JP2006212125A - Toilet system performing human waste treatment by utilizing fermentation ability of microorganism - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To improve a toilet which treats human wastes by microorganisms in a toilet tank (a fermentation tank). <P>SOLUTION: The toilet has the fermentation tank filled with a carbon source, for example sawdust, which contains an aerobic fermenting microorganism planted at the initial starting and has a high organic carbon content in the toilet tank which is equipped with an agitating means and formes a closed space. When the human wastes is thrown onto the sawdust, the human wastes are degraded and are made to degrade by the fermentation of the microorganism using organic matters and nitrogen in the human wastes as a nutritional source. The moisture in the human wastes is evaporated by applying heat energy which is generated by the degradation on the sawdust, and the sawdust is made into compost. The toilet is equipped with a separate urinal and a urine collecting tank for temporarily collecting urine to control to introduce the urine from the urine collecting tank into the toilet tank (the fermentation tank). <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to an improvement of a toilet in which manure treatment is performed using the fermentation ability of aerobic microorganisms (fermenting bacteria).

Conventional toilets in mountain and sea sightseeing areas have a flushing type and a flushing type. In the case of the flushing type, human waste is treated outdoors or in the sea, and in the case of flushing type purification at a sewage treatment plant. It was released after being carried out or released directly into the sea.
The purification treatment not only uses a large amount of water but also requires a lot of energy costs for purification. In addition, the draw-up ceremony caused water pollution of rivers, lakes and seawater by manure.

In order to improve the problem of the flush toilet, attempts have been made to decompose human waste using a natural purification action by aerobic microorganisms (fermenting bacteria).
As a specific example, a mixture of manure and sawdust, ground rice husk, beet moss, etc. is decomposed by aerobic microorganisms (fermenting bacteria), water is evaporated by heat of fermentation, etc., and the volume of manure is reduced. It is intended to effectively use as compost (organic fertilizer) by killing Escherichia coli and parasites by heating.
JP-A-60-220198 Japanese Patent Laid-Open No. 60-241999

An improved toilet has been put into practical use so that the toilet utilizing the fermentation mechanism of the aerobic microorganism (fermenting bacteria) can be performed more efficiently.
That is, a spiral blade is provided in a toilet tank (fermentor), and the spiral blade is composed of a forward-winding spiral blade and a reverse-winding spiral blade, and the spiral blade is crossed at an intermediate portion thereof. A chimney having an exhaust fan on the toilet tank (fermentation tank), a heating section provided in the lower part of the toilet tank (fermentation tank) The toilet is provided with a loading / unloading port and a toilet, and a heater is provided in a space in the toilet (fermentor).
JP-A-11-253353

The toilet (fermenter) 1 (Cosmo Ace Kogyo Co., Ltd., Cosmo Ace U-50 type) that has been put to practical use for the toilet has an effective capacity of 500 liters for the toilet (fermentor) 1; The external dimensions are 1069 mm in height, 880 mm in width, and 1870 mm in length, the weight is 220 kg, and the electric capacity is a heater 480 W, a motor 200 W, and an exhaust fan 17 W, for a total of 696 W.
FIG. 16 is a plan view of this specific example, FIG. 17 is a sectional view, FIG. 18 is a side view, and FIG. 19 is a wiring system diagram.
A chimney having a urinal, a urinal and an exhaust fan is attached to the upper surface of the toilet (fermenter) 1 to constitute a toilet room, and a push button switch or a light sensor is attached to the entrance of the toilet. It is a toilet system that counts the number of uses.
The system control panel is connected to the agitation motor with four terminals because the forward / reverse is switched from the push button switch or sensor every time it is used and input to the remote switch of the system control panel. Is also rotated by switching between normal and reverse.

