CN214078443U

CN214078443U - Kitchen waste treatment system

Info

Publication number: CN214078443U
Application number: CN202023266095.1U
Authority: CN
Inventors: 钱浩
Original assignee: Jiangsu Jintong Lingguang Nuclear Energy Technology Co ltd
Current assignee: Jiangsu Jintong Lingguang Nuclear Energy Technology Co ltd
Priority date: 2020-12-29
Filing date: 2020-12-29
Publication date: 2021-08-31
Anticipated expiration: 2030-12-29

Abstract

The utility model relates to a kitchen remains system of trash disposal, include: the device comprises a solar power supply unit, a crushing and dehydrating unit, a dehumidifying unit and a packaging unit; the crushing and dehydrating unit, the dehumidifying unit and the packaging unit are sequentially arranged according to the flow direction of the kitchen garbage; the solar power supply unit provides clean electric energy for other units; the crushing and dehydrating unit is used for crushing and pre-dehydrating kitchen waste and sterilizing solid kitchen waste at high temperature; the dehumidifying unit comprises a dehumidifying conveyor belt, a dehumidifying air box with a feeding hole and a discharging hole, a humidity monitor arranged on the discharging hole, a deodorizer and a dehumidifier which are in airflow communication with the dehumidifying air box; drying the solid kitchen waste by high-temperature super-dry air provided by a dehumidifier; the humidity monitor at the discharge port monitors the humidity of the kitchen garbage, and the drying degree of the kitchen garbage needing to be stored is strictly controlled. The kitchen waste treatment system reduces the breeding probability of bacteria and effectively protects the environment.

Description

Kitchen waste treatment system

Technical Field

The utility model belongs to the technical field of refuse treatment, in particular to kitchen garbage disposal system.

Background

At present, a large amount of kitchen waste can be generated in the catering industry and household life, the kitchen waste contains different kinds of components including vegetable leaves, leftovers, fruit peels, animal bones and the like, the water content of the kitchen waste is high, the organic matter content is rich, bacteria are easy to breed after the kitchen waste is stored for a long time, the garbage is easy to rot and deteriorate, pungent peculiar smell is generated, the difficulty of garbage treatment is increased, and the environment can be polluted due to improper treatment. Most of the existing kitchen waste treatment is landfill or incineration after concentrated compression, and the cost is high and the environment is easy to be polluted.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problem, the utility model aims at providing a reduce the moisture of rubbish from cooking, reduce bacterial growing probability, be convenient for store, effectively protect the rubbish from cooking processing system of environment.

In order to realize the purpose of the utility model, the utility model adopts the following technical scheme: kitchen waste disposal system includes:

a solar power unit comprising: at least one solar panel and at least one electricity storage device;

smash dehydration unit for tentatively dewater the disinfection after smashing kitchen garbage, include: the device comprises a pulverizer, an oil-water separator and an electric heating disinfection conveying belt, wherein the pulverizer is provided with a solid outlet and a liquid outlet, the oil-water separator is connected to the liquid outlet, and the electric heating disinfection conveying belt is connected to the solid outlet;

the dehumidification unit is used for carrying out dehumidification drying treatment to solid kitchen garbage, includes: dehumidification bellows, deodorizer and dehumidifier with feed inlet, discharge gate, air outlet and return air inlet, the inside dehumidification conveyer belt that is located that is provided with of dehumidification bellows between feed inlet and the discharge gate, the feed inlet with electrical heating disinfection conveyer belt meets, the dehumidifier include one and go into wind gap and an air outlet, the air outlet of dehumidification bellows with the entry switch-on of deodorizer, the income wind gap of dehumidifier with the export switch-on of deodorizer, the air outlet of dehumidifier with the return air inlet of dehumidification bellows passes through a tuber pipe switch-on, the discharge gate meet with an unloading conveyer belt.

In the above technical solution, preferably, the dehumidifying unit further includes a humidity monitor and a feedback conveyor connected to the discharge port and used for feeding the kitchen waste output from the discharge port to the dehumidifying conveyor via the feed port again, the feedback conveyor is located outside the dehumidifying air box, the humidity monitor is installed at the discharge port, and the control portion of the kitchen waste processing system is configured to be able to connect the discharge port to the feedback conveyor or connect the discharge port to the discharging conveyor based on a humidity detection result of the humidity monitor.

