CN113333080A

CN113333080A - Control method for crushing flux

Info

Publication number: CN113333080A
Application number: CN202110592936.8A
Authority: CN
Inventors: 孟行健
Original assignee: Anhui Tianjian Environmental Protection Co ltd
Current assignee: Anhui Tianjian Environmental Protection Co ltd
Priority date: 2019-11-27
Filing date: 2019-11-27
Publication date: 2021-09-03
Also published as: CN113333079A; CN113333078A; CN111036337A; CN111036337B

Abstract

The invention discloses a control method of broken flux, which is applied to a swill three-phase separation device with a breaking and extruding function. The swill three-phase separation device comprises a frame body, a sorting system and a crushing system. The control method first calculates the cumulative difference. And then judging whether the cumulant difference is greater than a preset crushing amount I and not greater than a preset crushing amount II, and determining whether to clean the crushing system according to a judgment result. And then judging whether the cumulative difference is larger than the second preset crushing amount and not larger than a third preset crushing amount, if so, cleaning the crushing system, and adjusting the crushing power of the crushing system according to the difference value of the cumulative difference and the third preset crushing amount. And finally, judging whether the cumulant difference is larger than the third preset crushing amount, if so, driving the crushing system to stop crushing. By the control method, the crushing system can improve the treatment efficiency of wet garbage and improve the utilization rate of cleaning resources and energy.

Description

Control method for crushing flux

The invention relates to a swill three-phase separation device with crushing and extruding functions and a divisional application of a three-phase separation method thereof, wherein the application number is CN 201911178081.3, the application date is 2019/11/27.

Technical Field

The invention relates to the technical field of kitchen waste treatment, in particular to a control method of broken circulation and a swill three-phase separation method; the control method of the broken flux is applied to three separation devices of swill with the functions of breaking and extruding; the swill three-phase separation method adopts the control method of the crushing flux.

Background

Swill is a domestic waste formed in the process of domestic consumption of residents, and various organic substances contained in the swill are extremely easy to corrode in summer; the contents of the residual vegetable soup, the rancidy water and the like are large, and the pollution is easily caused in the process of collecting and transporting the garbage; meanwhile, kitchen swill is also a main source of leachate in a refuse landfill and is also an important reason for atmospheric pollution and fly breeding; swill pigs fed by swill and extracted swill oil flow to the market and seriously harm the health of human beings. A large amount of kitchen swill has become a main source of urban pollution and harm to human health.

At present, two common kitchen swill collection modes are available at home and abroad, wherein the kitchen swill is directly recovered, namely, treated in a centralized way; secondly, the source is recycled after dehydration and reduction treatment, namely source treatment. The treatment methods mainly include chemical methods and biological methods. The chemical method utilizes chemical reaction, decomposes organic substances of swill by adding chemical substances, and then buries the swill. The method has the advantages of simplicity and high efficiency, and has the defects that a large amount of useful substances in the swill are wasted and secondary pollution is easily caused. The biological method converts kitchen swill into organic compound fertilizer for agricultural production through a series of treatment procedures. The method conforms to the reduction, harmless and recycling guidelines, and has the defects of high treatment cost, long production period and unobvious economic benefit.

The existing kitchen swill treatment device has the defects of low efficiency of a crushing system for treating wet garbage and low utilization rate of cleaning resources and energy when in use.

Disclosure of Invention

The invention provides a control method of crushing flux, which aims to solve the technical problems of low efficiency of wet garbage treatment and low utilization rate of cleaning resources and energy of a crushing system of the existing kitchen swill treatment device.

The invention is realized by adopting the following technical scheme: a control method of broken throughput is applied to a swill three-phase separation device with a breaking and extruding function, and the swill three-phase separation device with the breaking and extruding function comprises the following steps: support body, letter sorting system, broken system. The sorting system comprises a sorting platform and a screen plate. The sorting platform is installed on the frame body and used for containing kitchen swill. The screen plate is arranged on the sorting platform and used for solid-liquid separation of the kitchen swill. The crushing system is used for crushing and rolling the solid wet garbage separated from the screen plate. The method for controlling the crushing flux comprises the following steps:

(1.1) detecting a first accumulated amount of wet garbage entering a preset rolling space of the crushing system within a preset time period, and simultaneously detecting a second accumulated amount of wet garbage leaving the preset rolling space within the preset time period;

(1.2) calculating a cumulative difference of the first cumulative amount and the second cumulative amount; wherein the cumulative difference is a difference obtained by subtracting the cumulative amount two from the cumulative amount one;

(1.3) judging whether the cumulant difference is greater than a first preset crushing amount and not greater than a second preset crushing amount;

(1.4) cleaning the crushing system when the cumulative difference is greater than the first preset crushing amount and not greater than the second preset crushing amount;

(1.5) judging whether the cumulant difference is greater than the second preset crushing amount and not greater than a third preset crushing amount;

(1.6) when the cumulative difference is larger than the second preset crushing amount and not larger than a third preset crushing amount, cleaning the crushing system, and adjusting the crushing power of the crushing system according to the difference value of the cumulative difference and the third preset crushing amount; wherein the power is positively correlated with the difference;

(1.7) judging whether the cumulant difference is larger than the preset crushing amount III;

(1.8) when the cumulative difference is larger than the third preset crushing amount, driving the crushing system to stop crushing;

the invention also provides a swill three-phase separation method, which adopts the method for controlling the broken flux.

Compared with the prior art, the control method for the crushing flux has the following beneficial effects:

in the application process of the control method of the crushing circulation, when the accumulated difference is not more than a preset crushing quantity one, the situation that excessive garbage does not remain in the preset rolling space at the moment is shown, the cleaning can be omitted, the crushing power of a crushing system does not need to be increased, and the waste of cleaning water and crushing energy is avoided; when the accumulated difference is greater than the first preset crushing amount and not greater than the second preset crushing amount, indicating that a certain amount of garbage is adhered to the preset rolling space at the moment, and flushing the crushing system; when the accumulated difference is larger than the second preset crushing amount and smaller than the third preset crushing amount, the attached garbage in the preset rolling space is further increased, so that the crushing system needs to be flushed and the crushing power of the crushing system needs to be adjusted; when the accumulated difference is larger than the third preset crushing amount, excessive wet garbage exists in the preset rolling space, so that the crushing system is seriously damaged, and the crushing system is driven to stop working. So, this broken system not only can improve the treatment effeciency to wet rubbish, improves the broken speed of rubbish, can also improve the utilization ratio to washing resource and energy, can also protect broken system itself simultaneously, improves broken system's life.