When using the toilet system, 5000 liters of sawdust is initially charged in the toilet tank (fermenter) 1. If the moisture content of sawdust is 10 to 15% and the specific gravity is 0.6, the weight of sawdust will be 300 kg (actual measurement).
This sawdust is the carbon source that aerobic microorganisms need to decompose manure.
Aerobic microorganisms (fermentative bacteria) are planted on this carbon source.
When the user uses the toilet, it is counted, and when the manure enters the toilet tank (fermenter) 1, the screw rotates and the manure is mixed with the initial set of sawdust.
Due to the activity of microorganisms, heat of fermentation is generated in the process of decomposing manure, and the temperature in the stool (fermenter) 1 rises from 60 ° C to 70 ° C.
This heat evaporates all the water in the manure. The evaporated water is exhausted from a chimney having an exhaust fan.
More than 95% of human waste is water, and most of the water evaporates. And about 5% of organic matter in the remaining manure is decomposed by microorganisms.
In this way, all manure is decomposed and extinguished.
And aerobic microorganisms start to decompose manure and sawdust, urine disappears, and sawdust becomes compost. As the composting of sawdust progresses, the carbon source will be insufficient. Therefore, in order to maintain the fermentation in the toilet tank (fermenter) 1, new sawdust is regularly used (once every 4 to 6 months depending on the usage). About 18 liters is supplied to the stool (fermenter) 1.
At this time, the same amount of composted initial set of sawdust is taken out from the outlet. The compost taken out is dried and odorless and can be reused as high-quality compost.

The daily processing capacity of the toilet system is 25 liters at a normal temperature of 25 ° per unit.
It can be used 100 times a day as an average amount of 250ml per adult.
This toilet system is controlled by a counter, counts the number of times the user is used, and the door is automatically closed after 100 times so that it cannot be used.
Then, after 24 hours, it can be used by fermentation of aerobic microorganisms (fermenting bacteria), and the door can be automatically opened and used.

The simulation was performed as follows on the assumption that the toilet system in practical use was used in a tourist spot in a cold region.
The processing capacity of one toilet was 18.38 liters / day based on the past results when the temperature dropped to 5 ° and the temperature dropped.
The fermentation condition of the toilet tank (fermenter) 1 is that the moisture content of sawdust in the fermenter is 60% or less.
When the moisture content of sawdust exceeds 60%, the fermentation efficiency falls extremely.
Assume that the model accommodation facility has a capacity of 100 people, and one adult will use it twice a day.
The total processing capacity when installing 5 units was 92 liters per day.
Similarly, when three, four, and six were installed, a simulation was performed for comparison.
Assuming the tourist season, we assumed the number of toilet users as follows and simulated the processing situation.
1. Early July: Twice the capacity 2. Mid July: 4-5 times the capacity 3. Before and after the sea day: 8-9 times the capacity 4. Late July: 20 times the capacity 5. Early August: 20 times the capacity 6. Before and after the Bon Festival: 10-12 times the capacity Other days: 2-3 times the capacity

The simulation results are shown in Table 1 in FIG.
In addition to Table 1 shown in FIG. 4, the number starting from 1 in “Days” in the left column is the number of days elapsed from July 1st.
In this simulation, the total number of users is 20,630.
Moreover, the number of users and the number of times of use of the toilet tank (fermenter) 1 are the same.
In Table 1, the range enclosed by practice, that is, the period of use from 30 days to 61 days, the water content of the fermenter exceeds 60%, and the fermentation conditions (the water content of sawdust is 60% or less) greatly deviate. It has been.
This is because the user's urine is high at the peak of the tourist season.
There are many days when the total processing capacity (92 liters per day) of the five toilet tanks (fermenters) 1 is exceeded. Therefore, during this period, many toilets that cannot be used will come out.

The graph which shows transition of the frequency | count of use (use number of people) in the use days at the time of installing the five toilet tanks (fermentor) 1 in the said simulation table 1 (FIG. 4) is shown in FIG.
Moreover, similarly, the graph which shows transition of the fermenter moisture content (%) in use days is shown in FIG.
FIG. 8 is a graph showing the relationship between the fermenter moisture percentage (%) and the number of times of use (number of users) in the same manner, with FIG. 6 and FIG. 7 put together.
From FIG. 7 and FIG. 8, it is clear that at the peak of the tourist season, the moisture content of the fermenter exceeds 60%, and during this period, many unusable toilets come out.
Furthermore, in the said simulation table 1 (FIG. 1), the graph which shows transition of the fermenter moisture content (%) in the use days at the time of 3, 4, 5 and 6 sets of the toilet tank (fermentor) 1 Is shown in FIG. Similarly, the graph which shows the relationship between the fermenter moisture content (%) in use days and the number of times of use (number of users) is shown in FIG.
From FIG. 9 and FIG. 10, it is clear that at the peak of the tourist season, even if six toilet tanks (fermenters) 1 are provided, many unusable toilets will come out.

