CN114768740A - Copper melting reaction device - Google Patents

Abstract

The invention provides a copper melting reaction device which comprises an air supply mechanism, a reaction kettle, a feeding mechanism and a bearing mechanism, wherein the air supply mechanism is used for conveying air into the reaction kettle, the feeding mechanism is used for conveying reaction liquid into the reaction kettle, the bearing mechanism comprises a bearing plate and a sieve barrel, the bearing plate is axially movably connected to the inner wall of the reaction kettle, the sieve barrel is detachably connected to the bearing plate and is used for placing copper wires, bearing holes are formed in the bearing plate, so that the sieve barrel penetrates through the bearing plate and extends towards the bottom of the reaction kettle, and a heating mechanism is arranged on the outer side wall of the reaction kettle. Through setting up the loading board reaches the sieve bucket can place the copper line in the sieve bucket, avoid copper line and aeration pipe direct contact behind feed mechanism pours into the reaction liquid into, the copper line can fully contact with reaction liquid and air, promotes reaction efficiency.

Description

Copper melting reaction device

Technical Field

The invention relates to the technical field of copper treatment, in particular to a copper melting reaction device.

Background

The electrolytic copper foil is an important material for manufacturing a Copper Clad Laminate (CCL) and a Printed Circuit Board (PCB), and in the high-speed development of the current electronic information industry, the electrolytic copper foil is called a neural network for signal and power transmission of electronic products.

Copper foil is a negative electrolyte material that is deposited as a thin, continuous metal foil on the substrate layer of a circuit board, which serves as a conductor for a PCB, is easily adhered to an insulating layer, receives a printed resist, and is etched to form a circuit pattern.

In the process of producing copper foil, a copper wire is firstly placed in a reaction kettle containing sulfuric acid, and then air is exposed into the reaction kettle, so that copper sulfate is generated.

Disclosure of Invention

Aiming at the defects of the prior art, the invention aims to provide a copper melting reaction device, aiming at solving the technical problems that in the prior art, the copper wire cannot be fully contacted with the air because the copper wire in a reaction kettle is directly contacted with an aeration pipe, so that the reaction speed is reduced, and the production efficiency is reduced.

In order to achieve the purpose, the invention is realized by the following technical scheme:

the utility model provides a melt copper reaction unit, includes air feed mechanism, reation kettle, feed mechanism and bears the mechanism, air feed mechanism be used for to carry air in the reation kettle, feed mechanism be used for to carry reaction liquid in the reation kettle, it includes loading board and sieve bucket to bear the mechanism, loading board axial displacement connect in on reation kettle's the inner wall, sieve bucket detachable connect in on the loading board, the sieve bucket is used for placing the copper line, set up the bearing hole on the loading board, so that the sieve bucket passes the loading board, and to reation kettle's bottom direction extends, reation kettle's lateral wall sets up heating mechanism.

Compared with the prior art, the invention has the beneficial effects that: through setting up the loading board reaches sieve bucket can place the copper line in the sieve bucket, avoid copper line and aeration pipe direct contact after feed mechanism pours into the reaction liquid into, the copper line can fully contact with reaction liquid and air, promotes reaction efficiency, simultaneously, compares in traditional direct contact mode, still can avoid the copper line to take place the condition emergence of destruction aeration pipe when the reaction. The bearing plate is axially movably connected in the reaction kettle, and can axially keep away from the bottom of the reaction kettle after the reaction is completed, and the sieve barrel is communicated with the whole copper wire in which the reaction is completed to be detached and replaced, so that the production efficiency is improved.

Further, the air supply mechanism comprises a magnetic suspension centrifugal fan and an air supply pipe, and the magnetic suspension centrifugal fan is communicated with the inside of the reaction kettle through the air supply pipe.

Furthermore, the air supply pipe comprises a transmission pipe and an aeration pipe, one end of the transmission pipe is communicated with the magnetic suspension centrifugal fan, one end, far away from the magnetic suspension centrifugal fan, of the transmission pipe penetrates through the side wall of the reaction kettle and extends towards the bottom direction of the reaction kettle, one end, far away from the magnetic suspension centrifugal fan, of the transmission pipe is communicated with the aeration pipe, and the aeration pipe is uniformly distributed at the bottom of the reaction kettle.

