CN212916011U - Small-size fluid energy mill with multiple raw materials processing - Google Patents

Small-size fluid energy mill with multiple raw materials processing Download PDF

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Publication number
CN212916011U
CN212916011U CN202021521923.9U CN202021521923U CN212916011U CN 212916011 U CN212916011 U CN 212916011U CN 202021521923 U CN202021521923 U CN 202021521923U CN 212916011 U CN212916011 U CN 212916011U
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China
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chamber
dust collection
dust collecting
collection chamber
crushing
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CN202021521923.9U
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Chinese (zh)
Inventor
周斌
沈仙林
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Henan Jinqu Yintong Metal Material Co ltd
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Henan Jinqu Yintong Metal Material Co ltd
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Abstract

The utility model discloses a small-size fluid energy mill with multiple raw materials processing, including compression chamber, vibration feed chamber, crushing chamber, cyclone and second dust collecting chamber, the fixed compression chamber that is equipped with in bottom of rubbing crusher body, the inside of rubbing crusher body is fixed with crushing chamber, and smashes the chamber and pass through the compressed air import and be connected with the compression chamber, it has the vibration feed chamber to smash chamber top through connection, one side of vibration feed chamber is connected with cyclone, cyclone's below through connection has first dust collecting chamber, and one side outer wall of first dust collecting chamber fixes on one side inner wall of rubbing crusher body, there is the second dust collecting chamber below of first dust collecting chamber through the pipe connection, and the second dust collecting chamber is located the top of compression chamber. The utility model discloses an install the vibration feed chamber, through controlling means's single feeding volume, can avoid the too much emergence of the insufficient phenomenon of smashing that leads to of device single crushing work volume, improve the crushing efficiency of device.