  The problem to be solved is that the toilet cannot be used due to the increase in the number of users at the peak of the sightseeing season.

  In order to make the toilet usable even in an increase in the number of users at the peak of the tourist season, the present invention separately provides a urinal so as not to exceed the fermentation conditions (water content) of the toilet tank (fermenter) 1. The main feature is to provide a tank for collecting urine.

  The toilet system that performs the manure treatment of the present invention using the fermentation ability of aerobic microorganisms is provided with a separate urinal and a urine storage tank for temporarily storing the urine, so that it can be used at the peak of the tourist season. Since it can cope with the increase in the number of people, there is an advantage that it is not necessary to increase the number of toilets installed.

  In addition to the toilet tank (fermenter) 1, the purpose of making the toilet usable even at the peak of the tourist season is to provide a separate urinal and a urine storage tank to collect urine, so that the tourist season In order to cope with the increase in the number of times of use due to the increase in the number of users at the peak time, the number of installed toilet tanks (fermenters) 1 was not increased.

FIG. 1 shows a schematic diagram of Embodiment 1 according to the system of the present invention. A toilet tank (fermenter) 1 unit (U-50) is a Cosmo Ace U-50 type manufactured by Cosmo Ace Kogyo Co., Ltd. described in paragraph [0005].
As shown in FIGS. 16, 17 and 18, this toilet tank (fermenter) 1 unit (U-50) includes a toilet tank (fermenter) 1, an upper lid 2, a stirring screw 3, and a stirring motor 4 with a speed reducer. , Motor bracket 5, small sprocket 6, large sprocket 7, chain guide 8, chain 9, and heater 10, a toilet bowl mounting port, a urinal mounting port, It has an exhaust port.
And it has the control unit which controls these.
Moreover, as above-mentioned, the processing capacity of 1 unit (U-50) of a toilet tank (fermentor) is 25 liters / day at normal temperature 25 degrees per unit.
The number of installed toilet tanks (fermenters) 1 unit (U-50) is arbitrary, but in Example 1, five units are provided.
A toilet is attached to the toilet attachment port shown in FIG. 8, a chimney (not shown) having an exhaust fan 11 is attached to the exhaust port, and a deodorizing filter 12 (not shown) is installed in the exhaust passage of the chimney. Provide. Exhaust amount of the exhaust fan, but the range of 0.2-0.4 m ³ / min is appropriate, in Example 1, was set to 0.3 m ³ / min.
However, a urinal is not attached to the urinal attachment port, the urinal is provided separately, urine from the urinal is stored in a separately provided urine tank, and the piping from the urine tank is one unit of stool (fermentor) Connect to the urinal mounting port of (U-50), and provide solenoid valves V (A to E).
In this way, five toilet rooms are provided, and each room is provided with an optical sensor PS for detecting the number of times of use.
Each toilet room is connected to the control unit (A to E) from the light sensor PS by 4 terminals, and from the control unit (A to E) to the agitator motor 4 with a speed reducer by 4 terminals (see FIG. Reference), every time the toilet is used from the light sensor PS, the forward / reverse is switched and inputted to the remote switch of the control unit (A to E), and the forward / reverse is switched to the stirring motor 4 with a speed reducer accordingly. Then, the stirring motor 4 with a speed reducer rotates forward and backward.
The number of separately provided urinals and the size of the urine tank are arbitrary, but in Example 1, three urinals were provided and the capacity of the urine tank was 500 liters.
A chimney having an exhaust fan 11 is attached to the urine reservoir tank, and a deodorizing filter 12 is provided in the exhaust passage of the chimney. The exhaust amount of the exhaust fan 11 is set to 1.0 m ³ / min.
Furthermore, a fixed amount of urine is sent from the urine reservoir tank to the urinal attachment port of one unit of the stool (fermentor) through the piping, using the metering pump P, and through each of the solenoid valves V (A to E). It is a thing.
In the first embodiment, the metering pump P is set to send a fixed amount of 250 cc at a time.
This amount is the average amount of urine per adult.
And it has the system control apparatus which controls the control unit (A to E) of 1 unit (U-50) of a toilet tank (fermentor) and the metering pump P of a urine tank.

