KR101831626B1 - A control method of organic waste dissolution equipment using microbes - Google Patents

Abstract

The present invention relates to a method for controlling an organic waste disposal device using microorganisms, which is to definitely obtain effects of malodor prevention and thermal efficiency improvement, comprising: a normal operation executing step of operating in a predetermined basic operation state when power is turned on; an interrupt signal reception confirming step; a door opening signal confirming step of determining whether a received interrupt signal is a door opening signal; an input door opening signal confirming step; an input door opening operation executing step of executing an input door opening operation; a discharge door opening operation executing step of executing a discharge door opening operation; a dehumidification signal confirming step; a dehumidification operation executing step of executing a dehumidification operation; a withdrawal operation executing step of executing a withdrawal operation; a measured temperature confirming step of determining whether a measured temperature is less than a predetermined temperature by -10°C or more; a recovery operation executing step of executing a recovery operation; a normal operation executing time confirming step of returning to the normal operation executing step; and a power-saving mode operation executing step of executing an operation in a power saving mode.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a method for controlling an organic waste disposal apparatus using microorganisms,

The present invention relates to a control method of an organic waste disposal apparatus using microorganisms, and more particularly, to a method and apparatus for controlling an organic waste disposal apparatus using microorganisms, The present invention relates to a control method of an organic waste disposal apparatus using a microorganism capable of efficiently controlling the operation of an organic waste disposal apparatus using an organic waste disposal apparatus.

The present invention relates to a control method of an organic waste disposal apparatus using microorganisms.

Conventional organic waste disposal apparatus using microorganisms has a problem that the fermentation gas in the fermentation chamber leaks out through a gap between the inlet and outlet of the fermentation chamber without any additional treatment process, And the fermentation chamber is heated only by a heater without a separate air conditioning structure so that the heat efficiency is very low and consumes a large amount of electric power, so that the maintenance cost is high and the time required for fermentation is long, which is not suitable for treating a large amount of organic wastes. The amount of the secondary waste discharged after the fermentation is large, so that there is a problem that a separate treatment cost is required for treating the secondary waste.

The present applicant has made various attempts to overcome the above-mentioned problems, and as a result, it has been found that it is possible to prevent the exposure of odor, to reduce the power consumption cost remarkably due to the excellent thermal efficiency, (Hereinafter referred to as "selection name") using a microorganism.

1A through 1E, the selection name includes an inlet 21 through which an upper surface is formed to pass through, an inlet door 22 for opening and closing the inlet 21, A housing 20 having an exhaust port 23 and an exhaust door 24 for opening and closing the exhaust port 23, an exhaust port 25 formed on one side surface and a wheel unit 26 mounted on each lower surface corner, )and; A door state detecting means 30 mounted on the inlet 21 and the outlet 23 of the housing 20 for detecting the opening and closing states of the closing door 22 and the discharge door 24 and transmitting the detection signal, )and; A discharge passage 41 protruding outward from the front face of the housing 20 and communicating with the discharge port 23 of the housing 20; An agitating chamber 40 having an exhaust port 42 and an intake port 43 for recirculating the filtered air exhausted through the exhaust port 42 to the inside and mounted inside the housing 20; A temperature sensing means (50) mounted in the stirring chamber (40) to sense the temperature in the stirring chamber (40) and transmit the temperature sensing signal; A stirrer 60 rotatably and axially coupled to the stirring chamber 40 to mix microorganisms with the organic waste introduced into the stirring chamber 40 through the inlet 21 of the housing 20; A heater (70) mounted on an outer surface of the stirring chamber (40) to maintain the internal temperature of the stirring chamber (40) at a predetermined temperature; Far-infrared heat generating means (80) built in an inner upper end of the stirring chamber (40) to maintain the internal temperature of the stirring chamber (40) and sterilize the internal space of the stirring chamber (40); And the exhaust port is connected to the exhaust port 25 of the housing 20 so as to be communicated with the exhaust port 91. The exhaust port 91 is connected to the exhaust port 91, A deodorizing means 90 for deodorizing air in the air by reacting the air introduced into the interior with the deodorant therein and exhausting the odor-free air to the outside through the exhaust port; (101) is connected to the exhaust port (42) of the stirring chamber (40) in a cylindrical shape having an intake port (101), an exhaust port (102) and a drain port A moisture removing means (100) for removing moisture contained in the air in the stirring chamber (40) flowing into the inner hollow; The drain pump 102 is installed on the side of the drain port 102 of the moisture removal means 100 and pumps the water through the drain port 102 every time the condensation water stored on the inner bottom surface of the moisture removal means 100 reaches a certain water level. (110); A blowing means for blowing air in the stirring chamber 40 into the moisture removing means 100 is mounted on a connecting line connecting the air outlet of the stirring chamber 40 and the air inlet 101 of the moisture removing means 100, 120); A particle removing filter (130) mounted on a connecting line between the stirring chamber (40) and the blowing means (120) to remove particles contained in air blown from the stirring chamber (40); And an exhaust port of the moisture removal means (100) is connected to each of the exhaust port of the moisture removal means, the inlet port of the stirring chamber and the inlet port of the deodorization means, A predetermined amount of air in the dehumidification air flowing into the stirring chamber 40 flows into the stirring chamber 40 through the inlet port 19 of the deodorization unit 90, Air blowing means (140) for mixing the air into the air flowing into the air introducing means (140); A drive unit (150) operatively connected to the stirrer (60) to drive the stirrer (60); The door state sensing means 30, the temperature sensing means 50, the heater 70, the far infrared ray heating means 80, the drainage pump unit 110, the blowing means 120 and the drive unit 150 are electrically connected to each other A control unit 160 for controlling the operation of each component according to a door state detection signal and a temperature detection signal which are connected and received based on a setting state predetermined by the user; And an operation panel 170 that is electrically connected to the controller 160 and inputs a user command to the controller 160. [