Drawings

FIG. 1 is a perspective view of a swill three-phase separating device with crushing and squeezing functions in embodiment 1 of the present invention;

FIG. 2 is a perspective view of the swill three-phase separating device with the crushing and squeezing functions in FIG. 1 from another view angle;

FIG. 3 is a perspective view of the swill three-phase separating device with the crushing and squeezing functions in FIG. 2 after a part of the structure is removed;

FIG. 4 is a perspective view of the crushing system of the swill three-phase separating device in FIG. 1;

FIG. 5 is a perspective view of a portion of the construction of the crushing system of FIG. 4;

FIG. 6 is a perspective view of an extrusion system of the swill three-phase separation device in FIG. 1;

FIG. 7 is a schematic view of the extrusion system of FIG. 6 with the extrusion motor and extrusion frame removed;

FIG. 8 is a schematic view of the press system of FIG. 7 with the top portion of the sink housing and locking housing removed;

FIG. 9 is a schematic view of the compression system of FIG. 8 from another perspective;

FIG. 10 is a perspective view of a locking mechanism of the compression system of FIG. 7;

FIG. 11 is a perspective view of the discharge block of the locking mechanism of FIG. 10;

FIG. 12 is a perspective view of an oil-water separation system of the swill three-phase separation device shown in FIG. 1;

FIG. 13 is a partial perspective view of the oil water separation system of FIG. 1;

FIG. 14 is a front view of the oil separator tank of the oil water separation system of FIG. 13 with portions broken away;

FIG. 15 is an internal perspective view of the oil scraping mechanism of the oil water separation system of FIG. 13;

fig. 16 is a partial structural view of the crushing system of the swill three-phase separating device with crushing and squeezing functions in embodiment 2 of the present invention;

fig. 17 is a partial structural view of the crushing system of the swill three-phase separating device with crushing and squeezing functions in embodiment 3 of the invention;

FIG. 18 is a perspective view of an extrusion system of the swill three-phase separation device with crushing and extrusion functions in embodiment 4 of the present invention;

FIG. 19 is a perspective view of an oil-water separation system of the swill three-phase separation device with crushing and squeezing functions in embodiment 4 of the present invention;

FIG. 20 is a schematic diagram showing an internal configuration of the oil-water separation system shown in FIG. 19.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Example 1

Referring to fig. 1, fig. 2 and fig. 3, the present embodiment provides a three-phase separating device with a crushing and squeezing function for separating three phases of kitchen swill and separating solid garbage, waste water and grease. Wherein, this swill three-phase separator includes support body 1, letter sorting system, broken system, extrusion system and oil-water separation system, still includes the pan feeding system.

The frame body 1 is formed by splicing a plurality of square tubes, and the splicing mode can be welding, clamping, screwing and the like, and can be integrally formed. The bottom of support body 1 can set up structures such as pulley to support body 1 removes on ground. Simultaneously, the bottom of support body 1 also can set up limit structure, and limit structure can restrict support body 1 and remove subaerial, guarantees that support body 1 places stably in required fixed position. Certainly, the surface of the frame body 1 can be coated with oil-resistant and corrosion-resistant coating, so that the kitchen swill can be prevented from corroding the square pipe. The material of square pipe can be hard materials such as stainless steel or carbon steel, and its quantity is decided according to the overall structure of support body 1, can guarantee holistic fastness as far as possible. Of course, in this embodiment, a pulley and other components may be further disposed at the bottom of the frame body, so that the frame body 1 may slide on the ground as a whole.

In this embodiment, the feeding system is used for conveying the kitchen waste to be subjected to three-phase separation to the sorting system, and the feeding system comprises the elevator 4. The lifting machine 4 is installed on the frame body 1 and is used for lifting the garbage bin 5 used for containing the kitchen waste, so that the bin mouth of the garbage bin 5 faces the sorting system. The lifting machine 4 can adopt the existing lifting machine, and can directly lift the garbage can 5 from a low position to a high position so as to reduce the labor intensity of workers, and the garbage can 5 is rotated by a certain angle, for example, by 90 degrees, after the garbage can 5 is lifted to the high position, so that the kitchen swill/kitchen waste in the garbage can 5 is dumped into the sorting system.

The sorting system is used for sorting and separating the kitchen waste to remove hard foreign matters and obtain solid wet waste and liquid oil-water mixture. Wherein, letter sorting system includes letter sorting platform 2 and otter board 3. The sorting platform 2 is installed on the frame body 1 and used for containing kitchen swill. Sorting platform 2 can be funnel-shaped, and it can hold the kitchen swill/kitchen garbage of empting from garbage bin 5. The screen plate 3 is arranged on the sorting platform 2 and is used for solid-liquid separation of kitchen swill. In this embodiment, the mesh plate 3 is disposed at the lowest point of the sorting platform 2, so that the liquid in the kitchen swill/kitchen garbage can flow out, and the solid and part of the liquid adhered to the solid can be left on the sorting platform 2.

Referring to fig. 4 and 5, the crushing system is used for crushing the wet garbage to obtain a crushed product with a particle size meeting a predetermined particle size standard. Wherein the crushing system comprises a crushing roller 32, a crushing motor 33, a crushing shell 48, a flushing mechanism, a statistical mechanism and a crushing controller.

Both the upper and lower ends of the crushing shell 48 are open ends. The number of crushing rollers 32 is at least two and the crushing rollers 32 are rotatably mounted on the frame body 1, i.e. in the crushing shell 48. The two crushing rolls 32 are arranged in parallel in the axial direction, and the two ends of the two crushing rolls are aligned and separated by a preset rolling space. Wherein, wet rubbish enters from the same side of two crushing rollers 32, and leaves from the same side of two crushing rollers 32 after rolling through the preset rolling space. In this embodiment, the crushing roller 32 is rotatably mounted in the crushing shell 48, and the roller surface of the crushing roller 32 may be provided with a wear-resistant coating, which ensures a long-term use of the roller surface. In other embodiments, the roll surface of the crushing roller 32 may be provided with a convex structure, which can cut the meal or other solid composition in the kitchen waste, so that the kitchen waste can be sufficiently rolled and decomposed.

A crushing motor 33 is mounted on the frame body 1 and is used to drive the crushing roller 32 to rotate. The crushing motor 33 can be connected with the crushing roller 32 through a gear box, and can provide large torque for the crushing roller 32, so that the two crushing rollers 32 can sufficiently roll kitchen swill. Of course, the crushing motor 33 may also be arranged directly outside the crushing shell 48, with its output shaft inserted into the crushing shell 48 and coaxially connected with one of the crushing rollers 32. The working power of the crushing motor 33 can be selected according to the actual crushing requirements, i.e. when the crushing system is a small crushing device, the crushing motor 33 can be a low-power motor, and when the crushing system is a large crushing device, the crushing motor 33 needs to be replaced by a high-power motor.

The flushing mechanism comprises a plurality of spray heads 34, the spray heads 34 being mounted on the cartridge body 1. The spray head 34 is located on the same side of the two crushing rollers 32, and is used to spray washing water onto the roller surfaces of the crushing rollers 32. The washing mechanism can realize the cleaning function of the crushing roller 32, so that the roller surface can be kept clean, dirt generated in the long-term use process of the crushing roller 32 can be prevented from being accumulated, and the rolling efficiency of the crushing system is improved.