The deodorizing filter 12 provided in the exhaust passage of the chimney will be described. Various types of deodorizing filters are commercially available, and any of these known deodorizing filters can remove urine odors. A titanium photocatalyst is preferred because it can be used for a long time. In Example 1, there is a commercially available coating agent that causes a catalytic effect on titanium oxide due to the energy excitation effect of a special ceramic even without light, and exhibits the deodorizing effect of titanium oxide even in the dark. The coating agent is applied to any filter. A specific example of this coating agent is a deodorizing eco-guard sold by Kyoritsu Sangyo Co., Ltd. This product consists of 7 types of special ceramics, titanium oxide and binder.
Although it is different from the said coating agent, the data regarding a non-photosensitive photocatalyst are shown below.
JP 2001-170499 A

This will be described more specifically.
The toilet system of the present invention is characterized in that urine at the peak of the tourist season is temporarily stored in a urine storage tank, and this urine is sent to the toilet tank (fermentor) 1 and processed at a time when the load is low. is there.
When the urine treatment apparatus of the toilet system of the present invention is operated, the No. of the toilet tank (fermentation tank) 1 (U-50) in FIG. A to No. In the toilet tank (fermentation tank) 1 up to E (U-50), the toilet tank (fermentation tank) 1 whose daily throughput does not exceed its processing capacity is automatically selected, and the toilet tank (fermenter tank) 1) The solenoid valve V of 1 is automatically opened, the metering pump P of the urine storage tank is operated, and urine is fed into the stool (fermentation tank) 1.
The metering pump P uses a known metering type.
The amount of urine to be delivered is calculated from the operating time of the metering pump P and the delivery speed, and when the delivery amount exceeds the processing capacity of the stool (fermentation tank) 1, the solenoid valve is closed and the next available stool The tank (fermentation tank) 1 is selected, the electromagnetic valve V is opened, and the same process is repeated.
In addition, toilet bowl (fermentation tank) 1 (U-50) No. A to No. Each E is provided with an optical sensor PS as an input device of a counter CT for measuring the number of times of use. When the number of times of use exceeds a set value, the toilet door is automatically locked.
Urine is set so that urine for one person is sent to the stool (fermentation tank) 1 in one operation time, and the use time is added to the counter by controlling the operation time with the timer ON / OFF. .

The specific operation method is as follows.
No. of toilet tank (fermentation tank). A-No. In E, the solenoid valve V (A to E) of the younger stool (fermentation tank) 1 that has not reached the set number of times is automatically opened, and the urine storage tank is opened by the method set above. When urine is sent to the toilet tank (fermentation tank) 1 by the metering pump P and the number of measurements exceeds the set value, the solenoid valve V of the toilet tank (fermenter tank) is closed, and then the measured value is still set to the set value. The solenoid valve V of the next youngest toilet tank (fermentation tank) 1 that has not reached is opened, and the same operation is performed.
When the urine reservoir tank becomes empty, the metering pump P is automatically stopped by the level meter FL provided in the urine tank.

FIG. 2 shows a sequence diagram of the system control apparatus in the toilet system of the present invention.
Moreover, since each control unit (A to E) of the said toilet tank (fermentor) 1 (U-50) is the same, the sequence diagram of the control unit A is shown in FIG.
In FIG. 2 and FIG. 3, the relay contact (A contact) indicated by a black circle is OFF when energized, is ON when not energized, and the relay contact (B contact) indicated by a white circle is ON when energized and OFF when de-energized.
Further, the control relay RSA circuit to the control relay RSE circuit shown in FIG. 2 correspond to the control unit A to the control unit E, respectively.
Note that R and S at the right end in FIGS. 2 and 3 indicate that a voltage is applied.
Below, the sequence diagram of the urine processing system of this invention shown in FIG. 2 and FIG. 3 is demonstrated.

