CN211921356U - Kitchen garbage high temperature microbial bacteria treatment facility - Google Patents

Abstract

The utility model discloses a kitchen garbage high temperature microbial inoculum treatment facility relates to kitchen garbage treatment facility technical field. The utility model comprises a bacteria liquid preparation module, a decomposition processing module and a controller; the bacterial liquid preparation module comprises a mixing bin, a hopper, a turnover mechanism, a first stirrer, a first liquid pump, an electronic flowmeter and a gravity sensor; the decomposition processing module comprises a reaction barrel, a second liquid pump, a second stirrer, a heating rod, a temperature sensor and a pH meter; the output ends of the electronic flowmeter, the gravity sensor, the temperature sensor and the pH meter are respectively and electrically connected with the input end of the controller, and the output end of the controller is respectively and electrically connected with the first liquid pump, the second liquid pump, the first stirrer, the second stirrer, the turnover mechanism and the heating rod. The utility model discloses but accurate configuration appropriate amount fungus liquid when using has convenient operation, advantage that degree of automation is high, can satisfy extensive kitchen garbage processing's user demand.

Description

Kitchen garbage high temperature microbial bacteria treatment facility

Technical Field

The utility model relates to a kitchen garbage treatment facility technical field, concretely relates to kitchen garbage high temperature microbial inoculum treatment facility.

Background

The kitchen waste refers to food waste, food residues, food processing waste, inedible animal and vegetable oil and fat and various oil-water mixtures in families, schools, public dining halls and catering industries, and is part of municipal domestic waste. At present, the treatment mode of domestic kitchen waste is mainly to landfill and incineration together with household waste, and the landfill treatment mode can reduce the service life of a landfill. The incineration treatment mode can generate harmful gases and dust such as dioxin, nitrogen oxides, sulfur dioxide and the like, and the harmful gases and dust cannot be effectively controlled, so that the environment is greatly influenced.

With the implementation of the sustainable development concept, harmlessness is a necessary trend for treating domestic garbage. Microbial decomposition is one of effective ways for realizing harmless treatment of household garbage. Specifically, the microbial decomposition is to put microbes into the kitchen waste to decompose organic matters in the kitchen waste, so that the reduction of the kitchen waste is realized. The microbial decomposition mode solves the pollution problem caused by landfill, incineration and other modes, and has increasingly wide application.

Before the microorganisms such as aerobic microorganisms, anaerobic microorganisms, protease, fermentation bacteria, etc. are put into the kitchen waste for decomposition reaction, it is generally necessary to prepare a bacterial solution having a suitable concentration according to the amount of the kitchen waste. And then mixing the bacterial liquid with the kitchen waste for reaction. In the prior art, equipment for decomposing kitchen waste by microorganisms is simple and crude, is generally a reaction barrel or a reaction tank, and has the defects of inconvenient operation and incapability of large-scale batch kitchen waste treatment.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems existing in the prior art, the utility model aims to provide a kitchen waste high-temperature microbial bacteria treatment equipment. The utility model discloses but accurate configuration appropriate amount fungus liquid when using has convenient operation, advantage that degree of automation is high, can satisfy extensive kitchen garbage processing's user demand.

The utility model relates to a kitchen waste high-temperature microbial bacteria treatment device, which comprises a bacteria liquid preparation module, a decomposition treatment module and a controller;

the bacterial liquid preparation module comprises a mixing bin, a hopper, a turnover mechanism, a first stirrer, a first liquid pump, an electronic flowmeter and a gravity sensor; a feed port is formed in the upper part of the mixing bin, the hopper is arranged in the feed port and used for receiving fungus materials, and two ends of the hopper are rotatably connected with the side wall of the feed port; the turnover mechanism is arranged outside the feed opening, is linked with the hopper and is used for driving the hopper to turn over; the gravity sensor is arranged at the bottom of the hopper; one end of the first liquid pump is communicated with a water source, and the other end of the first liquid pump is communicated with the mixing bin through a liquid supply pipe; the electronic flowmeter is arranged at a water outlet of the first liquid pump and used for monitoring the liquid flow of the first liquid pump; the first stirrer is arranged in the mixing bin;

