CN113373308A - Utilize acid chemical reaction neodymium iron boron waste recovery device - Google Patents

Abstract

The invention relates to a recovery device, in particular to a recovery device for neodymium iron boron waste materials by utilizing an acidic chemical reaction. The technical problem to be solved by the invention is to provide a recovery device for neodymium iron boron waste materials by utilizing an acidic chemical reaction, which can automatically stir neodymium iron boron and acid safely, and is time-saving and labor-saving. In order to solve the above technical problems, the present invention provides a neodymium iron boron waste recycling device using an acidic chemical reaction, comprising: the bottom plate is connected with a bearing mechanism; and the stirring mechanism is connected to the bearing mechanism. According to the invention, the acid and the neodymium iron boron are stirred by the bearing mechanism and the stirring mechanism to generate a chemical reaction, and the neodymium iron boron waste is discharged and recovered without manually opening the discharge hole of the reaction box by the trigger mechanism, so that the labor is saved, and the working efficiency is improved.

Description

Utilize acid chemical reaction neodymium iron boron waste recovery device

Technical Field

The invention relates to a recovery device, in particular to a recovery device for neodymium iron boron waste materials by utilizing an acidic chemical reaction.

Background

The neodymium magnet is also called neodymium-iron-boron magnet, is a tetragonal crystal formed by neodymium, iron and boron, and in 1982, the Zuochuan true man who is a special metal of Sumitomo discovered the neodymium magnet, and the magnetic energy product of the magnet is larger than that of samarium-cobalt magnet, and is the largest substance in the magnetic energy product all over the world at that time.

At present people carry out acid chemical reaction waste recovery to neodymium iron boron and carry out the manual work usually and place neodymium iron boron in a clean container, then acid and neodymium iron boron contact are poured into to the manual work, and then the manual work stirs neodymium iron boron and acid with the puddler, and last manual work is retrieved neodymium iron boron waste after the reaction, retrieves like this and needs the manual work to do the stirring action always, wastes time and energy, and contact with acid easily at the stirring in-process, causes the injury to the manual work.

Therefore, it is urgently needed to design a recycling device for neodymium iron boron waste materials by utilizing acidic chemical reaction, which can automatically stir neodymium iron boron and acid safely and saves time and labor.

Disclosure of Invention

(1) Technical problem to be solved

In order to overcome the defects that manual stirring is required all the time, time and labor are wasted, the neodymium iron boron and acid are easy to contact in the stirring process, and the harm is caused to the manual work, the technical problem to be solved by the invention is to provide the recovery device for neodymium iron boron waste materials by utilizing the acidic chemical reaction, which can be used for automatically stirring neodymium iron boron and acid safely, and is time-saving and labor-saving.

(2) Technical scheme

In order to solve the above technical problems, the present invention provides a neodymium iron boron waste recycling device using an acidic chemical reaction, comprising: the bottom plate is connected with a bearing mechanism; and the stirring mechanism is connected to the bearing mechanism.

Preferably, the carrying mechanism comprises: support legs connected to the bottom plate; the waste bin is connected to the supporting legs; the supporting rod is connected to the waste bin; and the reaction box is connected to the supporting rod and is positioned right above the waste material box.

Preferably, the stirring mechanism includes: a support plate connected to the reaction chamber; a motor mounted on the supporting plate; the stirring rod is connected to the output shaft of the motor and is positioned in the reaction box.

Preferably, a trigger mechanism is further included, the trigger mechanism comprising: the lifting plate is connected to the output shaft of the motor in a sliding manner and is connected with the reaction box in a sliding manner; the limiting sleeve is connected to the reaction box; the sliding rod is connected to the limiting sleeve in a sliding manner and is matched with the lifting plate; the first spring is sleeved between the sliding rod and the limiting sleeve; the first clutch block is connected to the output shaft of the motor; the second clutch block is connected to the stirring rod in a sliding manner, the second clutch block is matched with the first clutch block, and the second clutch block is positioned right above the lifting plate; the screw rod is connected to the second clutch block; the first connecting rod is connected to the screw rod in a threaded manner and is matched with a discharge hole at the bottom of the reaction tank; the guide sleeve is connected to the reaction box and is connected with the first connecting rod in a sliding manner; and the return spring is connected between the lifting plate and the reaction box.

Preferably, the device further comprises a screening mechanism, wherein the screening mechanism comprises: the lower pressure rod is connected to the first connecting rod; the clamping sleeve is connected to the waste material box and is positioned right below the lower pressing rod; a screen slidably connected to the waste bin; and the second spring is sleeved between the screen and the waste bin.

