CN213377145U - System for cyclone separation of circuit board substrate - Google Patents

Abstract

The utility model provides a system of circuit board base plate is selected separately to whirlwind, including barrel and the material input system who is connected with the barrel, whirlwind generating system and material collecting system, the barrel includes the last material output portion that from the top down communicates in proper order, the impeller installation department, the guide part, the material input portion, funnel portion and lower material output portion, the internal diameter from the top down of guide part reduces after increasing earlier, lower material output portion becomes the acute angle with the horizontal plane and arranges, the material input system includes the breaker, shale shaker and input tube, one side of breaker and shale shaker links up, the opposite side of shale shaker links up the one end of input tube, the other end of input tube stretches into the material input portion, whirlwind generating system includes motor and impeller, the motor is located the top of material output portion, the impeller is located the impeller installation department, the motor passes through the motor hub connection and drives the impeller rotation. The utility model discloses the air is the medium, separates metal particle and non-metallic particle from the waste circuit board through "two whirlpools" rotatory air current.

Description

System for cyclone separation of circuit board substrate

Technical Field

The utility model relates to a technical field is retrieved to the circuit board, specifically is a system of circuit board base plate is selected separately to whirlwind.

Background

Printed wiring boards typically contain about 30% plastic, 30% inert oxide, and 40% metal. After the printed circuit board is scrapped after the service life is reached, if the printed circuit board is directly discarded, the environment is polluted and useful resources in the printed circuit board are wasted, so that the printed circuit board should be recycled. The printed circuit board comprises a substrate and a plurality of electronic components assembled on the substrate, and the substrate can be recycled after the recyclable electronic components and the harmful components are removed. The existing recovery method comprises a mechanical physical method, a chemical solvent method and an incineration pyrolysis method, the mechanical physical method is relatively low in cost and easy to popularize, but the existing mechanical physical method is complex in system and needs to further improve the separation efficiency.

SUMMERY OF THE UTILITY MODEL

The above-mentioned problem to prior art exists, the utility model aims at providing a system of circuit board base plate is selected separately to whirlwind, the air is the medium, separates metal particle and non-metal particle from the abandonment circuit board through "two whirlpools" rotatory air current, realizes the enrichment metal, discharges again after the air medium removes dust, avoids environmental pollution. The system is simple in structure and low in cost, and materials before entering the barrel are subjected to primary screening, so that damage to the barrel by large particles is prevented.

In order to realize the purpose, the utility model discloses the technical scheme who adopts is:

the utility model provides a system for circuit board base plate is selected separately to whirlwind, including barrel and the material input system who is connected with the barrel, whirlwind generation system and material collecting system, the barrel includes from the top down material output portion that feeds through in proper order, the impeller installation department, the guide part, the material input portion, funnel portion and material output portion down, the internal diameter from the top down of guide part reduces after increasing earlier, material output portion and horizontal plane acutangulate and arranges down, the material input system includes the breaker, shale shaker and input tube, one side of breaker and shale shaker links up, the opposite side of shale shaker links up the one end of input tube, the other end of input tube stretches into material input portion, whirlwind generation system includes motor and impeller, the motor is located the barrel outside, the top of going up material output portion, the impeller is located the impeller installation department, the motor passes through the motor shaft and connects and drives the impeller rotation.

As a further improvement of the above technical solution:

the input tube enters the barrel from the side wall of the lower material output part, sequentially passes through the funnel part and the material input part from bottom to top, and the end part of the input tube is located at the upper end of the material input part.

The material input system also comprises an air blower and a blast pipe, wherein the air blower is connected with the middle part of the input pipe through the blast pipe, and the blast pipe is a bent pipe which enables air blown by the air blower to blow towards the outlet direction of the input pipe.

The material input system also comprises a material cover, and the end part of the input pipe positioned in the cylinder body is connected with the material cover through a connecting rod.

The material input system also comprises a recovery part for recovering materials which are not sieved down on the vibrating screen, and the recovery part is connected with the vibrating screen.

The cyclone generation system further comprises an induced draft fan and an induced draft pipe, wherein one end of the induced draft pipe is communicated with the upper material output part, and the other end of the induced draft pipe is connected with the induced draft fan.