Description

Small-size fluid energy mill with multiple raw materials processing
Technical Field
The utility model relates to a reducing mechanism technical field specifically is a small-size fluid energy mill with multiple raw materials processing.
Background
The metal powder is light in weight and good in light and heat reflection performance, and is widely applied to the fields of devices on metal surfaces, corrosion prevention and heat preservation of heating devices, but in the production process of the metal powder, besides silver ingot ore blocks, some lubricating particles are needed to avoid aggregation of silver simple substances in the crushing process, so that impurities and lubricating particles in the silver ingots are required to be screened after the ore is crushed, and the purity and the quality of the metal powder are guaranteed.
The existing device has the defects that: present metal powder production reducing mechanism is when carrying out metal powder's production, often direct disposable throws the material to device inside, lead to inside when carrying out shredding of device, very easily because single crushing work load is too much, lead to some material to fail effectively to accomplish shredding, the efficiency that leads to device production metal powder is not high, and need to do over again many times smash, the mechanical consumption of device has been increased, the manufacturing cost of device has been promoted, mechanical life has been shortened.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a small-size fluid energy mill with multiple raw materials processing to solve the problem that proposes in the above-mentioned background art.
In order to achieve the above object, the utility model provides a following technical scheme: a small-sized jet mill with multiple raw material processing comprises a compression chamber, a mill body, a vibration feeding chamber, a milling chamber, a first dust collecting chamber, a cyclone separator and a second dust collecting chamber, wherein the compression chamber is fixedly arranged at the bottom of the mill body, the milling chamber is fixedly arranged in the mill body and is connected with the compression chamber through a compressed air inlet, the vibration feeding chamber is connected above the milling chamber in a penetrating way, one side of the vibration feeding chamber is connected with the cyclone separator through a gas transmission pipeline, the first dust collecting chamber is connected below the cyclone separator in a penetrating way, the outer wall of one side of the first dust collecting chamber is fixed on the inner wall of one side of the mill body through a bolt, the second dust collecting chamber is connected below the first dust collecting chamber through a pipeline and is positioned above the compression chamber, a vibration motor is fixed in the vibration feeding chamber through a supporting seat, the output of vibrating motor is connected with the connecting rod of a set of symmetric distribution, and has certain contained angle between connecting rod and vibrating motor, and the top welded mounting of connecting rod has the stock guide, and the stock guide passes through the axostylus axostyle and connects.
The inside of compression chamber is fixed with the air compressor, and the both sides of air compressor are equipped with the admission line, and the filter screen is installed to the inside laying of admission line, and the top of air compressor is equipped with a set of compressed air import, extends to the inside in crushing chamber through gas transmission pipeline.
The feed inlet is welded and installed above the crusher body, and the control panel is installed on the front face of the crusher body.
An installation part is fixed on the inner wall of the crushing cavity through bolts, and a grading wheel is connected inside the installation part through a rotating shaft.
The dust collecting device comprises a first dust collecting chamber and is characterized in that a first screen is fixed inside the first dust collecting chamber, the first screen divides the inner space of the first dust collecting chamber into a primary screening chamber and a first dust collecting chamber, the first dust collecting chamber is located below the side of the primary screening chamber, and a cabinet door is movably mounted on the front face of the first dust collecting chamber through a hinge.
An air suction port is connected to the outer wall of one side of the cyclone separator in a penetrating mode, and a conical cylinder is fixed below the air suction port.
The dust collecting device is characterized in that a second screen is fixed inside the second dust collecting chamber, the second screen divides the inner space of the second dust collecting chamber into a secondary screening chamber and a second dust collecting chamber, the second dust collecting chamber is located below the side of the secondary screening chamber, and a movable door is movably mounted on the front face of the second dust collecting chamber through a hinge.
Compared with the prior art, the beneficial effects of the utility model are that:
the utility model discloses in install the vibration feed chamber, install vibrating motor, connecting rod and stock guide in proper order inside the device, the vibration feed chamber can be through the vibration of vibrating motor, the single feeding volume of controlling means avoids crushing intracavity solid powder volume of advancing more, leads to some powder can't accomplish corresponding crushing work, and then ensures that crushing intracavity solid particle's crushing work is comparatively abundant; the vibration motor can convert electric energy into mechanical energy so as to provide vibration acting force for the vibration feeding chamber; when the connecting rod is used by the upward vibration action of the vibration motor, the connecting rod drives the material guide plate to be upwards expanded, the feeding channel is blocked, and feeding is prevented; when the connecting rod is used by the downward vibration action of the vibration motor, the connecting rod can drive the material guide plate to contract inwards, so that the feeding channel is opened, feeding work is continued, and a fixed vibration gap can be formed due to the fixed vibration frequency of the vibration motor, so that technical support is provided for controlling the feeding amount; the material guide plate can enable solid powder above the material guide plate to slide down along the gradient of the surface of the material guide plate to enter the crushing cavity, and crushing treatment of the material is completed.
