display window 227 is displayed. And the content moisture content display section 230d (or the operation panel display section 16)
b).

When the above procedure is completed, the operation preparation processing is completed, and the routine returns to FIG. 11 and proceeds to step 110.

In step 110, it is determined whether or not the garbage input button 229 of the garbage processing detailed display window 227 (or the garbage input switch 16a2 of the operation panel operation section 16a) has been turned ON. When the determination is satisfied, the process proceeds to step 200.

In step 200, upon completion of the operation preparation, control of a process immediately after the input of garbage is performed. FIG. 13 is a flowchart illustrating a detailed procedure of the process immediately after the input of the garbage.

In FIG. 13, first, at step 201,
It is determined whether or not the open / closed state of the input lid 5 is detected by the opening / closing detection unit 14. When the determination is satisfied, it is considered that the loading lid 5 is opened and the food waste is loaded on the medium 4, and the process proceeds to step 202 to determine whether the closing state of the loading lid 5 is detected. I do. Step 2
When the determination of 02 is satisfied, the process proceeds to step 203.

At step 203, the measured value by the mass detecting means 23 at this time is inputted, and the garbage to which the value is inputted and the medium 4 which has already been inputted (hereinafter, these 2
The total mass (= the amount of contents) l i (for example, i = 1 when the first time is charged, it becomes l 1) [kg] is stored in the RAM 15c, and the value is stored in the RAM 15c. The content is displayed on the operation panel display section 16b in the content substance amount display area 232a (or the operation panel display section 16b) of the post-garbage input mass / moisture content display area 232 of the display window 227.

At this time, the water content of the garbage is detected by a well-known water content detecting means outside the garbage disposal machine before the garbage disposal, and the detected value is used by the user to display a detailed garbage processing window. 227 (or operation panel operation unit 16a), and manually input the input means (not shown), and input this input signal to the control device 15 (so that the detection signal is automatically taken into the control device 15). Good). However, if the value of the water content of the garbage (or its average value) is statistically or empirically known, the user can input the value of the water content to the input means without performing detection. You may make it input manually. A plurality of moisture content values corresponding to a plurality of types of garbage are set and stored in the RAM 15c, and the type of garbage or the moisture content value corresponding to each garbage is displayed in the garbage processing detail display window 227 (or the operation panel 16). Of the garbage processing detailed display window 227 (operation panel operation unit 16a). Good.

The water content bi of the input garbage input to the control device 15 in this way (for example, b1 for the first input)
[%] Is stored in the RAM 15c, and the value is stored in the garbage processing detail display window 227.
2b (or the operation panel display section 16b) is output as a display signal and displayed.

The user does not input the moisture content bi of the garbage as described above.
In a state where the garbage is opened, a detecting means separate from the garbage disposal machine is inserted into the processing container 2 from outside, and the detection means is inserted into the garbage placed on the medium 4 to detect the water content bi of the garbage. Alternatively, a detecting means similar to the water content detecting means 13 may be arranged on, for example, the lower surface 3a of the inlet 3 (see FIG. 2), and the garbage may be detected by the detecting means when the garbage passes during the charging. May be detected. Conversely, if it is known that the fluctuation is small, the water content bi of the garbage may be set and stored in the RAM 15c of the control device 15 as a fixed value in advance. In any case, it suffices that the water content bi of the raw garbage 5 to be put into the control device 15 can be given.

Thereafter, the process proceeds to step 204, where the total mass l i of the contents (medium 4 + garbage) and the water content bi of the food garbage input in step 203 are used, and M1), mass of solid content mdi
(Md1 for the first charge) and water content mwi (mw1 for the first charge) are calculated. That is, garbage mass mi
Is: mi = li−ki, and the solid content of garbage mdi is mdi = (1−bi / 100) × mi, and the water mass of garbage mwi is obtained by mwi = bi × mi / 100.

The mass of the input garbage, mi, is not calculated by the mass detection means 23 by detecting the content li of the content li by using li-ki.
As in the case of the medium mass ki described in 3 above, detection may be performed by another detection means outside the garbage disposal machine before being put in, and the detection signal may be automatically taken into the control device 15, or The user may manually input the detected value to the input means, and the input signal may be taken into the control device 15.
Furthermore, when the mass of garbage (or its average value) is known statistically or empirically, or when the volume is fixed by using a fixed volume container, the input volume can be kept constant every time. In such a case, the user may manually input the value of the mass to the input means without performing the detection. If the change is small, the user may set and store the value in the RAM 15c of the control device 15 in advance. May be. In any case, mass m of garbage to be put in
If i can be set to the state given in the control device 15, it is not necessarily detected.

In this step 204, in addition to the above, the input garbage mass mi, the solid content mass mdi, and the water mass mwi are integrated in order from i = 1 (details will be described later).
Calculate the input garbage integrated mass Σmi, the solid content integrated mass Σmdi, and the water integrated mass Σmwi. For example, at the time of the first injection, since i = 1, Σmi = m1, Σmdi = md1,
Σmwi = mw1.

The mass mi, solid mass mdi, moisture mass mwi, accumulated mass Σmi, accumulated solid mass Σmdi, and accumulated moisture mass Σmwi of the input garbage thus determined are stored in the RAM 15.
c, and the value is displayed in the mass / moisture content display area 23 after the garbage is input in the garbage processing detail display window 227.
2 garbage mass display area 232c, garbage solid content mass display area 232d, garbage water mass display area 232e, garbage integrated mass display area 232f, garbage solids integrated mass display area 232g, garbage moisture integrated mass display Region 232
h (or the operation panel display section 16b).

When the above procedure is completed, the processing immediately after the input of garbage is completed, and the process returns to FIG.

In step 210, the operation of the garbage disposer is started (started). That is, a control signal is output to the driving device 19, the exhaust fan 10, the heater 6, and the like to start the operation thereof.

Thereafter, at step 220, the garbage input button 229 of the garbage processing detailed display window 227 (or the garbage input switch 16a2 of the operation panel operation section 16a).
Is turned on (again). When the determination is satisfied, it is considered that additional garbage is to be input, and the process proceeds to step 230.

In step 230, the operation of the garbage disposer is stopped. That is, the driving device 19 and the exhaust fan 1
0 and a control signal is output to the heater 6 and the like, and their operations are stopped. Then, at step 240, 1 is added to the above-mentioned index i representing the number of times of adding garbage, and the process proceeds to step 300.

In step 300, in response to the above-mentioned state of adding additional garbage, control for processing immediately before the next addition of garbage is performed. FIG. 14 is a flowchart showing a detailed procedure of the process immediately before the input of garbage.

In FIG. 14, first, at step 301,
At this time, the value measured by the mass detecting means 23 (that is, the total mass of the mixture of the garbage and the medium 4 stirred and mixed for a predetermined time) is input, and this value is used as the content substance ki (for example, i = 2 so k2) [kg]
And the value is displayed in the content substance amount display section 230a (or the operation panel display section 16b) of the content substance amount / water content display area 230 of the garbage processing detail display window 227. In addition, the measured value by the water content detecting means 13 at this time is inputted, and this value is set as the content water content ai (a2 for the first additional addition) [%] as R
The value is stored in the AM 15c, and the value is displayed on the content moisture content display section 230b (or the operation panel display section 16b) of the content substance content / water content display area 230.

The content water content ai is not detected by the water content detection means 13 but is used in the above-mentioned step 103.
Similarly to, for example, a detection unit separate from the garbage disposal machine may be inserted from the outside into the contents to perform detection, and the detection signal may be automatically taken into the control device 15,
Alternatively, the user may manually input the detected value to the input means, and the input signal may be taken into the control device 15.