Preferably, the device further comprises a pushing mechanism, wherein the pushing mechanism comprises: the rack is connected to the first connecting rod; the first bearing seat is connected to the reaction box; the gear is rotatably connected to the first bearing seat and meshed with the rack; the second bearing block is connected to the blanking plate; a rotating shaft rotatably connected to the second bearing housing; a belt connected between the rotating shaft and the gear; the rotating rod is connected to the rotating shaft; a special-shaped rail connected to the rotating rod; the sliding rail is connected to the blanking plate and is in sliding connection with the special-shaped rail; the blanking plate is connected to the reaction box; the first push plate is connected to the blanking plate in a sliding mode and matched with the special-shaped rail.

Preferably, still include unloading mechanism, unloading mechanism includes: a support plate connected to the reaction chamber; a charging box connected to the support plate; the second connecting rod is connected to the first push plate; and the second push plate is connected to the second connecting rod in a sliding manner.

Preferably, a cleaning mechanism is further included, the cleaning mechanism including: a cleaning plate slidably connected to the blanking plate; a push rod connected to the cleaning plate; and the third spring is sleeved between the push rod and the blanking plate.

(3) Advantageous effects

1. Thereby stirring acid and neodymium iron boron through bearing mechanism and rabbling mechanism and producing chemical reaction.

2. Thereby need not the manual work to open the reaction box discharge gate through trigger mechanism and discharge the recovery to the neodymium iron boron waste material, use manpower sparingly, improved work efficiency.

3. Thereby conveniently artifically take out the neodymium iron boron waste material in the screen cloth through screening mechanism.

4. Thereby reach the effect of an intermittent type unloading through pushing equipment, and avoid contacting acid when the stirring through placing the material on blanking plate.

5. Thereby do not need the manual work to place the neodymium iron boron on the blanking plate through unloading mechanism, further use manpower sparingly a large amount of work efficiency that has improved.

6. Thereby clean the blanking plate through clean mechanism, make equipment more pleasing to the eye.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic partial perspective view of a first embodiment of the present invention.

Fig. 3 is a second partial perspective view of the present invention.

Fig. 4 is a schematic view of a partial explosion in perspective according to the present invention.

Fig. 5 is a third partial perspective view of the present invention.

Fig. 6 is a schematic view of a fourth partial perspective structure of the present invention.

Fig. 7 is a schematic partial perspective view of a fifth embodiment of the present invention.

Fig. 8 is a schematic view of a sixth partial perspective structure of the present invention.

The labels in the figures are: 1-bottom plate, 2-bearing mechanism, 20-supporting legs, 21-waste bin, 22-supporting rod, 23-reaction box, 3-stirring mechanism, 30-supporting plate, 31-motor, 32-stirring rod, 4-triggering mechanism, 40-lifting plate, 41-limiting sleeve, 42-sliding rod, 43-first spring, 44-first clutch block, 45-second clutch block, 46-screw rod, 47-first connecting rod, 48-guide sleeve, 49-return spring, 5-screening mechanism, 50-lower pressing rod, 51-clamping sleeve, 52-screen, 53-second spring, 6-pushing mechanism, 60-rack, 61-first bearing seat, 62-gear, 63-second bearing seat, 64-rotating shaft, 65-belt, 66-rotating rod, 67-special-shaped rail, 68-sliding rail, 69-blanking plate, 610-first push plate, 7-blanking mechanism, 70-supporting plate, 71-charging box, 72-second connecting rod, 73-second push plate, 8-cleaning mechanism, 80-cleaning plate, 81-push rod and 82-third spring.

Detailed Description

The invention is further described below with reference to the figures and examples.

Example 1

The utility model provides an utilize acid chemical reaction neodymium iron boron waste recovery device, as shown in figure 1 fig. 2, including bottom plate 1, bearing mechanism 2 and rabbling mechanism 3, 1 upper portion of bottom plate is connected with bearing mechanism 2, and the intermediate junction has rabbling mechanism 3 on 2 upper portions of bearing mechanism.

Bearing mechanism 2 is connected with supporting leg 20 including supporting leg 20, waste bin 21, bracing piece 22 and reaction box 23 at 1 top of bottom plate, and supporting leg 20 upper portion is connected with waste bin 21, and waste bin 21 upper portion front side is connected with bracing piece 22, and bracing piece 22 upper portion rear side is connected with reaction box 23, and reaction box 23 is located directly over waste bin 21.