Drawings
Fig. 1 is an overall sectional view of the present invention;
fig. 2 is a schematic front structural view of the present invention;
fig. 3 is a schematic structural view of the vibration feeding chamber of the present invention.
In the figure: 1. a compression chamber; 101. an air compressor; 102. an air intake duct; 103. a compressed air inlet; 104. filtering with a screen; 2. a pulverizer body; 201. a feed inlet; 202. a control panel; 3. vibrating the feeding chamber; 301. a vibration motor; 302. a connecting rod; 303. a material guide plate; 4. a grinding chamber; 401. a grading wheel; 402. a mounting member; 5. a first dust collecting chamber; 501. a primary screening chamber; 502. a first screen; 503. a first dust collection chamber; 504. a cabinet door; 6. a cyclone separator; 601. an air suction port; 602. a conical cylinder; 7. a second dust collecting chamber; 701. a secondary screening chamber; 702. a second screen; 703. a second dust collecting chamber; 704. a movable door.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1-3, the present invention provides an embodiment: a small-sized jet mill with multiple raw material processing comprises a compression chamber 1, a mill body 2, a vibration feeding chamber 3, a milling cavity 4, a first dust collection chamber 5, a cyclone separator 6 and a second dust collection chamber 7, wherein the compression chamber 1 is fixedly arranged at the bottom of the mill body 2, the compression chamber 1 can provide compressed and filtered air for a device, so that the air entering the milling cavity 4 has certain energy and speed, solid particles in the milling cavity can be driven by high-speed moving air flow to ascend and collide to complete milling work, the milling cavity 4 is fixed in the mill body 2, the milling cavity 4 is connected with the compression chamber 1 through a compressed air inlet 103, the milling cavity 4 can provide milling space for the device to mill the solid particles, normal milling work is ensured, the vibration feeding chamber 3 is connected above the milling cavity 4 in a penetrating manner, the vibration feeding chamber 3 can control the single feeding amount of the device through the vibration of the vibration motor 301, so that the situation that the feeding amount of solid powder inside the crushing cavity 4 is large, and the corresponding crushing work of partial powder cannot be completed is avoided, and further the crushing work of solid particles inside the crushing cavity 4 is ensured to be sufficient, one side of the vibration feeding chamber 3 is connected with the cyclone separator 6 through a gas transmission pipeline, the cyclone separator 6 can enable the mixture after primary crushing entering the cyclone separator 6 to complete the thickness separation through the strong centrifugal force generated by the high-speed rotation of the internal gas flow, so that the mixture can conveniently enter the first dust collecting chamber 5 for primary screening treatment, the first dust collecting chamber 5 is connected with the first dust collecting chamber 5 in a penetrating way below the cyclone separator 6, the outer wall of one side of the first dust collecting chamber 5 is fixed on the inner wall of one side of the crusher body 2 through a bolt, and the first dust collecting chamber 5 can perform primary screening treatment on the powder after the centrifugal treatment, screening out fine particles with the particle size requirement, and preparing for the fine particles to enter a second dust collection chamber 7, wherein the second dust collection chamber 7 is connected below the first dust collection chamber 5 through a pipeline, the second dust collection chamber 7 is positioned above the compression chamber 1, the second dust collection chamber 7 can carry out secondary screening on powder subjected to primary screening treatment in the first dust collection chamber 5, further, the powder particles meeting the particle size requirement are screened out, the particles exceeding the particle size requirement are sent into the crushing cavity 4 again through a feeding pipe, crushing treatment is completed, the maximum powder crushing utilization degree is ensured, a vibration motor 301 is fixed in the vibration feeding chamber 3 through a supporting seat, the vibration motor 301 is an XVML75-4 motor, electric energy can be converted into mechanical energy, and then vibration acting force is provided for the vibration feeding chamber 3; the output end of the vibration motor 301 is connected with a group of symmetrically distributed connecting rods 302, a certain included angle is formed between each connecting rod 302 and the vibration motor 301, and when the connecting rods 302 are subjected to upward vibration action of the vibration motor 301, the connecting rods can drive the material guide plates 303 to be upwards opened, so that the feeding channel is blocked, and feeding is prevented; when the connecting rod 302 is vibrated downwards by the vibration motor 301, the connecting rod drives the material guide plate 303 to contract inwards, so that the feeding channel is opened, feeding work is continued, and a fixed vibration gap can be formed due to the fixed vibration frequency of the vibration motor 301, so that technical support is provided for controlling the feeding amount; the guide plate 303 is welded and installed above the connecting rod 302, and the guide plate 303 is connected through a shaft rod, so that the solid powder above the guide plate 303 can slide down along the slope of the surface of the solid powder to enter the crushing cavity 4, and the primary crushing treatment is completed.