Furthermore, a sliding beam is arranged on the inner side wall opposite to the reaction kettle, the sliding beam extends from the top of the reaction kettle to the bottom of the reaction kettle, and the bearing mechanism moves axially along the sliding beam.

Further, the bearing mechanism further comprises a sliding block, the opposite side edges of the bearing plate are connected with the sliding block, the sliding block is connected to the sliding beam in a clamped mode, a driving motor is arranged at the top of the reaction kettle and electrically connected with the sliding block, and therefore the sliding block can move axially along the sliding beam.

Furthermore, one surface of the bearing plate, which faces the top of the reaction kettle, is concave inwards to form a clamping groove, and an inserting block is arranged on the sieve barrel and is inserted into the clamping groove so as to fix the sieve barrel on the bearing plate.

Furthermore, the feeding mechanism comprises a feeding box, a conveying pipe and a sprinkling pipe, the top of the reaction kettle is connected with the feeding box, one end of the conveying pipe is communicated with the feeding box, and the other end of the conveying pipe penetrates through the top of the reaction kettle and is communicated with the sprinkling pipe.

Furthermore, a plurality of the material sprinkling pipes are arranged around the material conveying pipe, and obtuse angles are formed between the material sprinkling pipes and the material conveying pipe.

Furthermore, the top of the feeding box is provided with a first feeding hole and a second feeding hole, and the second feeding hole is communicated with the inside of the reaction kettle through a circulating pump.

Still further, the bottom of the feeding box forms an inclined surface, the inclined surface inclines from the side edge of the feeding box to the center direction of the feeding box, and the inclined surface and the side wall of the feeding box form an obtuse angle.

Drawings

FIG. 1 is a schematic structural view of a copper melting reaction apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic view of the interior of the reaction vessel of FIG. 1 at a first perspective;

FIG. 3 is a schematic view of the interior of the reaction vessel of FIG. 1 at a second viewing angle;

FIG. 4 is a disassembled view of the bearing structure of FIG. 2;

description of the main element symbols:

air supply mechanism	10	Magnetic suspension centrifugal fan	110
				Air supply pipe	120	Conveying pipe	121
Aeration pipe	122	Reaction kettle	20
				Sliding beam	210	Limiting plate	220
Feeding mechanism	30	Material feeding box	310
				Material conveying pipe	320	Sprinkler tube	330
First feed inlet	311	Second feed inlet	312
				Bearing mechanism	40	Bearing plate	410
Bearing hole	411	Clamping groove	412
				Screen barrel	420	Bump	421
Plug-in block	422	Handle bar	423
				Sliding block	430	Driving motor	50
Circulating pump	60	Heating plate	70
				Drain pipe	80

The following detailed description will further illustrate the invention in conjunction with the above-described figures.

Detailed Description

To facilitate an understanding of the invention, the invention will now be described more fully hereinafter with reference to the accompanying drawings. Several embodiments of the invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1 to 4, the copper melting reaction apparatus in the embodiment of the present invention includes an air supply mechanism 10, a reaction kettle 20, a feeding mechanism 30 and a carrying mechanism 40, wherein the air supply mechanism 10 is configured to deliver air into the reaction kettle 20, specifically, the air supply mechanism 10 includes a magnetic suspension centrifugal fan 110 and an air supply pipe 120, and the magnetic suspension centrifugal fan 110 is communicated with the inside of the reaction kettle 20 through the air supply pipe 120 and exposes air into the inside of the reaction kettle 20 so as to enable the inside of the reaction kettle to react.