The stirring mechanism 3 comprises a supporting plate 30, a motor 31 and a stirring rod 32, the supporting plate 30 is connected to the front side of the upper part of the reaction box 23, the motor 31 is installed on the rear side of the upper part of the supporting plate 30, the stirring rod 32 is connected to the output shaft of the motor 31, and the stirring rod 32 is located in the reaction box 23.

When needs retrieve the indisputable boron waste material of Ru, can use this equipment, at first the artifical discharge gate of plugging up 23 bottoms of reaction box, put into reaction box 23 with sour and neodymium iron boron after that, then rotate through artifical starter motor 31 and drive puddler 32 and rotate, puddler 32 rotates and stirs sour and neodymium iron boron and mixes, opens the discharge gate through the manual work after the mixture is accomplished and makes the neodymium iron boron waste material after taking place chemical reaction drop and retrieve in waste bin 21, so repeatedly.

Example 2

On the basis of embodiment 1, as shown in fig. 3 and 4, the device further includes a trigger mechanism 4, the trigger mechanism 4 includes a lifting plate 40, a limit sleeve 41, a sliding rod 42, a first spring 43, a first clutch block 44, a second clutch block 45, a screw rod 46, a first connecting rod 47, a guide sleeve 48 and a return spring 49, the output shaft of the motor 31 is slidably connected with the lifting plate 40, the lifting plate 40 is slidably connected with the reaction box 23, the left side of the upper portion of the reaction box 23 is connected with the limit sleeve 41, the upper portion of the limit sleeve 41 is slidably connected with the sliding rod 42, the sliding rod 42 is engaged with the lifting plate 40, the first spring 43 is sleeved between the sliding rod 42 and the limit sleeve 41, the output shaft of the motor 31 is connected with the first clutch block 44, the upper portion of the stirring rod 32 is slidably connected with the second clutch block 45, the second clutch block 45 is engaged with the first clutch block 44, the second clutch block 45 is located right above the lifting plate 40, the lower portion of the second clutch block 45 is connected with the screw rod 46, the upper part of the screw rod 46 is connected with a first connecting rod 47 in a threaded manner, the first connecting rod 47 is matched with a discharge hole at the bottom of the reaction box 23, the right side of the reaction box 23 is connected with a guide sleeve 48, the guide sleeve 48 is connected with the first connecting rod 47 in a sliding manner, and a return spring 49 is connected between the lifting plate 40 and the reaction box 23.

When the neodymium iron boron waste is recovered, the lifting plate 40 is pulled to move upwards manually to drive the sliding rod 42 to move leftwards, the lifting plate 40 moves upwards to drive the return spring 49 to be stretched, the sliding rod 42 moves leftwards to drive the first spring 43 to be compressed, the lifting plate 40 moves upwards to drive the first clutch block 44 to move upwards, the first clutch block 44 moves upwards to be meshed with the second clutch block 45, when the sliding rod 42 is not in contact with the lifting plate 40, the sliding rod 42 is reset under the action of the compressed first spring 43 to enable the lifting plate 40 to be limited, at the moment, the motor 31 rotates to drive the first clutch block 44 and the second clutch block 45 to rotate, the second clutch block 45 rotates to drive the lead screw 46 to rotate, the lead screw 46 rotates to drive the first connecting rod 47 to move downwards, the first connecting rod 47 moves downwards to enable the discharge hole of the reaction box 23 to be opened, and therefore the neodymium iron boron waste does not need to be discharged and recovered by manually opening the discharge hole of the reaction box 23, manpower is saved, work efficiency is improved, and after recovery is completed, the lifting plate 40 is reset under the action of the stretched reset spring 49 by manually pulling the sliding rod 42 to move leftwards.

Example 3

On the basis of the embodiment 2, as shown in fig. 5, the automatic waste bin sorting device further comprises a sorting mechanism 5, wherein the sorting mechanism 5 comprises a lower pressing rod 50, a clamping sleeve 51, a screen 52 and a second spring 53, the lower left side of the lower portion of a first connecting rod 47 is connected with the lower pressing rod 50, the front side and the rear side of the upper portion of the waste bin 21 are connected with the clamping sleeves 51, the clamping sleeves 51 are located under the lower pressing rod 50, the upper portion of the waste bin 21 is connected with the screen 52 in a sliding mode, and the second spring 53 is sleeved between the screen 52 and the waste bin 21.

When the first connecting rod 47 moves downwards, the first connecting rod 47 moves downwards to drive the lower pressing rod 50 to move downwards, the lower pressing rod 50 moves downwards to be clamped with the screen 52, the lower pressing rod 50 drives the screen 52 to move upwards when returning upwards, so that neodymium iron boron waste materials in the screen 52 can be conveniently taken out manually, the screen 52 moves upwards, the second spring 53 is stretched, when the second spring 53 is stretched to a certain degree, the lower pressing rod 50 is separated from the screen 52 to be clamped, and the screen 52 returns under the action of the second spring 53.