The statistical mechanism comprises a first detection component, a second detection component and a calculation module. The detection assembly I is used for detecting the first accumulated amount of the wet garbage entering the preset rolling space within a preset time period. The second detection assembly is used for detecting the second accumulation amount of the wet garbage leaving the preset rolling space in the preset time period. The calculation module is used for calculating the accumulated difference between the first accumulated amount and the second accumulated amount. Wherein the accumulated difference is the difference obtained by subtracting the accumulated amount two from the accumulated amount one. In this embodiment, the first detecting component can measure the garbage entering the rolling space through a device such as a flowmeter, and similarly, the second detecting component can also measure the rolled garbage through a device such as a flowmeter. Since there may be some dust adhering to the roll surface during rolling, the amount of dust remaining in the rolling space can be determined by determining the difference between the two measurements, and the crushing roll 32 can be cleaned using this information.

The crushing controller is configured to determine whether the cumulative difference is greater than a first preset crushing amount and not greater than a second preset crushing amount, and if so, drive the spray head 34 to spray the cleaning water. When the accumulated difference is between the first preset crushing amount and the second preset crushing amount, the situation that part of garbage is adhered to the roller surface at the moment is shown, and the roller surface needs to be cleaned, so that the crushing controller can drive the flushing mechanism to clean the roller surface. The crushing controller is also used for judging whether the cumulant difference is larger than a second preset crushing amount and not larger than a third preset crushing amount, if so, the spray head 34 is driven to spray cleaning water, and the rotating speed of the crushing motor 33 is increased according to the difference value of the cumulant difference and the third preset crushing amount. Wherein the increase in the rotational speed is positively correlated with the difference. When the accumulated difference is between the second preset crushing amount and the third preset crushing amount, the amount of the garbage adhered to the roller surface is very large, and the roller surface is required to be washed and the rolling speed is required to be increased so as to treat the garbage accumulated in the rolling space. The crushing controller is also used for judging whether the accumulated difference is larger than a preset crushing amount three, and if so, driving the crushing motor 33 to stop rotating. When the accumulated difference is larger than the preset crushing amount three, which indicates that the amount of garbage in the grinding space reaches the upper limit, if the crushing motor 33 continues to rotate, the crushing motor 33 and other equipment may be damaged, and thus the crushing controller stops the rotation of the crushing motor 33.

Referring to fig. 6-11, the extrusion system is used for extruding and dehydrating the crushed product, and obtaining extruded water and extruded material with water content reaching a preset dry humidity. The extrusion system comprises an extrusion shell 52, a screw rod 54, an extrusion motor 55, a locking mechanism and a water outlet pipe.

The crush can 52 is mounted on the frame 1, which in other embodiments may be integrally formed with the frame 1. The pressing chamber 53 is provided in the pressing shell 52, and the number of the pressing chambers 53 is at least two, and the pressing chambers 53 communicate with each other. The extrusion cavities 53 are connected together to form an extrusion channel, and the kitchen swill is extruded and dehydrated in the extrusion channel. The extruding shell 52 is also provided with a water outlet 56, and the number of the water outlets 56 is at least one. The squeezing cavity 53 near one end of the squeezing shell 52 is used for receiving kitchen swill, while the squeezing cavity 53 far away from one end of the squeezing shell 52 is used as a cavity for discharging liquid, and the liquid content in the mixture contained in the squeezing cavity is the highest, so that an oil scraping source can be provided for the follow-up process.

In this embodiment, the crush can 52 includes a housing 69 and a screen 70. The housing 69 includes a feed housing 71, a baffle 72, and a sump housing 73. The top of the feeding shell 71 is provided with a feeding hole for receiving kitchen swill, and the bottom of the feeding shell 71 is higher than the bottom of the water tank shell 73. The top opening of the feeding shell 71 is relatively large, and can be used for receiving sufficient kitchen swill. The partition 72 is disposed between the feeding shell 71 and the water tank shell 73, and has a plurality of through holes 74 communicating the feeding shell 71 and the water tank shell 73. Thus, the liquid in the feeding housing 71 can also directly flow into the water tank housing 73 through the through hole 74 for collection. The partition 72 is further provided with a discharge port 75, and the discharge port 75 is used for conveying kitchen swill to the sieve tube 70 described later. The sieve tube 70 is positioned in the water tank shell 73, and the side wall of the sieve tube is provided with a plurality of water permeable holes which can allow the liquid positioned in the sieve tube 70 to flow out. The screen 70 has one end capped at the outlet 75 and the other end capped at the end of the circular channel 60 adjacent to the sump housing 73. Thus, the kitchen waste in the feeding shell 71 can enter the sieve tube 70 through the discharge hole 75 and is located in the extrusion chamber 53 in the sieve tube 70. Wherein the screw rod 54 is arranged in the sieve tube 70, and the locking shell 57 and the end of the water tank shell 73 far away from the partition plate 72 are arranged.

A screw 54 is rotatably mounted in the extrusion housing 52 and extends through all of the extrusion chambers 53. The screw rod 54 may be formed of two integrally formed parts, one part being a rotating shaft structure and the other part being a spiral structure surrounding the rotating shaft structure. Helical structure is when following the pivot structure and rotating, and it can carry out directional extrusion to the kitchen garbage in the extrusion chamber 53, makes extrusion chamber 53 to same direction motion, and at the in-process of motion, the liquid composition among the kitchen garbage then can be followed the hole outflow of permeating water, and this dehydration function to kitchen garbage has just been realized.

The extruding motor 55 is installed on the frame body 1 and is coaxially connected with the screw rod 54. The extrusion motor 55 drives the screw rod 54 to rotate through rotation, so that the kitchen swill in the extrusion cavity 53 is extruded from one end to the other end of the extrusion shell 52, and the extruded water flows out from the water outlet 56. The pressing motor 55 can raise the torque through a special gear box so that the screw rod 54 has a larger rotational torque, which may reduce the rotational speed of the screw rod 54, but does not need a faster rotational speed when pressing the kitchen waste, and thus does not have a great influence.