The air supply pipe 120 includes a transmission pipe 121 and an air exposure pipe 122, one end of the transmission pipe 121 is communicated with the magnetic suspension centrifugal fan 110, one end of the transmission pipe 121, which is far away from the magnetic suspension centrifugal fan 110, passes through a side wall of the reaction kettle 20 and extends toward the bottom of the reaction kettle 20, it can be understood that the transmission pipe 121 transmits the air sent out from the magnetic suspension centrifugal fan 110 to the bottom of the reaction kettle 20, one end of the transmission pipe 121, which is far away from the magnetic suspension centrifugal fan 110, is communicated with the air exposure pipe 122, and the air exposure pipe 122 is used for transmitting the air to the inside of the reaction kettle 20. The aeration pipes 122 are uniformly arranged at the bottom of the reaction kettle 20, and understandably, a plurality of aeration holes are formed in the aeration pipe 122, the plurality of aeration holes are uniformly distributed on the aeration pipe 122, and the plurality of aeration holes are communicated with the inside of the reaction kettle 20, when the transmission pipe 121 transmits air to the bottom of the reaction kettle 20, the air enters the aeration pipe 122 and passes through the aeration holes formed in the aeration pipe 122 to aerate the air.

The feeding mechanism 30 is configured to convey reaction liquid into the reaction kettle 20, specifically, the feeding mechanism 30 includes a feeding box 310, a feeding pipe 320, and a sprinkling pipe 330, the top of the reaction kettle 20 is connected to the feeding box 310, one end of the feeding pipe 320 is communicated with the feeding box 310, the other end of the feeding pipe 320 passes through the top of the reaction kettle 20 and is communicated with the sprinkling pipe 330, it can be understood that the first feeding port 311 is formed in the top of the feeding box 310, reaction liquid is injected into the feeding box 310 through the first feeding port 311, and the reaction liquid enters the sprinkling pipe 330 through the feeding pipe 320 and is sprinkled into the reaction kettle 20, so that a copper wire is reacted in the reaction kettle 20.

The bottom of the material feeding box 310 forms an inclined surface, the inclined surface inclines from the lateral edge of the material feeding box 310 to the center direction of the material feeding box 310, and the inclined surface and the lateral wall of the material feeding box 310 form an obtuse angle, so that the inclined surface inclines from the lateral wall of the material feeding box 310 to the direction of the material conveying pipe 320, when the reaction liquid is injected through the first feed port 311, the reaction liquid can flow into the material conveying pipe 320 through the inclined surface, and the situation that the reaction liquid is retained in the material feeding box 310 and cannot be completely injected into the reaction kettle 20 is avoided.

Surround the conveying pipeline 320 sets up a plurality of spill material pipe 330, understandably, a plurality of spill material pipe 330 encircles the lateral wall evenly distributed of conveying pipeline 320, a plurality of spill material pipe 330 with form the obtuse angle between the conveying pipeline 320, set up through the slope spill material pipe 330 can make the reaction liquid get into behind the conveying pipeline 320, along inclination inflow spill in the material pipe 330, spill material pipe 330 sets up and spills the material hole, spill the opening orientation in material hole reation kettle 20's bottom reaction liquid gets into spill material pipe 330 after, through spill the material hole and pour into reation kettle 20's inside. Through setting up a plurality of spill material pipe 330, just spill material pipe 330 evenly distributed in the lateral wall of conveying pipeline 320 can make the reaction liquid pass through a plurality of spill the even cover of material pipe 330 on the copper line in reation kettle 20, make the cover of reaction liquid more even, and then make the reaction of copper line more abundant for production efficiency.

Second feed inlet 312 is seted up at the top of feed box 310, circulation mouth is seted up to reation kettle 20's lateral wall, second feed inlet 312 with circulation pump 60 is connected between the mouth, understandably, second feed inlet 312 passes through circulation pump 60 intercommunication reation kettle 20's inside, through setting up circulating pump 60, can with the reaction liquid in reation kettle 20 passes through circulating pump 60 is taken out extremely in the feed box 310, in order to realize the function of the interior reaction liquid recycle of reation kettle 20, avoid extravagant, practice thrift manufacturing cost.

Bearing mechanism 40 includes loading board 410 sieve bucket 420, loading board 410 axial displacement connect in on reation kettle 20's the inner wall, sieve bucket 420 detachable connect in on the loading board 410, sieve bucket 420 is used for placing the copper line, through setting up loading board 410 reaches sieve bucket 420, can place the copper line in sieve bucket 420 avoids copper line and aeration pipe 122 direct contact after feed mechanism 30 pours into the reaction liquid into, the copper line can fully contact with reaction liquid and air, promotes reaction efficiency, simultaneously, compares in traditional direct contact mode, still can avoid the copper line to take place the condition emergence of destruction aeration pipe 122 when reacting. It can be understood that the bottom and the side wall of the sieve barrel 420 are provided with a plurality of sieve holes, and the reaction liquid can enter the sieve barrel 420 through the sieve holes, so that the reaction liquid can fully contact with the copper wires in the sieve barrel 420, and the reaction is quicker.

