CN216440544U - Centralized feeding and mixing system for stone plastic boxes - Google Patents

Abstract

The utility model relates to the technical field of stone-plastic boxes and discloses a stone-plastic box centralized feeding and mixing system, wherein two sides of the upper surface of a receiving bin are respectively communicated and connected with a vacuum feeding machine, the middle part of the left side of the vacuum feeding machine is respectively fixed with a stone-plastic box additive feeding pipeline, the upper part of the left side of the vacuum feeding machine is respectively fixed with three powder pipelines, the left parts of the three powder pipelines are respectively provided with a calcium powder bin, a stone powder bin and a talc powder bin, and the middle parts of the calcium powder bin, the stone powder bin and the talc powder bin are respectively fixedly provided with a powder vibrator. The additionally arranged vacuum feeding machine is matched with a stone plastic box auxiliary agent feeding pipeline, three powder pipelines and a functional particle feeding pipeline, so that the device can concentrate materials for mixing, and workers do not need to take out the mixed materials to be sent into the vacuum feeding machine; add the powder electromagnetic shaker who establishes and can shake calcium powder feed bin, mountain flour feed bin and the export of talcum powder feed bin, improved the discharging efficiency of device.

Description

Centralized feeding and mixing system for stone plastic boxes

Technical Field

The utility model relates to the technical field of stone plastic boxes, in particular to a stone plastic box centralized feeding and mixing system.

Background

The feeding machine is also called plastic feeding machine, which is a necessary product in waste plastic production line, and is divided into a single full-automatic vacuum feeding machine and a split high-power full-automatic vacuum feeding machine, the premix is an additive premix, which is called as additive premix for short, and is an intermediate compound feed product prepared by uniformly mixing one or more trace elements (including various trace mineral elements, various vitamins, synthetic amino acids, certain drugs and other additives) with a diluent or a carrier according to the required proportion.

A common feeding and mixing system for a stone plastic box generally weighs and mixes materials, then sends the weighed materials into a mixing machine for mixing, utilizes a vacuum pump to generate vacuum negative pressure through a vacuum feeding machine to suck the mixed materials from a feeding hole, then separates air from the materials in a filtering bin of a separating container, the materials automatically fall down due to the action of gravity, and are collected in a storage bin, but due to the adoption of the method, workers need to mix the materials firstly, take out the mixed materials and send the materials into the vacuum feeding machine, then weigh and mix other materials, so that the workers need to spend a large amount of time for mixing the materials, time and labor are wasted, and meanwhile, due to the fact that the mineral materials are large in size, pipelines are easy to be blocked, the device cannot normally operate, the working efficiency of the device is reduced, and the working requirements of the feeding and mixing system for the stone plastic box cannot be met, therefore, a centralized feeding and mixing system of the stone plastic box is provided.

SUMMERY OF THE UTILITY MODEL

Technical problem to be solved

Aiming at the defects of the prior art, the utility model provides a centralized feeding and mixing system for a stone-plastic box, which aims to solve the problems in the background art.

(II) technical scheme

In order to achieve the purpose, the utility model provides the following technical scheme: the stone plastic box centralized feeding and mixing system comprises a hot mixer, wherein a receiving bin is arranged at the bottom end of the hot mixer, a cold mixer is arranged on the right side of the receiving bin, the receiving bin is communicated with the cold mixer, two sides of the upper surface of the receiving bin are communicated and connected with a vacuum feeding machine, a stone plastic box auxiliary agent feeding pipeline is fixed in the middle of the left side of the vacuum feeding machine, a stone plastic box auxiliary agent weighing machine is arranged at the left end of the stone plastic box auxiliary agent feeding pipeline, three powder pipelines are fixed on the upper portion of the left side of the vacuum feeding machine, a calcium powder bin, a stone powder bin and a talc powder bin are respectively arranged on the left portion of each of the three powder pipelines, powder vibrators are fixedly arranged in the middle of each of the calcium powder bin, the stone powder bin and the talc powder bin, powder material pokers are arranged on the lower portions of each of the calcium powder bin, the stone powder bin and the talc powder bin, functional particle feeding pipelines are respectively fixed on the lower portion of the left side of the vacuum feeding machine, the left end of the functional particle feeding pipeline is provided with a stone-plastic box particle automatic metering scale, and the right side of the stone-plastic box particle automatic metering scale is fixedly provided with a functional particle bin.