The locking mechanism comprises a locking housing 57, a drop assembly, a spring 58 and a pressure block 59. The locking case 57 is mounted on the other end of the pressing case 52 and is opened with a circular through groove 60 communicating with the pressing chamber 53. The discharging assembly comprises a pressing rod 61 and a discharging block 62. The discharge block 62 is of a circular truncated cone structure and is coaxially connected to the screw rod 54. A discharge block 62 is located in the circular through-slot 60 with a thinner end located in the extrusion chamber 53 and a thicker end located in the lock housing 57. The pressing rod 61 is coaxially connected with the discharging block 62 and is rotatably installed in the locking shell 57. The locking shell 57 can be used as a discharging mechanism, the circular through groove 60 is arranged for extruding, discharging and separating, the discharging function of dry materials is realized, and the discharging block can be propped in the circular through groove 60 under the action of the spring 58 and the pressure rod 61, the gap formed in this way can be extruded by extrusion discharge, and because the discharge block 62 is of a truncated cone structure, the depth of the pressure block inserted in the circular through groove 60 determines the size of the gap, when the discharging amount needs to be adjusted, the pressure block can generate a pushing force on the spring 58, so that the spring drives the discharging block 62 to move in the axial direction of the screw rod 54, the size of the gap is adjusted, thereby changing the discharge amount, so that the locking mechanism can control the discharge amount of extrusion discharge, further adjusting the water content of the discharge, the discharge amount can be increased when the discharge is required to be accelerated, and the gap can be reduced when the water content is too high, so that the discharge amount is reduced.

In the present embodiment, the screw rod 54 is integrally formed with the pressing rod 61, and the discharge block 62 is fitted over the pressing rod 61. The spring 58 is sleeved on the pressure rod 61, and one end of the spring is abutted against the material discharging block 62. The number of the pressure blocks 59 is at least one, and the pressure blocks 59 are sleeved on the pressure rod 61 and used for providing axial pressure to the other end of the spring 58, so that the spring 58 limits the discharging block 62 in the circular through groove 60, and the gap between the discharging block 62 and the locking shell 57 is in negative correlation with the axial pressure. The pressure block 59 may be threaded with the pressing rod 61 and rotate to push the spring 58 to move along the axial direction of the pressing rod 61, so that the discharging block 62 moves along the axial direction of the pressing rod 61 to change the gap. This embodiment can adjust the position of blanking piece 62 through pressure piece 59 and spring 58, adjusts the discharge capacity, and the moisture content of material is extruded in the regulation control for the moisture content of the extrusion ejection of compact reaches actual required standard, guarantees the suitable living environment of follow-up biodegradable reaction bacterial, improves the speed and the effect of follow-up degradation. Moreover, the discharging amount can be adjusted in real time, so that discharging can be more timely, the fault rate is reduced, and normal operation is guaranteed, so that the discharging efficiency of the extrusion system is improved, and the working time is shortened. And, spring 58 can cushion the extrusion ejection of compact, prevents that the extrusion is excessive and cause the damage to other equipment, simultaneously, when clout was more in the extrusion chamber, owing to extrude shell 52 and lock shell 57 separately, can separately draw these two clearly, and convenient knot is clear, avoids the stock dry and hard rotten and give off the stink.

The number of the water outlet pipes is at least one, and at least one water outlet pipe corresponds to at least one water outlet 56. Each outlet pipe is connected to a corresponding outlet 56. The water outlet pipe can discharge liquid generated by extrusion and convey the liquid to a special oil-water separation system for oil-water separation. The water outlet pipe can be provided with a special valve, when the squeezing dehydration is more, the valve is opened, and the valve can be normally closed at other times.

Referring to fig. 12-15, the oil-water separation system is used to mix the oil-water mixture and the extruded water into an oil-water mixture, separate oil from the oil-water mixture, separate layers of the oil-water mixture, and finally scrape out floating oil residues in the oil layer and separate wastewater and grease. The oil-water separation system comprises an oil separation tank 111, an oil scraping mechanism, a liquid outlet mechanism and a U-shaped heating pipe 126.

The oil separation tank 111 comprises a tank body I112 and a plurality of separation plates 113, and also comprises a ball valve I127. The top end of the first box body 112 is of an inverted funnel-shaped structure, and an opening is formed in the top end of the first box body 112. A plurality of partition plates 113 are provided in the first case 112, and partition a plurality of oil-separating spaces 114 that are sequentially communicated. The adjacent two oil-separating spaces 114 communicate with each other through the upper space and the lower space of one partition plate 113. An oil-separating space 114 in one end of the oil-separating tank 111 is used for receiving the oil-water mixture and is defined as a material receiving space, and an oil-separating space 114 in the other end of the oil-separating tank 111 is defined as a liquid outlet space. From the material receiving space to the liquid outlet space, the heights of the top and the bottom of the partition plate 113 relative to the bottom wall of the first box body 112 are increased in sequence. Ball valve one 127 is mounted on the outer wall of box one 112 and is used to release liquid to the liquid layer. Like this, after oil water mixture got into oil removal space 114 and the layering of stewing, the oil reservoir of upper strata can only pass through the upper space of division board 113, and the water layer of lower floor or deposit layer can only pass through the lower part space, thereby realize the separation to oil water mixture, and because the height of upper space can be higher and higher, will make fluid can reach next oil removal space after filling up previous oil removal space like this, thereby make the oiliness rate in the fluid improve step by step, and whole oil removal's in-process need not repeated layering, can improve the efficiency and the oil removal effect of oil removal greatly, make the oiliness rate of fluid in the oil removal space that arrives at last reach the maximum value, thereby improve oil water separation's separation effect, improve the separation efficiency of fluid, improve the oil removal rate greatly.

The oil scraping mechanism comprises an oil scraping tank 115, an oil scraping motor 116 and an oil scraping assembly. The bottom end of the oil scraping box 115 is of an opening structure and covers the opening. The oil scraping box 115 comprises a second box body 128 and a second ball valve 129, and the bottom end of the second box body 128 is communicated with the inverted funnel-shaped structure. The oil scraping box 115 is provided with an oil outlet, and the height of the oil outlet is greater than that of the opening. The oil scraping motor 116 is installed on the oil scraping tank 115, and the second ball valve 129 is installed on the outer wall of the second box body 128 and is used for releasing liquid in the second box body 128. The oil scraping assembly includes at least two pairs of sprockets 117, two chains 118, and a plurality of oil scraping plates 119. Each pair of chain wheels 117 is rotatably mounted on two opposite inner walls of the oil scraping tank 115, and the oil scraping motor 116 is used for driving one pair of chain wheels 117 to synchronously rotate. Each chain 118 is sleeved on at least two chain wheels 117 on the same inner wall, and the two chains 118 can rotate synchronously through the rotation of the chain wheels 117. Each of the oil scraping plates 119 is fixed at both ends thereof to two chains 118, respectively, and a line segment connecting the points of connection of the two chains 118 is parallel to the central axis of each pair of sprockets 117. When the oil scraping motor 116 rotates, the chain 118 drives the oil scraping plate 119 to move from above the opening to above the oil outlet. When the chain 118 moves along with the rotation of the sprocket 117, the oil scraping plate 119 connected to the chain 118 continuously enters the oil scraping box 115, thereby scraping oil or oil sludge in the oil scraping box 115.