Thereafter, the process proceeds to step 302, where the solid mass kdi of the content (kd2 for the first additional charging) and the water mass kwi ( If it is the first additional throw, calculate kw2). That is, the mass kdi of the solid content is obtained by: kdi = (1-ai / 100) × ki, and the water mass kwi is obtained by: kwi = ai × ki / 100.

The solid content mass kdi and the water content kwi of the content thus obtained are stored in the RAM 15c, and the values are stored in the content solid content mass display portion 230c of the garbage processing detailed display window 227 and the content water content. The display is displayed on the display unit 230d (or the operation panel display unit 16b), and the process proceeds to step 303.

In step 303, the amount of garbage is reduced (weight reduced by volume) ni-1 (n1 for the first additional charge), the solid content reduction ndi-1 (nd1 for the first additional charge), and the water loss nwi- 1 (nw1 for the first additional throw) is calculated by the following equation. That is, the food waste reduction ni-1 is: ni-1 = ki-1 + mi-1 + H-ki The solid content reduction ndi-1 is ndi-1 = kdi-1 + mdi-1 + Hd-kdi and the water loss nwi-1 is nwi- 1 = kwi-1 + mwi-1 + Hw-kwi

Taking as an example the garbage reduction n1, the solid content reduction nd1, and the water reduction nw1 at the time of the first additional charging (i = 2), the garbage reduction n1 is determined by the input medium mass k1 detected in step 103. And the input garbage mass m1 calculated in step 204 and the content substance amount k2 detected in step 301.
Since it is initialized to = 0, it can be obtained by n1 = k1 + m1 + H-k2 = k1 + m1-k2.

Further, the garbage solid content reduction nd1 is obtained by calculating the input medium solid content mass kd1 calculated in step 104 and the input garbage solid content mass md1 calculated in step 204.
And the content solid content mass k calculated in step 302 described above.
Since d2 is used and Hd = 0 is initialized in step 10 above, it can be obtained by nd1 = kd1 + md1 + Hd-kd2 = kd1 + md1-kd2.

Further, the water loss nw1 of the garbage is calculated by calculating the water mass kw1 of the input medium calculated in step 104, the water weight mw1 of the input garbage calculated in step 204, and the water content kw2 calculated in step 302. And since Hw is initialized to 0 in step 10 above, it can be obtained by nw1 = kw1 + mw1 + Hw-kw2 = kw1 + mw1-kw2.

In step 303, in addition to the above, the garbage reduction ni-1, solid content reduction ndi-1, and water reduction nwi-1 are sequentially integrated from i = 1 (details will be described later). Garbage weight loss Σni-1, solid content weight loss Σndi-
1. Calculate the integrated water loss Σnwi-1. For example, at the time of the first additional injection according to the above example, since i = 2, Δni−1 = n1, Δndi−1 = nd1, and Δnwi−1 = nw1.

The thus obtained garbage weight loss ni-1, solid content weight ndi-1, water weight loss nwi-1, cumulative weight loss Σni-1, solid weight loss Σndi-1, and water weight loss Σnwi-1 are represented by R.
In addition to storing the values in the AM 15c, the values are displayed in the garbage processing detail display window 227, and the garbage reduction display area 233a, the garbage solid content reduction display area 233b, and the garbage moisture reduction display in the weight / water content display area 233 before the garbage input. Area 23
3c, the garbage cumulative weight loss display area 233d, the garbage solid content cumulative weight loss display area 233e, and the garbage moisture cumulative weight loss display area 233f (or the operation panel display 16b). Upon completion of the above, the procedure moves to step 304.

In step 304, the untreated amount of garbage (non-reduced mass) zi-1 (for the first additional addition,
1) The untreated amount of solid content zdi-1 (zd1 at the time of the first additional charge) and the untreated amount of water zwi-1 (zw1 at the first additional charge) are calculated by the following equations. That is, the raw garbage untreated amount zi-1 is: zi-1 = mi-1-ni-1 The solid content untreated amount zdi-1 is zdi-1 = mdi-1-ndi-1 and the water untreated amount zwi. -1 is obtained by zwi-1 = mwi-1-nwi-1.

Taking the unprocessed amount of garbage z1, the unprocessed amount of solids zd1, and the unprocessed amount of water zw1 at the time of the first additional introduction (i = 2) as an example, the unprocessed amount of garbage z1 Using the input garbage mass m1 calculated in step 204 and the garbage reduction n1 detected in step 303, z1 = m1-n1.

The unprocessed amount of solid garbage zd1 is the input solid garbage solid mass md1 calculated in step 204.
And the garbage solid content reduction n detected in step 303
By using d1 and zd1 = md1-nd1.

Further, the raw garbage water unprocessed amount zw1 is calculated by adding the input garbage water mass mw1 calculated in the above step 204 to:
Using the garbage water loss nw1 detected in step 303, zw1 = mw1-nw1.

In this step 304, in addition to the above, the unprocessed amount of garbage zi-1 and the unprocessed amount of solids zdi-
1, and the untreated water amount zwi-1 were integrated in order from i = 1 (details will be described later). The untreated treated food waste amount Σzi-1, the untreated treated solid amount Σzdi-1, and the untreated treated water amount Σzwi. Calculate -1. For example, at the time of the first additional insertion according to the above example, since i = 2, Δzi−1 = z1 and Δzdi−1 = z
d1 and Σzwi-1 = zw1.

The raw garbage unprocessed amount zi-1, thus obtained,
The solid unprocessed amount zdi-1, the water unprocessed amount zwi-1, the integrated unprocessed amount Σzi-1, the solids integrated unprocessed amount Σzdi-1, and the water integrated unprocessed amount Σzwi-1 are stored in the RAM 15c. , The value of the raw garbage unprocessed amount display area 233 g of the garbage unprocessed amount display area 233 g of the garbage before inputting the mass / water content display area 233 of the garbage processing detail display window 227,
33h, garbage water unprocessed amount display area 233i, garbage integrated unprocessed amount display area 233j, garbage solids integrated unprocessed amount display area 233k, garbage moisture integrated unprocessed amount display area 233l (or operation panel display section) 16b) is output as a display signal and displayed. When the above is completed, step 3
Move to 05.

In step 305, from the viewpoint of the current performance limit of the microorganisms carried on the medium 4 and the capacity limit of the processing container 2, the number of times that garbage can be additionally input at this point in time without replacing the medium 4 is determined. Is calculated as the upper limit X [times].
This X is calculated as follows.

First, the total number of garbage inputs i up to this point
The number x [times] less than or equal to i of [times] (the value of x may be a fixed value set and stored in advance, or an input provided separately by the user in the garbage processing detail display window 227 or the operation panel operation unit 16a). Means (not shown) as appropriate), and the solid content in the processing vessel 2 at the time of feeding the garbage from the time point x + 1 times (that is, from the ix times to the i times) from this point onward Amount accumulated (in other words, the amount of unprocessed solids remaining per garbage charge) B
[Kg] is calculated using the content solid content mass kdi in the processing vessel 2 at this time (calculated in step 302) and the content solid content kdi-x before x times, and B = (kdi−kdi− x) / x

Then, for example, a predetermined upper limit mass C determined according to the volume of the processing container 2 (a fixed value set and stored in advance, or may be appropriately input by the user using the input means provided separately) ) And the mass kdi of the solid content in the processing container 2 at this point described above, the additional upper limit value X [times] of garbage is determined by X = (C−kdi) / B.

The upper limit value X of the number of additional throws calculated in this way is stored in the RAM 15c, and the value is stored in the garbage throw count display area 234 (or the operation panel display section 16b) of the garbage processing detail display window 227. It is output as a display signal and displayed. When the above is completed, step 3
Move to 06.

In step 306, the above step 305
Similarly, from the viewpoint of the performance limit of the microorganism and the capacity limit of the processing container 2, it is determined at this point whether the medium 4 needs to be replaced immediately. This determination is made as follows.