The carrying plate 410 is provided with a carrying hole 411 so that the sieve barrel 420 penetrates through the carrying plate 410 and extends toward the bottom of the reaction kettle 20, and it can be understood that the carrying plate 410 is a frame-shaped structure, and the size of the carrying hole 411 is the same as that of the sieve barrel 420. One surface of the supporting plate 410, which faces the top of the reaction kettle 20, is recessed to form a locking groove 412, an insertion block 422 is disposed on the sieve barrel 420, and the insertion block 422 corresponds to the locking groove 412. It can be understood that the top side edge of the sieve barrel 420 extends toward the side wall of the reaction kettle 20 to form a projection 421, and the bearing plate 410 is abutted by the projection 421, so that the sieve barrel 420 is borne on the bearing plate 410. The protrusion 421 protrudes toward one surface of the bearing plate 410 to form the insertion block 422, and the sieve barrel 420 is fixed on the bearing plate 410 by inserting the insertion block 422 into the engagement groove 412. After the reaction in the reaction kettle 20 is completed, the sieve barrel 420 can be detached from the bearing plate 410 by the aid of the sieve barrel 420, so that the whole copper wire communicated with the sieve barrel 420 can be detached and replaced.

Bearing mechanism 40 still includes slider 430, the relative lateral margin of loading board 410 is connected slider 430, set up sliding beam 210 on the relative inside wall of reation kettle 20, sliding beam 210 certainly reation kettle 20's top to reation kettle 20's bottom direction extends, slider 430 joint in on the sliding beam 210, through the relative lateral margin of loading board 410 sets up slider 430 joint sliding beam 210 can make sliding beam 210 with the mutual butt of loading board 410 avoids the condition that drops to take place.

The top of the reaction kettle 20 is provided with a driving motor 50, the driving motor 50 is electrically connected to the sliding block 430, as can be understood, the driving motor 50 is connected to the sliding block 430 through a driving rod, and the driving motor 50 is configured to drive the driving rod to extend and retract, so that the sliding block 430 moves axially along the sliding beam 210, and further drives the bearing plate 410 to move axially along the sliding beam 210. By axially moving and connecting the bearing mechanism 40 to the inner wall of the reaction kettle 20, the sieve barrel 420 can be lifted after the reaction is completed in the reaction kettle 20, and the reaction liquid is sieved out of the sieve barrel 420 through the sieve holes, so that the sieve barrel 420 can be conveniently replaced. Preferably, a limit plate 220 is disposed on an inner sidewall of the reaction kettle 20, the limit plate 220 is connected to an end of the sliding beam 210 facing the bottom of the reaction kettle 20, the limit plate 220 is perpendicular to the sliding beam 210, and by disposing the limit plate 220, an axial moving position of the sliding block 430 may be limited so as to prevent the sliding block 430 from being detached from the sliding beam 210.

A handle 423 is arranged on the sieve barrel 420, specifically, one surface of the bump 421 facing the top of the reaction kettle 20 is connected to the handle 423, the handle 423 is arranged to facilitate operation of an operator, and the sieve barrel 420 is detached from the carrying plate 410 through the handle 423.

Further, a liquid discharge port is formed in the reaction kettle 20, a liquid discharge pipe 80 is connected to the liquid discharge port, waste liquid in the reaction kettle 20 can be discharged through the liquid discharge pipe 80, understandably, an opening and closing device is arranged on the liquid discharge pipe 80, the clamping device is used for controlling the opening and closing of the liquid discharge pipe 80, one end, far away from the reaction kettle 20, of the liquid discharge pipe 80 is connected with a purification device, and the purification device is used for treating waste liquid and waste discharged from the liquid discharge pipe 80, so that the environmental protection performance of the copper melting reaction device is improved.