the decomposition processing module comprises a reaction barrel, a second liquid pump, a second stirrer, a heating rod, a temperature sensor and a PH meter; the reaction barrel is communicated with the mixing bin through the second liquid pump; the second stirrer is arranged in the reaction barrel; the heating rods are distributed on the outer side of the second stirrer uniformly; the temperature sensor and the PH meter are both arranged in the reaction barrel; the upper part of the reaction barrel is provided with an exhaust port, and the lower part of the reaction barrel is provided with a liquid outlet;

the output ends of the electronic flowmeter, the gravity sensor, the temperature sensor and the pH meter are respectively and electrically connected with the input end of the controller, and the output end of the controller is respectively and electrically connected with the first liquid pump, the second liquid pump, the first stirrer, the second stirrer, the turnover mechanism and the heating rod.

Preferably, the turnover mechanism comprises two turnover cylinders, the two turnover cylinders are respectively arranged on two sides of the hopper, and an output shaft of each turnover cylinder is fixedly connected with the hopper.

Preferably, kitchen garbage high temperature microbial inoculum treatment facility still includes the switch board, be provided with control panel on the switch board, the controller sets up in the switch board, just the controller with control panel electricity each other is connected.

Preferably, the tail end of the exhaust port is provided with a deodorization box, and activated carbon is filled in the deodorization box.

Preferably, a first spraying head is arranged at the upper part in the mixing bin, and the first liquid pump is communicated with the first spraying head; and a second spray head is arranged at the upper part in the reaction barrel, and the second liquid pump is communicated with the second spray head.

Preferably, a transparent observation window is arranged in the middle of the reaction barrel.

Preferably, the upper part of the reaction barrel is provided with a movable sealing cover for sealing the reaction barrel.

Preferably, the kitchen waste high-temperature microbial bacteria treatment equipment further comprises a timer, wherein the timer is arranged on the outer wall of the reaction barrel, and the output end of the timer is electrically connected with the input end of the controller.

A kitchen garbage high temperature microbial bacteria treatment facility, its advantage is in, the utility model discloses can accomplish the configuration of fungus liquid and kitchen garbage's decomposition process, equipment integration degree is high, and it is more convenient to use and operate, can satisfy extensive kitchen garbage's processing demand, does benefit to the popularization. The fungus liquid configuration module is provided with the electronic flowmeter and the gravity sensor, so that the input amount of the solution and the strain raw materials can be accurately mastered, the amount and the concentration of the prepared fungus liquid are further controlled, the fungus liquid can fully decompose the kitchen waste, unnecessary waste of the fungus liquid can be reduced, and the method is more efficient and reasonable. The reaction barrel is internally provided with a pH meter and a temperature sensor, so that the reaction temperature can be mastered in real time, and the decomposition reaction can be continuously and efficiently carried out. The controller can control the operation of each executive component through the detection input of each sensor, the automation degree of the equipment is high, and the treatment process of the kitchen waste is more intelligent.

Drawings

FIG. 1 is a schematic structural diagram of a kitchen waste high-temperature microbial bacteria treatment device.

Description of reference numerals: 1-a mixing bin, 2-a hopper, 3-a turnover mechanism, 4-a first stirrer, 5-a first liquid pump, 6-a reaction barrel, 61-an exhaust port, 62-a liquid discharge port, 63-a movable sealing cover, 7-a second liquid pump, 8-a second stirrer, 91-a first spray head, 92-a second spray head and 10-a heating rod.

Detailed Description

As shown in figure 1, the high-temperature microbial bacteria treatment equipment for kitchen waste mainly comprises a bacteria liquid preparation module, a decomposition treatment module and a controller.

