CN209755787U - automatic energy-saving granulating equipment - Google Patents

Abstract

the utility model discloses an automatic change energy-conserving granulation equipment, it includes: the device comprises a reaction kettle mechanism, an extrusion mechanism, a cooling mechanism, a cutting mechanism, a conveying mechanism, a dehydration discharging mechanism, a wastewater circulating and filtering mechanism and a machine table. The utility model discloses an adopt reation kettle mechanism, extrusion mechanism, cooling body, cutting mechanism, conveying mechanism, dehydration discharge mechanism and wastewater circulating filtration mechanism's structural design, one-stop is the former material of plastics from the reaction to the extrusion, from extrusion to cutting grain processing, and the product yield is high, and is safe high-efficient to increase substantially work efficiency, the practicality is strong.

Description

Automatic energy-saving granulating equipment

Technical Field

the utility model relates to a granulation production technical field, in particular to change energy-conserving granulation equipment.

Background

the plastic is a new material, and the new material refers to a structural material with excellent performance and a functional material with special properties which are newly developed or are being developed. The new material has wide application, and needs the support of a plurality of new materials along with the rapid development of modern science and technology. Similarly, the emergence of new materials will drive the rapid development of related industries and technologies, and even bring forth new industries and technologies. The plastic cement has good prospect, is widely applied to various aspects of industry or life, particularly the application of new plastics, gradually replaces some building materials such as metal wood and the like, has wide application, has large market demand and needs large-scale processing and manufacturing.

At present, the traditional whole reaction kettle equipment only has the functions of mixing, stirring, heating, evaporating and cooling plastic raw materials, but along with the continuous development of the society and the continuous improvement of the technical level, the function of the traditional whole reaction kettle equipment is too single, and the current processing requirement cannot be met. Meanwhile, the existing extruders and granulators are also the same, and only have single functions. In the contemporary society where a large amount of plastic materials are used, the productivity is low, and it is too time-consuming and labor-consuming to operate and carry the materials manually, and meanwhile, the power consumption of the conventional method using an extruder as a melt pushing device is very large, which is an unsolved problem in the field.

Therefore, the utility model provides a collect reation kettle mechanism, extruding means, cutting mechanism, conveying mechanism, dehydration discharge mechanism and waste water circulating filtration mechanism in the automatic energy-conserving granulation equipment of an organic whole solve above problem.

SUMMERY OF THE UTILITY MODEL

the utility model provides a technical problem be to the defect that exists among the above-mentioned prior art, an automatic change energy-conserving granulation equipment is provided, through adopting reation kettle mechanism, extruding means, cutting mechanism, conveying mechanism, dehydration discharge mechanism and waste water circulating and filtering mechanism's structural design, one-stop is former material from reacting to the extrusion with plastics, from extrusion to cutting grain processing, its the hand labor who significantly reduces and manufacturing cost, product yield is high, and is safe high-efficient, and increase substantially work efficiency, with the problem of proposing in solving above-mentioned background art.

in order to solve the technical problem, the utility model discloses the technical scheme who takes as follows:

an automated energy efficient pelletizing apparatus comprising:

The reaction kettle mechanism is used for mixing, stirring, heating, polymerizing, evaporating and cooling the plastic raw materials to form a plastic primary finished product;

The extrusion mechanism is connected with the reaction kettle mechanism through a pipeline and is used for carrying out extrusion molding on the plastic processed by the reaction kettle mechanism to form a plastic semi-finished product;

The cooling mechanism is arranged between the extruding mechanism and the cutting mechanism and is used for rapidly cooling the plastic melt extruded by the extruding mechanism;

The cutting mechanism is arranged opposite to the extrusion mechanism and is used for carrying out a granulating process on the plastic cement extruded by the extrusion mechanism to form a granulated plastic cement finished product;

The conveying mechanism is arranged at the lower end of the cutting position of the extruding mechanism and the cutting mechanism and is used for receiving granulated plastic finished products and cooling water cut by the cutting mechanism;

the dehydration discharging mechanism is connected with the conveying mechanism through a pipeline and is used for separating the granulated plastic finished products from the cooling water, conveying the granulated plastic finished products to an outlet and conveying the cooling water to the wastewater circulating and filtering mechanism;

the waste water circulating and filtering mechanism is used for filtering the cooling water and sending the cooling water to the circulating water storage tank again for recycling;