The number of the positioning shafts 125 is at least two, and the at least two positioning shafts 125 correspond to the at least two pairs of sprockets 117, respectively. Two ends of each positioning shaft 125 are respectively fixed on two opposite inner walls of the oil scraping box 115, and each pair of chain wheels 117 are respectively sleeved on two ends of the corresponding positioning shaft 125; wherein, the oil scraping motor 116 is installed on the outer wall of the oil scraping box 115, and the output shaft is connected with one positioning shaft 125. The positioning shaft 125 enables each pair of chain wheels 117 to rotate synchronously, so that the two chains 118 can rotate through one oil scraping motor 116, the utilization rate of electric energy can be improved, and the use is convenient.

The liquid outlet mechanism comprises a liquid outlet pipe 120 and may further comprise a liquid outlet pump 124. The number of the liquid outlet pipes 120 is at least one. One end of the liquid outlet pipe 120 is arranged in the liquid outlet space, and the other end is arranged in the oil scraping box 115. The other end of the outlet pipe 120 is positioned above the opening. The oil-water mixture is separated into a solid layer and a liquid layer in the oil separation spaces 114, the liquid in the liquid layer flows from one end of the liquid outlet pipe 120 to the other end and is dispersed into the oil scraping box 115, and the oil scraping plate 119 scrapes the oil from the liquid to the oil outlet. An effluent pump 124 is disposed in the effluent space and an effluent port is connected to one end of the effluent pipe 120. Thus, when the oil needs to be discharged to the oil scraping box 115, the liquid outlet pump 124 can be driven to work, and the oil is pumped to the upper part of the opening through the liquid outlet pipe 120. And frizing motor 116 just can order about sprocket 117 and rotate, make sprocket 117 drive chain 118 and rotate, and further make frizing plate 119 follow chain 118 and move, like this at the in-process of motion, frizing plate 119 can be located and scrape out with the oil slick sediment of scraping in the oil tank 115, thereby realize the frizing function, whole frizing in-process need not manual operation, and a plurality of frizing plates 119 scrape to fluid ceaselessly and get, can improve frizing efficiency greatly, further improve oil-water separation's separation efficiency, the while still makes the purity of the fluid of scraping out or the oil slick sediment higher, can improve oil-water separation's separation effect.

The U-shaped heating pipe 126 is inserted into the first box body 112 and is used for heating the oil-water mixture in the oil separation space. When the temperature of the oil-water mixture in the first box 112 is too low, the grease is solidified, so that the oil cannot be scraped, and therefore, the U-shaped heating pipe 126 can keep the temperature of the oil-water mixture above the solidification temperature all the time, and the grease is prevented from being condensed.

To sum up, compare in current kitchen swill processing apparatus, the swill three-phase separator who takes broken extrusion function of this embodiment has following advantage:

1. this take swill three-phase separator of broken extrusion function forms a predetermineeing the space that rolls between two crushing rollers 32 in its broken system, separates out wet rubbish from the kitchen swill like this and will roll in this space, makes great rubbish pulverize for tiny rubbish, realizes the crushing function to wet rubbish. The spray head 34 of the flushing mechanism of the system can spray water to the roller surface for flushing, can flush garbage adhered to the roller surface, and guarantees the cleanliness of the roller surface, so that the crushing efficiency of the crushing roller 32 can be improved. The first detection assembly of the statistical mechanism can detect the feeding amount of the wet garbage in a period of time, the second detection assembly synchronously detects the discharging amount of the wet garbage in the period of time, and finally the calculation module calculates the difference value between the feeding amount and the discharging amount so as to facilitate the judgment of the crushing controller. The crushing controller compares the accumulated difference with each preset range and respectively processes: (1) when the accumulated difference is not greater than the preset crushing amount, it indicates that excessive garbage is not attached to the crushing roller 32 at this time, cleaning may not be performed, and the rotating speed of the crushing motor 33 does not need to be increased, so that waste of washing water and crushing energy is avoided; (2) when the accumulated difference is greater than the first preset crushing amount and not greater than the second preset crushing amount, a certain amount of garbage is attached to the roller surface, the fact that the roller surface needs to be washed is indicated, and the crushing controller controls the washing mechanism to wash; (3) when the accumulated difference is larger than the second preset crushing amount and smaller than the third preset crushing amount, the attached garbage on the roller surface is further increased, so that the crushing controller not only needs to wash the roller surface, but also needs to increase the rotating speed of the crushing motor 33 to accelerate the treatment speed of the wet garbage; (4) when the accumulated difference is greater than the preset crushing amount three, excessive wet garbage exists in the preset rolling space, and serious damage is caused to the crushing motor 33, so that the crushing motor stops working by the crushing controller. So, this broken system not only can improve the treatment effeciency to wet rubbish, improves the broken speed of rubbish, can also improve the utilization ratio to washing resource and energy, can also protect broken motor 33 simultaneously, improves broken motor's life.

2. This take swill three-phase separator of broken extrusion function, a plurality of extrusion chambeies 53 that set up in the extrusion shell 52 communicate each other in its extrusion system, and hob 54 is in extrusion chamber 53 through extrusion motor 55 spin for the kitchen swill that is arranged in extrusion chamber 53 can be along same direction motion and extrusion together, and extrude the water outlet and flow out, realizes the extrusion dehydration function to the kitchen swill. The locking shell 57 of the locking mechanism is connected with the extrusion shell 52, the locking shell 57 can be used as a discharging mechanism, the round through groove 60 formed in the locking shell can be used for extruding and discharging materials to realize the discharging function of dry materials, the discharging block can be propped against the round through groove 60 under the action of the spring 58 and the pressure rod 61, the gap formed in this way can be used for extruding and discharging materials to be extruded, meanwhile, the discharging block 62 is of a round platform-shaped structure, the depth of the discharging block inserted in the round through groove 60 determines the size of the gap, when the discharging amount needs to be adjusted, the pressure block can generate driving force on the spring 58, the spring 58 drives the discharging block 62 to move in the axial direction of the screw rod 54, the size of the gap is adjusted, so that the discharging amount is changed, the discharging amount can be controlled by the locking mechanism, the water content of the extruded materials is adjusted, the discharging amount can be increased when the discharging amount needs to be accelerated, and the gap can be reduced when the water content is too high, the discharge amount is reduced.

This extrusion system just can be according to various kitchen garbage's the moisture condition, adjusts the position of blanking piece 62 through pressure piece 59 and spring 58, adjusts the load, and the moisture content of regulation control extrusion material for the moisture content of the extrusion ejection of compact reaches the actual required standard, guarantees the suitable living environment of follow-up biodegradable reaction bacterial, improves the speed and the effect of follow-up degradation. Moreover, the discharging amount can be adjusted in real time, so that discharging can be more timely, the fault rate is reduced, and normal operation is guaranteed, so that the discharging efficiency of the extrusion system is improved, and the working time is shortened. And, spring 58 can cushion the extrusion ejection of compact, prevents that the extrusion is excessive and cause the damage to other equipment, simultaneously, when clout was more in the extrusion chamber, owing to extrude shell 52 and lock shell 57 separately, can separately draw these two clearly, and convenient knot is clear, avoids the stock dry and hard rotten and give off the stink.