The selection name having such a structure has a closed circulation type air conditioning structure to prevent the odor from leaking to the outside when the organic waste is fermented and to purify the fermentation gas at the appropriate temperature from which the contained moisture has been removed to a high pressure, It is possible to greatly reduce the power consumption cost while greatly shortening the fermentation time of organic wastes and remarkably increase the amount of organic wastes to be eliminated so as to minimize the amount of secondary wastes discharged.

It is therefore an object of the present invention to provide a control method of an organic waste disposal apparatus using a microorganism which can reliably obtain the effect of preventing odor and improving thermal efficiency by allowing the operation of the selection name having the above- .

The above object of the present invention can be also achieved by an air conditioner having a hollow interior and having an inlet for passing through the upper surface, an inlet door for opening and closing the inlet, an outlet formed through the front portion, A housing having an exhaust port formed therein and a wheel unit mounted on each lower surface corner; A door state sensing unit mounted on an inlet and an outlet of the housing, respectively, for detecting an opening / closing state of the closing door and the discharge door, and transmitting the sensing signal; A discharge port formed to protrude outward from the front surface of the housing and connected to the discharge port of the housing to communicate with the discharge port; an exhaust port protruding from one side of the rear surface to exhaust the inside air; An agitating chamber having an intake port for recirculating air into the interior of the housing; Temperature sensing means mounted in the stirring chamber for sensing the temperature in the stirring chamber and transmitting the temperature sensing signal; A stirrer rotatably and axially coupled to the stirring chamber to mix microorganisms with the organic waste introduced into the stirring chamber through the inlet of the housing; A heater mounted on an outer surface of the stirrer chamber to maintain an internal temperature of the stirring chamber at a predetermined temperature; A far infrared ray heating unit built in an inner upper end of the stirring chamber to maintain an internal temperature of the stirring chamber and to sterilize an inner space of the stirring chamber; And an exhaust hole communicating with the exhaust port of the housing, wherein the air introduced into the interior through the air inlet port is reacted with a deodorant in the air, Deodorizing means for removing the odor-removing air and discharging the odor-removing air to the outside through the exhaust port; The stirring chamber has an air inlet, an air outlet and a drain port. The air inlet is connected to the exhaust port of the stirring chamber, and the moisture contained in the air in the stirring chamber, Removing means; A drain pump unit mounted on the drain port side of the moisture removal means and pumping through the drain port every time condensation water stored on the inner bottom surface of the moisture removal means reaches a certain level; A blowing means mounted on a connecting line connecting the exhaust port of the stirring chamber and the inlet port of the moisture removing means to blow air in the stirring chamber into the moisture removing means; A particle removing filter mounted on a connecting line between the stirring chamber and the blowing means to remove particles contained in air blown from the stirring chamber; And is connected to each of the exhaust port of the moisture removing means, the inlet port of the stirring chamber and the inlet port of the deodorizing means so as to communicate with the inlet port of the moisture removing means and the inlet port of the dehumidifying means, An air distribution blowing means for discharging a predetermined amount of air in the moisture removing air introduced into the stirring chamber through the air inlet of the deodorizing means and mixing the air into the air introduced into the stirring chamber by a predetermined air flow amount; A drive unit operatively connected to the stirrer to drive the stirrer; A door state sensing signal and a temperature sensor signal, which are electrically connected to the door state sensing means, the temperature sensing means, the heater, the far infrared ray heating means, the drain pump unit, the blowing means and the drive unit, respectively, A control unit for controlling the operation of each component according to the detection signal; A control method of an organic waste disposal apparatus using a microorganism for controlling an operation of an organic waste disposal apparatus using microorganisms comprising an operation panel electrically connected to the control unit and inputting a user's command to the control unit, A normal operation step of operating in a predetermined basic operation state when the vehicle is turned on; An interrupt signal reception confirmation step of confirming whether or not an interrupt signal has been received; A door opening signal checking step of checking whether the received interrupt signal is a door opening signal when receipt of an interrupt signal is confirmed in the interrupt signal reception confirmation step; A door opening signal checking step of checking whether the door opening signal is a closing door opening signal if the door opening signal is correct; Executing an input door opening operation to execute an input door opening operation if the input door signal is correct in the input door opening signal checking step; Executing an exit door opening operation for executing an exit door opening operation if the input door door signal is not an input door signal at the input door open signal checking step; A dehumidifying signal checking step of checking whether the door opening signal is a dehumidifying signal if it is not a door opening signal; A dehumidifying operation executing step of performing dehumidifying operation in the dehumidifying signal checking step if the dehumidifying signal is correct; A take-out operation executing step of executing a take-out operation if the dehumidifying signal is not a dehumidifying signal; Checking whether the measured temperature is lower than the preset temperature by -10 ° C or more if the interrupt signal is not received in the interrupt signal reception confirmation step; A recovery operation execution step of executing a recovery operation so that the measured temperature can quickly reach the predetermined temperature if the measured temperature is lower than -10 ° C lower than the preset temperature in the measurement temperature confirmation step; If it is determined that the execution time of the normal operation execution step has not exceeded 36 hours, if the measured temperature is not lower than -10 ° C lower than the predetermined temperature in the measurement temperature confirmation step, A normal operation execution time confirmation step of returning to the execution step; And a power saving mode operation execution step of executing an operation in a power saving mode if the execution time of the normal operation execution step exceeds 36 hours in the normal operation execution time confirmation step. Can be achieved by the control method of FIG.