That is, the unprocessed garbage solid content unprocessed amount Σzdi-1 calculated in the previous step 304 is, for example, a predetermined solid content integrated unprocessed upper limit value A (for example, The value of the maximum amount of unprocessed garbage solids that can be held in the container 2 may be a fixed value set and stored in advance,
(The user may input the data appropriately using an input means provided separately). If it is larger, it is determined that the medium 4 needs to be replaced immediately. I do.

When the determination is satisfied, the process moves to step 307, and a medium exchange display window 235 is further displayed in the garbage processing detailed display window 227 of the operation display screen 225.
(FIG. 10 shows a state in which this interrupt display is made). The fact that the medium needs to be replaced may be output and displayed as a display signal on the operation panel display 16b.
Thereafter, the process proceeds to step 308, and the operation of the garbage disposal machine is stopped. That is, the driving device 19, the exhaust fan 10,
And a control signal is output to the heater 6 and the like, and their operations are stopped.

If the determination in step 306 is not satisfied, it is considered that the operation can be continued without replacing the medium 4 immediately, and the processing immediately before putting in the garbage is completed.
It returns to 1 and moves to step 310.

In step 310, when the index j indicating the number of times the medium 4 has been added, the integrated mass H of the medium 4, the integrated mass Hd of the solid content, and the integrated mass Hw of the added water are values other than 0. Also initializes them all to zero,
Return to step 200.

On the other hand, in FIG. 11, the garbage processing detailed display window 227 in step 220 described above is displayed.
Garbage input button 229 (or garbage input switch 1)
If the determination as to whether or not 6a2) has been turned ON is not satisfied, it is considered that additional input of garbage has not been performed yet, and the process proceeds to step 250.

In step 250, the medium input button 228 (or the medium input switch 16a1 of the operation panel operation section 16a) of the garbage processing detailed display window 227 is turned (again).
It is determined whether an ON operation has been performed. If the determination is not satisfied, the process returns to step 220. If the determination is satisfied, it is determined that the medium 4 is to be added, and the process proceeds to step 260.

In step 260, the above-mentioned step 23 is executed.
Similarly to the case of 0, the operation of the driving device 19, the exhaust fan 10, the heater 6 and the like are stopped to stop the operation of the garbage disposer. After that, in step 270, 1 is added to the above-mentioned index j indicating the number of times the medium 4 has been inserted, and the flow proceeds to step 400.

In step 400, in response to the above-mentioned medium addition planned state, the medium addition processing is controlled.
FIG. 15 is a flowchart showing a detailed procedure of this additional medium loading process.

In FIG. 15, first, at step 401,
At this time, the value measured by the mass detecting means 23 (that is, the total mass of the mixture of the garbage and the medium 4 immediately before the additional addition of the medium 4) is input, and this value is used as the content substance amount kj (for example, the step (K = 1 since j = 1 at 270) [kg] is stored in the RAM 15c, and the value is displayed in the garbage processing detailed display window 2
27 is displayed on the content amount display section 231a (or the operation panel display section 16b) of the mass / moisture content display area 231 when the medium is added.

Thereafter, in step 403, it is determined whether or not the opening state of the input cover 5 is detected by the open / close detecting means 14. When the judgment is satisfied, the input lid 5 is opened,
It is considered that the medium 4 has been additionally loaded, and the process proceeds to step 403 to determine whether the closed state of the loading lid 5 has been detected. When the determination in step 403 is satisfied, the process proceeds to step 404.

In step 404, the value measured by the mass detecting means 23 at this time (after the additional addition of the medium 4) is input, and this value is used as the total mass (= content material amount) lj (for example, (In case of one additional charge, j = 1 so it becomes l1) [kg] is stored in the RAM 15c, and the value is stored in the mass / moisture content display area 231 at the time of additional medium charge in the garbage processing detail display window 227. It is displayed on the quantity display section 231b (or the operation panel display section 16b).

At this time, similarly to the above-mentioned steps 103 and 203, the detected value of the water content of the medium 4 by the well-known water content detecting means manually input by the user (or automatically taken in) is used. The fixed value of the input water content or the input value selected by the user from the set storage value, the water content bj of the additional input medium 4 (for example, b1 for the first additional input) [%] is stored in the RAM 15c. At the same time, the value is output as a display signal to the medium moisture content display section 231c (or the operation panel display section 16b) of the medium / moisture content / moisture content display area 231 in the garbage processing detail display window 227 and displayed.

Instead of the user inputting the water content bj of the additional medium 4 as described above, the water content bj of the medium 4 may be detected by, for example, rushing into the additional medium 4 from outside. Alternatively, the moisture content bj of the medium 4 may be detected by the detecting means arranged on the lower surface 3a of the inlet, or if the variation is small, the moisture content bj of the medium 4 is set and stored as a fixed value in the RAM 15c in advance. In any case, it goes without saying that it is sufficient if the water content bj of the medium 4 to be additionally charged can be set in a state provided in the control device 15.

Thereafter, the flow shifts to step 405, where the total mass kj of the contents (medium 4 + garbage) before addition of the medium 4 input in step 401 and the contents of the contents after addition of the medium 4 input in step 404 are described. Using the total mass lj and the water content bj of the additional charging medium 4, the mass hj of the additionally charged medium 4 (h1 for the first additional charging) and the solid content mass hdj (hd1 for the first additional charging). ), And the water mass hwj (hw1 for the first additional charge) are calculated. That is, the additional input medium mass hj is hj = lj-kj, the additional input medium solid content mass hdj is hdj = (1-bj / 100) × hj, and the additional input medium moisture mass hwj is hwj = bj × hj / Calculate by 100.

In step 405, in addition to the above, the additional input medium mass hj, the solid content mass hdj, and the water mass hwj are sequentially integrated from j = 1 (details will be described later). = Σhj, integrated solid mass Hd = Σhdj, and integrated moisture mass Hw = Σhwj. For example, at the time of the first additional throw, since j = 1, H = h1, Hd = hd1, and Hw = hw1.

The mass hj of the additional charging medium thus determined,
The solid content mass hdj, the moisture mass hwj, the accumulated mass H, the solid content accumulated mass Hd, and the moisture accumulated mass Hw are stored in the RAM 15c, and the values are stored in the media mass display portion 231 of the mass / moisture content display area 231 when a medium is added. 231d, medium solid content display section 231e, medium moisture weight display section 231f, medium integrated mass display section 231g, medium solid content integrated mass display section 23
1h, a display signal is output to the medium moisture integrated mass display section 231i (or the operation panel display section 16b) and displayed.

When the above procedure is completed, the process for adding a medium is completed, and the process returns to FIG. 11 and proceeds to step 410.

In step 410, the operation of the garbage disposer is started. That is, the driving device 19 and the exhaust fan 1
0, and outputs a control signal to the heater 6 and the like to start the operation thereof, and then returns to step 220.

(D) Daily Report Display on Personal Computer Next, referring to FIGS.
The daily report display of the state quantity information of the food waste disposer 100 in FIG. 1 will be described.

FIG. 16 is a functional block diagram showing the data processing function of the CPU 101b of the user's personal computer 101. In FIG. 16, the CPU 101b has the respective processing functions of the weight reduction information processing unit 106 and the comparison determination processing unit 107. The weight-loss information processing unit 106 is the machine-side control device 1
Predetermined processing is performed using the information input from step 5 (described later). The comparison determination processing unit 107 includes a weight reduction information processing unit 106
The necessary information is selected from among the information created in step 1 and the information stored and stored in the database 104, and the display unit 101g
To be displayed.

Here, the processing functions of the weight reduction information processing unit 106 of the user-side personal computer 101 and the machine-side control device 15 will be described with reference to flowcharts.