The bacteria liquid preparation module specifically comprises a mixing bin 1, a hopper 2, a turnover mechanism 3, a first stirrer 4, a first liquid pump 5, an electronic flowmeter and a gravity sensor. The mixing bin 1 is of a square structure made of steel, and is narrow at the upper part and wide at the lower part. The upper part of the mixing bin 1 is provided with an open feeding port for feeding solid fungus materials. The lower part of the mixing bin 1 is provided with a square hollow cavity for stirring and mixing the strain raw materials. Hopper 2 sets up in throwing the material mouth for accept the fungus material. Two ends of the hopper 2 are rotatably connected with the inner side wall of the feeding port, so that the hopper 2 can rotate around the connecting position. Tilting mechanism 3 sets up on the outer wall of dog-house, and links with hopper 2 for drive hopper 2 upset, in order to empty the fungus material. The gravity sensor is arranged at the bottom of the hopper 2 and used for sensing the weight of the fungus materials in the hopper 2. The gravity sensor can be LRD type gravity sensor of MTO company. The first liquid pump 5 is arranged outside the mixing bin 1, one end of the first liquid pump is communicated with a water source, the other end of the first liquid pump is communicated with the interior of the mixing bin 1 through a liquid supply pipe, and clean water can be supplied into the mixing bin 1 through the first liquid pump 5. The electronic flow meter is arranged at the water outlet of the first liquid pump 5 and is used for detecting the flow of the liquid flowing out through the first liquid pump 5. The electronic flow meter can be LDG-MIK series electronic flow meter of American control company. First agitator 4 sets up in the middle part of mixing storehouse 1 for the stirring mixes clear water and fungus material, makes fungus liquid concentration even.

The decomposition processing module specifically comprises a reaction barrel 6, a second liquid pump 7, a second stirrer 8, a heating rod 10, a temperature sensor and a pH meter. One end of the second liquid pump 7 is communicated with the interior of the mixing bin 1, and the other end is communicated with the reaction barrel 6. The second stirrer 8 is disposed at the middle of the reaction tub 6. The number of the heating rods 10 is multiple, for example, 4-6, and the heating rods can be set according to the size of the reaction barrel 6. The plurality of heating rods 10 are uniformly distributed outside the second stirrer 8, for example, may be arranged circumferentially around the center of the second stirrer 8. The heating rod 10 is used for heating the kitchen waste in the reaction process, so that the decomposition reaction is carried out at the optimal temperature, the reaction rate is improved, and the decomposition reaction can be more sufficient. The arrangement of the heating rods 10 can make the heating effect more uniform. Temperature sensor and pH meter all set up in reaction barrel 6, and is concrete, and the response end of temperature sensor and pH meter all is located reaction barrel 6's well lower part, can contact with kitchen garbage in the reaction process to real-time supervision kitchen garbage's temperature and pH value. The temperature sensor can be OMEGA i series temperature sensor, and the pH meter can be JY-PH6.0 series electronic pH meter. An exhaust port 61 is provided at the upper part of the reaction barrel 6 for exhausting gas generated during the reaction, and a liquid discharge port 62 is provided at the lower part for discharging the decomposed liquid product.

The output ends of the electronic flowmeter, the gravity sensor, the temperature sensor and the pH meter are respectively and electrically connected with the input end of the controller, and the output end of the controller is respectively and electrically connected with the first liquid pump 5, the second liquid pump 7, the first stirrer 4, the second stirrer 8, the turnover mechanism 3 and the heating rod 10.

In the embodiment, the controller can be A single chip microcomputer or A PLC (programmable logic controller), in the embodiment, the controller is A Mitsubishi FX3G-60MR-ES-A series single chip microcomputer, the PLC has 60-point input and output points, is stable in control and sufficient in interface number, and is suitable for being used as A control element of the embodiment.