The machine table is used for installing and fixing the reaction kettle mechanism, the extruding mechanism, the cooling mechanism, the cutting mechanism, the conveying mechanism, the dehydration discharging mechanism and the wastewater circulating and filtering mechanism.

the machine table comprises a machine case and a machine cabinet, the machine cabinet is arranged at the front end of the machine case, the reaction kettle mechanism is arranged in the machine case, the extruding mechanism, the cooling mechanism and the cutting mechanism are all arranged at the upper end of the machine cabinet, the conveying mechanism is arranged in the machine cabinet, the dehydration discharging mechanism is arranged at one side of the machine case and is located at the rear end of the machine cabinet, and the wastewater circulating and filtering mechanism is arranged in the machine case.

The reaction kettle mechanism comprises a first reaction kettle component and a second reaction kettle component, wherein the first reaction kettle component and the second reaction kettle component respectively comprise a reaction kettle feed inlet, a charging basket connected with the reaction kettle feed inlet, a reaction kettle motor arranged at the upper end of the charging basket, a stirring component and a heating component arranged inside the charging basket, and a reaction kettle discharge port arranged at the lower end of the charging basket, and the reaction kettle discharge port is connected with an extrusion mechanism through a pipeline.

the extrusion mechanism comprises an extrusion feed inlet, an extrusion pump, a static cooler, a machine head and an extrusion module, wherein the extrusion feed inlet is communicated with the discharge port of the reaction kettle, the static cooler is arranged at the front end of the extrusion pump, the machine head is arranged at the rear end of the static cooler, the extrusion module is arranged at the front end of the machine head, the static cooler comprises an outer cavity and an inner cavity, an extrusion screw is arranged in the inner cavity, the extrusion pump is used for providing power for the extrusion screw, and a circulating cooling water channel is arranged between the outer cavity and the.

the cutting mechanism comprises a sliding assembly, a cutting motor, a bearing assembly and a cutter assembly, the cutter assembly and the extrusion module are arranged oppositely, the cutter assembly is sleeved on the bearing assembly, the bearing assembly is sleeved on a rotating shaft of the cutting motor, the cutting motor is fixed on the sliding assembly, the cooling mechanism comprises a cooling water conveying pipeline and a cooling water spray head, the cooling water spray head is arranged above the joint of the cutter assembly and the extrusion module, and the cooling water conveying pipeline is communicated with the wastewater circulating and filtering mechanism.

The conveying mechanism comprises a storage box and a water pump, the storage box is used for storing granulated plastics after the cutting procedure and cooling water used in the cutting procedure, and the storage box conveys the granulated plastics after the storage cutting procedure and the cooling water used in the cutting procedure to the dehydration discharging mechanism through the water pump and a pipeline.

the dehydration discharging mechanism comprises a mixture feeding port communicated with the storage box, a mixture storage box communicated with the mixture feeding port, a granulated plastic pumping-out pump, a cooling water pumping-out pump and a granulated plastic discharging port, the mixture storage box is provided with a mixture isolating net, the net diameter of the mixture isolating net is smaller than the grain diameter of the granulated plastic, the mixture storage box conveys the granulated plastic to the granulated plastic discharging port through the granulated plastic pumping-out pump and a pipeline, and the mixture storage box conveys the cooling water used in the cutting process to the wastewater circulating and filtering mechanism through the cooling water pumping-out pump and the pipeline.

The waste water circulating and filtering mechanism comprises a filtering water inlet, a sewage water storage tank and a circulating water storage tank, the filtering water inlet is communicated with the mixture storage tank, the sewage water storage tank comprises a pollutant isolation net and a pollutant isolation bag, the pollutant isolation net and the pollutant isolation bag are used for filtering pollutants of cooling water used in the cutting process, the circulating water storage tank is communicated with the sewage water storage tank, and the circulating water storage tank is communicated with a cooling water conveying pipeline of the cooling mechanism.