Preferably, the Roots blower is arranged on the left side of the collecting bin, and the control cabinet is fixedly arranged on the left side of the Roots blower.

Preferably, horizontal auger delivery ware has been installed to the bottom of cold mixer, and the upper surface dress of cold mixer frame is equipped with dust collector, and the upper surface of stone plastic case auxiliary agent title material machine and talcum powder storehouse has also installed dust collector.

Preferably, the lower parts of the vacuum feeding machines are provided with powder bin discharge valves.

(III) advantageous effects

Compared with the prior art, the utility model provides a centralized feeding and mixing system for a stone-plastic box, which has the following beneficial effects:

1. this stone plastic case concentrates material loading compounding system, the vacuum material loading machine who establishes that adds can be with stone plastic case auxiliary weighing machine, calcium powder feed bin, stone powder feed bin, the material in talcum powder feed bin and the functional particle feed bin is taken out to the hot mixer and is mixed through stone plastic case auxiliary agent material loading pipeline, three powder pipelines and functional particle material loading pipeline, make the device can concentrate the material and mix, the staff need not to take out the material after mixing and send into in the vacuum material loading machine then weigh the mixture to other materials again, save time, laborsaving, the work efficiency of device has been improved;

2. this case is moulded to stone concentrates material loading compounding system adds the powder electromagnetic shaker of establishing and can shakes calcium powder feed bin, mountain flour feed bin and the export of talcum powder feed bin, has improved the discharging efficiency of device, adds the powder plectrum of establishing simultaneously and can give the decurrent effort of material, can transport the material to the transportation pipeline in for mineral material can not cause the jam to the pipeline, has guaranteed the normal operating of device.

Drawings

FIG. 1 is a schematic view of the structure of the present invention.