The machine-side control device 15 first has the configuration shown in FIGS.
As explained using 0, the input garbage mass mi, the input garbage solid content mdi, the input garbage water mass mwi, the garbage weight loss ni-1, the garbage solid content weight loss ndi-1, and the garbage water weight loss It has a function of collecting weight loss information such as nwi-1, input weight h, input solid weight hd, and input water weight hw.
06 has a function of processing the weight loss information.

FIG. 17 shows the communication control unit 15 of the control unit 15 when transmitting the weight loss information data collected as described above.
6 is a flowchart illustrating a processing function of h. In FIG. 17, the communication control unit 15h first monitors whether additional garbage has been input (step 610). More specifically, for example, when step 304 (FIG. 14) in the process immediately before the input of garbage described in step 300 of FIG. 11 is completed, it is determined that additional garbage is to be input. Alternatively, when the loading lid 5 of the garbage disposal machine 100 is opened and closed and the mass detected by the mass detecting means 23 increases, it may be determined that additional garbage is to be thrown (in this case, however, the time of the first throw is determined. Excluded in some way). When additional garbage is added, the weight reduction information (with date and time) stored and accumulated in the RAM 15c of the control device 15 is read (step 620), and these data are transmitted to the user-side personal computer 101 (step 630). It should be noted that at a fixed time of the day, for example, midnight, the timer 15g
N, and the data for the previous day for one day is stored in the user's personal computer 101.
It may be sent to.

The CPU 15a and the communication control unit 15h repeatedly perform the above processing every day. The data stored in the CPU 15a is deleted after a predetermined number of days, for example, 365 days (one year), after being transmitted to the user-side personal computer 101.

FIG. 18 shows the CP of the user-side personal computer 101 when the weight-loss information is sent from the machine-side controller 15.
It is a flowchart which shows the processing procedure of U101b (weight reduction information processing part 106).

In FIG. 18, the CPU 101b monitors whether or not the weight reduction information has been input from the machine-side control device 15 (step 710). When the information is input, the information is read and stored and accumulated in the database 104 as weight loss data (described later) (step 720).

Next, the weight reduction data for a predetermined number of days, for example, one month, is read from the database 104, and the amount of medium input, the amount of garbage input, the amount of garbage reduction, the rate of garbage reduction (this A daily report (see FIG. 20 to be described later) and a graph (FIG. 21 to be described later) relating to the calculation (calculation based on the input amount / reduction amount in step) are created (step 730).

Further, based on the weight loss data read from the database 104, an accumulated data table (see FIG. 22 described later) from the time of medium exchange is created (step 740), and an average data table (described later) from the time of medium exchange is created. FIG.
(See step 750).

The daily report, graph, and data table created in this way are output to the display unit 101g (step 7).
60).

FIG. 19 is a diagram showing the storage status of weight loss data in the database 104.

In FIG. 19, the database 104
The above-mentioned input garbage mass, input garbage solid content mass, input garbage water mass, garbage weight loss, garbage solid content reduction, garbage water loss, input mass, input solid content mass, and input water mass Is stored as an integrated value corresponding to the date and time. In the illustrated example, mi (1), mdi (1), mw
i (1), ni-1 (1), ndi-1 (1), nwi-1 (1),
, h (1), hd (1), hw (1),..., are the mass of input garbage, the mass of input garbage solid, Input garbage water mass, garbage reduction, garbage solid content reduction, garbage water reduction, input mass, input solid content mass, and input water mass are integrated values, respectively, mi (K), mdi (K), mw
i (K), ni-1 (K), ndi-1 (K), nwi-1 (K),
h (K), hd (K), hw (K),.
Year 0 / Month □ This is the integrated value from the time of garbage input to the time of next garbage input.

(E) Operation and Function of this Embodiment Next, regarding the remote operation from the personal computer and the daily report display described in the above (C) and (D), the control performed by the control device 15 according to this embodiment. The operation and its operation will be described with reference to specific examples. As a specific example, the medium 4 is placed in the processing container 2.
In the state where the garbage is accommodated, the first garbage is put into the disintegration processing operation, the second garbage is put into the disintegration processing operation, and the third garbage is put into the disassembly processing operation. And then the fourth garbage input will be described as an example.

(1) Until the start of the decomposition processing operation of the first-time input garbage In order to start the garbage processing operation, the worker in charge goes to, for example, the garbage processing machine 100 first, and first, the medium input switch of the operation panel. After turning on 16a1, the charging lid 5 is opened and the medium 4 (for example, mass 100 kg, water content 30
%). In addition, it is preferable that the water content of the charging medium 4 at this time falls within an optimum value range for efficiently treating garbage. Then, when the input lid 5 is closed, the determination of the step 20 of the flow of FIG. 11 by the control device 15 is satisfied, and after i = 1 in the step 30, the steps 101 and 102 of the flow of FIG. Then, in step 103, the detection result k1 = 100 kg by the mass detecting means 23 is input, and the detection result a1 = 30% by the water content detecting means 13 is input.

Then, at step 104, the solid content mass kd1 and the water mass kw1 of the medium 4 are calculated as follows: kd1 = (1-a1 / 100) × k1 = 70 kg kw1 = a1 × k1 / 100 = 30 kg It is stored in the RAM 15c and displayed on the display 16b of the operation panel 16 (however, k1 and a1 are also displayed.
Of garbage processing details display window 227
It is also displayed simultaneously in the water content display area 230).

After turning on the garbage input switch 16a2 of the operation panel before inputting the garbage, the input lid 5 is opened and the garbage (for example, having a mass of 10 kg, (Water content: 70%), and the charging lid 5 is closed. In addition, the detected moisture content value (= 70%) is manually input to input means (not shown) of the operation panel operation unit 16a.
Then, step 1 of the flow of FIG.
10 are satisfied, and further, steps 201 and 202 of the flow of FIG.
At 3, the detection result l1 = 110 kg by the mass detecting means 23
(100 kg of medium + 10 kg of garbage) is input to the control device 15, and b1 = 70% by manual input is also input.

Then, at step 204, the mass m of the garbage
1, solid content mass md1, moisture mass mw1, input garbage integrated massΣm1, solid content integrated massΣmd1, and moisture integrated massΣ
mw1 is: m1 = l1-k1 = 1100-100 = 10 kg md1 = (1-b1 / 100) × m1 = 3 kg mw1 = b1 × m1 / 100 = 7 kg Σm1 = m1 = 10 kg Σmd1 = md1 = 3 kg Σmw1 = mw1 = It is calculated as 7 kg, stored in the RAM 15c of the control device 15 and displayed on the display unit 16b of the operation panel 16 (in the mass / moisture content display area 232 in the personal garbage disposal detail display window 227 of the personal computer 101 after the garbage is input). Is also displayed at the same time).

Then, in step 210, the operation of the garbage disposer is started. Thus, the decomposition process of the garbage put into the processing container 2 is started. After confirming that the processing has started normally, the worker returns to the building 102 and monitors the personal computer 101 as appropriate.

(2) Decomposition of garbage is started as described above until the start of the second operation of decomposition of garbage.
When a predetermined time (for example, a whole day) has elapsed, the first-time input garbage m1 = 10 kg (including water mw1 = 7 kg, solid content md1)
= 3 kg), it is assumed that all 7 kg of water evaporates and disappears, 2 kg of solids are decomposed, and only 1 kg of solids remains untreated. The medium 4 has no change in the mass of both the solid content and the water content, and the mass k1 = 10
It is assumed that the state is 0 kg (solid content kd1 = 70 kg, moisture kw1 = 30 kg).

At this point, the worker turns on the garbage input button 229 of the garbage processing detailed display window 227 of the personal computer 101 for the second input (ie, additional input) of garbage. Then, FIG.
The determination in step 220 of the flow of 1 is satisfied, the operation of the garbage processor is stopped in step 230, and i = 2 in step 240.