A control method of an organic waste disposal apparatus using microorganisms according to the present invention comprises:

By effectively controlling the operation of the organic waste disposal device using microorganisms, it is possible to prevent odor exposure, significantly reduce power consumption costs, and significantly reduce the amount of organic wastes to be discharged, thereby significantly reducing the amount of secondary waste discharged. .

FIG. 1A is a perspective view showing an apparatus for destroying organic waste using microorganisms of the selected name,
FIG. 1B is a perspective view showing a state in which the housing of the organic waste disposal apparatus using the microorganism of the selected name is removed.
FIG. 1C is a plan view showing a state in which the housing of the organic waste disposal apparatus using the microorganism of the selected name is removed,
FIG. 1D is a side view showing a state in which the housing of the organic waste disposal apparatus using the microorganism of the selected name is removed,
FIG. 1E is a block diagram illustrating an organic relationship between constituent elements connected to the control unit and their constituent elements among the apparatus for destroying organic wastes using microorganisms according to the invention,
2 is a flowchart illustrating a control method of an organic waste disposal apparatus using microorganisms according to the present invention,
FIGS. 3A and 3B are flow charts illustrating a normal operation step of the control method of the organic waste disposal apparatus using microorganisms according to the present invention,
FIG. 4 is a flowchart illustrating a step of opening the door of a door of a control method of the organic waste disposal apparatus using microorganisms according to the present invention,
FIG. 5 is a flow chart illustrating a discharge door open operation step in the control method of the organic waste disposal apparatus using microorganisms according to the present invention,
6 is a flowchart illustrating a dehumidifying operation execution step in the control method of the organic waste disposal apparatus using microorganisms according to the present invention,
FIG. 7 is a flow chart illustrating a step of executing a take-out operation in a control method of an organic waste disposal apparatus using microorganisms according to the present invention,
8 is a flowchart illustrating a recovery operation step of a control method of an organic waste disposal apparatus using microorganisms according to the present invention,
FIG. 9 is a flowchart illustrating a power saving mode operation execution step of the control method of the organic waste disposal apparatus using microorganisms according to the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and the manner of achieving them, will be apparent from and elucidated with reference to the embodiments described hereinafter in conjunction with the accompanying drawings. However, it is to be understood that the present invention is not limited to the disclosed embodiments, but may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. It is intended that the disclosure of the invention and its features be included only with reference to the appended claims and their equivalents.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the embodiments of the present invention, which may vary depending on the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a preferred embodiment of a control method of an organic waste disposal apparatus using microorganisms according to the present invention will be described in detail with reference to the accompanying drawings.

2, a control method of an organic waste disposal apparatus using microorganisms according to the present invention includes a housing 20, a door state sensing unit 30, a stirring chamber 40, and a temperature sensing unit 50 The stirrer 60, the heater 70, the far-infrared inventing means 80, the deodorizing means 90, the pawl removing means 100, the drain pump unit 110, the blowing means 120, The operation of the organic waste disposal apparatus using the microorganism of the selected name consisting of the particle removing filter 130, the air distribution blowing means 140, the drive unit 150, the control unit 160 and the operation panel 170 can be effectively (Step S100), an interrupt signal reception confirmation step S200, a door opening signal confirmation step S300, an input door opening signal confirmation step S400, an input door opening operation execution step S400, (S500), a discharge door opening operation execution step (S600), a dehumidification signal checking step (S700), a dehumidifying operation execution step (S800) Consists of a series (S900), and the measured temperature check step (S1000), the recovery operation execution step (S1100), and a check step the normal operating run time (S1200), and a sleep mode operation execution step (S1300).

