阅读说明：本技术 一种废催化剂熔炼回收装置 (Recovery unit is smelted to useless catalyst ) 是由 杜占平 葛凌云 孙永华 于 2021-07-31 设计创作，主要内容包括：本发明涉及一种废催化剂熔炼回收装置,涉及催化剂回收的技术领域,其包括回收桶,回收桶的侧壁上开设有排料口,回收桶的侧壁上设置有排料槽,排料槽与排料口连通,排料槽中设置有卸料机构,回收桶内设置有用于导料的导料机构。本发明中金属球的形成以及排出互不影响,使得熔融状态的镍、钴、钼可以被连续冷却,提高了镍、钴、钼的回收效率。(The invention relates to a waste catalyst smelting and recycling device, which relates to the technical field of catalyst recycling and comprises a recycling bin, wherein a discharge opening is formed in the side wall of the recycling bin, a discharge groove is formed in the side wall of the recycling bin and communicated with the discharge opening, a discharge mechanism is arranged in the discharge groove, and a material guide mechanism for guiding materials is arranged in the recycling bin. The formation and the discharge of the metal balls are not influenced mutually, so that the nickel, the cobalt and the molybdenum in a molten state can be continuously cooled, and the recovery efficiency of the nickel, the cobalt and the molybdenum is improved.)

1. A waste catalyst smelting recovery device is characterized in that; including recycling bin (200), bin outlet (210) have been seted up on the lateral wall of recycling bin (200), be provided with blow-off groove (220) on the lateral wall of recycling bin (200), blow-off groove (220) with blow-off opening (210) intercommunication, be provided with discharge mechanism (400) in blow-off groove (220), be provided with guide mechanism (300) that are used for the guide in recycling bin (200).

2. The apparatus for recovering spent catalyst from smelting as recited in claim 1, wherein: the material guide mechanism (300) comprises a first driving motor (310) and a material guide plate (320), the material guide plate (320) is arranged in a conical shape, the outer peripheral surface of the material guide plate (320) is abutted to the inner peripheral surface of the recycling bin (200), the material guide plate (320) is rotatably connected with the recycling bin (200) along the axis of the material guide plate (320), the first driving motor (310) is fixedly connected to the recycling bin (200), and the first driving motor (310) is in transmission connection with the material guide plate (320).

3. The apparatus for recovering spent catalyst from smelting as recited in claim 2, wherein: the material guiding mechanism (300) further comprises a plurality of partition plates (330), the partition plates (330) are fixedly connected to the upper end face of one side, away from the axis of the material guiding plate (320), of the material guiding plate, and a partition groove (340) is formed between every two adjacent partition plates (330).

4. The apparatus for recovering spent catalyst from smelting as recited in claim 2, wherein: discharge mechanism (400) includes chain (410), sprocket (420) and second driving motor (430), sprocket (420) rotates to be connected on the lateral wall of discharge chute (220), the output shaft of second driving motor (430) with sprocket (420) transmission is connected, chain (410) cover is established on sprocket (420), the material loading end of chain (410) is less than bin outlet (210), the unloading end of chain (410) is higher than the material loading end of chain (410).

5. The apparatus for recovering spent catalyst from smelting as recited in claim 4, wherein: fixedly connected with takes flitch (411) on the outer peripheral face of chain (410), take the both ends of flitch (411) respectively with the both sides wall butt of bin outlet (210).

6. The apparatus for recovering spent catalyst from smelting as recited in claim 5, wherein: the material carrying plates (411) are arranged in an arc shape, and the arc direction of the material carrying plates (411) is opposite to the conveying direction of the chain (410).

7. The apparatus for recovering spent catalyst from smelting as recited in any one of claims 2 to 6, wherein: the recycling bin (200) is further provided with a pre-cooling mechanism (500), the pre-cooling mechanism (500) comprises a guide chute (510) and a pre-cooling pipe (520), the guide chute (510) is fixedly connected to the recycling bin (200), the guide chute (510) is obliquely arranged, the lowest end of the guide chute (510) faces the inside of the recycling bin (200), the pre-cooling pipe (520) is fixedly connected to the recycling bin (200), and the outlet of the pre-cooling pipe (520) is over against the lowest end of the guide chute (510).

8. The apparatus for recovering spent catalyst from smelting as recited in claim 7, wherein: still be provided with circulation mechanism (600) on recycling bin (200), circulation mechanism (600) includes first water pump (610), cooling water tank (620) and second water pump (630), the end intercommunication of intaking of first water pump (610) the bottom of recycling bin (200), the play water end intercommunication of first water pump (610) cooling water tank (620), cooling water tank (620) rethread second water pump (630) with recycling bin (200) intercommunication.

9. The apparatus for recovering spent catalyst from smelting as recited in claim 8, wherein: the water outlet end of the second water pump (630) is communicated with the water inlet end of the pre-cooling pipe (520).

Technical Field

The invention relates to the field of catalyst recovery, in particular to a waste catalyst smelting recovery device.