Compared with the prior art, the beneficial effects of the utility model reside in that: the utility model has the advantages of reasonable design and novel structure, the reaction kettle mechanism, the extrusion mechanism, the cutting mechanism, the conveying mechanism, the dehydration discharging mechanism and the wastewater circulating and filtering mechanism are integrated, the plastic raw material is extruded from the reaction to the extrusion in a one-stop way, the plastic raw material is extruded from the extrusion to the grain-sized dicing treatment, wherein, the plastic material is mixed, stirred, heated, evaporated and cooled through the structural design of the reaction kettle mechanism, the plastic material is pressurized and formed through the extrusion mechanism, then, the formed plastic material is cut into grains through the cutting material, finally, the granulated plastic is dehydrated and separated from the cooling water, the final process is completed, the labor force and the production cost are greatly reduced, the yield of the product is high, the plastic forming effect is good, the cutting surface is flat, the cooling water is supplied to the cooling mechanism for recycling again after being filtered through the structural design of the wastewater circulating and filtering, meanwhile, the high-pressure pump is used as a melt propeller, so that the power consumption is reduced to less than one tenth of the original power consumption, the energy consumption is greatly reduced, the safety and the high efficiency are realized, the working efficiency is greatly improved, and the aim of automatic processing is fulfilled.

Drawings

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

Fig. 2 is a schematic view of the internal structure of the present invention;

Fig. 3 is a schematic view of a partial structure of the present invention.

In the figure: 1. the device comprises a reaction kettle mechanism, 2, an extrusion mechanism, 3, a cutting mechanism, 4, a conveying mechanism, 5, a dehydration discharging mechanism, 6, a wastewater circulating filtering mechanism, 7 and a machine table.

Detailed Description

the present invention will be described in further detail with reference to fig. 1 to 3.

The embodiments described by referring to the drawings are exemplary and intended to be used for explaining the present application and are not to be construed as limiting the present application. In the description of the present application, it is to be understood that the terms "center," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the present application and for simplicity in description, and are not intended to indicate or imply that the referenced devices or elements must have a particular orientation, be constructed in a particular orientation, and be operated in a particular manner, and thus should not be considered limiting. Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, "a plurality" means two or more unless specifically limited otherwise. In this application, unless expressly stated or limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can include, for example, fixed connections, removable connections, or integral connections; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate. In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact of the first and second features, or may comprise contact of the first and second features not directly but through another feature in between. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly above and obliquely above the second feature, or simply meaning that the first feature is at a lesser level than the second feature.

As shown in the figures 1-3 of the drawings,

An automated energy efficient pelletizing apparatus comprising:

The reaction kettle mechanism 1 is used for mixing, stirring, heating, polymerizing, evaporating and cooling plastic raw materials to form a plastic primary finished product;

The extruding mechanism 2 is connected with the reaction kettle mechanism 1 through a pipeline, and is used for extruding and molding the plastic processed by the reaction kettle mechanism 1 to form a plastic semi-finished product;

The cooling mechanism is arranged between the extruding mechanism 2 and the cutting mechanism 3 and is used for rapidly cooling the plastic melt extruded by the extruding mechanism 2;

the cutting mechanism 3 is arranged opposite to the extruding mechanism 2, and is used for carrying out a granulating process on the plastic cement formed by extrusion of the extruding mechanism 2 to form a granulated plastic cement finished product;

the conveying mechanism 4 is arranged at the lower end of the cutting position of the extruding mechanism 2 and the cutting mechanism 3, and is used for receiving granulated plastic finished products and cooling water cut by the cutting mechanism 3;

A dewatering and discharging mechanism 5, wherein the dewatering and discharging mechanism 5 is connected with the conveying mechanism 4 through a pipeline, and is used for separating the granulated plastic finished products from the cooling water, conveying the granulated plastic finished products to an outlet, and conveying the cooling water to a wastewater circulating and filtering mechanism 6;

The waste water circulating and filtering mechanism 6 is used for filtering the cooling water and sending the cooling water to the circulating water storage tank again for recycling;

And the machine table 7 is used for installing and fixing the reaction kettle mechanism 1, the extruding mechanism 2, the cooling mechanism, the cutting mechanism 3, the conveying mechanism 4, the dehydration discharging mechanism 5 and the wastewater circulating and filtering mechanism 6.