Example 4

In addition to embodiment 3, as shown in fig. 6, the material pushing apparatus 6 further includes a material pushing mechanism 6, the material pushing mechanism 6 includes a rack 60, a first bearing seat 61, a gear 62, a second bearing seat 63, a rotating shaft 64, a belt 65, a rotating rod 66, a profile rail 67, a slide rail 68, a material dropping plate 69 and a first push plate 610, the rack 60 is connected to the rear side of the upper portion of the first connecting rod 47, the first bearing seat 61 is connected to the right side of the upper portion of the reaction box 23, the gear 62 is rotatably connected to the lower portion of the right side of the first bearing seat 61, the gear 62 is engaged with the rack 60, the material dropping plate 69 is connected to the rear side of the upper portion of the reaction box 23, the second bearing seat 63 is connected to the rear side of the right side of the material dropping plate 69, the rotating shaft 64 is rotatably connected to the front side of the second bearing seat 63, the belt 65 is connected between the rotating shaft 64 and the gear 62, the rotating rod 66 is connected to the left side of the rotating shaft, the profile rail 67 is connected to the front side of the rotating rod 66, the front portion of the material dropping plate 69 is connected to a slide rail 68, the slide rail 68 is connected with the special-shaped rail 67 in a sliding way, the front part of the inner side of the blanking plate 69 is connected with a first push plate 610 in a sliding way, and the first push plate 610 is matched with the special-shaped rail 67.

When the first connecting rod 47 moves downwards, the first connecting rod 47 moves downwards to drive the gear 62 to rotate, the gear 62 rotates to drive the rotating shaft 64 to rotate through the belt 65, the rotating shaft 64 rotates to drive the rotating rod 66 to rotate, the rotating rod 66 rotates to drive the special-shaped rail 67 to move backwards, the special-shaped rail 67 moves backwards to drive the first push plate 610 to move backwards, when the first push plate 610 moves backwards to a limit position, neodymium iron boron is manually placed on the front side of the blanking plate 69, the first connecting rod 47 drives the first push plate 610 to move forwards when upwards resetting, the operation is repeated, and therefore an intermittent blanking effect is achieved, and materials are placed on the blanking plate 69 to avoid contacting with acid during stirring.

On the basis of embodiment 3, as shown in fig. 7, the device further comprises a blanking mechanism 7, wherein the blanking mechanism 7 comprises a supporting plate 70, a charging box 71, a second connecting rod 72 and a second push plate 73, the supporting plate 70 is connected to the rear side of the top of the reaction box 23, the charging box 71 is connected to the upper portion of the supporting plate 70, the second connecting rod 72 is connected to the rear side of the lower portion of the first push plate 610, and the second push plate 73 is slidably connected to the rear side of the second connecting rod 72.

When needs carry out the unloading to the neodymium iron boron, drive second push pedal 73 rearward movement through first push pedal 610 rearward movement, second push pedal 73 rearward movement makes the neodymium iron boron drop on blanking plate 69, when first push pedal 610 forward movement, first push pedal 610 forward movement drives second push pedal 73 forward movement, second push pedal 73 forward movement pushes away the neodymium iron boron to reaction box 23 in, thereby do not need the manual work to place the neodymium iron boron on blanking plate 69, further use manpower sparingly a large amount of work efficiency that has improved.

On the basis of embodiment 3, as shown in fig. 8, the cleaning device further includes a cleaning mechanism 8, the cleaning mechanism 8 includes a cleaning plate 80, a pushing rod 81 and a third spring 82, the cleaning plate 80 is slidably connected to the rear side inside the blanking plate 69, the pushing rod 81 is connected to the rear side of the cleaning plate 80, and the third spring 82 is sleeved between the pushing rod 81 and the blanking plate 69.

After the neodymium iron boron waste recovery is accomplished, promote push rod 81 through the manual work and move forward and drive cleaning plate 80 forward motion to clean blanking plate 69, make equipment more pleasing to the eye, third spring 82 is compressed this moment, stops to promote push rod 81, and third spring 82 is tensile to drive cleaning plate 80 rearward movement through push rod 81 and resets.

The above examples are merely representative of preferred embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, various changes, modifications and substitutions can be made without departing from the invention, and all such changes, modifications and substitutions fall within the scope of the invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (8)

1. The utility model provides an utilize acid chemical reaction neodymium iron boron waste recovery device which characterized in that includes:

the bottom plate (1) is connected with a bearing mechanism (2);

and the stirring mechanism (3) is connected to the bearing mechanism (2).