3A and 3B, when the power is turned on, the normal operation step S100 operates in a predetermined basic operation state, and the heating means operation step S110, the blowing means medium speed operation step S120, , The drive motor forward direction middle speed operation step S130, the drive motor forward direction operation time confirmation step S140, the first drive motor operation stopping step S150, the first drive motor operation stop time confirmation step S160, The drive motor reverse direction middle speed operation step S170, the drive motor reverse direction operation time confirmation step S180, the second drive motor operation suspension step S190, the second drive motor operation suspension time confirmation step S100-1, , A first measurement temperature confirmation step (S100-2), a heater operation suspension step (S100-3), and a second measurement temperature confirmation step (S100-4).

In the normal operation execution step (SlOO), the deodorizing means side of the damper and the stirring chamber side passage are opened.

In the heating step (S110), the heating means (far infrared ray heating means and heater) is turned on.

The blowing means middle speed operation step (S120) turns on the blowing means and operates at medium speed (medium speed).

The drive motor forward direction middle speed operation step (S130) causes the drive motor of the drive unit that drives the stirrer to operate at a medium speed in the forward direction.

The driving motor forward operation time checking step (S140) checks whether the forward driving time of the driving motor has exceeded 5 minutes.

If it is determined that the forward driving time of the driving motor has exceeded 5 minutes in the step S140 of checking the forward driving time of the driving motor, the operation stopping step S150 of stopping the driving of the first driving motor Stop.

The first drive motor operation stoppage time confirmation step S160 checks whether the execution time of the first drive motor operation stoppage step S150 has passed five minutes.

In the driving motor reverse direction middle speed operation step S170, when it is confirmed that the operation stoppage time of the driving motor has exceeded 5 minutes in the driving motor stoppage time confirmation step S160, the driving motor is operated in the reverse direction at a medium speed.

The step of checking the backward driving time of the driving motor (S180) confirms whether the backward running time of the driving motor has exceeded 5 minutes.

If it is determined that the backward running time of the driving motor has exceeded 5 minutes in the backward driving time check step (S180) of checking the backward driving time of the driving motor, the second driving motor operation stopping step (S190) Stop.

The second driving motor operation stopping time checking step S100-1 checks whether the execution time of the second driving motor operation stopping step S190 has exceeded 5 minutes and if the second driving motor operation stopping step S190 ) Is determined to have passed the driving motor forward direction middle speed operation step S130.

If it is determined in step S100-1 that the execution time of the second drive motor operation stop step S190 is five minutes, If it is confirmed that the measured temperature is not higher than the set temperature, the process returns to the step S100-1 for checking the operation stoppage time of the second driving motor.

In the heater operation stopping step S100-3, if it is determined in the first measured temperature checking step S100-2 that the measured temperature is higher than the set temperature, the heater is turned off.

In the second measurement temperature checking step S100-4, it is checked whether the measured temperature is lower than the set temperature. If it is confirmed that the measured temperature is equal to or higher than the set temperature, the drive motor returns to the medium speed operation step S130.

Referring again to FIG. 2, the interrupt signal acknowledging step (S200) confirms whether an interrupt signal has been received.

The door open signal checking step S300 checks whether the received interrupt signal is a door open signal when the reception of the interrupt signal is confirmed in the interrupt signal reception confirmation step S200.

In the door opening signal checking step (S400), if the door opening signal is correct in the door opening signal checking step (S300), it is checked whether the door opening signal is the closing door opening signal.

Referring to FIG. 4, in the step S500 of executing the closing door opening operation, in the step S400 of checking the closing door opening signal, if the closing door signal is correct, the closing door opening operation is executed, (Step S510), the blowing means high-speed operation step S520, the heating means operation suspension step S530, the elapsed time confirmation step S540, the closing door opening step S550, And a closing door closing step S570.

The driving motor stopping step S510 stops the driving motor.

The blowing means high-speed operation step (S520) operates the blowing means at a high speed.

In the heating stop operation step (S530), the heating means (heater and far-infrared heat generating means) is turned off.

The elapsed time checking step S540 checks whether 3 seconds have elapsed since the completion of the operation stopping step S530.

The closing door opening step S550 opens the closing door in the elapsed time setting step S540 if three seconds have elapsed.

After the closing door opening step S550 is completed, the door signal checking step S560 confirms whether a closing door closing signal has been received.

The closing door closing step S570 closes the closing door hermetically if the door signal is confirmed in the door signal checking step S560.

2 and 5, the discharge door opening operation execution step S600 includes a driving motor operation stopping step S610, a blowing means high-speed operation step S620, a heating means operation stopping step S630, An elapsed time confirmation step S640, a discharge door opening step S650, a filling signal confirmation step S660, and a discharge door filling step S670.

In the operation stop step S610, the drive motor is stopped.

The blowing means high-speed operation step (S620) operates the blowing means at a high speed.

In the operation stop step S630, the heating means (the heater and the far-infrared heat generating means) are turned off.

The elapsed time checking step (S640) checks whether 3 seconds has elapsed since the completion of the operation stopping step (S630) of the heating means.

The discharging door opening step S650 opens the discharging door in the elapsed time setting step S640 if 3 seconds have elapsed.

In the closing signal checking step S660, after the discharging door opening step S650 is completed, it is confirmed whether a discharge door closing signal has been received.

In step S660, the door door closing step S670 closes the door door hermetically if the door signal is authentic.