The material collecting system comprises a material output pipe, a material collecting device and a filter screen, wherein the material output pipe is communicated with a material output part, the filter screen is detachably mounted in the middle of the material output pipe, the material output pipe is horizontally arranged, the filter screen is perpendicular to the material output pipe, the material collecting device is positioned under the filter screen, and the material output pipe, close to one side of the barrel, of the material collecting device and the filter screen is communicated through a pipeline.

One end of the upper material output pipe is communicated with the upper material output part, and the other end of the upper material output pipe is connected with the dust removal device.

The inner diameters of all parts of the material input part are equal, and the inner diameter of the funnel part is gradually reduced from top to bottom.

The utility model has the advantages that: the air is used as a medium, metal particles and non-metal particles are separated from the waste circuit board through the double-vortex rotary airflow, metal enrichment is realized, the air medium is discharged after dust removal, and environmental pollution is avoided. The system is simple in structure and low in cost, and materials before entering the barrel are subjected to primary screening, so that damage to the barrel by large particles is prevented.

Drawings

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings. It is to be understood that the description of the embodiments herein is for purposes of illustration and explanation only and is not intended to limit the invention.

Spatially relative terms, such as "above … …," "above … …," "above … …," "above," and the like, may be used herein for ease of description to describe one device or feature's spatial relationship to another device or feature as illustrated in the figures. It will be understood that the spatially relative terms are intended to encompass different orientations of the device in use or operation in addition to the orientation depicted in the figures. For example, if a device in the figures is turned over, devices described as "above" or "on" other devices or configurations would then be oriented "below" or "under" the other devices or configurations. Thus, the exemplary term "above … …" can include both an orientation of "above … …" and "below … …". The device may be otherwise variously oriented (rotated 90 degrees or at other orientations) and the spatially relative descriptors used herein interpreted accordingly.

A system for cyclone separation of circuit board substrates, as shown in fig. 1, includes a barrel and a material input system, a cyclone generation system, and a material collection system connected to the barrel. The barrel is provided with an inner containing cavity, materials are input into the barrel through the material input system, the cyclone generation system generates cyclone in the barrel, and the light materials and the heavy materials in the materials are separated through the cyclone, are respectively sent out of the barrel and are collected through the material collection system.

The barrel comprises an upper material output part 11, an impeller mounting part 12, a guide part 13, a material input part 14, a funnel part 15 and a lower material output part 16 which are sequentially communicated from top to bottom. The material output part 11, the impeller mounting part 12, the guide part 13, the material input part 14 and the funnel part 15 are coaxial.

An upper material output port is arranged on the upper material output part 11. The inner diameter of the guide portion 13 increases from top to bottom and then decreases, and preferably, the inner diameters of both end portions of the guide portion 13 are equal. The inner diameter of the material input part 14 is equal at all positions, i.e. the material input part 14 is a cylinder. The funnel part 15 is in a funnel shape, that is, the inner diameter of the funnel part 15 gradually decreases from top to bottom. The lower material output part 16 is arranged at an acute angle with the horizontal plane, specifically, the conveying direction of the material in the lower material output part 16 is at an acute angle with the horizontal plane, in other words, one end of the lower material output part 16 is connected with the funnel part 15, and the other end is arranged obliquely downwards. One end of the lower material output part 16 is connected with the funnel part 15, and the other end is an outlet 17.

The material input system comprises a crusher 21, a vibrating screen 22, a recovery section 23, an input pipe 24, a blower 25, a blower pipe 26 and a material hood 27.

The crusher 21 is engaged with one side of the vibrating screen 22, the other side of the vibrating screen 22 is engaged with one end of the input pipe 24, and the other end of the input pipe 24 is extended into the material input portion 14. Specifically, the input pipe 24 enters the inside of the barrel body from the side wall of the lower material output part 16, and after sequentially passing through the funnel part 15 and the material input part 14 from bottom to top, the end part of the input pipe 24 is located at the upper end of the material input part 14, and the end part of the input pipe 24 is an input pipe outlet, that is, the material in the input pipe 24 enters the inside of the barrel body through the input pipe outlet. Preferably, the inlet pipe 24 located inside the barrel is located on the centerline of the material inlet 14 and the funnel 15.