2. The recycling device for neodymium iron boron waste materials by utilizing acid chemical reaction according to claim 1, characterized in that the bearing mechanism (2) comprises:

support legs (20) connected to the base plate (1);

a waste bin (21) connected to the support leg (20);

a support bar (22) connected to the waste bin (21);

and the reaction box (23) is connected to the support rod (22), and the reaction box (23) is positioned right above the waste box (21).

3. The recycling device for neodymium iron boron waste materials by utilizing acid chemical reaction according to claim 2, characterized in that the stirring mechanism (3) comprises:

a support plate (30) connected to the reaction chamber (23);

a motor (31) mounted on the support plate (30);

and the stirring rod (32) is connected to an output shaft of the motor (31), and the stirring rod (32) is positioned in the reaction box (23).

4. The recycling device for neodymium iron boron waste materials by utilizing acidic chemical reaction according to claim 3, characterized by further comprising a trigger mechanism (4), wherein the trigger mechanism (4) comprises:

a lifting plate (40) which is connected to the output shaft of the motor (31) in a sliding manner, wherein the lifting plate (40) is connected with the reaction box (23) in a sliding manner;

a limiting sleeve (41) connected to the reaction box (23);

a sliding rod (42) which is connected to the limiting sleeve (41) in a sliding manner, wherein the sliding rod (42) is matched with the lifting plate (40);

the first spring (43) is sleeved between the sliding rod (42) and the limiting sleeve (41);

a first clutch block (44) connected to an output shaft of the motor (31);

the second clutch block (45) is connected to the stirring rod (32) in a sliding mode, the second clutch block (45) is matched with the first clutch block (44), and the second clutch block (45) is located right above the lifting plate (40);

a spindle (46) connected to the second clutch plate (45);

the first connecting rod (47) is connected to the screw rod (46) in a threaded manner, and the first connecting rod (47) is matched with a discharge hole at the bottom of the reaction box (23);

the guide sleeve (48) is connected to the reaction box (23), and the guide sleeve (48) is connected with the first connecting rod (47) in a sliding manner;

and a return spring (49) connected between the lift plate (40) and the reaction box (23).

5. The recycling device for neodymium iron boron waste materials by utilizing acid chemical reaction according to claim 4, characterized in that it further comprises a screening mechanism (5), the screening mechanism (5) comprises:

a lower pressure lever (50) connected to the first connecting rod (47);

the clamping sleeve (51) is connected to the waste box (21), and the clamping sleeve (51) is positioned right below the lower pressing rod (50);

a screen (52) slidably connected to the waste bin (21);

and the second spring (53) is sleeved between the screen (52) and the waste box (21).

6. The recycling device for neodymium iron boron waste materials by using acidic chemical reaction according to claim 5, characterized in that it further comprises a material pushing mechanism (6), the material pushing mechanism (6) comprises:

a rack (60) connected to the first connecting rod (47);

a first bearing block (61) connected to the reaction tank (23);

a gear (62) rotatably connected to the first bearing housing (61), the gear (62) meshing with the rack (60);

a second bearing block (63) connected to the blanking plate (69);

a rotating shaft (64) rotatably connected to the second bearing housing (63);

a belt (65) connected between the rotating shaft (64) and the gear (62);

a rotating rod (66) connected to the rotating shaft (64);

a profile rail (67) connected to the rotating rod (66);

the sliding rail (68) is connected to the blanking plate (69), and the sliding rail (68) is connected with the special-shaped rail (67) in a sliding manner;

a blanking plate (69) connected to the reaction box (23);

a first push plate (610) slidably connected to the blanking plate (69), the first push plate (610) cooperating with the profiled rail (67).

7. The recycling device for neodymium iron boron waste materials by utilizing acidic chemical reaction according to claim 6, characterized by further comprising a blanking mechanism (7), wherein the blanking mechanism (7) comprises:

a support plate (70) connected to the reaction chamber (23);

a charging box (71) connected to the support plate (70);

a second connecting rod (72) connected to the first push plate (610);

a second push plate (73) slidably connected to the second connecting rod (72).

8. The recycling device for neodymium iron boron waste materials by utilizing acid chemical reaction according to claim 7, characterized in that it further comprises a cleaning mechanism (8), the cleaning mechanism (8) comprises:

a cleaning plate (80) slidably attached to the blanking plate (69);

a push rod (81) connected to the cleaning plate (80);

and the third spring (82) is sleeved between the push rod (81) and the blanking plate (69).

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