as a further improvement of the utility model, the board 7 includes quick-witted case 71 and rack 72, the rack 72 sets up in the front end of quick-witted case 71, reation kettle mechanism 1 sets up in the inside of quick-witted case, extruding means 2, cooling body and cutting mechanism 3 all set up in the upper end of rack 72, conveying mechanism 4 sets up in the inside of rack 72, dehydration discharge mechanism 5 sets up in one side of quick-witted case 71 and is located the rear end of rack 72, waste water circulating and filtering mechanism 6 sets up in the inside of quick-witted case 71.

as a further improvement of the utility model, reation kettle mechanism 1 includes first reation kettle subassembly 11 and second reation kettle subassembly 12, first reation kettle subassembly 11 and second reation kettle subassembly 12 all include reation kettle feed inlet 13, the storage bucket 14 that is connected with reation kettle feed inlet 13, set up in the reation kettle motor 15 of 14 upper ends of storage bucket, set up in 14 inside stirring subassembly and the heating element of storage bucket, and set up in the reation kettle discharge gate 16 of 14 lower extremes of storage bucket, reation kettle discharge gate 16 is connected with extrusion mechanism 2 through the pipeline.

as a further improvement, the extrusion mechanism 2 includes that the extrusion feed inlet 21, the extrusion pump 22 that are linked together with above-mentioned reation kettle discharge gate 16, set up in the static cooler 23 of extrusion pump 22 front end, set up in the aircraft nose 24 of static cooler 23 rear end and install in the module 25 of extruding of 24 front ends of aircraft nose, static cooler 23 includes exocoel and inner chamber, the inside of inner chamber is provided with extrudes the screw rod, the extrusion pump 22 is used for providing power for extruding the screw rod, be provided with the circulation water course between exocoel and the inner chamber.

as a further improvement, the cutting mechanism 3 includes drive assembly 31, cutting motor 32, bearing assembly 33, cutter assembly 34 and cooling water shower nozzle 35, cutter assembly 34 with extrude that module 25 sets up relatively, cutter assembly 34 overlaps and locates on bearing assembly 33, the pivot of cutting motor 32 is located to bearing assembly 33 cover, cutting motor 32 is fixed in on the drive assembly 31, cooling water shower nozzle 35 sets up in cutter assembly 34 and the top of extruding module 25 junction, cooling water shower nozzle 35 is linked together through pipeline and waste water circulating and filtering mechanism 6.

as a further improvement of the present invention, the conveying mechanism 4 includes a storage box 41 and a water pump 42, the storage box 41 is used for storing the granulated plastic after the cutting process and the cooling water used during the cutting process, the storage box 41 is used for conveying the granulated plastic after the storage cutting process and the cooling water used during the cutting process to the dewatering and discharging mechanism 5 through the water pump 42 and the pipeline.

as a further improvement of the present invention, the dewatering and discharging mechanism 5 includes a mixture feed port communicated with the storage box 41, a mixture storage box communicated with the mixture feed port, a granulated plastic extraction pump, a cooling water extraction pump, and a granulated plastic discharge port 51, the mixture storage box is provided with a mixture separation net, the net diameter of the mixture separation net is smaller than the particle diameter of the granulated plastic, the mixture storage box delivers the granulated plastic to the granulated plastic discharge port 51 through the granulated plastic extraction pump and the pipe, and the mixture storage box delivers the cooling water used when the cutting process is carried to the wastewater circulating and filtering mechanism 6 through the cooling water extraction pump and the pipe.

As a further improvement, the wastewater circulating and filtering mechanism 6 comprises a filtering water inlet, a sewage storage tank and a circulating water storage tank, the filtering water inlet is communicated with the mixture storage tank, the sewage storage tank comprises a pollutant isolation net and a pollutant isolation bag, the pollutant isolation net and the pollutant isolation bag are used for filtering pollutants of cooling water used in the cutting process, the circulating water storage tank is communicated with the sewage storage tank, and the circulating water storage tank is communicated with a cooling water nozzle of the cutting mechanism.