In the step S500 of performing the closing door opening operation and the step S600 of executing the discharging door opening operation, the deodorizing means and the stirring chamber side passage of the damper are all closed.

Referring to FIG. 2, the dehumidification signal checking step (S700) checks whether the door opening signal is a dehumidifying signal if it is not a door opening signal (S300).

Referring to FIGS. 2 and 6, in the dehumidifying operation execution step S800, if the dehumidification signal is correct, the dehumidification operation is executed in the dehumidification signal checking step S700, and the driving motor forward operation step S810 The first measurement temperature confirmation step S830, the heating means operation suspension step S840, the second measurement temperature confirmation step S850, the heating means operation step S860, And a dehumidification stop signal checking step (S870).

In the dehumidifying operation step (S800), the damper deodorization means side passage is opened and the stirring chamber side passage is closed.

The drive motor forward drive step S810 drives the drive motor in the forward direction.

The blowing means medium speed operation step (S820) operates the blowing means at a medium speed.

The first measurement temperature confirmation step (S830) checks whether the measurement temperature reaches 70 占 폚.

In the operation stop step S840, the heating means (the heater and the far-infrared heat generating means) is turned off if the measured temperature reaches 70 deg. C in step S830.

In the second measurement temperature confirmation step (S850), it is confirmed whether the measurement temperature is less than 70 deg. C after the heating means operation suspension step (S840) is completed.

In the heating step S860, the heating means (the heater and the far infrared ray heating means) is turned on in the second measurement temperature checking step S850 if the measured temperature is less than 70 deg.

The dehumidification stop signal checking step S870 may include checking whether the measured temperature is less than 70 deg. C or checking the second measured temperature at step S850 if the measured temperature is equal to or higher than 70 deg. (S860), and if the dehumidification stop signal has not been received, it returns to the first measured temperature confirmation step (S830).

2 and 7, the take-out operation execution step (S900) executes the take-out operation if it is not a dehumidifying signal in the dehumidifying signal check step (S700), the high speed operation step S910 A blowing means high-speed operation step S920, a heating means operation stopping step S930, and a blow-out operation stop signal confirmation step S940.

Further, the take-out operation step (S900) is executed without stopping the driving motor even when either or both of the closing door and the discharging door are open.

The high-speed drive step S910 in the reverse direction of the drive motor drives the drive motor at a high speed in the reverse direction.

The blowing means high-speed operation step (S920) operates the blowing means at a high speed.

In the operation stop step S930, the heating means (the heater and the far-infrared heat generating means) are turned off.

The take-out operation stop signal checking step (S940) checks whether a take-out operation stop signal has been received.

Referring to FIG. 2, in the step of checking the measured temperature (S1000), if the interrupt signal is not received, it is checked whether the measured temperature is lower than the preset temperature by -10 ° C or more in the interrupt signal reception confirmation step (S200).

Referring to FIGS. 2 and 8, if the measured temperature is lower than the predetermined temperature by -10 ° C or more in the measured temperature check step (S 1000) (S1110), a blowing device low-speed operation step (S1120), and a measurement temperature confirmation step (S1130).

The drive motor low-speed operation step S1110 drives the drive motor at low speed.

The low-speed operation step S1120 of the blowing unit operates the blowing unit at low speed.

The measurement temperature confirmation step (S1130) checks whether the measurement temperature has reached the preset temperature.

Referring to FIG. 2, in the step S1200 of checking the normal operation execution time, if the measured temperature is not lower than -10 ° C lower than the predetermined temperature in the measurement temperature check step S 1000, And if the 36 hours have not elapsed, it returns to the normal operation execution step S100.

2 and 9, in the power saving mode operation execution step S1300, if the execution time of the normal operation execution step S100 has elapsed in the normal operation execution time confirmation step S1200, (S1310), a drive motor forward low speed operation time confirmation step (S1320), a first drive motor operation stopping step (S1330), an operation stop time confirmation step (S1340) (Step S1350), a step S1360 of checking the low-speed operation time in the direction reverse to the driving motor S1360, a step S1370 of checking the measured temperature S1370, a step S1380 of stopping the heating means operation, A measurement temperature confirmation step (S1390), and a heating means operation step (S1400).

The drive motor forward low speed operation step S1310 lowers the drive motor in the forward direction.

The driving motor forward direction low speed operation time checking step (S1320) checks whether the driving time of the driving motor in the low speed operation in the forward direction has passed 5 minutes.

In the step S1330, if the low-speed operation time of the driving motor in the forward direction is less than 5 minutes, the operation of the driving motor is stopped.

The operation stopping time checking step (S1340) checks whether 20 minutes has elapsed after the first driving motor operation stopping step (S1330) is completed.

The low-speed driving operation S1350 in the backward direction of the driving motor operates the driving motor at a low speed in the reverse stopping time checking step (S1340) if 20 minutes has elapsed.

The step S1360 of checking the reverse speed of the driving motor in the reverse direction confirms whether the driving time of the driving motor during the low speed operation in the reverse direction has exceeded 5 minutes and returns to the driving motor forward speed low driving step S1310 if 5 minutes have elapsed do.