1. First, the urine processing switch SS1 is pressed to power on the urine processing system (FIG. 2).
2. The relay contact R2A (A contact) of the control relay RSA circuit (FIG. 2) of the control unit A is less than the processing capability of the control unit A because the counter CT circuit of the control unit A (FIG. 3) is less than the processing capacity of the control unit A. Since it is OFF, the relay contact R2A (A contact) in FIG. 2 is turned ON, and the control relay RSA circuit is turned ON.
When the control relay RSA circuit is turned on, all the relay contacts RSA (A contacts) from the control relay RSB circuit of the control unit B to the control relay RSE circuit of the control unit E are all turned off.
For this purpose, the control unit A is preferentially used.
3. Next, since the control relay RSA circuit of the control unit A of FIG. 2 is turned on, the relay contact RSA of the urine control timer TR4 circuit of the control unit A of FIG. 3 is turned on, the urine control timer TR4 is activated, Repeat ON and OFF.
4). When the urine control timer TR4 in FIG. 3 is turned on, the relay contact TR4 of the relay R4 circuit is turned on, and the relay R4 circuit is turned on. When the relay R4 circuit is turned on, the relay contact R4 of the counter CT circuit is turned on. Each time the relay contact R4 of the counter CT circuit is turned ON, a quantity is added to the counter CT.
5. When the relay R4 circuit is turned ON, the relay contact R4 of the urine valve VA circuit is turned ON, and the urine valve VA is opened.
6). At the same time, since the relay RA circuit is turned on, the relay contact RA of the urine tank pump P circuit of FIG. 2 is turned on, the pump P of the urine processing system is operated, and urine is transferred from the urine storage tank to the fermentation tank 1. Sent.
7. Adjust the pump of the urine processing system to the amount of urine sent per person (250 ml) per urine.
8). The counter CT circuit of FIG. 3 also counts the number of people entering the toilet room by the relay contact R1 from the relay contact TR1 of the photosensor PS circuit provided in the toilet room via the relay R1 circuit.
9. When the sum of the relay contact R4 and the relay contact R1 of the counter CT circuit exceeds the processing capacity of the fermentation tank 1, the relay R2 circuit of the counter CT circuit is turned on.
10. When the relay R2 circuit is turned on, the relay contact R2 of the warning light L circuit is turned on and the warning light is turned on. At the same time, the relay contact R2 of the door locking LC circuit is turned on, the door lock of the door locking LC circuit is activated, and the door of the toilet is locked.
11. The anti-locking R3 circuit is a self-holding circuit provided with an anti-locking switch SS2 in the toilet room, and when the anti-locking switch SS2 is pressed, the timer TR3 of the anti-locking R3 circuit is activated and simultaneously closed. The relay contact R3 of the prevention R3 circuit is turned ON, and even if the prevention switch SS2 is released, the closing prevention R3 circuit is turned ON for a certain time. When the lock prevention R3 circuit is turned ON, the relay contact R3 (A contact) of the door locking circuit LC is turned OFF, and the door locking is released. On the other hand, when the timer circuit TR3 is turned on after a certain time, the relay contact TR3 (A contact) of the anti-locking R3 circuit is turned OFF, and the anti-locking R3 circuit is turned OFF.
12 Next, when the relay R2 circuit is turned on, the relay contact R2A (A contact) of the control relay RSA circuit of FIG. 2 is turned off, so that the control relay RSA circuit is turned off. At the same time, the relay contact RSA of the urine control timer TR4 circuit is turned off, and the urine control timer TR4 is stopped.
13. When the urine control timer TR4 in FIG. 3 is turned off, the relay contact TR4 of the relay R4 circuit is turned off, the relay circuit R4 is turned off, and the relay contact R4 of the urine valve VA circuit is turned off. Therefore, the electromagnetic valve VA installed in the fermentation tank 1 is closed, and the relay RA is turned off.
14 Since the relay RA of FIG. 3 is turned off, the relay contact RA of the urine tank pump P circuit of FIG. 2 is turned off, and the pump P that sends urine to the urine valve VA of the control unit A is stopped.
15. As described above, when the control unit A reaches the processing capacity, the relay contact R2A (A contact) of the control relay RSA circuit of the control unit A in FIG. 2 is turned off, and the control relay RSA circuit is turned off. As a result, the control unit A is not used.
16. On the other hand, when the control relay RSA circuit of FIG. 2 is turned OFF, the relay contact RSA (A contact) of the control relay RSB circuit of the control unit B is turned ON. For this purpose, the control unit B is then used. Similarly, the control units C, D, and E are selected one after another.
17. Then, when the urine tank is emptied by the level meter FL of FIG. 2, the urine tank level meter RL circuit is turned on, and the relay contact RL (A contact) of the urine tank pump P circuit is turned off. The pump P stops.