In the above technical solution, it is further preferable that the system further includes a packaging unit for compressing and packaging the solid kitchen waste, and the packaging unit includes: the pressing device is connected with the blanking conveying belt, and the vacuum packaging machine is connected with the pressing device.

In the above technical scheme, it is further preferred that the crushing and dewatering unit, the dehumidifying unit and the packaging unit are sequentially arranged along the circulation direction of the kitchen garbage, and the solar power supply unit provides electric energy for the working of the crushing and dewatering unit, the dehumidifying unit and the packaging unit.

In the above technical solution, it is further preferable that the oil-water separator has an oil outlet and a moisture outlet, and the liquid of the kitchen waste output from the liquid outlet is divided into oil and moisture to be discharged.

In the above technical scheme, it is further preferred that the electric heating sterilization transmission belt adopts heating wires for heating sterilization or ultraviolet lamps for heating sterilization.

In the above technical solution, it is further preferable that the dehumidifying conveyor belt is arranged in an "S" shape.

In the above technical solution, it is further preferable that the dehumidifier includes an evaporator, a first condenser, a compressor, and an expansion valve, the compressor, the evaporator, the expansion valve, and the first condenser are sequentially connected to form a first refrigeration cycle for circulating a refrigerant inside, and an air flow entering the dehumidifier from an air inlet of the dehumidifier sequentially passes through the evaporator and the first condenser and then flows out from an air supply outlet of the dehumidifier. More preferably, the dehumidifier further comprises a second condenser, the compressor, the evaporator, the expansion valve and the second condenser are sequentially connected to form a second refrigeration cycle for circulating the refrigerant inside, and a water supply path exchanges heat with the second condenser.

Compared with the prior art, the utility model obtain following beneficial effect: according to the scheme, the solar power supply unit is arranged, so that renewable clean energy is used, and the treatment cost is reduced; the drying unit and the dehumidification unit are arranged, high-temperature disinfection is performed for multiple times, moisture of kitchen garbage is reduced, the probability of bacterial breeding is reduced, storage is facilitated, and the environment is effectively protected.

Drawings

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the working process of the present invention;

FIG. 3 is a schematic flow chart of the humidity monitor of the present invention;

FIG. 4 is a schematic flow chart illustrating the operation principle of the dehumidifying unit according to the present invention;

wherein: 100. a solar power supply unit; 101. a solar panel; 102. an energy storage device; 200. a crushing and dewatering unit; 201. a pulverizer; 2011. a solids outlet; 2012. a liquid outlet; 202. an oil-water separator; 203. electrically heating the disinfection conveyor belt; 300. a dehumidification unit; 301. a dehumidifying wind box; 3010. a dehumidification conveyor belt; 3011. a feed inlet; 3012. a discharge port; 3013. a blanking conveyor belt; 3014. a feed back conveyor belt; 3015. an air outlet; 3016. an air return opening; 302. a humidity monitor; 303. a deodorizer; 304. a dehumidifier; 3041. an evaporator; 3042. a first condenser; 3043. a second condenser; 3044. an air inlet; 3045. an air outlet; 3046. a compressor; 3047. an expansion valve; 305. an air duct; 400. a packaging unit; 401. a pressing device; 3402. a vacuum packaging machine; 50. a water supply waterway.

Detailed Description

To explain the technical content, structural features, achieved objects and functions of the present invention in detail, the following detailed description is made with reference to the accompanying drawings.

As shown in fig. 1, the kitchen garbage disposal system of the present invention includes four units, which are a solar power supply unit 100, a pulverizing and dehydrating unit 200, a dehumidifying unit 300, and a packaging unit 400. The crushing and dehydrating unit 200, the dehumidifying unit 300 and the packaging unit 400 are sequentially arranged along the flowing direction of the kitchen waste to complete the dry-wet separation of the kitchen waste; the solar power supply unit 100 supplies power to each device of the pulverizing and dehydrating unit 200, the dehumidifying unit 300, and the packing unit 400 (see a dotted line in fig. 2).