Background

The hydrogenation catalyst can be used in the production process of products and also can be widely used in the refining process of raw materials and products. The hydrogenation catalyst includes selective hydrogenation catalyst, non-selective hydrogenation catalyst and hydrogenolysis catalyst. When petroleum hydrocarbon is cracked into ethylene, propylene and the like which are used as raw materials for polymerization, selective hydrogenation is firstly carried out to remove trace impurities such as alkyne, diene, carbon monoxide, carbon dioxide, oxygen and the like without losing alkene, and in this case, a selective hydrogenation catalyst is required. The selective hydrogenation catalyst is generally prepared by supporting nickel, cobalt, molybdenum on alumina.

At present, most of the methods of melting are used to recover nickel, cobalt and molybdenum in the catalyst, i.e. the catalyst which is about to lose effectiveness is placed in a heating furnace to be heated, so that the nickel, cobalt and molybdenum are in a molten state, and then the molten nickel, cobalt and molybdenum are poured into cold water to be rapidly cooled, so that metal balls are formed.

Referring to fig. 1, when molten nickel, cobalt, molybdenum are cooled and finally formed metal balls are collected, a recovery tank 110 is mostly used, the recovery tank 110 is filled with cooling water, an aggregate plate 120 for aggregating is arranged in the recovery tank 110, a baffle 121 is fixedly connected to the upper end surface of the aggregate plate 120, and a notch 122 is formed in the baffle 121. When the material collecting plate 120 is used, the material collecting plate 120 is arranged in cooling water, then molten nickel, cobalt and molybdenum can be poured into the recovery pool 110, the nickel, cobalt and molybdenum are cooled by water to form metal balls, the metal balls fall on the material collecting plate 120 under the action of gravity, after the nickel, cobalt and molybdenum are cooled, the material collecting plate 120 is taken out from the recovery pool 110, the cooling water on the material collecting plate 120 can flow out from the notch 122, and only the metal balls are left on the material collecting plate 120 at the moment.

In view of the above-mentioned related arts, the inventors considered that, when cooling the molten nickel, cobalt, and molybdenum, the aggregate plate needs to be taken out from the recovery pond once the metal balls are fully accumulated on the aggregate plate, and thus the cooling of the nickel, cobalt, and molybdenum must be suspended, which reduces the recovery efficiency of the nickel, cobalt, and molybdenum.

Disclosure of Invention

The invention provides a waste catalyst smelting and recycling device in order to improve the recycling efficiency of nickel, cobalt and molybdenum.

The invention provides a waste catalyst smelting recovery device, which adopts the following technical scheme:

the utility model provides a recovery unit is smelted to useless catalyst, includes the recycling bin, the bin outlet has been seted up on the lateral wall of recycling bin, be provided with the blow off tank on the lateral wall of recycling bin, the blow off tank with the bin outlet intercommunication, be provided with shedding mechanism in the blow off tank, be provided with the guide mechanism who is used for the guide in the recycling bin.

By adopting the technical scheme, when the recovery device is used, the recovery barrel is filled with cooling water, then the nickel, cobalt and molybdenum in a molten state are poured into the recovery barrel, at the moment, the nickel, cobalt and molybdenum are cooled to form metal balls, then the metal balls are discharged to the discharge chute from the discharge opening under the action of the material guide mechanism, and then the metal balls in the discharge chute are discharged out of the discharge chute by the discharge mechanism; through the arrangement of the material guide mechanism and the material discharge mechanism, the formation and discharge of the metal balls are not influenced mutually, so that the nickel, cobalt and molybdenum in a molten state can be continuously cooled, and the recovery efficiency of the nickel, cobalt and molybdenum is improved.

Optionally, the material guiding mechanism includes a first driving motor and a material guiding plate, the material guiding plate is disposed in a conical shape, an outer peripheral surface of the material guiding plate abuts against an inner peripheral surface of the recycling bin, the material guiding plate is rotatably connected with the recycling bin along an axis of the material guiding plate, the first driving motor is fixedly connected to the recycling bin, and the first driving motor is in transmission connection with the material guiding plate.

Through adopting above-mentioned technical scheme, after molten nickel, cobalt, molybdenum pour into the recycling bin and solidify into the metal ball, the metal ball can fall in the one side that self axle center was kept away from to the stock guide under the effect of gravity, later the stock guide takes place rotatoryly under driving action of a driving motor, when the metal ball was rotated to discharge outlet department, the metal ball rolled out from discharge outlet department, and then was carried to discharge mechanism on.

Optionally, the material guiding mechanism further includes a plurality of partition plates, the partition plates are fixedly connected to the upper end surface of one side of the material guiding plate away from the axis of the material guiding plate, and a separation groove is formed between two adjacent partition plates.

Through adopting above-mentioned technical scheme, the metal ball falls to separating the groove under the effect of gravity, and the stock guide rotates under first driving motor's drive effect, and the division board just drives the metal ball more easily and rotates this moment, has reduced the probability that metal ball slew rate reduces under the effect of the resistance of water, has improved the recovery efficiency of nickel, cobalt, molybdenum.