Further, an air compressor 101 is fixed inside the compression chamber 1, air inlet pipelines 102 are arranged on two sides of the air compressor 101, a filter screen 104 is paved inside the air inlet pipelines 102, a group of compressed air inlets 103 are arranged above the air compressor 101 and extend into the crushing cavity 4 through air conveying pipelines, the model of the air compressor 101 is VG1560130080A, and the air entering the crushing cavity 4 can be compressed to ensure that the air entering the crushing cavity 4 has certain speed and energy; the air inlet pipeline 102 can provide raw material support for air compression of the air compressor 101, and the working continuity of the air compressor 101 is guaranteed; the filter screen 104 can filter the air entering the air inlet duct 102 to ensure the purity of the air; the compressed air inlet 103 can provide a channel support for compressed air with certain speed and energy after being compressed by the air compressor 101 to enter the crushing cavity 4.
Further, a feed inlet 201 is welded and installed above the pulverizer body 2, a control panel 202 is installed on the front surface of the pulverizer body 2, and the feed inlet 201 can provide an inlet for a solid to be pulverized to enter the device to complete the pulverization; the control panel 202 is electrically connected with the air compressor 101 and the vibration motor 301 through wires, so that the working state of the device can be controlled, and the simplicity and convenience of the operation of the device are ensured.
Further, the inner wall of the crushing cavity 4 is fixed with a mounting part 402 through bolts, the interior of the mounting part 402 is connected with a grading wheel 401 through a rotating shaft, and a shaft rod is mounted inside the mounting part 402, so that technical conditions can be provided for the mounting and rotation of the grading wheel 401; the classifying wheel 401 is driven by the bottom compressed air flow, and can rotate rapidly on the surface of the shaft rod inside the mounting part 402, so that the solid material inside is subjected to primary cutting and smashing treatment by utilizing the sharp edge angle on the surface, and the smashing purpose is achieved.
Further, a first screen 502 is fixed inside the first dust collection chamber 5, the first screen 502 divides the inner space of the first dust collection chamber 5 into a primary screen cavity 501 and a first dust collection cavity 503, the first dust collection cavity 503 is located below the side of the primary screen cavity 501, a cabinet door 504 is movably mounted on the front surface of the first dust collection chamber 5 through a hinge, the mesh diameter of the first screen 502 meets the screening requirement of certain raw materials, and then certain raw material particles meeting the particle size requirement in the mixed solid material centrifugally processed by the cyclone separator 6 can be screened out and enter the first dust collection cavity 503, so that workers can conveniently collect and process the mixed solid material uniformly; the primary screening cavity 501 is used for storing the coarse particles screened by the first screen 502, so that the coarse particles are conveyed into the second dust collecting chamber 7 by a pipeline to complete secondary screening and ensure normal screening work; the cabinet door 504 can be opened, and the staff can concentrate some kind of raw materials granule that collects in the first dust collecting cavity 503 and shift, accomplishes the screening processing.
Further, an air suction port 601 is connected to the outer wall of one side of the cyclone separator 6 in a penetrating manner, a conical cylinder 602 is fixed below the air suction port 601, and the air suction port 601 can suck the crushed solid-gas mixture into the cyclone separator 6 to complete subsequent centrifugal treatment; the cone 602 contains a grading turbine, which generates a strong centrifugal force when rotating, and the solid powder enters the first dust collecting chamber 5 after finishing the thickness separation, thereby improving the screening efficiency of the first screen 502.
Further, a second screen 702 is fixed inside the second dust collecting chamber 7, the second screen 702 divides the inner space of the second dust collecting chamber 7 into a secondary screening chamber 701 and a second dust collecting chamber 703, the second dust collecting chamber 703 is located below the side of the secondary screening chamber 701, a movable door 704 is movably mounted on the front surface of the second dust collecting chamber 7 through a hinge, the mesh diameter of the second screen 702 meets the screening requirement of another type, and further coarse particles which do not meet the particle size requirement in the mixed solid material screened by the first dust collecting chamber 5 can be screened out and retained inside the secondary screening chamber 701 and slide down along the slope of the second screen 702, and enter the crushing chamber 4 again through a feeding pipeline to complete secondary crushing, so as to ensure sufficient crushing of the material; the second dust collecting cavity 703 is used for storing the particulate matters which meet the requirement of the granularity after being screened by the second screen 702, so that the particulate matters can be conveniently collected by the workers; the cabinet door 504 can be opened, and the staff can concentrate and transfer the fine particles collected in the second dust collecting cavity 703 to complete the screening process.
The working principle is as follows: when a worker utilizes the device to mix and crush metal powder materials, the vibration feeding chamber 3 and the compression chamber 1 are started firstly, preparation work before material crushing is done, then the mixed materials are put into the device through the feeding hole 201, then the vibration feeding chamber 3 is utilized to control the single material crushing amount entering the crushing cavity 4, so that the full crushing of the device is guaranteed, high-pressure gas with energy and speed after compression and filtration in the compression chamber 1 is utilized to drive solid materials entering the crushing cavity 4 to rub and collide with each other and the grading wheel 401, after the crushing treatment is finished, a solid particle mixture enters the cyclone separator 6 to finish centrifugal treatment, and then the solid particle mixture enters the first dust collection chamber 5 and the second dust collection chamber 7 successively, so that related screening work is finished, and the crushing effect of the device and the crushing quality of the materials are guaranteed.
It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein, and any reference signs in the claims are not intended to be construed as limiting the claim concerned.