Simultaneously the utility model discloses still provide an automatic change granulation method of energy-conserving granulation equipment, its step includes:

(1) processing plastic raw materials, wherein the plastic raw materials enter a charging basket through a reaction kettle feeding hole of a reaction kettle mechanism, a stirring component of the reaction kettle mechanism is driven by a reaction kettle motor to carry out a mixing and stirring process on the plastic raw materials in the charging basket, meanwhile, a heating component of the reaction kettle mechanism carries out a heating process on the plastic raw materials in the charging basket, so that a polymerization reaction occurs among the plastic raw materials, after the polymerization reaction of the plastic raw materials is finished, the reaction kettle mechanism carries out an evaporation and cooling process on the plastic raw materials, and finally, after the evaporation and cooling process is finished, a plastic primary product is conveyed to an extrusion mechanism through a reaction kettle discharging hole and a pipeline;

(2) After the plastic semi-finished product is cooled, the plastic semi-finished product is conveyed to a machine head through a cooling pipeline of a static cooler, and then the plastic semi-finished product is conveyed to an extrusion module at the front end of the machine head;

(3) Cutting and cooling the plastic semi-finished product, after the plastic semi-finished product is conveyed to an extrusion module at the front end of a machine head, a sliding assembly of a cutting mechanism drives a cutting motor to reach a specified position, a cutter assembly arranged on the cutting motor carries out a cutting procedure on the plastic semi-finished product extruded and molded by the extrusion module to form a granulated plastic finished product, and the cooling mechanism sprays cooling water to cool a cutting processing part while the cutting procedure is carried out, so that the cutting procedure can be stably carried out for a long time;

(4) Conveying the granulated plastic finished product and cooling water, wherein after the plastic semi-finished product is cut into the granulated plastic finished product, the granulated plastic finished product and the cooling water fall freely into a storage box of a conveying mechanism together, and the granulated plastic finished product and the cooling water in the storage box are conveyed to a dehydration discharging mechanism by a water pump;

(5) Separating the granulated plastic finished product from the wastewater, after the granulated plastic finished product and the cooling water in the storage box are conveyed to a dehydration discharging mechanism by a water pump, the mixture of the granulated plastic finished product and the cooling water enters the mixture storage box through a mixture feeding port, the granulated plastic finished product is conveyed to a granulated plastic discharging port by a granulated plastic extracting pump, and the cooling water is conveyed to a wastewater circulating filtering mechanism by a cooling water extracting pump;

(6) And discharging the granulated plastic product and recycling the waste water, wherein the granulated plastic product is discharged after reaching a granulated plastic discharge port, the granulated plastic discharge port is opened for discharging, meanwhile, after the cooling water reaches the waste water circulating and filtering mechanism, waste residue is filtered through a pollutant isolating net and a pollutant isolating bag of the waste water circulating and filtering mechanism, and the filtered cooling water is conveyed to the cooling mechanism again for recycling.

The above is not intended to limit the technical scope of the present invention, and any modifications, equivalent changes and modifications made to the above embodiments according to the technical spirit of the present invention are all within the scope of the technical solution of the present invention.

Claims (8)

1. An automatic energy-saving granulation equipment, characterized by comprising:

The reaction kettle mechanism is used for mixing, stirring, heating, polymerizing, evaporating and cooling the plastic raw materials to form a plastic primary finished product;

the extrusion mechanism is connected with the reaction kettle mechanism through a pipeline and is used for carrying out extrusion molding on the plastic processed by the reaction kettle mechanism to form a plastic semi-finished product;

The cooling mechanism is arranged between the extruding mechanism and the cutting mechanism and is used for rapidly cooling the plastic melt extruded by the extruding mechanism;

The cutting mechanism is arranged opposite to the extrusion mechanism and is used for carrying out a granulating process on the plastic cement extruded by the extrusion mechanism to form a granulated plastic cement finished product;

The conveying mechanism is arranged at the lower end of the cutting position of the extruding mechanism and the cutting mechanism and is used for receiving granulated plastic finished products and cooling water cut by the cutting mechanism;

The dehydration discharging mechanism is connected with the conveying mechanism through a pipeline and is used for separating the granulated plastic finished products from the cooling water, conveying the granulated plastic finished products to an outlet and conveying the cooling water to the wastewater circulating and filtering mechanism;

The waste water circulating and filtering mechanism is used for filtering the cooling water and sending the cooling water to the circulating water storage tank again for recycling;

The machine table is used for installing and fixing the reaction kettle mechanism, the extruding mechanism, the cooling mechanism, the cutting mechanism, the conveying mechanism, the dehydration discharging mechanism and the wastewater circulating and filtering mechanism.