As shown in fig. 1 and 2, the solar power supply unit 100 includes at least one solar panel 101 and at least one energy storage device 102, and the energy storage device 102 is connected to the solar panel 101. The solar panel 101 supplies power in sunny days, and redundant electric energy is stored in the energy storage device 102; stored electrical energy is provided by energy storage device 102 when the weather is not clear. The crushing and dewatering unit 200 comprises a crusher 201, an oil-water separator 202 and an electric heating disinfection conveying belt 203; the pulverizer 201 is provided with a liquid outlet 2012 and a solid outlet 2011, the oil-water separator 202 is connected to the liquid outlet 2012, the electric heating disinfection conveying belt 203 is connected to the solid outlet 2011, kitchen waste enters the pulverizer 201 to be pulverized, oil-liquid mixed liquid and solid are separated, the oil-liquid mixed liquid enters the oil-water separator 202 through the liquid outlet 2012, and oil and water are separated and are discharged out of the system through the oil-liquid outlet and the water outlet respectively; solid kitchen waste is transported electrical heating disinfection transmission band 203 from solid export 2011, installs a plurality of heater strips on the electrical heating disinfection transmission band 203, and the heater strip heating produces high temperature, and the temperature control of heater strip is within 150, makes solid kitchen waste realize predrying and pasteurization, and the moisture in the solid kitchen waste is evaporated into vapor by high temperature. The dehumidifying unit 300 is connected behind the crushing and dehydrating unit 200 and comprises a dehumidifying wind box 301, a humidity monitor 302, a deodorizer 303 and a dehumidifier 304, wherein the dehumidifying wind box 301, the deodorizer 303 and the dehumidifier 304 are sequentially in fluid circulation communication; the dehumidifying air box 301 is provided with an S-shaped dehumidifying conveyor 3010, a feeding port 3011, a discharging port 3012, an air outlet 315 and an air return port 316, the dehumidifying conveyor 3010 is connected between the feeding port 3011 and the discharging port 3012, the feeding port 3011 is connected to the electric heating sterilizing conveyor 203, and the solid kitchen garbage enters the dehumidifying air box 301 after being pre-dried and sterilized by the electric heating sterilizing conveyor 203.

Referring to the right part of fig. 4, the dehumidifier 304 includes an evaporator 3041, a first condenser 3042, a second condenser 3043, a compressor 3046 and an expansion valve 3047, the compressor 3046, the evaporator 3041, the expansion valve 3047 and the first condenser 3042 are sequentially connected to form a first refrigeration cycle for circulating a refrigerant inside, the compressor 3046, the evaporator 3041, the expansion valve 3047 and the second condenser 3043 are sequentially connected to form a second refrigeration cycle for circulating a refrigerant inside, an air flow entering the dehumidifier 304 from an air inlet 3044 of the dehumidifier 304 sequentially passes through the evaporator 3041 and the first condenser 3042 and then flows out from an air supply outlet 3045 of the dehumidifier 304, and a water supply path 50 exchanges heat with the second condenser 3043. The first refrigeration cycle in the dehumidifier 304 may dehumidify and warm up the humid air and the second refrigeration cycle may be used to heat the water in the water supply circuit 50. In other embodiments, the condensed water generated at the evaporator 3041 may be sent to the water supply path 50 for heating output.

Continuing to refer to fig. 1 and 4, the high-temperature ultra-dry air (see the direction of hollow arrow in fig. 4) entering the box from the air return port 3016 of the dehumidifying air box 301 takes away the residual moisture in the solid kitchen garbage on the dehumidifying conveyor 3010, and the air with moisture is sent out from the air outlet 3015 and enters the deodorizer 303 from the inlet of the deodorizer 303 for deodorization; the deodorizer 303 removes odor and sends the odor out of the outlet of the deodorizer 303, the air flow deodorized by the deodorizer 303 enters the dehumidifier 304 from the air inlet 3044 of the dehumidifier 304, the air flow sequentially flows through the evaporator 3041 and the first condenser 3042, becomes high-temperature super-dry air and is sent out of the air supply outlet 3045, and then enters the dehumidifying wind box 301 again through the wind pipe 305; the air flow is cooled and dehumidified when passing through the evaporator 3041, moisture contained in the air flow is condensed into condensed water and stored in a water storage container in the dehumidifier 304, and the air flow flowing out of the evaporator 3041 is heated when passing through the first condenser 3042 to reduce the relative humidity, and is changed into high-temperature super-dry air to be output.