Claims (7)

1. The utility model provides a small-size fluid energy mill with processing of multiple raw materials, includes compression chamber (1), rubbing crusher body (2), vibration feed chamber (3), crushing chamber (4), first dust collecting chamber (5), cyclone (6) and second dust collecting chamber (7), its characterized in that: the bottom of the crusher body (2) is fixedly provided with a compression chamber (1), the inside of the crusher body (2) is fixedly provided with a crushing cavity (4), the crushing cavity (4) is connected with the compression chamber (1) through a compressed air inlet (103), the upper part of the crushing cavity (4) is in through connection with a vibration feeding chamber (3), one side of the vibration feeding chamber (3) is connected with a cyclone separator (6) through a gas transmission pipeline, the lower part of the cyclone separator (6) is in through connection with a first dust collection chamber (5), the outer wall of one side of the first dust collection chamber (5) is fixed on the inner wall of one side of the crusher body (2) through a bolt, the lower part of the first dust collection chamber (5) is connected with a second dust collection chamber (7) through a pipeline, the second dust collection chamber (7) is positioned above the compression chamber (1), the inside of the vibration feeding chamber (3) is fixedly provided with a vibration motor (301) through a supporting seat, the output of vibrating motor (301) is connected with connecting rod (302) of a set of symmetric distribution, and has certain contained angle between connecting rod (302) and vibrating motor (301), and the top welded mounting of connecting rod (302) has stock guide (303), and stock guide (303) pass through the axostylus axostyle and connect.
2. A compact fluidic mill with multiple raw material processing according to claim 1, characterized in that: the inside of compression chamber (1) is fixed with air compressor (101), and the both sides of air compressor (101) are equipped with admission line (102), and the inside of admission line (102) is laid and is installed filter screen (104), and the top of air compressor (101) is equipped with a set of compressed air import (103), extends to the inside of smashing chamber (4) through gas transmission pipeline.
3. A compact fluidic mill with multiple raw material processing according to claim 1, characterized in that: a feeding hole (201) is welded and installed above the crusher body (2), and a control panel (202) is installed on the front face of the crusher body (2).
4. A compact fluidic mill with multiple raw material processing according to claim 1, characterized in that: the inner wall of the crushing cavity (4) is fixedly provided with a mounting piece (402) through a bolt, and the inside of the mounting piece (402) is connected with a grading wheel (401) through a rotating shaft.
5. A compact fluidic mill with multiple raw material processing according to claim 1, characterized in that: a first screen (502) is fixed inside the first dust collection chamber (5), the first screen (502) divides the inner space of the first dust collection chamber (5) into a primary screen cavity (501) and a first dust collection cavity (503), the first dust collection cavity (503) is located below the side of the primary screen cavity (501), and a cabinet door (504) is movably mounted on the front face of the first dust collection chamber (5) through a hinge.
6. A compact fluidic mill with multiple raw material processing according to claim 1, characterized in that: an air suction port (601) penetrates through the outer wall of one side of the cyclone separator (6), and a conical cylinder (602) is fixed below the air suction port (601).
7. A compact fluidic mill with multiple raw material processing according to claim 1, characterized in that: the inside of the second dust collection chamber (7) is fixed with a second screen (702), the second screen (702) divides the inner space of the second dust collection chamber (7) into a secondary screening chamber (701) and a second dust collection chamber (703), the second dust collection chamber (703) is located below the side of the secondary screening chamber (701), and the front face of the second dust collection chamber (7) is movably provided with a movable door (704) through a hinge.
CN202021521923.9U 2020-07-28 2020-07-28 Small-size fluid energy mill with multiple raw materials processing Active CN212916011U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202021521923.9U CN212916011U (en) 2020-07-28 2020-07-28 Small-size fluid energy mill with multiple raw materials processing

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202021521923.9U CN212916011U (en) 2020-07-28 2020-07-28 Small-size fluid energy mill with multiple raw materials processing

Publications (1)

Publication Number Publication Date
CN212916011U true CN212916011U (en) 2021-04-09

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Application Number Title Priority Date Filing Date
CN202021521923.9U Active CN212916011U (en) 2020-07-28 2020-07-28 Small-size fluid energy mill with multiple raw materials processing

Country Status (1)

Country Link
CN (1) CN212916011U (en)

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