3. This take swill three-phase separator of broken extrusion function, it still sets up moisture sensor 63 in the extrusion system and can detect the moisture content that gets into the meal kitchen swill in the extrusion chamber 53, and the extrusion controller then can judge according to the moisture content, when the moisture content is located predetermine moisture proportion one and predetermine between the moisture proportion two, the extrusion controller increases the rotational speed that extrudees motor 55 according to the difference of predetermineeing moisture proportion two and moisture content, and the rotational speed increases the value and the difference is positive correlation, the moisture content is big more promptly, the rotational speed is then big more, can fully extrude out with the moisture of meal kitchen swill like this. When the water content is smaller than the preset water content ratio II, the water content of the kitchen swill is too low, the extrusion motor 55 or the screw rod 54 can be damaged by continuing to rotate the extrusion motor 55, and therefore the extrusion controller stops rotating the extrusion motor 55, equipment is protected, and the service life of the extrusion system is prolonged.

4. In the swill three-phase separation device with the crushing and extruding functions, the partition plate 113 of the oil separating tank 111 in the oil-water separation system divides the interior of the tank body I112 into a plurality of oil separating spaces 114, and the oil separating spaces 114 are communicated with each other through the upper space and the lower space of the partition plate 113, so that after an oil-water mixture enters the first oil separating space 114, the oil-water mixture can be kept still and layered in the oil separating spaces 114 and is divided into at least two layers. The oil reservoir that is located the upper strata then can flow to next oil removal space 114 from the upper space of division board, and the water layer that is located the lower floor or the precipitate layer then can enter into the bottom in other oil removal spaces 114 through the lower part space, just so need not stratify again, so, the oiliness rate that the oil water mixture can make the oil reservoir in the separation process of a plurality of oil removal spaces 114 improves greatly, make the oil content rate of the fluid in the oil removal space 114 that reachs at last reach the maximum value, thereby improve oil-water separation's separation effect, improve the separation efficiency of fluid, improve oil removal rate greatly.

Example 2

Referring to fig. 16, the present embodiment provides a swill three-phase separation device with crushing and squeezing functions, which is based on embodiment 1 and refines the statistical mechanism (the flushing mechanism is not shown in the figure).

The first detection assembly comprises a first sliding plate 43 and a first weighing sensor 44. The first sliding plate 43 is installed on the frame body 1 and is arranged obliquely, and one end of the first sliding plate, which is inclined downwards, faces to the preset rolling space. The wet garbage slides from the first sliding plate 43 to the preset rolling space. The first load cell 44 is installed between the frame body 1 and the first sliding plate 43, and is used for detecting the weight of the wet garbage on the first sliding plate 43. In this embodiment, assuming that the sliding speed of the wet trash on the first sliding plate 43 is a fixed value and can be measured in advance, and the sliding length of the wet trash on the first sliding plate 43 is also a fixed value, the calculation formula of the accumulated amount one is:

in the formula, V₁Is the cumulative amount one, t is the duration of a preset time period, v₁The gliding speed L of the wet garbage on the first sliding plate 43₁For the sliding length of wet garbage on the first sliding plate 43, a₁The weight detected by load cell one 44. The ratio of the sliding distance of the wet garbage on the first sliding plate 43 to the sliding length is equal to the ratio of the wet garbage to the weight in the preset time period, so that the calculation formula can be calculated.

The second detection assembly comprises a second sliding plate 45 and a second weighing sensor 46. The second sliding plate 45 is installed on the frame body 1 and is obliquely arranged, and the inclined plane is located below the preset rolling space. And the second weighing sensor 46 is arranged between the frame body 1 and the second sliding plate 45 and is used for detecting the weight of the wet garbage on the second sliding plate 45. Similarly, assuming that the gliding speed of the wet garbage on the second sliding plate 45 is constant, and the gliding length is also constant, the calculation formula of the second cumulant is as follows:

in the formula, V₂Is a cumulative amount of two, v₂The sliding speed L of the wet garbage on the second sliding plate 45₂The sliding length of the wet garbage on the second sliding plate 45, a₂The weight detected by the second load cell 46.

Therefore, the calculation formula for the calculation module to calculate the cumulative difference is:

in the formula, Δ is an accumulated difference.

This take swill three-phase separator of broken extrusion function, the detection subassembly one of the statistical mechanism sets up slide 43 and weighing sensor 44 in its broken system, and wet rubbish can slide at slide 43 before getting into the preset space that rolls, and weighing sensor 44 this moment then can detect the total amount of wet rubbish that is located slide 43. Therefore, the sliding speed of the wet garbage on the first sliding plate 43 can be regarded as a fixed value when the accumulated amount is calculated, the stroke of the wet garbage on the first sliding plate 43 in the preset time period can be calculated firstly, then the ratio of the stroke to the sliding length of the first sliding plate 43 is calculated, finally the accumulated entering amount of the wet garbage in the preset time period can be obtained by multiplying the ratio and the detected weight, the accumulated discharging amount of the crushed garbage can also be calculated, the difference value between the accumulated entering amount and the accumulated discharging amount can be calculated by the calculating module, and the difference value actually represents the garbage residual amount in the crushing roller 32 and the preset rolling space. Therefore, the crushing controller can control the flushing mechanism and the crushing motor 33 according to the condition of the residual quantity of the garbage, so that the maximization of resource and energy utilization is realized, and the crushing motor 33 is protected.

Example 3

Referring to fig. 17, the present embodiment provides a swill three-phase separation device with a crushing and squeezing function, wherein the crushing system is added with an electromagnet 25, a slide rail 26, an electric slide block 27, a third weighing sensor 28 and a magnetic material recycling bin 47 on the basis of embodiment 1.

The electromagnet 25 is installed on the frame body 1, and is located above the preset rolling space, and is used for magnetically adsorbing the magnetic impurities in the wet garbage. The slide rail 26 is installed on the frame body 1, and one end thereof is located above the preset rolling space. The motorized slider 27 is mounted on the slide rail 26 and can slide on the slide rail 26. The electromagnet 25 is connected with an electric slide block 27 through a third weighing sensor 28. The third weighing sensor 28 is used for detecting the total weight of the magnetic impurities adsorbed on the electromagnet 25. A magnetic material recovery bucket 47 is located below the other end of the slide rail 26. The crushing controller is further configured to determine whether the total weight exceeds a predetermined weight, and if so, drive the electric slider 27 to slide from one end of the slide rail 26 to the other end, and then drive the electromagnet 25 to stop working, so that the magnetic impurities fall into the magnetic material recycling bin 47.