The end of the input pipe 24 in the cylinder is connected with a material cover 27, in particular, the input pipe 24 and the material cover 27 are connected through a connecting rod, so that the input pipe 24 and the material cover 27 are spaced and not closed, and the connecting rod can not completely block the material from coming out of the input pipe 24.

The blower 25 is connected to the middle of the input pipe 24 through a blower pipe 26, the blower pipe 26 is a bent pipe smoothly connected to the input pipe 24, and the bent pipe is provided to guide the wind so that the wind blown by the blower 25 blows toward the outlet of the input pipe 24.

Preferably, for ease of arrangement and installation, the inlet pipe 24 comprises a horizontal section and a vertical section connected to each other, the horizontal section engaging the vibrating screen 22 at one end and the vertical section at the other end, the vertical section at the other end extending into the interior of the cylinder. A blast pipe 26 connects the horizontal segments.

The recovery part 23 is connected with the vibrating screen 22 and is used for recovering materials which are not sieved on the vibrating screen 22. The material recovered by the recovery portion 23 enters the crusher 21 again to be crushed.

The cyclone generation system includes an induced draft fan 31, an induced draft duct 32, a motor 33, and an impeller 34. The motor 33 is positioned outside the cylinder and above the upper material output part 11, the impeller 34 is positioned on the impeller mounting part 12, and the motor 33 is connected with the impeller 34 through the motor shaft and drives the impeller 34 to rotate. One end of the induced draft pipe 32 is communicated with the upper material output part 11, and the other end is connected with the induced draft fan 31.

The material collecting system comprises an upper material output pipe 41, an upper material collecting device 42 and a filter screen 43, and a lower material collecting device (not shown in the figure) connected with the outlet 17. One end of the upper material output pipe 41 is communicated with the upper material output part 11, and the other end is connected with the dust removal device 5. The middle part of the upper material output pipe 41 is detachably provided with a filter screen 43, the upper material output pipe 41 is horizontally arranged, and the filter screen 43 is vertical to the upper material output pipe 41. The upper material collecting device 42 is positioned right below the filter screen 43, and the upper material collecting device 42 is communicated with the upper material output pipe 41 of one side of the filter screen 43 close to the cylinder body through a pipeline. The filter screen 43 can be replaced and cleaned.

The working principle and the process of the utility model are as follows: the crusher 21, the blower 25, the induced draft fan 31 and the motor 33 are started. At this time, the wind blown by the blower 25 travels inside the inlet pipe 24 toward the outlet of the inlet pipe 24 in the cylinder. External air is introduced into the induced draft fan 31 and is delivered into the barrel from the upper material output part 11 through the induced draft pipe 32, the introduced air generates rotational flow movement under the action of the impeller 34 to form rotational flow, the air outside the rotational flow moves downwards to form external vortex, and the air at the center of the rotational flow moves upwards to form internal vortex.

The base plate of the circuit board to be processed is placed into the crusher 21, the material crushed by the crusher 21 falls into the vibrating screen 22, the vibrating screen 22 screens the material, the material with the particle size meeting the design requirement falls into one end of the input pipe 24 through the vibrating screen 22, the material which cannot pass through the vibrating screen 22 and stays on the surface of the material slides into the recovery part 23 through the screen surface of the inclined vibrating screen 22, the material in the recovery part 23 is periodically recovered, and the material is placed into the crusher 21 for further crushing.

The material falling into the input pipe 24 is driven by the wind blown by the blower 25 to move along the input pipe 24, and then flows out from the outlet end of the input pipe 24 and enters the inside of the cylinder, and the material flowing out from the outlet end of the input pipe 24 is blocked by the material cover 27 and cannot continuously rise in the inside of the cylinder, but moves around the material cover 27.

After the material got into the barrel, under the effect of outer vortex and interior vortex, because metal particle weight is greater than nonmetal granule weight, metal particle is driven downstream by outer vortex, get into down material output 16 behind material input part 14 and funnel portion 15 in proper order, slide down along the "slope" of material output 16 down, fall into down material collection device from export 17, nonmetal granule that the weight is relatively little is driven upward movement by interior vortex, material output pipe 41 on getting into through last material delivery outlet on material output 11, nonmetal granule falls into material collection device 42 under the effect of gravity after being blockked by filter screen 43, the dirty gas of passing through filter screen 43 sends into dust collector 5 and removes dust.