Set up heating mechanism on reation kettle 20's the lateral wall, specifically, heating mechanism includes a plurality of hot plate 70, connect on reation kettle 20's the lateral wall hot plate 70, hot plate 70 electric connection external power source through the switch-on external power source, so that hot plate 70 heats, and with heat transfer extremely in reation kettle 20, through promoting the temperature, can accelerate reaction in reation kettle 20 takes place, promotes reaction efficiency.

Heating mechanism still can set up to the heating pipe, the heating pipe encircles reation kettle 20's lateral wall sets up, just the heating pipe certainly reation kettle 20's middle part to reation kettle 20's bottom direction spiral extends, heating pipe intercommunication boiler room, through produce heat in the boiler room, with heat transmission extremely in the heating pipe, so that it is right reactant heating in reation kettle 20, and then accelerate reaction rate in the reation kettle 20.

In the description herein, references to the description of the term "one embodiment," "some embodiments," "an example," "a specific example," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the present invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. The utility model provides a melt copper reaction unit, its characterized in that, includes air feed mechanism, reation kettle, feed mechanism and bears the mechanism, air feed mechanism be used for to carry air in the reation kettle, feed mechanism be used for to carry reaction liquid in the reation kettle, it includes loading board and sieve bucket to bear the mechanism, loading board axial displacement connect in on reation kettle's the inner wall, sieve bucket detachable connect in on the loading board, the sieve bucket is used for placing the copper line, set up the bearing hole on the loading board, so that the sieve bucket passes the loading board, and to reation kettle's bottom direction extends, reation kettle's lateral wall sets up heating mechanism.

2. The copper melting reaction device according to claim 1, wherein the gas supply mechanism includes a magnetic levitation centrifugal fan and a gas supply pipe, and the magnetic levitation centrifugal fan communicates with the inside of the reaction vessel through the gas supply pipe.

3. The copper melting reaction device according to claim 2, wherein the gas supply pipe comprises a transmission pipe and a gas explosion pipe, one end of the transmission pipe is communicated with the magnetic suspension centrifugal fan, one end of the transmission pipe, far away from the magnetic suspension centrifugal fan, penetrates through the side wall of the reaction kettle and extends towards the bottom of the reaction kettle, one end of the transmission pipe, far away from the magnetic suspension centrifugal fan, is communicated with the gas explosion pipe, and the gas explosion pipe is uniformly distributed at the bottom of the reaction kettle.

4. A copper melting reactor as claimed in claim 1, wherein a sliding beam is provided on the opposing inner side walls of the reactor, the sliding beam extending from the top of the reactor to the bottom of the reactor, and the carrying mechanism moves axially along the sliding beam.

5. A copper smelting reaction unit according to claim 4, wherein the carrying mechanism further includes a slider, opposite side edges of the carrying plate are connected to the slider, the slider is clamped to the sliding beam, and a driving motor is arranged at the top of the reaction vessel and electrically connected to the slider so as to move the slider axially along the sliding beam.

6. The copper melting reaction device as claimed in claim 1, wherein a surface of the carrying plate facing the top of the reaction vessel is recessed to form a locking groove, and an insertion block is provided on the sieve barrel and inserted into the locking groove to fix the sieve barrel to the carrying plate.

7. The apparatus of claim 1, wherein the feeding mechanism includes a feeding box, a feeding pipe and a sprinkling pipe, the feeding box is connected to the top of the reaction vessel, one end of the feeding pipe is connected to the feeding box, and the other end of the feeding pipe passes through the top of the reaction vessel and is connected to the sprinkling pipe.

8. A copper smelting reactor according to claim 7, wherein a plurality of said sprinklers are disposed around said feed delivery pipe, and an obtuse angle is formed between said sprinklers and said feed delivery pipe.

9. A copper melting reaction device according to claim 7, wherein a first feed port and a second feed port are formed in the top of the feed box, and the second feed port is communicated with the inside of the reaction kettle through a circulating pump.

10. A molten copper reaction apparatus according to claim 7, wherein the bottom of the feed box is formed with an inclined surface which is inclined from a side edge of the feed box toward the center of the feed box, and the inclined surface forms an obtuse angle with a side wall of the feed box.

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