Then, step 301 in the flow of FIG.
, The detection result k2 of the mass detection means 23 at this time
= 101kg (100kg of medium + 1k remaining amount of raw garbage)
g) is input to the control device 15, and the detection result a2 ≒ 29.7% by the water content detection means 13 at this time is input to the control device 15.

Thereafter, in step 302, the contents (1
Solid content kd2 of 00 kg of medium 4 + 1 kg of residual garbage
And water mass kw2 are calculated as kd2 = (1−a2 / 100) × k2 = 71 kg kw2 = a2 × k2 / 100 = 30 kg and stored in the RAM 15 c of the control device 15, and the garbage processing detailed display window 227 is displayed. It is displayed in the content amount / moisture content display area 230 (the above k2,
a2 is also displayed).

In step 303, the garbage reduction n1, the solids reduction nd1, the moisture reduction nw1, the garbage cumulative reduction Σn1, the solids cumulative reduction Σnd1, and the water content representing the decomposition performance of the conventional garbage disposer up to now. N1 = k1 + m1-k2 = 100 + 10-101 = 9 kg nd1 = kd1 + md1-kd2 = 70 + 3-71 = 2 kg nw1 = kw1 + mw1-kw2 = 30 + 7-30 = 7 kg Σn1 = n1 = 9 kg Σnd1 = nw1 = 7 kg is calculated and stored in the RAM 15c of the control device 15, and is displayed in the mass / moisture content display area 233 before the input of the garbage in the garbage processing detail display window 227.

Thereafter, at step 304, the unprocessed amount of garbage z1, the unprocessed amount of solids zd1, the unprocessed amount of water zw1, the unprocessed amount of water wz1, the integrated unprocessed amount Σz1, The unprocessed solid content Σzd1 and the unprocessed water content Σzw1 are as follows: z1 = m1-n1 = 10-9 = 1 kg zd1 = md1-nd1 = 3-2 = 1 kg zw1 = mw1-nw1 = 7-7 = 0 kg Σz1 = Z1 = 1kg Σzd1 = zd1 = 1kg Σzw1 = zw1 = 0kg, is stored in the RAM 15c of the control device 15, and is displayed in the mass / moisture content display area 233 of the garbage processing detail display window 227 before the garbage input. You.

At this time, on the other hand, the completion of step 304 satisfies step 610 in FIG. 17, and the communication control unit 15h causes the RAM 1
The above-mentioned input garbage mass m stored and accumulated in 5c
i, input garbage solid content mass mdi, input garbage water mass MW
i, weight loss information such as weight loss of food waste ni-1, weight loss of food waste ndi-1, weight loss of food waste nwi-1, input mass h, input solid mass hd, input water mass hw (with date and time) )
Are read out (step 620), and these data are transmitted to the user-side personal computer 101 (step 63).
0). In response, the user-side personal computer 101
The weight loss information sent after the completion of Step 710 of Step 8 is read and stored in the database 104 (Step 7).
20) Then, based on the weight loss information, a daily report (step 73)
0), cumulative data from the time of medium exchange (step 740)
And average data (step 750) are created and calculated, and displayed on the display unit 101g. For specific examples of these daily reports, accumulated data and average data from the time of medium exchange,
It will be described later.

At this time, for example, the above-mentioned x = 1 for calculating the upper limit value X of the additional number of garbage can be set and stored at a predetermined upper limit mass C = 220 kg determined according to the volume of the processing container 2. In step 305, the solid content accumulation amount B in the processing container 2 becomes B = kd2-kd1 = 71-70 = 1 kg, and the additional upper limit value X of the additional garbage is X = (C-kd2) / B = (220-71) / 1 = 149
The value of X is displayed in the garbage disposal detail display window 2
27 are displayed in the garbage input count display area 234.

Further, for example, a predetermined solid content integrated unprocessed amount upper limit A = 20 kg determined according to the volume of the processing container 2 in order to determine the necessity of medium exchange is stored in advance (that is, fixed). Value), in step 306,
The determination is not satisfied because the garbage solids integrated unprocessed amount Σzd1 = zd1 = 1 kg calculated in the previous step 304, which is smaller than A, and the medium replacement display is not performed. When step 306 ends as described above, step 310
After the initialization, the process returns to step 200.

When the processing immediately before the second garbage input is completed as described above, it has been confirmed that the garbage can be input yet. Go to the point, open the input lid 5 and again put the same amount of garbage (mass 10 kg, water content 70%) whose moisture content has been detected, close the input lid 5, and manually input the detected water content 70%. 14 through the control device 15 in FIG. 14, the detection result l 2 = 111 kg (100 kg of medium + first-time input garbage remaining amount 1 kg + second-time input) of the detection result of the mass detection means 23 at this point in step 203 (Garbage 10 kg) is input to the control device 15, and the water content b of the garbage
2 = 70% is also input.

Then, at step 204, the mass m of the garbage
2, solid content mass md2, moisture mass mw2, input garbage integrated massΣm2, solid content integrated massΣmd2, and moisture integrated massΣ
mw2 = m2 = l2-k2 = 111-101 = 10 kg md2 = (1-b2 / 100) * m2 = 3 kg mw2 = b2 * m2 / 100 = 7 kg @ m2 = m1 + m2 = 10 + 10 = 20 kg @ md2 = md1 + md2 = 3 + 3 = 6 kg Σmw2 = mw1 + mw2 = 7 + 7 = 14 kg is calculated and stored in the RAM 15c of the control device 15 and displayed on the display section 16b of the operation panel 16 (simultaneously, the garbage processing detailed display window 22 of the personal computer 101).
7 is also displayed in the mass / moisture content display area 232 after the input of the garbage).

Then, in step 210, the operation of the garbage disposer is started again, and the worker returns to the inside of the building 102.

(3) Until the start of the third garbage disintegration processing operation The second garbage decomposition processing is started as described above, and, for example, when a predetermined time (for example, a full day) elapses In the same way as the previous (first), the second input garbage m2 = 10k
It is assumed that 7 kg of water in g is completely evaporated and disappeared, and that 2 kg of 3 kg of solid content is decomposed and only 1 kg of solid content remains untreated. The medium 4 has a solid content,
It is assumed that there is no change in the mass of both moisture.

At this point, when the worker intends to input the garbage for the third time and turns on the garbage input button 229 of the garbage processing detail display window 227 of the personal computer 101 again, the process proceeds to step 220 in the flow of FIG. Is satisfied, the operation of the food waste disposer 100 is stopped in step 230, and i = 3 in step 240.

Then, step 301 in the flow of FIG.
At this time, the detection result k3 by the mass detection means 23
= 102 kg (100 kg of medium + 1 kg of remaining raw garbage)
+ 2nd input garbage remaining amount 1 kg) is input to the control device 15, and the detection result a3ａ29.4% by the water content detection means 13 at this time is input to the control device 15.

After that, in step 302, the mass kd3 of the solid content and the mass kw3 of the water content are calculated as follows: kd3 = (1-a3 / 100) × k3 = 72 kg kw3 = a3 × k3 / 100 = 30 kg Is displayed in the content amount / water content display area 230 of the garbage disposal detail display window 227 (the above k3,
a3 is also displayed).

Then, at step 303, the garbage loss n2, the solid content nd2, the water loss nw2, the garbage cumulative loss Σn2, the solid content cumulative loss Σnd2, and the water loss 積 算 nw
2 is n2 = k2 + m2-k3 = 101 + 10-102 = 9 kg nd2 = kd2 + md2-kd3 = 71 + 3-72 = 2 kg nw2 = kw2 + mw2-kw3 = 30 + 7-30 = 7 kg Σn2 = n1 + n2 = 9 + 9 = 18 kg ＋ nd2 = n2d2 Σnw2 = nw1 + nw2 = 7 + 7 = 14 kg is calculated and stored in the RAM 15c of the control device 15, and displayed in the mass / moisture content display area 233 in the garbage processing detail display window 227 before the garbage is put.