The first measured temperature check step S1370 checks whether the measured temperature is equal to or higher than 30 DEG C in step S1360, if the five minutes have not elapsed.

In the heating stop step S1380, the heating means (the heater and the far-infrared heat generating means) is turned off if the measured temperature is equal to or higher than 30 DEG C in the first measured temperature checking step S1370.

In the second measurement temperature confirmation step (S1390), it is confirmed whether the measurement temperature is less than 30 占 폚.

In the heating step S1400, the heating means (the heater and the far-infrared ray heating means) is turned on if the measured temperature is less than 30 ° C in the second measuring temperature checking step S1390, (S1370).

The control method of the organic waste disposal apparatus using the microorganisms according to the present invention having the above-described structure can operate the closed circulation air-conditioning structure together with the heat generator to maintain the set fermentation temperature, The organic waste disposal apparatus using the microorganisms is efficiently controlled so that the emission amount of the organic waste is greatly increased and the emission amount of the secondary waste is significantly reduced.

As described above, it is to be understood that the technical structure of the present invention can be embodied in other specific forms without departing from the spirit and essential characteristics of the present invention.

Therefore, it should be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than the foregoing description, All changes or modifications that come within the scope of the present invention should be construed as being included within the scope of the present invention.

S100: Normal operation step S200: Interrupt signal reception confirmation step
S300: Door open signal check step S400: Open door open signal check step
S500: Executing the closing door opening operation S600: Executing the discharging door opening operation step
S700: Dehumidifying signal check step S800: Dehumidifying operation execution step
S900: take-out operation execution step S1000: measurement temperature confirmation step
S1100: Recovery operation execution step S1200: Normal operation execution time confirmation step
S1300: Power saving mode operation execution step

Claims (12)