The utility model discloses a specific application process is as follows. Biological enzyme and zymophyte are used as bacterial materials, wherein the biological enzyme is protease, the zymophyte is bacillus subtilis and mould, and the bacterial materials can be used for quickly decomposing and fermenting the kitchen waste to convert the kitchen waste into a fertilizer which can be utilized. During specific operation, the amount of the required bacteria material is calculated according to the amount of the treated kitchen waste, and the proper bacteria liquid concentration and solution amount are calculated. Then, the equipment is started, and the kitchen waste is put into the reaction barrel 6 to wait for reaction. The weight of the required bacterial material and the amount of solution are then input into the controller. Firstly, the material of fungus is put into hopper 2, and in the in-process of putting into the material of fungus, the weight of the material of fungus in hopper 2 is responded to in real time to the gravity sensor of hopper 2 bottom to the signal of telecommunication input that can be discerned by the controller is sent into the controller to the conversion. The fungus material weight of controller contrast input and real-time fungus material weight, when real-time fungus material weight reachd the fungus material weight of input, the controller sent upset control signal, and automatic downward upset of control tilting mechanism 3 is poured the fungus material in the hopper 2 into the lower part of mixing bunker 1. At this time, the first liquid pump 5 is started, the first liquid pump 5 pumps outside clean water into the mixing bin 1, and the first stirrer 4 can be synchronously started while the first liquid pump 5 is started for stirring and mixing the clean water and the mushroom materials. In the process of starting the first liquid pump 5, the electronic flowmeter can sense the liquid amount passing through the first liquid pump 5 in real time and convert the liquid amount into an electric signal which can be recognized by the controller and input the electric signal into the controller, the controller compares the input solution amount with the real-time liquid flow, and when the real-time liquid flow reaches the input solution amount, the controller sends out a stop signal to stop the first liquid pump 5. Foretell structure, completion fungus liquid configuration that can be accurate makes the fungus liquid can fully decompose kitchen garbage, can reduce fungus liquid unnecessary waste again, and is more high-efficient reasonable. And the automation degree of the configuration process is high, the operation is convenient, and the configuration process is more intelligent.

After a proper amount of fungus materials and solution are added into the mixing bin 1, the first stirrer 4 fully stirs and mixes the fungus materials and the solution, and then the second liquid pump 7 can be started to pump the prepared bacterium solution into the reaction barrel 6. And meanwhile, the second stirrer 8 is started, and the bacteria liquid and the kitchen waste are fully mixed and reacted through the second stirrer 8. And starting the heating rod 10 to raise the temperature of the kitchen waste so as to further improve the reaction rate of the decomposition reaction. And in the course of the decomposition reaction proceeding, depending on the type of reaction, the decomposition reaction may exhibit endothermic or exothermic phenomena, which may affect the temperature of the reaction environment. Therefore, a temperature sensor is arranged in the reaction barrel 6, senses the temperature in the reaction barrel 6 in real time, and sends the sensing result to the controller. An optimal reaction temperature can be preset in the controller, the controller can compare the real-time temperature with the optimal reaction temperature and adjust the operation power of the heating rod 10 in real time, so that the temperature in the reaction barrel 6 is kept near the optimal temperature, and the continuous and efficient operation of the decomposition reaction is ensured. The optimal temperature of the mushroom material selected in this embodiment is about 55 ℃. The pH value is also one of the important parameters influencing the decomposition reaction, so that the pH meter is arranged in the reaction barrel 6, and the pH value of the reaction environment can be mastered in real time, so that an operator can adjust according to the detected pH value to ensure that the decomposition reaction is carried out efficiently.

Through the structure, an operator can well control the reaction environment of the decomposition reaction so as to ensure that the decomposition reaction is continuously and efficiently carried out. After the decomposition reaction is completed, the kitchen waste can be decomposed into liquid organic fertilizers, and the fertilizers can be discharged through the liquid outlet 62 for standby. Thus, the microbial decomposition process of the kitchen waste is completed.