As shown in fig. 1 and 2, the discharge port 3012 is divided into a blanking conveyor 3013 and a return conveyor 3014, and the return conveyor 3014 communicates with the discharge port 3012 and the feed port 3011 from the outside of the dehumidifying wind box 301. A humidity monitor 302 installed at the discharge port 3012 of the dehumidifying wind box 301 for detecting whether the humidity of the solid kitchen garbage dried in the dehumidifying wind box 301 and discharged from the discharge port 3012 meets a standard that the solid kitchen garbage can be transported to the packing unit 400; the humidity monitor 302 is connected to a control part (not shown) of the kitchen waste disposal system in a signal manner, and the control part of the kitchen waste disposal system can connect the discharge port 3012 to the feed back conveyor 3014 or connect the discharge port 3012 to the feed-back conveyor 3013 based on the humidity detection result of the humidity monitor 302.

The dehumidification unit 300 work flow shown in fig. 3:

s1, enabling the solid kitchen waste to enter a dehumidifying wind box 301 for high-temperature dehumidifying treatment;

s2, the humidity monitor 3012 obtains the current humidity K of the solid kitchen waste conveyed by the discharge port 3012 in real time and feeds the current humidity K back to the control part of the kitchen waste treatment system;

s3, judging whether the humidity K of the current solid kitchen waste is less than the standard humidity K or not in real time by the control part of the kitchen waste treatment system₀(ii) a In a preferred embodiment, the standard humidity K₀20 percent;

s4, if the current humidity K is not less than the standard humidity K₀If so, controlling the discharge port 3012 to be communicated with the feed-back conveyor 3014, so that the solid kitchen waste is sent into the dehumidifying wind box 301 again from the discharge port 3012, and executing step S1;

s5, if the current humidity K is not less than the standard humidity K₀And the solid kitchen waste is dehumidified and transported to the compacting device 401.

As shown in fig. 1 and 2, the packing unit 400 is installed at the end of the kitchen garbage disposal system, and includes a pressing device 401 and a vacuum packing machine 402, wherein the pressing device 401 is connected to a discharging conveyor 3013, and compresses the solid kitchen garbage completely dried in the dehumidifying wind box 301 by the pressing device 401 to reduce the volume, and the solid kitchen garbage is packed by the vacuum packing machine 402 in vacuum and then is stored in a warehouse.

The kitchen waste enters a pulverizer 201, is processed into granular solid kitchen waste by the pulverizer 201, separates an oil-water mixture into an oil-water separator 202, and separates the oil-water mixture into oil and water to be discharged out of the system by the oil-water separator 202; the solid kitchen waste is sent to an electric heating disinfection conveying belt 203 for pre-drying and disinfection; the solid kitchen garbage after pre-drying and disinfection and the steam evaporated at high temperature are sent into a dehumidification wind box 301; high-temperature super-dry air in the dehumidifying air box 301 dehumidifies solid kitchen waste at high temperature, the high-temperature super-dry air outputs water vapor in the waste and conveys the water vapor to the deodorizer 303 for deodorization, the air flow enters the dehumidifier 304 after being deodorized by the deodorizer 303, the water in the air flow is condensed into water after the air flow carrying water passes through the evaporator 3041 and is stored in the dehumidifier 304, and the dehumidified air absorbs heat after exchanging heat with the first condenser 3042 to become high-temperature super-dry air which is then conveyed back to the dehumidifying air box 301 through the air pipe 305. The humidity in the solid kitchen garbage is monitored by a humidity monitor 302 when the solid kitchen garbage dehumidified by a dehumidifying wind box 301 is output, and if the humidity exceeds K₀(for example, 20%) and then the solid kitchen waste is conveyed back to the dehumidifying wind box 301 for re-dehumidification, and the solid kitchen waste with the humidity lower than 20% is conveyed to the compacting device 401; the compacting device 401 compresses the dried solid kitchen waste to reduce the volume, and then the solid kitchen waste is sent into the vacuum packaging machine 402, and the solid kitchen waste is sent into a warehouse for storage after being vacuum-packaged.

The utility model uses renewable clean energy by arranging the solar power supply unit 100, reduces the processing cost and provides sustainable electric energy; the crushing and dehydrating unit 200 and the dehumidifying unit 300 are arranged to sterilize the kitchen waste at high temperature for many times, reduce the moisture of the kitchen waste, reduce the breeding probability of bacteria and facilitate storage; the packaging unit 400 is arranged to store kitchen garbage in vacuum, so that the environment is effectively protected.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration only, and that various changes and modifications may be made without departing from the spirit and scope of the invention as defined by the appended claims, specification and equivalents thereof.