This take swill three-phase separator of broken extrusion function, electro-magnet 25 can adsorb the wet rubbish that gets into to predetermine in the space of rolling in its broken system to get rid of the magnetic impurity in the wet rubbish, can avoid this kind of the great rubbish of hardness of magnetic impurity to get into on the one hand like this and predetermine the roll surface that rolls the roller in the space and cause the damage, on the other hand can carry out recycle with magnetic impurity, realizes refuse classification. Moreover, weighing sensor three 28 can detect magnetic impurity's adsorption capacity, and after magnetic impurity adsorbed total weight reached and predetermine weight, crushing controller just made electric slider earlier with these magnetic impurity slide to the other end from the one end of slide rail 26, drives electro-magnet 25 stop work again, makes these magnetic impurity fall and retrieves in magnetic material recycling bin 47, and whole recovery process is full automatic goes on, and the user only need collect the magnetic impurity in the magnetic material recycling bin 47, and is very convenient.

Example 4

Referring to fig. 18, the present embodiment provides a swill three-phase separation device with a crushing and squeezing function, wherein a moisture sensor 63 and a squeezing controller are added to a squeezing system of the swill three-phase separation device in embodiment 1. The moisture sensor 63 is used for detecting the moisture content of the kitchen swill entering the extrusion cavity 53, and can be installed in the extrusion cavity 53 into which the kitchen swill enters first.

The extrusion controller is used for judging whether the water content is smaller than a preset water content proportion I and larger than a preset water content proportion II. When the water content is smaller than the first preset water content ratio and larger than the second preset water content ratio, the extrusion controller drives the extrusion motor 55 to increase the rotation speed according to the difference between the water content and the second preset water content ratio. Wherein the increase in the rotational speed is positively correlated with the difference. The extrusion controller is also used for judging whether the water content is not more than a second preset water content ratio. When the water content is not greater than the second preset water content ratio, the extrusion controller drives the extrusion motor 55 to stop rotating.

This take swill three-phase separator of broken extrusion function, its extrusion system's moisture sensor 63 can detect the moisture content of the meal kitchen swill that gets into in the extrusion chamber 53, and the extrusion controller then can judge according to the moisture content, when the moisture content is located predetermine moisture content proportion one and predetermine between the moisture content proportion two, the extrusion controller increases the rotational speed that extrudees motor 55 according to the difference of predetermineeing moisture content proportion two and moisture content, and rotational speed increase value and difference are positive correlation, the moisture content is big more promptly, the rotational speed is then big more, can fully extrude the moisture in the meal kitchen swill like this. When the water content is smaller than the preset water content ratio II, the water content of the kitchen swill is too low, the extrusion motor 55 or the screw rod 54 can be damaged by continuing to rotate the extrusion motor 55, and therefore the extrusion controller stops rotating the extrusion motor 55, equipment is protected, and the service life of the extrusion system is prolonged.

Example 5

Referring to fig. 19 and 20, in the present embodiment, a swill three-phase separation device with a crushing and squeezing function is provided, and a detection mechanism, an oil-water separation controller, a feeding pipe 122 and a feeding valve 123 are added to an oil-water separation system of the swill three-phase separation device in embodiment 1.

The sensing mechanism is used to sense a parameter of the liquid in the wiper tank 115 and includes a level sensor 121. The liquid level sensor 121 is installed in the scraped oil tank 115, and is used to detect the level of liquid located in the scraped oil tank 115. The liquid level sensor 121 may be an existing distance measuring sensor, which can emit electromagnetic waves to the liquid level and receive the electromagnetic waves reflected by the liquid level, so as to record the time taken by the whole process, thereby calculating the distance transmitted in a single pass, and further calculating the height of the liquid level.

The number of the feeding pipes 122 is at least one, and the feeding pipes are used for conveying the oil-water mixture to the receiving space. The feeding pipe 122 can be directly connected with an external kitchen swill extruding device or a filtering device, and directly receives the oil-water mixture extruded or/and filtered. The number of feed valves 123 is at least one, and each feed valve 123 corresponds to one feed pipe 122. The feed valve 123 is installed on the feed pipe 122 and is used to open or close the corresponding feed pipe 122, of course, the feed valve 123 can also adjust the feed amount of the feed pipe 122.

The oil-water separation controller is used for judging whether the liquid level height is greater than a preset height I. When the liquid level is higher than the preset height, the oil-water separation controller drives the oil scraping motor 116 to rotate. The oil-water separation controller also calculates a height change value of the liquid level within a preset time, and adjusts the rotation speed of the oil scraping motor 116 according to the height change value of the liquid level and a preset change value-rotation speed comparison table. Wherein, the height variation value and the rotating speed have a negative correlation one-to-one comparison relationship in the variation value-rotating speed comparison table.

In this embodiment, the oil-water separation controller is further configured to determine whether the liquid level is greater than a second preset level. When the liquid level is higher than the second liquid level, the oil-water separation controller drives the feed valve 123 to close the corresponding feed pipe 122. The oil-water separation controller also calculates a height change value of the liquid level within a preset time, and adjusts the feeding amount of the feeding pipe 122 through the feeding valve 123 according to the height change value of the liquid level and a preset change value-flow comparison table comparison relation. Wherein, the height variation value and the feeding amount have a positive correlation one-to-one contrast relation in the variation value-flow rate contrast table.

Example 6

The present embodiment provides a three-phase swill separating method, which is applied to any one of the three-phase swill separating devices with the functions of crushing and squeezing provided in embodiments 1 to 5, and the three-phase separating method includes the following steps:

(1) crushing and rolling the solid matters separated by the screen plate 3, and controlling the crushing flux of the crushing system; the method for controlling the crushing flux comprises the following steps:

(1.1) detecting a first accumulated amount of wet garbage entering a preset rolling space of the crushing system in a preset time period, and simultaneously detecting a second accumulated amount of wet garbage leaving the preset rolling space in the preset time period;

(2) extruding and dehydrating the kitchen swill generated by rolling of the crushing system; the extrusion dehydration method of the kitchen swill comprises the following steps:

(2.1) feeding kitchen swill into the extrusion cavity 53 close to one end of the extrusion shell 52;

(2.2) driving the screw rod 54 to rotate, so that the kitchen swill in the extrusion cavity 53 is extruded from one end of the extrusion shell 52 to the other end, and the extruded water flows out from the water outlet 56;

(2.3) detecting the moisture content of the kitchen swill entering the extrusion cavity 53;

(2.4) judging whether the water content is smaller than a preset water content ratio I and larger than a preset water content ratio II;

(2.5) when the water content is smaller than the first preset water content ratio and larger than the second preset water content ratio, driving the extrusion motor 55 to increase the rotating speed according to the difference value between the water content and the second preset water content ratio; wherein the increase in the rotational speed is positively correlated with the difference;

(2.6) judging whether the water content is not greater than the second preset water content ratio;

(2.7) when the water content is not more than the second preset water content ratio, driving the extrusion motor 55 to stop rotating;

(3) carrying out oil-water separation on oil-water mixtures generated by the sorting system and the extrusion system; the oil-water separation method of the oil-water mixture comprises the following steps:

(3.1) detecting the liquid level of the liquid in the oil scraping mechanism;

(3.2) judging whether the liquid level height is greater than a preset height I;

(3.3) when the liquid level height is greater than the preset height, driving the oil scraping mechanism to scrape oil on the liquid;

(3.4) judging whether the liquid level height is greater than a preset height II;

(3.5) stopping conveying the oil-water mixture to the material receiving space when the liquid level height is larger than the liquid level height II;

(3.6) calculating a height variation value of the liquid level height within a preset time;

(3.7) adjusting the power of the oil scraping mechanism according to the liquid level height change value and a preset change value-power comparison table comparison relation; wherein, the height variation value and the power have a negative correlation one-to-one comparison relationship in the variation value-power comparison table.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims

1. A control method of broken throughput is applied to a swill three-phase separation device with a breaking and extruding function, and is characterized in that the swill three-phase separation device with the breaking and extruding function comprises:

a frame body (1);

a sorting system comprising a sorting platform (2) and a screen plate (3); the sorting platform (2) is arranged on the frame body (1) and is used for accommodating kitchen swill; the screen plate (3) is arranged on the sorting platform (2) and is used for solid-liquid separation of the kitchen swill;

the crushing system is used for crushing and rolling the solid wet garbage separated from the screen plate (3);

the method for controlling the crushing flux comprises the following steps:

(1.8) when the cumulative difference is larger than the third preset crushing amount, driving the crushing system to stop crushing.

2. The extrusion dehydration method of kitchen slops according to claim 1, characterized in that said crushing system comprises a crushing motor (33), at least two crushing rollers (32), a flushing mechanism, a statistical mechanism and a crushing controller; the crushing motor (33) is arranged on the frame body (1) and is used for driving the crushing roller (32) to rotate; the crushing roller (32) is rotatably arranged on the frame body (1); the two crushing rollers (32) are axially arranged in parallel, two ends of the two crushing rollers are aligned, and a preset rolling space is formed by spacing; the wet garbage enters from the same side of the two crushing rollers (32), and leaves from the same side of the two crushing rollers (32) after being crushed by the preset crushing space; the flushing mechanism comprises a plurality of spray heads (34); the spray head (34) is arranged on the frame body (1), is positioned on the same side of the two crushing rollers (32), and is used for spraying cleaning water to the roller surfaces of the crushing rollers (32).

3. The extrusion dehydration method of kitchen swill according to claim 2, characterized in that said statistical mechanism comprises a first detection component, a second detection component and a calculation module; the detection assembly I is used for detecting the first accumulated amount of wet garbage entering the preset rolling space within a preset time period; the detection assembly is used for detecting the second accumulated amount of the wet garbage leaving the preset rolling space in the preset time period; the calculation module is used for calculating the cumulative difference of the first cumulative quantity and the second cumulative quantity; wherein the cumulative difference is a difference obtained by subtracting the cumulative amount two from the cumulative amount one; the crushing controller is used for judging whether the cumulant difference is greater than a preset crushing amount I and not greater than a preset crushing amount II, and if so, driving the spray head (34) to spray the cleaning water; the crushing controller is also used for judging whether the cumulant difference is larger than the second preset crushing amount and not larger than a third preset crushing amount, if so, driving a spray head (34) to spray the cleaning water, and increasing the rotating speed of a crushing motor (33) according to the difference value between the cumulant difference and the third preset crushing amount; wherein the increase in the rotational speed is positively correlated with the difference; the crushing controller is also used for judging whether the accumulated difference is larger than the preset crushing amount III or not, and if so, driving the crushing motor (33) to stop rotating.

4. The squeezing dewatering method for kitchen slops according to claim 3, characterized in that the first detecting component includes a first slide plate (43) and a first weighing sensor (44); the first sliding plate (43) is installed on the frame body (1) and is arranged in an inclined mode, and one end, facing downwards in an inclined mode, faces the preset rolling space; the wet garbage slides into the preset rolling space from the first sliding plate (43); the first weighing sensor (44) is arranged between the frame body (1) and the first sliding plate (43) and is used for detecting the weight of wet garbage on the first sliding plate (43); wherein the calculation formula of the first accumulation amount is as follows:

in the formula, V₁Is the cumulative amount one, t is the duration of the preset time period, v₁For the speed of the wet waste sliding down on the first sliding plate (43), L₁For the sliding length of the wet waste on the first sliding plate (43), a₁The weight detected by the load cell one (44).

5. The squeezing dewatering method for kitchen slops according to claim 3, characterized in that the second detecting component includes a second sliding plate (45) and a second weighing sensor (46); the second sliding plate (45) is installed on the frame body (1) and is arranged in an inclined mode, and the inclined plane is located below the preset rolling space; the second weighing sensor (46) is arranged between the frame body (1) and the second sliding plate (45) and is used for detecting the weight of wet garbage on the second sliding plate (45); wherein the formula for calculating the second accumulation amount is as follows:

in the formula, V₂Is the cumulative amount of two, v₂Is the sliding speed L of the wet garbage on the second sliding plate (45)₂For the sliding length of the wet waste on the second sliding plate (45), a₂The weight detected by the second weighing sensor (46);

the calculation formula of the calculation module for calculating the cumulative difference is as follows:

wherein Δ is the cumulative difference.

6. The extrusion dehydration method of kitchen slops according to claim 3, characterized in that said crushing system further comprises an electromagnet (25), a slide rail (26), an electric slide block (27), and a load cell III (28); the electromagnet (25) is positioned above the preset rolling space and is used for magnetically adsorbing magnetic impurities in the wet garbage; one end of a sliding rail (26) is positioned above the preset rolling space; the electric sliding block (27) is arranged on the sliding rail (26) and can slide on the sliding rail (26); the electromagnet (25) is connected with the electric sliding block (27) through a weighing sensor III (28); the weighing sensor III (28) is used for detecting the total weight of the magnetic impurities adsorbed on the electromagnet (25); the crushing controller is also used for judging whether the total weight exceeds a preset weight, if so, the electric sliding block (27) is driven to slide from one end of the sliding rail (26) to the other end, and then the electromagnet (25) is driven to stop working, so that the magnetic impurities leave the other end of the sliding rail (26).

7. The squeezing dewatering method for kitchen slops according to claim 6, characterized in that the crushing system further includes a magnetic material recycling bin (47), the magnetic material recycling bin (47) is located below the other end of the sliding rail (26) for receiving the magnetic impurities.

8. The extrusion dehydration method of kitchen slops according to claim 6, characterized in that the electromagnet (25) is installed on the frame body (1).

9. The squeezing dehydration method of kitchen slops according to claim 6, characterized in that the slide rail (26) is installed on the frame body (1).

10. A three-phase separation method of swill, characterized in that it adopts the control method of the broken flux according to any one of claims 1-9.