The utility model discloses can accomplish the configuration of fungus liquid and kitchen garbage's decomposition process, equipment integration degree is high, and it is more convenient to use and operate, can satisfy extensive kitchen garbage's processing demand, does benefit to the popularization. The fungus liquid configuration module is provided with the electronic flowmeter and the gravity sensor, so that the input amount of the solution and the strain raw materials can be accurately mastered, the amount and the concentration of the prepared fungus liquid are further controlled, the fungus liquid can fully decompose the kitchen waste, unnecessary waste of the fungus liquid can be reduced, and the method is more efficient and reasonable. A pH meter and a temperature sensor are arranged in the reaction barrel 6, so that the reaction temperature can be mastered in real time, and the decomposition reaction can be continuously and efficiently carried out. The controller can control the operation of each executive component through the detection input of each sensor, the automation degree of the equipment is high, and the treatment process of the kitchen waste is more intelligent.

In this embodiment, the turning mechanism 3 is specifically two turning cylinders. Two upset cylinders set up respectively in the both sides of hopper 2, and the output shaft and the hopper 2 fixed connection of upset cylinder. The turnover cylinder is also called as a rotary cylinder, can realize 360-degree rotation, has large torque and stable control, and is suitable for serving as the turnover mechanism 3 of the embodiment.

In the embodiment, a control cabinet is further arranged, and a control panel is arranged on the control cabinet. The controller is arranged in the control cabinet, and the controller is electrically connected with the control panel. The main body of the control panel is a touch screen and control buttons, the control panel is electrically connected with the controller, a control instruction can be input to the controller through the control panel, the controller can output a signal to the control panel, and the running state of the equipment is displayed at the touch screen. The structure of the control cabinet and the control panel can facilitate the operation of an operator and the integral operation of the monitoring equipment.

The tail end of the exhaust port 61 is provided with a deodorization box filled with activated carbon. The gas generated in the reaction process is exhausted from the exhaust port 61, generally has peculiar smell, and is directly exhausted, so that the production environment is not clean. Therefore, the activated carbon is arranged for deodorization and then is discharged.

The upper part in the mixing bin 1 is provided with a first spray head 91, and the first liquid pump 5 is communicated with the first spray head 91. The upper part in the reaction barrel 6 is provided with a second spray head 92, and the second liquid pump 7 is communicated with the second spray head 92. The first spraying head 91 can spray liquid in an atomizing manner, so that clean water is uniformly sprayed in the mixing bin 1, and the clean water and the fungus materials are uniformly mixed. The second spray head 92 can uniformly spray the bacteria liquid into the reaction barrel 6, so that the bacteria liquid is fully contacted with the kitchen waste.

In this embodiment, be equipped with transparent observation window in the middle part of reaction barrel 6, transparent observation window is made for glass, can make things convenient for the operator to observe inside reaction barrel 6, and then master kitchen garbage's decomposition progress.

The upper part of the reaction barrel 6 is provided with a movable sealing cover 63 for sealing the reaction barrel 6, and the movable sealing cover 63 is used for sealing the reaction barrel 6 in the reaction process so as to seal the decomposition reaction.

In this embodiment, a timer is further provided. The timer is arranged on the outer wall of the reaction barrel 6, and the output end of the timer is electrically connected with the input end of the controller. The time required by the decomposition reaction is generally more than ten hours, the time period is long, so that a timer is arranged, the estimated reaction time is arranged on the timer when the reaction starts, the timer sends a signal to the controller after the timing is finished, and the controller can display the signal of the completion of the reaction at the control panel after receiving the signal, so that an operator can be helped to better master the time point of the completion of the reaction.

In the description of the present application, it is to be understood that the orientation or positional relationship indicated by the directional terms such as "front, rear, upper, lower, left, right", "lateral, vertical, horizontal" and "top, bottom", etc., are generally based on the orientation or positional relationship shown in the drawings, and are used for convenience of description and simplicity of description only, and in the case of not making a reverse explanation, these directional terms do not indicate and imply that the device or element being referred to must have a specific orientation or be constructed and operated in a specific orientation, and therefore, should not be considered as limiting the scope of the present application.