Claims

1. A kitchen waste disposal system comprising:

solar power supply unit (100) comprising: at least one solar panel (101) and at least one electrical storage device (102);

smash dehydration unit (200), be used for with kitchen garbage crushing back dehydration disinfection in advance, include: a pulverizer (201) having a solids outlet (2011) and a liquid outlet (2012), an oil-water separator (202) connected to the liquid outlet (2012), and an electrically heated sterilization conveyor (203) connected to the solids outlet (2011); and

a dehumidifying unit (300) for dehumidifying and drying solid kitchen waste, comprising: a dehumidifying wind box (301) with a feed inlet (3011), a discharge outlet (3012), an air outlet (3015) and an air return inlet (3016), a deodorizer (303) and a dehumidifier (304), a dehumidifying conveyor belt (3010) positioned between the feed inlet (3011) and the discharge outlet (3012) is arranged in the dehumidifying air box (301), the feed inlet (3011) is connected with the electric heating disinfection conveying belt (203), the dehumidifier (304) comprises an air inlet (3044) and an air supply outlet (3045), an air outlet (3015) of the dehumidifying air box (301) is communicated with an inlet of the deodorizer (303), an air inlet (3044) of the dehumidifier (304) is communicated with an outlet of the deodorizer (303), the air supply outlet (3045) of the dehumidifier (304) is communicated with the air return inlet (3016) of the dehumidifying air box (301) through an air pipe (305), and the discharge outlet (3012) is connected with a blanking conveyor belt (3013).

2. The kitchen waste disposal system according to claim 1, wherein said dehumidifying unit (300) further comprises a humidity monitor (302) and a feedback conveyor (3014) connected to said discharge port (3012) and feeding the kitchen waste discharged from said discharge port (3012) to said dehumidifying conveyor (3010) through said feed port (3011), the feed back conveyor belt (3014) is located outside the dehumidifying air box (301), the humidity monitor (302) is installed at the discharge port (3012), the control part of the kitchen waste treatment system is configured to be capable of switching on the discharge port (3012) and the feed-back conveyor belt (3014) or switching on the discharge port (3012) and the blanking conveyor belt (3013) based on the humidity detection result of the humidity monitor (302).

3. The kitchen waste disposal system of claim 1, further comprising a packing unit (400) for packing the solid kitchen waste, said packing unit (400) comprising: a pressing device (401) connected with the blanking conveyor belt (3013) and a vacuum packaging machine (402) connected with the pressing device (401).

4. The kitchen waste treatment system according to claim 2, wherein the pulverizing and dehydrating unit (200), the dehumidifying unit (300) and the packaging unit (400) are sequentially arranged along a circulation direction of the kitchen waste, and the solar power supply unit (100) supplies electric energy for the operation of the pulverizing and dehydrating unit (200), the dehumidifying unit (300) and the packaging unit (400).

5. The kitchen waste disposal system according to claim 1, wherein said oil-water separator (202) has an oil outlet and a moisture outlet, and discharges the liquid of the kitchen waste outputted from said liquid outlet (2012) as oil and moisture.

6. The kitchen waste treatment system according to claim 1, wherein the electric heating sterilization conveyor (203) is heat-sterilized by heating wires or heat-sterilized by ultraviolet lamps.

7. The kitchen waste disposal system of claim 1, wherein said dehumidifying conveyor (3010) is arranged in an "S" shape.

8. The kitchen waste treatment system according to claim 1, wherein the dehumidifier (304) comprises an evaporator (3041), a first condenser (3042), a compressor (3046) and an expansion valve (3047), the compressor (3046), the evaporator (3041), the expansion valve (3047) and the first condenser (3042) are sequentially connected to form a first refrigeration cycle for circulating a refrigerant inside, and an air flow entering the dehumidifier (304) from an air inlet (3044) of the dehumidifier (304) sequentially passes through the evaporator (3041) and the first condenser (3042) and then flows out from an air outlet (3045) of the dehumidifier (304).

9. The kitchen waste disposal system according to claim 8, wherein the dehumidifier (304) further comprises a second condenser (3043), the compressor (3046), the evaporator (3041), the expansion valve (3047) and the second condenser (3043) are sequentially connected to form a second refrigeration cycle for circulating the refrigerant, and a water supply path (50) is in heat exchange with the second condenser (3043).