In the figure: 1. a hot mixer; 2. a material receiving bin; 3. a cold mixer; 4. a vacuum feeding machine; 5. a stone-plastic box additive feeding pipeline; 6. a stone-plastic box auxiliary agent weighing machine; 7. three powder pipelines; 8. a calcium powder bin; 81. a powder vibrator; 82. a powder kick-out device; 9. a stone powder bin; 10. a talc powder bin; 11. a functional particle feeding pipeline; 12. automatically weighing the stone-plastic box particles; 13. a functional particle bin; 14. a Roots blower; 15. a control cabinet; 16. a horizontal screw conveyor; 17. a dust removal device; 18. powder bin emptying valve.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The utility model provides a technical scheme, a centralized feeding and mixing system of a stone-plastic box comprises a hot mixer 1, a receiving bin 2, a cold mixer 3, a vacuum feeding machine 4, a stone-plastic box auxiliary agent feeding pipeline 5, a stone-plastic box auxiliary agent weighing machine 6, three powder pipelines 7, a calcium powder bin 8, a powder vibrator 81, a powder kickoff 82, a stone powder bin 9, a talcum powder bin 10, a functional particle feeding pipeline 11, an automatic stone-plastic box particle metering scale 12, a functional particle bin 13, a Roots blower 14, a control cabinet 15, a horizontal spiral conveyor 16, a dust removal device 17 and a powder bin discharge valve 18, referring to figure 1, the bottom end of the hot mixer 1 is provided with the receiving bin 2, the hot mixer 1 is used for mixing materials, the receiving bin 2 is used for storing the fed materials, the left side of the receiving bin 2 is provided with the Roots blower 14, and the left side of the Roots blower 14 is fixedly provided with the control cabinet 15, the parts of the device are controlled by a control cabinet 15, the cold mixer 3 is arranged on the right side of the material receiving bin 2, the material receiving bin 2 is communicated with the cold mixer 3, the materials mixed by the hot mixer 1 enter the cold mixer 3 to be secondarily mixed, so that the materials can be further uniformly mixed, two sides of the upper surface of the material receiving bin 2 are communicated and connected with a vacuum feeding machine 4, powder bin discharge valves 18 are arranged on the lower parts of the vacuum feeding machine 4, a stone-plastic box additive feeding pipeline 5 is fixed on the middle part of the left side of the vacuum feeding machine 4, a stone-plastic box additive weighing machine 6 is arranged at the left end of the stone-plastic box additive feeding pipeline 5, three powder pipelines 7 are fixed on the upper part of the left side of the vacuum feeding machine 4, a calcium powder bin 8, a stone powder bin 9 and a talcum powder bin 10 are respectively arranged on the left parts of the three powder pipelines 7, powder bins 8, 9 and talcum powder bins 81 are respectively fixed on the middle parts of the calcium powder bin 8, the stone powder bin 9 and the talcum powder bin 10, the lower parts of the calcium powder bin 8, the stone powder bin 9 and the talcum powder bin 10 are respectively provided with a powder kickoff 82, the powder vibrator 81 can vibrate outlets of the calcium powder bin 8, the stone powder bin 9 and the talcum powder bin 10, the discharging efficiency of the device is improved, the powder kickoff 82 can give downward acting force to materials and can transport the materials to a transport pipeline, the lower part of the left side of the vacuum feeding machine 4 is fixedly provided with a functional particle feeding pipeline 11, the left end of the functional particle feeding pipeline 11 is provided with an automatic stone-plastic box particle metering scale 12, the right side of the automatic stone-plastic box particle metering scale 12 is fixedly provided with a functional particle bin 13, the automatic stone-plastic box particle metering scale 12 is used for weighing the materials in the functional particle bin 13, the vacuum feeding machine 4 is started to weigh the auxiliary stone-plastic box additive weighing 6 through the auxiliary feeding pipeline 5, the three powder pipelines 7 and the functional particle feeding pipeline 11, Materials in the calcium powder bin 8, the stone powder bin 9, the talcum powder bin 10 and the functional particle bin 13 are pumped out to the hot mixer 1 to be mixed, the horizontal spiral conveyor 16 is installed at the bottom of the cold mixer 3, the dust removal device 17 is installed on the upper surface of the frame of the cold mixer 3, and the dust removal device 17 is also installed on the upper surfaces of the stone plastic box auxiliary agent weighing machine 6 and the talcum powder bin 10.

The working principle of the device is as follows: firstly, proper materials are classified and placed into a stone plastic box additive weighing machine 6, a calcium powder bin 8, a stone powder bin 9, a talcum powder bin 10 and a functional particle bin 13, then a vacuum feeding machine 4 is started to pump the materials in the stone plastic box additive weighing machine 6, the calcium powder bin 8, the stone powder bin 9, the talcum powder bin 10 and the functional particle bin 13 out to a hot mixer 1 for mixing through a stone plastic box additive feeding pipeline 5, three powder pipelines 7 and a functional particle feeding pipeline 11, a powder vibrator 81 can vibrate outlets of the calcium powder bin 8, the stone powder bin 9 and the talcum powder bin 10, the discharging efficiency of the device is improved, a powder kickoff 82 can give downward acting force to the materials, the materials can be conveyed to a conveying pipeline, so that the mineral materials cannot block the pipeline, the normal operation of the device is ensured, the materials mixed by the hot mixer 1 can enter the cold mixer 3 for secondary mixing, make the misce bene that the material can be further, flow into in receiving storehouse 2 at last for the device can concentrate the material and mix, and the staff need not to take out the material after mixing and send into in vacuum feeding machine 4 then weigh other materials and mix, saves time, laborsaving, has improved the work efficiency of device.