Spatially relative terms, such as "above … …," "above … …," "above … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial relationship to another device or feature as illustrated in the figures, and it is to be understood that spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "above … …" can include both orientations of "above … …" and "below … …". The device may be otherwise variously oriented (rotated 90 or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

It should be noted that the terms "first", "second", and the like are used to define the components, and are only used for convenience of distinguishing the corresponding components, and the terms have no special meanings unless otherwise stated, and therefore, the scope of protection of the present application is not to be construed as being limited.

Various other modifications and changes may be made by those skilled in the art based on the above-described technical solutions and concepts, and all such modifications and changes are intended to fall within the scope of the claims.

Claims (8)

1. The kitchen waste high-temperature microbial bacterium treatment equipment is characterized by comprising a bacterium liquid preparation module, a decomposition treatment module and a controller;

the bacterial liquid preparation module comprises a mixing bin, a hopper, a turnover mechanism, a first stirrer, a first liquid pump, an electronic flowmeter and a gravity sensor; a feed port is formed in the upper part of the mixing bin, the hopper is arranged in the feed port and used for receiving fungus materials, and two ends of the hopper are rotatably connected with the side wall of the feed port; the turnover mechanism is arranged outside the feed opening, is linked with the hopper and is used for driving the hopper to turn over; the gravity sensor is arranged at the bottom of the hopper; one end of the first liquid pump is communicated with a water source, and the other end of the first liquid pump is communicated with the mixing bin through a liquid supply pipe; the electronic flowmeter is arranged at a water outlet of the first liquid pump and used for monitoring the liquid flow of the first liquid pump; the first stirrer is arranged in the mixing bin;

the decomposition processing module comprises a reaction barrel, a second liquid pump, a second stirrer, a heating rod, a temperature sensor and a pH meter; the reaction barrel is communicated with the mixing bin through the second liquid pump; the second stirrer is arranged in the reaction barrel; the heating rods are distributed on the outer side of the second stirrer uniformly; the temperature sensor and the pH meter are both arranged in the reaction barrel; the upper part of the reaction barrel is provided with an exhaust port, and the lower part of the reaction barrel is provided with a liquid outlet;

the output ends of the electronic flowmeter, the gravity sensor, the temperature sensor and the pH meter are respectively and electrically connected with the input end of the controller, and the output end of the controller is respectively and electrically connected with the first liquid pump, the second liquid pump, the first stirrer, the second stirrer, the turnover mechanism and the heating rod.

2. The kitchen waste high-temperature microbial bacterium treatment equipment according to claim 1, wherein the turnover mechanism comprises two turnover cylinders, the two turnover cylinders are respectively arranged on two sides of the hopper, and an output shaft of the turnover cylinder is fixedly connected with the hopper.

3. The high-temperature microbial treatment equipment for kitchen waste according to claim 1, further comprising a control cabinet, wherein a control panel is arranged on the control cabinet, the controller is arranged in the control cabinet, and the controller and the control panel are electrically connected with each other.

4. The high-temperature microbial treatment equipment for kitchen waste according to claim 1, wherein a deodorization box is arranged at the tail end of the exhaust port, and activated carbon is filled in the deodorization box.

5. The high-temperature microbial bacteria treatment equipment for kitchen waste according to claim 1, wherein a first spray head is arranged at the upper part in the mixing bin, and the first liquid pump is communicated with the first spray head; and a second spray head is arranged at the upper part in the reaction barrel, and the second liquid pump is communicated with the second spray head.

6. The high-temperature microbial treatment equipment for kitchen waste according to claim 1, wherein a transparent observation window is arranged in the middle of the reaction barrel.

7. The high-temperature microbial bacteria treatment equipment for kitchen waste according to claim 1 or 6, wherein a movable sealing cover for sealing the reaction barrel is arranged at the upper part of the reaction barrel.

8. The high-temperature microbial bacteria treatment equipment for kitchen waste according to claim 1, further comprising a timer, wherein the timer is arranged on the outer wall of the reaction barrel, and the output end of the timer is electrically connected with the input end of the controller.

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