The simulation was performed on the premise that the toilet system of the present invention is used in a cold tourist spot. The conditions are the same as in paragraph [0007], and the difference is that urine processing is performed using a separately provided urine reservoir tank.
That is, urine at the peak of the tourist season is temporarily stored in a urine storage tank, and this urine is sent to the stool (fermentor) 1 at a time when the load is low.
In the urine treatment, the urine volume per adult was 0.25 liter, and the capacity of the urine storage tank was 500 liter.
FIG. 5 shows the results of a simulation performed using the toilet system under the same conditions as paragraph number [0007] as Table 2.
In the simulation of Table 2 (FIG. 5), the case where three to six toilet tanks (fermentation tanks) 1 are installed is also shown for comparison.

In addition to Table 2 (FIG. 5), the “days” in the left column is the number of days that have elapsed since July 1 as described above. The total number of users is 20,630, which is the same as in Table 1.
However, the number of users and the number of times the toilet tank (fermenter) 1 is used differ depending on whether the urine tank is used.
That is, when all the urine in the urine reservoir tank is sent to the toilet tank (fermenter) 1 and the remaining amount is 0, the number of users and the number of uses of the toilet tank (fermentor) 1 are the same.
However, when urine is stored in the urine storage tank, the number of users and the number of times the toilet tank (fermenter) 1 is used are different.
For example, when the number of elapsed days from July 1 is 31 days, the urine volume for 1500 people is stored in the urine storage tank with respect to 2000 users (displayed as −1500). Therefore, the use frequency of the toilet tank (fermenter) 1 is 500.
When urine is sent from the urine tank to the toilet tank (fermenter) 1 (indicated by +), the amount of urine sent from the urine tank to the toilet tank (fermenter) 1 to the number of users of the user The number added is the number of uses.
This relationship is shown in FIG. 11 as a graph showing the number of times the toilet tank (fermenter) 1 is used in the number of days used.

That is, the outline of the simulation is as follows.
(1). Of 2,000 users on July 31 (31st), the urine volume for 1500 people is stored in the urine tank, from August 1 (32) to August 4 (35) The amount of urine for 100 people was sent from the urine reservoir tank to the toilet tank (fermentor) 1 every day.
(2). The urine volume for 1500 of the 2000 users on August 6th (37th) is stored in the urine storage tank. From August 7th (38th) to August 14th (45th) The amount of urine for the number of people listed in the table was sent from the urine reservoir tank to the toilet tank (fermentor) 1 and processed.
(3). The urine volume of 860 people is stored in the urine storage tank among the 1260 users on August 15th (46th). From August 16th (47th) to September 1st (61st) Then, the urine amount for the number of persons described in the table was sent from the urine reservoir tank to the toilet tank (fermenter) 1, and the entire amount of urine in the urine reservoir tank was processed in the toilet tank (fermentor) 1.

In Table 2 (FIG. 5), as is apparent from the case where five toilet tanks (fermenters) 1 are installed, in the toilet system of the present invention, the urine treatment is performed by the urine storage tank, so that the fermenter The moisture content (%) is always below 60%, and about 20,630 manure is completely treated.
At the time of installing five toilet tanks (fermenters) 1 in Table 1 (FIG. 4) of the conventional example, the fermenter moisture content (%) is within the range surrounded by practice, that is, the period of use from 30 days to 61 days. The effectiveness of the urine treatment system using the urine storage tank in the toilet system of the present invention is compared with the fact that it exceeds 60% and the fermentation conditions (the moisture content of sawdust is 60% or less) are greatly deviated. it is obvious.

Furthermore, in order to make the effects of the present invention easier to understand, when five stool tanks (fermenters) 1 in the simulation table 2 (FIG. 5) are installed, when the urine storage tank of the present invention is used, The graph which shows transition of the fermenter moisture content (%) in use days is shown in FIG.
In addition, FIG. 13 is a graph showing the relationship between the fermenter moisture content (%) and the number of times of use in the same number of days of use.
That is, FIG. 6 of the conventional example and FIG. 11 of the present invention, FIG. 7 of the conventional example and FIG. 12 of the present invention, and FIG. 8 of the conventional example and FIG. It is clear that the toilet system of the present invention maintains good fermentation conditions without increasing the moisture content of the fermenter over 60% even when the number of users increases and the number of uses increases.