And an exhaust port formed on one side of the exhaust port, wherein the exhaust port is formed on one side of the exhaust port, and the exhaust port is formed on the other side of the exhaust port. A housing having a wheel unit mounted on each corner; A door state sensing unit mounted on an inlet and an outlet of the housing, respectively, for detecting an opening / closing state of the closing door and the discharge door, and transmitting the sensing signal; A discharge port formed to protrude outward from the front surface of the housing and connected to the discharge port of the housing to communicate with the discharge port; an exhaust port protruding from one side of the rear surface to exhaust the inside air; An agitating chamber having an intake port for recirculating air into the interior of the housing; Temperature sensing means mounted in the stirring chamber for sensing the temperature in the stirring chamber and transmitting the temperature sensing signal; A stirrer rotatably and axially coupled to the stirring chamber to mix microorganisms with the organic waste introduced into the stirring chamber through the inlet of the housing; A heater mounted on an outer surface of the stirring chamber to maintain an internal temperature of the stirring chamber at a predetermined temperature; A far infrared ray heating unit built in an inner upper end of the stirring chamber to maintain an internal temperature of the stirring chamber and to sterilize an inner space of the stirring chamber; And an exhaust hole communicating with the exhaust port of the housing, wherein the air introduced into the interior through the air inlet port is reacted with a deodorant in the air, Deodorizing means for removing the odor-removing air and discharging the odor-removing air to the outside through the exhaust port; The stirring chamber has an air inlet, an air outlet and a drain port. The air inlet is connected to the exhaust port of the stirring chamber, and the moisture contained in the air in the stirring chamber, Removing means; A drain pump unit mounted on the drain port side of the moisture removal means and pumping through the drain port every time condensation water stored on the inner bottom surface of the moisture removal means reaches a certain level; A blowing means mounted on a connecting line connecting the exhaust port of the stirring chamber and the inlet port of the moisture removing means to blow air in the stirring chamber into the moisture removing means; A particle removing filter mounted on a connecting line between the stirring chamber and the blowing means to remove particles contained in air blown from the stirring chamber; And is connected to each of the exhaust port of the moisture removing means, the inlet port of the stirring chamber and the inlet port of the deodorizing means so as to communicate with the inlet port of the moisture removing means and the inlet port of the dehumidifying means, An air distribution blowing means for discharging a predetermined amount of air in the moisture removing air flowing into the stirring chamber through an air inlet of the deodorizing means and mixing the air into the air introduced into the stirring chamber by a predetermined air flow amount; A drive unit operatively connected to the stirrer to drive the stirrer; A door state sensing signal and a temperature sensor signal, which are electrically connected to the door state sensing means, the temperature sensing means, the heater, the far infrared ray heating means, the drain pump unit, the blowing means and the drive unit, respectively, A control unit for controlling the operation of each component according to the detection signal; The method of controlling an organic waste disposal apparatus using microorganisms for controlling an operation of an organic waste disposal apparatus using a microorganism, the method comprising: an operation panel electrically connected to the control unit and inputting a user's command to the control unit,
The method comprises:
A normal operation step (S100) in which when the power is turned on, operation is performed in a predetermined basic operation state;
An interrupt signal reception confirmation step (S200) for confirming whether an interrupt signal has been received;
A door open signal checking step (S300) of checking whether the received interrupt signal is a door open signal when the reception of the interrupt signal is confirmed in the interrupt signal reception confirmation step (S200);
(S400) a door open signal confirmation step (S300) for confirming whether the door open signal is correct if the door open signal is correct;
A step S500 of executing an unloading door opening operation to execute an unloading door releasing operation if the closing door signal is correct in the step S400 of checking the closing door opening signal;
(S600) executing an exit door opening operation to execute an exit door opening operation if the input door door signal is not an input door signal (S400);
A dehumidifying signal checking step (S700) of checking whether the door opening signal is a dehumidifying signal if the door opening signal is not a door opening signal (S300);
A dehumidifying operation execution step (S800) of performing a dehumidification operation if the dehumidification signal is correct in the dehumidification signal checking step (S700);
A take-out operation execution step (S900) for executing a take-out operation if it is not a dehumidifying signal in the dehumidification signal checking step (S700);
(S1000) for confirming whether the measured temperature is lower than the predetermined temperature by -10 ° C or more if the interrupt signal is not received in the interrupt signal reception confirmation step (S200);
If it is determined in step S1000 that the measured temperature is lower than the predetermined temperature by -10 DEG C or more, a recovery operation execution step (S1100) in which the recovery operation is performed so that the measured temperature can quickly reach the predetermined temperature, Wow;
If it is determined in step S1000 that the execution time of the normal operation step S100 has not exceeded 36 hours if the measured temperature is not lower than -10 DEG C lower than the preset temperature, A normal operation execution time confirmation step (S1200) of returning to the normal operation step (S100);
And a power saving mode operation execution step (S1300) for executing the operation in the power saving mode if the execution time of the normal operation execution step (S100) exceeds 36 hours in the normal operation execution time confirmation step (S1200) A method for controlling an organic waste disposal apparatus using microorganisms.
The method according to claim 1,
In the normal operation step S100,
A heating step (S110) of heating means for turning on heating means (far-infrared ray heating means and heater);
A blowing means middle speed operation step (S120) in which the blowing means is turned on and operated at a medium speed;
A driving motor forward direction middle speed operation step (S130) of moving the driving motor of the driving unit for driving the stirrer in the normal direction in the forward direction;
A driving motor forward operation time confirmation step (S140) of confirming whether the forward driving time of the driving motor has exceeded 5 minutes;
(S150) for stopping the driving of the driving motor in the forward direction when the forward driving time of the driving motor has been determined to be 5 minutes in the driving motor forward driving time checking step (S140) Wow;
A first drive motor downtime check step (S160) for checking whether the execution time of the first drive motor downtime step (S150) has exceeded 5 minutes;
A drive motor reverse direction middle speed operation step (S170) of operating the drive motor in the reverse direction when it is determined that the drive stop time of the drive motor has exceeded 5 minutes in the step of checking the drive motor stoppage time (S160);
A step S180 of confirming whether the backward driving time of the driving motor has exceeded 5 minutes;
(S190) for stopping the operation of the driving motor in the backward direction when it is determined that the backward driving time of the driving motor has exceeded 5 minutes in the backward driving time check step (S180) Wow;
When it is determined that the execution time of the second drive motor operation stoppage step (S190) has exceeded 5 minutes, and when it is confirmed that the execution time of the second drive motor operation stoppage step (S190) has passed 5 minutes, A second drive motor operation stop time confirmation step (S100-1) for returning to the motor normal direction middle speed operation step (S130);