The operation flow of the device is as follows:

and (4) running for the first time, clicking a main interface of a control screen to continuously meter to switch to single metering, and switching manual feeding to automatic feeding.

The first step is as follows: metering and feeding

The metering system starts to operate automatically by pressing a metering start button of the control cabinet 15, and the vacuum feeding machine 4 starts to suck materials automatically when the weights of the powder, the first small materials and the granular materials reach set values.

The second step is that: discharge start-up

When the powder suction is finished, the discharging start button of the control cabinet 15 can be pressed, the discharging valve 18 of the powder bin is opened, and the hot mixer 1 is placed in the powder bin, and meanwhile, the hot mixer 1 automatically operates. And if the other materials are not metered or sucked completely, the metering or sucking is continued.

The third step: discharging of activating agent

The material temperature of the hot mixer 1 reaches the set temperature (105 ℃), the first small material (activating agent) is put into the hot mixer 1, and the activation time is 180S.

The fourth step: discharging of granular material and second small material

And when the activation time reaches 180S, automatically putting the second small materials and the granules into the hot mixer 1.

The fifth step: thermal mixer 1 discharge

When the mixing temperature reaches 120 ℃ (the current is about 180-200A), the hot mixer 1 automatically discharges materials and starts.

And a sixth step: the cold mixer 3 is operated

The hot mixer 1 is put into the cold mixer 3, and the cold mixer 3 is automatically started. The cold water circulating system is automatically started according to the set material temperature.

If continuous operation is needed, the single metering is switched to continuous metering by clicking the main interface of the control screen, manual feeding is switched to automatic feeding, and the system continues to perform the next cycle action after completing one cycle action.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (4)

1. Mould case and concentrate material loading compounding system, including hot mixer (1), its characterized in that: the bottom of the hot mixer (1) is provided with a receiving bin (2), the right side of the receiving bin (2) is provided with a cold mixer (3), the receiving bin (2) is communicated with the cold mixer (3), both sides of the upper surface of the receiving bin (2) are communicated with a vacuum feeding machine (4), the middle of the left side of the vacuum feeding machine (4) is fixedly provided with a stone-plastic box auxiliary agent feeding pipeline (5), the left end of the stone-plastic box auxiliary agent feeding pipeline (5) is provided with a stone-plastic box auxiliary agent weighing machine (6), the upper part of the left side of the vacuum feeding machine (4) is fixedly provided with three powder pipelines (7), the left parts of the three powder pipelines (7) are respectively provided with a calcium powder bin (8), a stone powder bin (9) and a talcum powder bin (10), the middle parts of the calcium powder bin (8), the stone powder bin (9) and the talcum powder bin (10) are fixedly provided with a powder vibrator (81), the lower part of calcium powder feed bin (8), mountain flour feed bin (9) and talcum powder feed bin (10) all is equipped with powder setting gauge (82), the left side lower part of vacuum feeding machine (4) all is fixed with functional particle feeding pipeline (11), the left end of functional particle feeding pipeline (11) has been installed stone and has been moulded case granule automatic measurement and call (12), the right side fixed mounting that the case granule automatic measurement was called (12) is moulded to stone has functional particle feed bin (13).

2. A stone-plastic box centralized feeding and mixing system as recited in claim 1, characterized in that: the left side of the collecting bin (2) is provided with a Roots blower (14), and the left side of the Roots blower (14) is fixedly provided with a control cabinet (15).

3. A stone-plastic box centralized feeding and mixing system as recited in claim 1, characterized in that: horizontal screw conveyor (16) have been installed to the bottom of cold blender (3), and the upper surface dress of cold blender (3) frame is equipped with dust collector (17), and dust collector (17) have also been installed to the upper surface of stone plastic case auxiliary agent title material machine (6) and talcum powder feed bin (10).

4. A stone-plastic box centralized feeding and mixing system as recited in claim 1, characterized in that: the lower parts of the vacuum feeding machines (4) are provided with powder bin discharge valves (18).

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