2. The automatic energy-saving granulation equipment as claimed in claim 1, wherein the machine platform comprises a machine box and a machine cabinet, the machine cabinet is arranged at the front end of the machine box, the reaction kettle mechanism is arranged inside the machine box, the extrusion mechanism, the cooling mechanism and the cutting mechanism are arranged at the upper end of the machine cabinet, the conveying mechanism is arranged inside the machine cabinet, the dehydration discharging mechanism is arranged at one side of the machine box and located at the rear end of the machine cabinet, and the wastewater circulating and filtering mechanism is arranged inside the machine box.

3. The automatic energy-saving granulation equipment as claimed in claim 2, wherein the reaction kettle mechanism comprises a first reaction kettle component and a second reaction kettle component, the first reaction kettle component and the second reaction kettle component both comprise a reaction kettle feed inlet, a charging basket connected with the reaction kettle feed inlet, a reaction kettle motor arranged at the upper end of the charging basket, a stirring component and a heating component arranged inside the charging basket, and a reaction kettle discharge outlet arranged at the lower end of the charging basket, and the reaction kettle discharge outlet is connected with the extrusion mechanism through a pipeline.

4. The automatic energy-saving granulation equipment as claimed in claim 3, wherein the extrusion mechanism comprises an extrusion feed inlet communicated with the discharge port of the reaction kettle, an extrusion pump, a static cooler arranged at the front end of the extrusion pump, a machine head arranged at the rear end of the static cooler and an extrusion module arranged at the front end of the machine head, the static cooler comprises an outer cavity and an inner cavity, an extrusion screw is arranged inside the inner cavity, the extrusion pump is used for providing power for the extrusion screw, and a circulating cooling water channel is arranged between the outer cavity and the inner cavity.

5. the automatic energy-saving granulating equipment of claim 4, wherein the cutting mechanism comprises a sliding assembly, a cutting motor, a bearing assembly and a cutter assembly, the cutter assembly and the extrusion module are oppositely arranged, the cutter assembly is sleeved on the bearing assembly, the bearing assembly is sleeved on a rotating shaft of the cutting motor, the cutting motor is fixed on the sliding assembly, the cooling mechanism comprises a cooling water conveying pipeline and a cooling water spray head, the cooling water spray head is arranged above the joint of the cutter assembly and the extrusion module, and the cooling water conveying pipeline is communicated with the wastewater circulating and filtering mechanism.

6. the automatic energy-saving granulating apparatus as claimed in claim 5, wherein the conveying mechanism comprises a storage tank and a water pump, the storage tank is used for storing the granulated plastics after the cutting process and the cooling water used in the cutting process, and the storage tank conveys the granulated plastics after the cutting process and the cooling water used in the cutting process to the dewatering and discharging mechanism through the water pump and a pipeline.

7. the automatic energy-saving granulating apparatus as claimed in claim 6, wherein the dewatering discharging mechanism comprises a mixture inlet communicating with the storage tank, a mixture storage tank communicating with the mixture inlet, a granulated plastic extracting pump, a cooling water extracting pump and a granulated plastic outlet, the mixture storage tank is provided with a mixture separating net, the net diameter of the mixture separating net is smaller than the grain diameter of the granulated plastic, the mixture storage tank conveys the granulated plastic to the granulated plastic outlet through the granulated plastic extracting pump and a pipeline, and the mixture storage tank conveys the cooling water used in the cutting process to the waste water circulating filtering mechanism through the cooling water extracting pump and the pipeline.

8. the automatic energy-saving granulation equipment as claimed in claim 7, wherein the wastewater circulating and filtering mechanism comprises a filtering water inlet, a wastewater water storage tank and a circulating water storage tank, the filtering water inlet is communicated with the mixture storage tank, the wastewater water storage tank comprises a pollutant isolation net and a pollutant isolation bag, the pollutant isolation net and the pollutant isolation bag are used for filtering pollutants in cooling water used in the cutting process, the circulating water storage tank is communicated with the wastewater water storage tank, and the circulating water storage tank is communicated with a cooling water conveying pipeline of the cooling mechanism.