In the above process, under the action of the blast air and the swirling air of the blower 25, part of the metal particles are brought into the guide part 13, and since the inner diameter of the guide part 13 is increased from top to bottom and then decreased, that is, the inner wall of the guide part 13 protrudes outwards, the blocking and guiding effects on the part of the large particles and the metal particles are formed, so that the large particles and the metal particles move downwards.

Preferably, the diameter of the material particles entering the input pipe 24 through the vibrating screen 22 is 0.6mm to 0.1 mm.

Finally, it must be said here that: the above embodiments are only used for further detailed description of the technical solutions of the present invention, and should not be understood as limiting the scope of the present invention, and the modifications and adjustments made by those skilled in the art according to the above-mentioned contents of the present invention are all included in the scope of the present invention.

Claims (9)

1. A system for cyclone separation of circuit board substrates is characterized by comprising a cylinder body, a material input system, a cyclone generation system and a material collection system, wherein the material input system, the cyclone generation system and the material collection system are connected with the cylinder body, the cylinder body comprises an upper material output part (11), an impeller installation part (12), a guide part (13), a material input part (14), a funnel part (15) and a lower material output part (16) which are sequentially communicated from top to bottom, the inner diameter of the guide part (13) is increased and then reduced from top to bottom, the lower material output part (16) and a horizontal plane are arranged in an acute angle, the material input system comprises a crusher (21), a vibrating screen (22) and an input pipe (24), the crusher (21) is connected with one side of the vibrating screen (22), the other side of the vibrating screen (22) is connected with one end of the input pipe (24), the other end of the input pipe (24) extends into the material input part (14), the cyclone generation system comprises a motor, the motor (33) is positioned outside the cylinder and above the upper material output part (11), the impeller (34) is positioned on the impeller mounting part (12), and the motor (33) is connected with and drives the impeller (34) to rotate through a motor shaft.

2. The system of claim 1, wherein: the input pipe (24) enters the barrel from the side wall of the lower material output part (16), sequentially passes through the funnel part (15) and the material input part (14) from bottom to top, and the end part of the input pipe (24) is positioned at the upper end of the material input part (14).

3. The system according to claim 1 or 2, characterized in that: the material input system further comprises a blower (25) and a blast pipe (26), the blower (25) is connected with the middle part of the input pipe (24) through the blast pipe (26), and the blast pipe (26) is an elbow pipe which enables wind blown by the blower (25) to blow towards the outlet direction of the input pipe (24).

4. The system of claim 1, wherein: the material input system also comprises a material cover (27), and the end part of the input pipe (24) positioned in the cylinder body is connected with the material cover (27) through a connecting rod.

5. The system of claim 1, wherein: the material input system also comprises a recovery part (23) used for recovering unscreened materials on the vibrating screen (22), and the recovery part (23) is connected with the vibrating screen (22).

6. The system of claim 1, wherein: the cyclone generating system also comprises an induced draft fan (31) and an induced draft pipe (32), wherein one end of the induced draft pipe (32) is communicated with the upper material output part (11), and the other end of the induced draft pipe is connected with the induced draft fan (31).

7. The system of claim 1, wherein: the material collecting system comprises a material output pipe (41), a material collecting device (42) and a filter screen (43), the material output part (11) is communicated with the material output pipe (41), the filter screen (43) is detachably mounted in the middle of the material output pipe (41), the material output pipe (41) is horizontally arranged, the filter screen (43) is perpendicular to the material output pipe (41), the material collecting device (42) is located under the filter screen (43), and the material output pipe (41) which is close to one side of the cylinder body and is communicated with the material collecting device (42) and the filter screen (43) through a pipeline.

8. The system of claim 7, wherein: one end of the upper material output pipe (41) is communicated with the upper material output part (11), and the other end is connected with the dust removal device (5).

9. The system of claim 1, wherein: the inner diameters of all parts of the material input part (14) are equal, and the inner diameter of the funnel part (15) is gradually reduced from top to bottom.

Images