Thereafter, at step 304, the raw garbage unprocessed amount z2, the solid content unprocessed amount zd2, the water unprocessed amount zw2, the integrated unprocessed amount Σz2, the solid content integrated unprocessed amount Σzd2, and the water integrated unprocessed amount Σzw2 Z2 = m2-n2 = 10-9 = 1 kg zd2 = md2-nd2 = 3-2 = 1 kg zw2 = mw2-nw2 = 7-7 = 0 kg Σz2 = z1 + z2 = 1 + 1 = 2 kg Σzd2 = zd1 + zd2 = 1 + 1 = 2 kg Σzw2 = Zw1 + zw2 = 0 + 0 = 0 kg, which is stored in the RAM 15c of the control device 15 and displayed in the mass / moisture content display area 233 of the garbage processing detail display window 227 before the garbage is put.

At this time, similarly to the above, the communication control unit 15h transmits the weight loss information to the user's personal computer 101, and the user's personal computer 101 outputs the daily report, the accumulated data and the average data from the time of medium exchange based on the weight loss information. It is created / calculated again and displayed on the display unit 101g.

Thereafter, in step 305, the processing vessel 2
Of solid content B in food and upper limit X of additional amount of garbage
B = kd3-kd2 = 72-71 = 1kg X = (C-kd3) / B = (220-72) / 1 = 148
The value of X is displayed in the garbage disposal detail display window 2
27 are displayed in the garbage input count display area 234.

In step 306, the garbage solids integrated unprocessed amount Σzd2 = 2 calculated in step 304 above.
Since the weight is kg, the determination is not satisfied, and the medium replacement display is not performed. Then, after step 310, step 2 is performed again.
Return to 00.

As described above, the third processing immediately before the input of the garbage is completed, and the worker goes to the installation place of the garbage processing machine 100 and removes the garbage (mass 10 kg, water content 70%) in the same manner as before. When you enter and manually enter the water content of 70%,
In step 203 of FIG. 14, the detection result l3 = 112 kg (100 kg of medium + remaining amount of first-time input garbage 1 kg + remaining amount of second-time input garbage 1 kg + third-time input garbage 10 kg) is input to the control device 15 in step 203 of FIG. As well as
The garbage water content b3 = 70% by the above manual input is also input.

Then, at step 204, the mass m of the garbage
3. Solid content mass md3, moisture mass mw3, input garbage integrated massΣm3, solid content integrated massΣmd3, and moisture integrated massΣ
mw3 = m3 = l3-k3 = 112-102 = 10 kg md3 = (1−b3 / 100) × m3 = 3 kg mw3 = b3 × m3 / 100 = 7 kg Σm3 = m1 + m2 + m3 = 30 kg 21 kg is calculated and stored in the RAM 15c of the control device 15 and displayed on the display unit 16b of the operation panel 16 (at the same time, the detailed garbage processing display window 22 of the personal computer 101).
7 is also displayed in the mass / moisture content display area 232 after the input of the garbage).

Then, in step 210, the operation of the garbage disposer is started again, and the worker returns to the inside of the building 102.

(4) Immediately after the first additional medium addition The garbage decomposition process is started again as described above. For example, when a predetermined time has elapsed, the third input garbage m3
Suppose that 7 kg of water out of 10 kg evaporates and disappears, 2 kg of solids are decomposed by 2 kg out of 3 kg, and only 1 kg of solids remains untreated. The medium 4 is assumed to be in a state where there is no change in the mass of both the solid content and the water content.

At this point, the operator turns on the medium insertion button 228 of the garbage processing detailed display window 227 of the operation panel operation unit 16 personal computer 101 with the intention of adding the medium 4 for the first time. Then, FIG.
Is satisfied, the operation of the food waste disposer 100 is stopped in step 260 in the same manner as in step 230, and j = 1 in step 270.
Becomes

Then, step 401 in the flow of FIG.
, The detection result k1 of the mass detection means 23 at this time
= 103 kg (100 kg of medium + 1 kg of remaining raw garbage)
+ 2nd input remaining amount of garbage 1 kg + 3rd input remaining amount of garbage 1 kg) is input to the control device 15.

Then, the user goes to the place where the garbage disposer 100 is installed and opens the charging lid 5, and the moisture content is detected by, for example, a known means in advance (or from a fixed value manually input by the user or a stored value from the set value). ) (For example, mass 100 kg, water content 30%), and the input lid 5 is closed. Then, steps 402 and 403 of the flow of FIG.
At 04, the detection result l1 = 203 kg by the mass detecting means 23
(200 kg of medium + 3 kg of residual garbage) is input to the control device 15, and b1 = 70% by manual input is also input.

Then, in step 405, the mass h1, the solid mass hd1, the moisture mass hw1, the cumulative mass H = Σh1, the cumulative solid mass Hd = Σhd1, and the cumulative moisture mass Hw = Σhw1 of the charging medium 4 are given by h1 = L1-k1 = 203-103 = 100kg hd1 = (1-b1 / 100) xh1 = 70kg hw1 = b1xh1 / 100 = 30kg H = Σh1 = 100kg Hd = Σhd1 = 70kg Hw = Σhw1 = 30kg It is stored in the RAM 15c of the control device 15 and displayed on the display 16b of the operation panel 16 (the above k1, l1, and b1 are also displayed. The personal computer 10)
1 is also displayed in the mass / moisture content display area 231 when the medium is added in the garbage processing detail display window 227). Then, in step 410, the operation of the garbage disposer is started.

(5) Until immediately before the 4th garbage input The garbage input switch of the operation panel is prepared by adding the medium 4 as described above and immediately applying the 4th garbage to utilize the medium. When 16a2 is turned on again, FIG.
The determination at step 220 of the flow of 1 is satisfied, the operation of the garbage disposal is stopped at step 230, and i = 4 at step 240.

Then, step 301 in the flow of FIG.
At this time, the detection result k4 by the mass detecting means 23
= 203 kg (200 kg of medium + 3 kg of remaining garbage remaining) is input to the control device 15 and the water content detection means 13 at this time (however, the water content detection means 13 detects the water content by the temporary operation of the garbage processing machine) 70.4% is input to the control device 15.

Thereafter, in step 302, the mass kd4 of the solid content and the mass kw4 of the water content of the contents are calculated as kd4 = (1-a4 / 100) .times.k4 = 143 kg, and kw4 = a4.times.k4 / 100 = 60 kg. Is displayed on the display unit 16b of the operation panel 16 (the above k4 and a4 are also displayed. The content and water content display area 230 of the personal computer 101 is also displayed at the same time). There).

Then, at step 303, the garbage loss n3, the solid content nd3, the water loss nw3, the garbage cumulative weight loss Σn3, the solid weight loss Σnd3, and the water loss Σnw
3 is n3 = k3 + m3 + H-k4 = 102 + 10 + 100-20
3 = 9 kg nd3 = kd3 + md3 + Hd-kd4 = 72 + 3 + 70-14
3 = 2 kg nw3 = kw3 + mw3 + Hw-kw4 = 30 + 7 + 30-60
= 7 kg Σn3 = n1 + n2 + n3 = 27 kg Σnd3 = nd1 + nd2 + nd3 = 6 kg Σnw3 = nw1 + nw2 + nw3 = 21 kg is stored in the RAM 15c of the control unit 15 and displayed on the display unit 16b of the operation panel 16 (detailed garbage processing of the personal computer 101). It is also displayed in the display area 233 of the mass / moisture content before food waste input in the display window 227).

That is, even if the amount of contents in the processing container 2 is greatly increased by adding the medium 4 as described above, the corresponding garbage is handled similarly to the above (2) and (3). By operating the processor 100, 27 kg out of 30 kg of input garbage disappeared and its volume was reduced, of which 21 kg was simply evaporated by water, and the remaining 6 kg was detected by clearly distinguishing that it was disappeared by microbial decomposition treatment. Can be displayed.