Similarly to Example 1, the case where three, four, and six toilet tanks (fermenters) 1 in the simulation table 2 (FIG. 5) are installed will be described.
When three toilet tanks (fermenters) 1 are installed, the period from 30 days to 61 days is used. When four toilet tanks (fermenters) 1 are installed, the period from 38 days to 61 days is used. Each fermenter moisture content (%) exceeds 60%, and the fermentation conditions (60% or less) are not met.
However, there is no problem when five and six toilet tanks (fermenters) 1 are installed.
This shows the relationship between the processing capacity of the toilet system of the present invention and the number of users.

In order to make it easy to understand the relationship between the processing capacity of the toilet system of the present invention and the number of users, three, four, five and six toilet tanks (fermenters) 1 in the simulation table 2 (FIG. 5) are used. FIG. 14 shows a graph showing the transition of the fermenter moisture content (%) in the number of days of use when the urine storage tank of the present invention is used when the stand is installed.
In addition, FIG. 15 is a graph showing the relationship between the fermenter moisture content (%) and the number of times of use (number of users) in the same manner as the above FIG. 11 and FIG.
Then, as can be understood by comparing FIG. 9 of the conventional example and FIG. 14 of the present invention, and FIG. 10 of the conventional example and FIG. 15 of the present invention, the toilet system using the urine storage tank of the present invention is It is clear that the conventional toilet system has been greatly improved.

From the above-described graph, accommodation facilities in sightseeing spots can determine how many toilet tanks (fermenters) 1 should be installed in the toilet system of the present invention according to the prediction of the number of users. .
Since this is an example of simulation, it is possible to further increase the number of persons to be processed by changing the amount and timing of collecting urine in the urine storage tank, the timing of processing urine, and the like.

Since the toilet system of the present invention can appropriately select the number of urinals and the amount of urine tanks, the toilet system can be used even when the number of users increases at the peak of the tourist season. It can also be applied to sightseeing spots in the sea, mountains, and parks where protection of the surrounding environment is indispensable by attaching a deodorizing filter to the chimney.
It is also a clean and comfortable toilet system that does not use any cleaning water or chemicals.
Furthermore, since the compost taken out from the toilet tank (fermenter) 1 is dry and odorless, it can be reused as an excellent compost.

1 is a schematic explanatory diagram showing an entire urine processing system according to the present invention. It is a sequence diagram of the system control apparatus in this invention. It is a sequence diagram of the toilet tank (fermenter) 1 control unit A of this invention. It is Table 1 which shows the number of toilet tanks (fermenter) of a prior art example, and a fermenter moisture content (%). It is Table 2 which shows the number of the toilet tank (fermentor) of this invention, and a fermenter moisture content (%). It is a graph which shows transition of the use days in a prior art example, and the number of times of use. It is a graph which shows transition of the use days in a prior art example, and a fermenter moisture content (%). It is a graph which shows the relationship between the fermenter moisture content (%) in use days in a prior art example, and the frequency | count of use (number of users). It is a graph which shows transition of the fermenter moisture rate (%) in the use days at the time of installing the toilet tank (fermenter) 1 of a prior art example from 3 units to 6 units. It is a graph which shows the relationship between the fermenter moisture content (%) in the use days at the time of installing the toilet tank (fermenter) 1 of a prior art example from 3 units | sets to 6 units | sets, and the frequency | count of use (number of users). It is a graph which shows the use days of the toilet tank (fermenter) 1 of Example 1, and the frequency | count of use. It is a graph which shows transition of the fermenter moisture content (%) in the use days of the toilet tank (fermenter) 1 of Example 1. It is a graph which shows the relationship between the fermenter moisture content (%) in the use days of the toilet tank (fermenter) 1 of Example 1, and the frequency | count of use. It is a graph which shows transition of the fermenter moisture content (%) in the use days of Example 2. FIG. It is a graph which shows the relationship between the fermenter moisture content (%) in the use days of Example 2, and the frequency | count of use. It is a top view of the conventional toilet tank (fermentor). It is sectional drawing of the conventional toilet tank (fermentor). It is a side view of a notch of a conventional toilet tank (fermentor). It is a wiring system figure of the conventional toilet tank (fermentor).