If it is determined that the execution time of the second drive motor operation stopping step (S190) has not elapsed for 5 minutes in the second drive motor operation stopping time checking step (S100-1), whether the measured temperature is equal to or higher than the set temperature (S100-2) of returning to the second driving motor downtime checking step (S100-1) if the measured temperature is less than the set temperature;
(S100-3) of turning off the heater if it is determined that the measured temperature is equal to or higher than the set temperature in the first measured temperature checking step (S100-2);
(S100-4) that returns to the drive motor forward direction middle speed operation step (S130) if it is confirmed that the measured temperature is lower than the set temperature and if the measured temperature is confirmed to be higher than the set temperature A method for controlling an organic waste disposal apparatus using microorganisms.
The method according to claim 1,
In the step S500 of executing the closing door opening operation,
A driving motor operation stopping step (S510) for stopping the driving motor;
A blowing means high-speed operation step (S520) for operating the blowing means at a high speed;
A heating stopping step S530 for turning off the heating means (heater and far-infrared heat generating means);
An elapsed time confirmation step (S540) of confirming whether 3 seconds have elapsed since the completion of the operation stopping step (S530) of the heating means;
(S550) of opening the closing door if the elapsed time is determined to be 3 seconds (S540);
A door signal confirmation step (S560) of confirming whether a door closing door signal has been received after the door door opening step (S550) is completed;
(S570) for closing the closing door in an airtight manner (S560) if the door signal is authentic in the door signal checking step (S560). ≪ RTI ID = 0.0 & Way.
The method according to claim 1,
The discharge door opening operation execution step (S600)
A drive motor stopping step (S610) for stopping the drive motor;
A blowing means high-speed starting step (S620) for operating the blowing means at a high speed;
A heating stopping step (S630) for turning off the heating means (heater and far-infrared heat generating means);
An elapsed time confirmation step (S640) of confirming whether 3 seconds have elapsed since the completion of the operation stopping step (S630) of the heating means;
In step S640, if the elapse of three seconds has elapsed, an exit door opening step (S650) for opening the exit door;
A closing signal checking step (S660) of confirming whether a discharge door closing signal has been received after the discharge door opening step (S650) is completed;
(S670) for closing the discharge door in an airtight manner if the door signal is authentic in the door signal confirmation step (S660). The method of controlling an organic waste disposal apparatus using microorganisms according to claim 1,
The method according to claim 1,
The dehumidifying operation execution step (S800)
A driving motor forward driving step (S810) for driving the driving motor in the forward direction;
A blowing means middle speed operation step (S820) for moving the blowing means at an intermediate speed;
A first measurement temperature confirmation step (S830) of confirming whether the measurement temperature has reached 70 DEG C;
(S840) for turning off the heating means (the heater and the far infrared ray heating means) if the measured temperature reaches 70 DEG C in the step S830 of checking the measured temperature;
A second measurement temperature confirmation step (S850) of confirming whether the measured temperature is less than 70 deg. C after the heating means operation suspension step (S840) is completed;
A heating step (S860) for turning on the heating means (the heater and the far-infrared ray heating means) if the measured temperature is less than 70 DEG C in the second measuring temperature checking step (S850);
If it is determined in step S830 that the measured temperature is less than 70 DEG C or the measured temperature is determined to be 70 DEG C or more in the second measured temperature verification step S850, And a dehumidification stop signal checking step (S870) for checking whether a dehumidification stop signal has been received after the completion of the step S860 and returning to the first measured temperature confirmation step S830 if no dehumidification stop signal has been received And controlling the organic waste disposal apparatus using the microorganism.
The method according to claim 1,
The take-out operation execution step (S900)
A driving motor reverse direction high-speed operation step (S910) for moving the driving motor in the reverse direction at high speed;
A blowing means high-speed operation step (S920) for operating the blowing means at a high speed;
A heating stopping step S930 for turning off the heating means (heater and far-infrared heat generating means);
And a take-out operation stop signal confirmation step (S940) for confirming whether a take-out operation stop signal has been received by the microorganism.
The method according to claim 1,
The recovery operation execution step (S1100)
A drive motor low-speed operation step (S1110) for driving the drive motor at a low speed;
An air blowing means low speed operation step (S1120) for operating the blowing means at a low speed;
And a measurement temperature confirmation step (S1130) of confirming whether the measurement temperature has reached a preset temperature. The method for controlling an organic waste disposal apparatus using microorganisms according to claim 1,
The method according to claim 1,
In the power saving mode operation execution step S1300,
A driving motor forward low speed driving step (S1310) for driving the driving motor in a forward direction at a low speed;
A step S1320 of confirming whether or not the driving time of the driving motor in the low speed operation in the forward direction has exceeded 5 minutes;
(S1330) for stopping the drive motor if the low-speed operation time of the drive motor in the forward direction is less than 5 minutes in the step S1320;
(S1340) for confirming whether 20 minutes has elapsed after the first drive motor operation stopping step (S1330) is completed;
(S1350) in which the drive motor is operated at a low speed in the reverse direction in the reverse stop time checking step (S1340) if 20 minutes has elapsed;
(S1360) to check whether the driving time of the low-speed driving motor in the reverse direction has elapsed for 5 minutes and return to the driving motor forward low-speed driving step S1310 if 5 minutes have elapsed ;
A first measurement temperature confirmation step (S1370) of confirming whether the measured temperature is equal to or higher than 30 占 폚 if the 5 minutes have not elapsed in the low-speed operation time confirmation step (S1360);
(S1380) for turning off the heating means (the heater and the far infrared ray heating means) if the measured temperature is equal to or higher than 30 DEG C in the first measured temperature confirmation step (S1370);
A second measurement temperature confirmation step (S1390) of confirming whether the measurement temperature is less than 30 占 폚;
If the measured temperature is less than 30 占 폚, the heating means (heater and far-infrared heat generating means) is turned on and the heating means returning to the first measured temperature checking step (S1370) (S1400). ≪ RTI ID = 0.0 > 18. < / RTI >
The method according to claim 1,
In the normal operation execution step (SlOO)
Wherein the dewatering means side of the damper and the stirring chamber side passage are opened.
6. The method of claim 5,
The dehumidifying operation execution step (S800)
Wherein the damper deodorization means side passage is opened and the stirring chamber side passage is closed.
5. The method according to any one of claims 3 to 4,
In the step S500 of performing the closing door opening operation and the step S600 of executing the discharging door opening operation,
The deodorizing means of the damper, and the stirring chamber side passage are all closed.
The method according to claim 6,
The take-out operation execution step (S900)
Wherein the operation of the organic waste disposal apparatus is performed without stopping the driving motor even when either or both of the inlet door and the discharge door are open.

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