Thereafter, in step 304, the raw garbage unprocessed amount z3, the solid content unprocessed amount zd3, the water unprocessed amount zw3, the integrated unprocessed amount Σz3, the solid content integrated unprocessed amount Σzd3, and the water integrated unprocessed amount Σzw3 Z3 = m3-n3 = 10-9 = 1 kg zd3 = md3-nd3 = 3-2 = 1 kg zw3 = mw3-nw3 = 7-7 = 0 kg Σz3 = z1 + z2 + z3 = 1 + 1 + 1 = 3 kg Σzd3 = zd1 + zd2 + zd3 = 1 + 1z = Zw1 + zw2 + zw3 = 0 + 0 + 0 = 0 kg, which is stored in the RAM 15c of the control device 15 and displayed on the display unit 16b of the operation panel 16 (the weight and water content before the garbage input in the garbage processing detailed display window 227 of the personal computer 101). It is also displayed in the rate display area 233).

Step 305 and step 306
This is the same as the above (2) and (3), and the description is omitted.

As described in the above (1) to (5), when food garbage is to be added thereafter, the determination in step 220 in FIG. 11 is satisfied, and steps 230 to 310 are performed. 4 is added, the determination in step 250 of FIG.
Steps 60 to 410 are carried out, and
Return to and repeat the same procedure.

Each time the control device 15 completes step 304 in FIG. 14, the user computer 101 executes steps 710 to 76 as described above.
0 is executed, the input garbage mass mi, the input garbage solid content mass mdi, the input garbage water mass mwi, and the garbage reduction ni-
1, garbage solid content loss ndi-1, garbage water loss nwi-1,
Input mass h, input solid mass hd, and input moisture mass hw
Daily report (step 730), accumulated data (step 740) and average data (step 750) from the time of medium exchange based on weight loss information (with date and time) such as
The calculated value is displayed on the display unit 101g.

FIG. 20 shows an example of a daily report created on the user's personal computer 101 in step 730 and displayed on the display unit 101g. This daily report is 20 as an example.
One month for October, 2000 (10 October 2000
The amount of weight loss data until the 31st of the month is shown as a table of numerical values corresponding to the date and time (in this example, the input time).

FIG. 21 shows an example in which the daily report in the form of a table as shown in FIG. 20 is represented by a graph on the user's personal computer 101.
1 month / month (July 3 to July 31, 2000)
Is shown as a line graph with date on the horizontal axis. In this example, the garbage input amount mi, the garbage reduction ni, and the garbage reduction rate α (m
i, ni). The garbage input amount mi and the garbage reduction ni fluctuate every day, but the difference therebetween gradually increases. In addition, the garbage reduction rate α gradually decreases to the right, confirming the above, that is, it indicates that the function of decomposing microorganisms in the medium 4 is gradually degraded.

FIG. 22 shows an example of an accumulated data table from the time of medium exchange, which is created in step 740 and displayed on the display unit 101g.
The medium input amount h during the two months from April 4 to October 31 (that is, when the medium is replaced without replacing the medium until October 31 after the medium replacement on September 4), the integrated garbage input mass Σmi, The table shows the cumulative garbage input waste reduction -1ni-1, the weight reduction rate (calculated from Σmi and Σni-1), and the total value of the medium and the garbage.

FIG. 23 shows an example of an average data table from the time of medium exchange, which is created in step 750 and displayed on the display 101g.
Average input garbage mass (calculated from each mi during the period), average weight loss of input garbage (calculated from each ni-1 during the period) for the two months from September 4, 2009 to October 31, and The weight loss rate (calculated from each weight loss rate during the period) is shown.

The daily report, an example of which is shown in FIGS.
The accumulated data table / average data table from the time of medium exchange is displayed as a list that can be listed on the display unit 101g of the user-side personal computer 101, so that the user can use his / her own garbage processor 100 for the past month. The amount of garbage decomposed and the rate of weight loss can be grasped at a glance and managed, and the amount of garbage decomposed and the rate of weight loss can be accurately recorded and counted in an easy-to-report manner. This makes it possible to easily cope with the enforcement of the Food Recycling Law, in which a prescribed rate of reduction in the amount of garbage is required.

At this time, the control device 15 shown in FIG.
Every time after step 303 of step 4, as described above, not only how much of the input garbage has disappeared and volume has been reduced by the operation of the garbage processing machine up to that time,
It is possible to clearly distinguish and detect how much of the loss is due to the mere evaporation of water and how much is lost by the decomposition treatment of the microorganism, and remotely display the information on the personal computer 101 in the building 102. As described above, since the volume reduction of the solid content of the garbage can be obtained by clearly distinguishing from the volume reduction of the water content of the garbage, the operator can accurately and remotely determine the substantial throughput of the garbage. Can grasp and manage.

Further, every time after step 305, the upper limit value X of the number of garbage throws up to the time when the medium is exchanged is remotely displayed, so that the operator can take care of the garbage processing machine 10
It is possible to grasp the approximate replacement time of the medium 4 without having to go to the installation location of 0, to optimize the maintenance time (immediate response) and the number of times (required minimum) of the garbage disposal and to improve the operation efficiency. And cost reduction. further,
Each time after step 306, it is determined whether or not additional garbage can be added without replacing the medium. If additional garbage is difficult to be added, the fact is displayed on the personal computer 101. The maintenance time of the garbage disposal machine 100 can be easily known without going to the place where the garbage disposal machine 100 is installed. Therefore, this also makes it possible to optimize the timing and frequency of maintenance, thereby improving operation efficiency and reducing costs.

The daily report and the like are not limited to being displayed only on the display unit 101g of the user's personal computer 101. For example, the garbage processing machine 1 installed in another building described above is actually operated. Needless to say, the information may also be displayed on the personal computer 104 for a user who does not use it (for example, a boss, an administrator, or the like) or for a manufacturer (the nearest sales branch, service factory, production factory, or the like).

In the above, the communication control unit 15h
However, when step 304 (FIG. 14) is completed by the control device 15, the weight reduction information is transmitted to the user-side personal computer 101, and in response to this, the user-side personal computer 101 automatically creates a daily report or the like in steps 710 to 760. , But is not limited to this. That is, for example, an appropriate daily report output display button is provided on a predetermined screen (for example, an operation display screen 225) displayed on the display unit 101g of the user-side personal computer 101, and based on the weight loss information stored up to that time in accordance with this operation. A daily report or the like may be displayed.

In the above description, the main storage device 101e including the database 104 is provided in the user's personal computer 101 as shown in FIG. 6. However, the present invention is not limited to this, and the main storage device 101e may be an external device. Good.

Further, in the above, the purpose of the present invention is to strictly detect the decomposition processing amount (reduced volume) of garbage composed of water and other solid contents (dry matter). Although the mass loss due to the decomposition of garbage solids was calculated separately from the mass loss due to the mere evaporation of garbage, there may be cases where the amount of decomposition treatment in such a strict sense is not required. Weight loss of the contents in the tank (in other words, the weight loss ni-
1) may be identified as the amount of garbage disposal.

In the above description, FIGS.
The control procedure shown in the flow of FIG. 17 is stored in the ROM 15b of the control device 15 in advance, and the control procedure shown in the flow of FIG. 18 is stored in the ROM 101d of the personal computer 101 in advance. Other storage means may be stored in advance. In addition, it is stored in a recording medium such as a floppy (registered trademark) disk, and is externally used, for example, in the RAM
The above control procedure may be executed by inputting the information to the RAM 15c of the personal computer 101 or 15c.