Explanation of symbols

1 Toilet tank (fermentor)
2 Upper lid 3 Stirring screw 4 Stirrer motor with reduction gear 5 Motor bracket 6 Small sprocket 7 Large sprocket 8 Chain guide 9 Chain 10 Heater 11 Exhaust fan 12 Deodorizing filter CT Counter FL Urine tank level meter L Warning light LC Door lock P metering pump PS light sensor R relay SS switch TR timer VA ~ VE solenoid valve

Claims (5)

  A predetermined amount of carbon source having a high organic carbon content is filled in a toilet tank forming a closed space provided with a stirring means, and an aerobic fermentation microorganism is planted in the carbon source at the initial start-up to form a fermentation tank. The manure dropped in the fermenter) is converted into heat energy by decomposing and extinguishing organic substances and nitrogen in the manure using the fermentation ability of the microorganisms, and the heat energy is applied to the carbon source. In the toilet in which the urine treatment characterized by evaporating the water in the interior and composting the carbon source is performed using the fermentation ability of aerobic microorganisms, a urinal is provided separately, and further from the urinal A toilet system characterized in that a urine reservoir tank for temporarily storing urine is provided, and urine from the urine reservoir tank is guided into the toilet tank (fermentor).   The stirring means according to claim 1 is formed by opposing two spiral blades, each of which forms a spiral in the anti-winding direction, and each spiral blade terminal at the opposed portion is formed from the intersection of both blades. In the toilet in which the urine treatment is performed by utilizing the fermentation ability of aerobic microorganisms, characterized in that it is configured to extend, a separate urinal is provided, and the urine from the urinal is temporarily removed A toilet system provided with a urine reservoir tank for storing and controlling and guiding urine from the urine reservoir tank into the stool (fermentor).   In the toilet tank (fermentation tank) which forms the closed space according to claim 1 and claim 2, the air is heated through a heater in a space portion where air flows in and out. In the toilet where the urine treatment is performed using the fermentation ability of aerobic microorganisms, a separate urinal is provided, and a urine tank for temporarily storing urine from the urinal is further provided. A toilet system in which urine is controlled and guided into the stool (fermentor).   The chimney having an exhaust fan is attached to the urine tank, a deodorizing filter is provided in the exhaust passage of the chimney, and the chimney having the exhaust fan is also attached to the toilet tank (fermentor). A toilet system configured to control and guide urine from a urine reservoir tank into the toilet tank (fermentor), wherein a deodorizing filter is provided in the exhaust passage. In the stool, a stirring part having a crossing part of the spiral blades is provided in the middle part of the spiral wings of the forward direction and the reverse direction. Provide a drive unit, provide a heating means in the lower part of the toilet, provide a heater in the space in the toilet, and provide a chimney having an exhaust fan, an inlet / outlet, and a toilet on the toilet A predetermined amount of a substance having a high organic carbon content is filled in the stool to make a fermenter, and the drive unit is operated left and right alternately to reciprocate the predetermined amount of the filler in the axial direction in the fermenter. It increases the residence time of manure,
On the other hand, a plurality of urinals provided separately and a urine reservoir tank for temporarily storing urine from the urinals are provided, and piping from the urine reservoir tanks is connected to a plurality of toilet tanks (fermenters). ) In a toilet system that connects via a solenoid valve every time and sends a fixed amount from a urine tank through a pump,
Multiple toilets (fermenters) are equipped with counters that measure the number of uses, and when the number of uses exceeds the set value, the toilet door is automatically locked,
The urine stored in the urine tank from the urinal is set so that the urine for one person is sent to the stool (fermenter) 1 in the operation time of one metering pump P, and the operation time is set to ON / OFF of the timer. By controlling, add the number of uses to the above counter,
In a plurality of toilet tanks (fermenters), the solenoid valve of the younger toilet tank (fermenter tank) 1 that has not reached the set number of times has been automatically opened, and the urine tanks are operated in the manner set above. When urine is sent to the tank (fermentation tank) 1 and the number of measurements exceeds the set value, the solenoid valve of the toilet tank (fermenter) closes, and then the measured value has not yet reached the set value, the next youngest When the solenoid valve of the toilet tank (fermentation tank) 1 is opened and the same operation is performed and the urine reservoir tank becomes empty, the metering pump P is automatically stopped by a level meter provided in the urine tank. The toilet system according to any one of claims 1 to 4, wherein the urine is sent from a urine reservoir tank for temporarily storing urine into a toilet tank (fermentor).

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