Further, in the above, the control device 15
Input the detection signals (content substance amount data ki, kj, li, lj, content water content data ai) from the mass detection means 23 and the water content detection means 13 of the garbage disposal 100, and input them to the CPU 15a. Of the PC 101 of the personal computer 101 after at least part of the
b transmitted through the information communication to the weight reduction information processing unit 106
Although the secondary processing was performed on the garbage state quantity information in the above, the invention is not limited to this. That is, the controller 15 does not perform the primary processing,
The CPU 101b of the personal computer 101 as it is as the detection signals (content substance amount data ki, kj, li, lj, content moisture content data ai) from the mass detection means 23 and the water content detection means 13.
To the primary processing and 2
Both of the following processings may be performed. In this case, a similar effect is obtained.

In the above, the case where the garbage disposer 100 is used for business purposes has been described as an example, but the present invention is not necessarily limited to this. That is, although there is no legal obligation as in business use, if the present invention is applied to a household garbage disposer, the use situation of the garbage disposer 100 in the home can be clearly grasped. And can be managed.

[0195]

According to the present invention, when the garbage disposer is operated and the garbage is decomposed, the control means collects the garbage state quantity data, and the operation terminal operates on the basis of the collected data. The signal is input by information communication, and the garbage state quantity information for a predetermined period is displayed as a chart that can be listed according to the signal. Therefore, the user can grasp at a glance the amount of the garbage decomposition treatment and the weight loss rate for the predetermined period, and manage them, and by appropriately arranging the aspects of the above-described table, the amount of the garbage decomposition treatment and It is possible to accurately record and count the weight loss rate in an easy-to-report manner.

[Brief description of the drawings]

FIG. 1 is an overall system schematic diagram showing an embodiment of a garbage processing machine management system of the present invention together with a garbage processing machine to be controlled.

FIG. 2 is a front view showing the entire structure of a garbage processing machine to be controlled by an embodiment of the garbage processing machine management system of the present invention.

FIG. 3 is a side sectional view showing the entire structure of the garbage disposal machine to be controlled by the embodiment of the garbage disposal machine management system of the present invention as viewed from the right in FIG.

FIG. 4 is a perspective sectional view showing the entire structure of the garbage disposal machine to be controlled by one embodiment of the garbage disposal machine management system of the present invention, as viewed in the same direction as FIG. 2;

FIG. 5 is a functional block diagram illustrating a functional configuration of a control device provided in the embodiment of the garbage disposal management system of the present invention.

FIG. 6 is a functional block diagram showing a functional configuration of a personal computer provided in an embodiment of the garbage processing machine management system of the present invention.

FIG. 7 is a diagram showing an initial display screen of a personal computer provided in an embodiment of the garbage processing machine management system of the present invention.

FIG. 8 is a diagram showing an operation setting screen of a personal computer provided in an embodiment of the management system for a garbage disposer of the present invention.

FIG. 9 is a diagram showing an operation display screen of a personal computer provided in an embodiment of the management system for a garbage disposer according to the present invention.

FIG. 10 is a diagram showing an interrupt display window on a personal computer provided in an embodiment of the garbage disposal machine management system of the present invention.

FIG. 11 is a flowchart showing the overall control performed by the control device with respect to remote control from a personal computer provided in one embodiment of the garbage processing machine management system of the present invention.

FIG. 12 is a flowchart showing a detailed procedure of an operation preparation process in the overall control performed by the control device provided in the embodiment of the garbage disposal machine management system of the present invention shown in FIG. 11;

FIG. 13 is a flowchart showing a detailed procedure of a process immediately after putting in garbage in the overall control performed by the control device provided in the embodiment of the management system for garbage disposal of the present invention shown in FIG.

FIG. 14 is a flowchart showing a detailed procedure of a process immediately before input in the overall control performed by the control device provided in the embodiment of the garbage processing machine management system of the present invention shown in FIG. 11;

FIG. 15 is a flowchart showing a detailed procedure of a process for adding a medium in the overall control performed by the control device provided in the embodiment of the management system of the garbage processing machine of the present invention shown in FIG.

FIG. 16 is a functional block diagram showing a data processing function of a CPU of a user-side personal computer provided in an embodiment of a management system for a food waste disposer according to the present invention.

FIG. 17 is a flowchart showing processing functions of a communication control unit of a control device provided in an embodiment of a management system for a garbage processing machine of the present invention.

FIG. 18 is a flowchart showing a processing procedure of a CPU of a user-side personal computer provided in an embodiment of a management system for a garbage disposer of the present invention.

FIG. 19 is a diagram showing a storage state of weight loss data in a database in a personal computer provided in an embodiment of a management system for a garbage processor according to the present invention.

FIG. 20 is a diagram showing an example of a daily report on a user-side personal computer provided in an embodiment of the garbage processing machine management system according to the present invention.

FIG. 21 is a diagram showing an example in which a daily report on a user-side personal computer provided in an embodiment of a management system for a garbage disposer according to the present invention is represented by a graph.

FIG. 22 is a diagram showing an example of a cumulative data table from the time of medium exchange in the user-side personal computer provided in the embodiment of the garbage processing machine management system of the present invention.

FIG. 23 is a diagram showing an example of an average data table from the time of medium exchange in a user-side personal computer provided in an embodiment of a management system for a garbage disposer of the present invention.

[Explanation of symbols]

2 Container (processing vessel) 13 Water content detection means (content water content detection means) 15 Controller (control means, food waste moisture content signal input means, food waste solid content change amount detection means) 15a CPU (calculation means) 15f I / O (input means, output means) 100 Garbage disposal machine 101 User side personal computer (operation terminal)

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) B09B 5/00 B09B 5/00 M (72) Inventor Atsushi Kitaguchi 650, Kandamachi, Tsuchiura-shi, Ibaraki Prefecture Hitachi Construction Machinery (72) Inventor: Hironori Ishii 650, Kandamachi, Tsuchiura-shi, Ibaraki Prefecture DA11 DA16 DA20

Claims (6)

[Claims] 1. A control means for controlling the operation of a garbage disposer for decomposing garbage, collecting control data for garbage, outputting an operation signal to the control means by information communication, An operation terminal for inputting a signal based on the garbage state quantity data collected by the control means through information communication, and displaying the garbage state quantity information for a predetermined period as a list that can be listed according to the signal; A garbage disposal management system characterized by the following. 2. The management system for a garbage disposer according to claim 1, wherein said garbage disposer has a processing container for receiving said garbage, and said control means includes at least a content substance in said processing container. A management system for a garbage disposer, wherein the garbage amount data is collected as the garbage state quantity data. 3. The management system for a garbage disposer according to claim 2, wherein the operation terminal includes a garbage input amount and a garbage as the garbage state amount information in the chart based on the content material amount data. A management system for a garbage processor, wherein at least one of weight loss and a garbage reduction rate is displayed in association with the predetermined period. 4. A management system for a garbage disposer according to claim 2, wherein said garbage disposer has a processing container for receiving said garbage, and said control means includes at least contents in said processing container. The material amount data and the content moisture content data are collected as the garbage state quantity data, and the operation terminal calculates the garbage solid content change amount based on the content material amount data and the content moisture content data as the garbage state quantity. A management system for a garbage disposer, wherein information is displayed on the chart as information. 5. A control device for a garbage disposal machine for controlling the operation of a garbage disposal machine for decomposing garbage, comprising: input means for inputting state data of the garbage; Comprising: arithmetic means for generating a display signal for displaying the amount of state information of the garbage for a predetermined period based on the amount data as a chart capable of listing, and output means for outputting the generated display signal by information communication. A control device for a garbage processor. 6. A table capable of inputting state quantity data of garbage to be processed by the garbage processing machine to a computer and listing the state quantity information of the garbage for a predetermined period based on the input data. A computer-readable recording medium that stores a program for generating a display signal to be displayed as an image and outputting the generated display signal by information communication.