Optionally, discharge mechanism includes chain, sprocket and second driving motor, the sprocket rotates to be connected on the lateral wall of blow-off groove, second driving motor's output shaft with sprocket drive is connected, the chain cover is established sprocket is last, the material loading end of chain is less than the bin outlet, the unloading end of chain is higher than the material loading end of chain.

By adopting the technical scheme, the metal balls discharged from the discharge outlet fall on the feeding end of the chain, and then leave the discharging mechanism from the discharging end of the chain under the driving action of the chain; the metal balls conveyed to the discharging mechanism by the material guide plate can be continuously conveyed, so that the nickel, cobalt and molybdenum in a molten state can be continuously cooled, and the recovery efficiency of the nickel, cobalt and molybdenum is improved.

Optionally, a material carrying plate is fixedly connected to the outer peripheral surface of the chain, and two ends of the material carrying plate are respectively abutted to two side walls of the discharge port.

Through adopting above-mentioned technical scheme, when using the chain to carry the metal ball, under the effect of blockking of taking the flitch, the metal ball is difficult for rolling downwards on the chain, has improved the conveying efficiency of metal ball, and then has improved the recovery efficiency of nickel, cobalt, molybdenum.

Optionally, the material carrying plate is arranged in an arc shape, and the arc direction of the material carrying plate is opposite to the conveying direction of the chain.

Through adopting above-mentioned technical scheme, when taking the flitch to pass through discharge opening department, the metal ball that is located discharge opening department rolls to the row flitch more easily on, has reduced the probability that the metal ball rolls back to the recycling bin in from discharge opening department, has improved the conveying efficiency of metal ball, and then has improved the recovery efficiency of nickel, cobalt, molybdenum.

Optionally, a pre-cooling mechanism is further disposed on the recycling bin, the pre-cooling mechanism includes a material guiding groove and a pre-cooling pipe, the material guiding groove is fixedly connected to the recycling bin, the material guiding groove is obliquely disposed, a bottom end of the material guiding groove faces the inside of the recycling bin, the pre-cooling pipe is fixedly connected to the recycling bin, and an outlet of the pre-cooling pipe faces a bottom end of the material guiding groove.

By adopting the technical scheme, when molten nickel, cobalt and molybdenum are poured into the recycling bin, the molten nickel, cobalt and molybdenum are poured into the guide chute, the molten nickel, cobalt and molybdenum gradually flow into the recycling bin under the action of gravity, cold water sprayed from the pre-cooling pipe is contacted with the molten nickel, cobalt and molybdenum while the molten nickel, cobalt and molybdenum flow out of the guide chute, and the cold water pre-cools the molten nickel, cobalt and molybdenum to reduce the particle size of the formed metal balls, so that the surface area of the metal balls in unit weight is increased, the cooling rate of the metal balls is increased, the metal balls are cooled into lumps, and the metal balls are convenient to convey.

Optionally, a circulating mechanism is further arranged on the recycling bin and comprises a first water pump, a cooling water tank and a second water pump, the water inlet end of the first water pump is communicated with the bottom end of the recycling bin, the water outlet end of the first water pump is communicated with the cooling water tank, and the cooling water tank is communicated with the recycling bin through the second water pump.

Through adopting above-mentioned technical scheme, water in the recycling bin can be heated by molten nickel, cobalt, molybdenum, and the water after the heating is cooled off in being delivered to the cooling water tank by first water pump, later passes through the second water pump with the water in the cooling water tank and delivers to the recycling bin in to improve the cooling efficiency of nickel, cobalt, molybdenum.

Optionally, the water outlet end of the second water pump is communicated with the water inlet end of the pre-cooling pipe.

Through adopting above-mentioned technical scheme, when pouring into the recycling bin with fused nickel, cobalt, molybdenum, first water pump constantly carries the water in the recycling bin to the cooling water tank cooling, and during the second water pump constantly sends the water pump in the cooling water tank to the precooling pipe, and then carries out the precooling to fused nickel, cobalt, molybdenum, improved the cooling efficiency of cooling water, and then improved the cooling efficiency to nickel, cobalt, molybdenum.

In summary, the invention includes at least one of the following beneficial technical effects:

1. through the arrangement of the material guide mechanism and the material discharge mechanism, the formation and the discharge of the metal balls are not influenced mutually, so that the nickel, the cobalt and the molybdenum in a molten state can be cooled continuously, and the recovery efficiency of the nickel, the cobalt and the molybdenum is improved.

2. Through the setting of separating the groove, the stock guide rotates under driving action of first driving motor, makes the division board drive the metal ball rotation more easily, has reduced the probability that metal ball slew rate reduces under the effect of the resistance of water, has improved the recovery efficiency of nickel, cobalt, molybdenum.

3. Through the setting of taking the flitch, under the effect of blockking of taking the flitch, the metal ball is difficult for rolling downwards on the chain, has improved the conveying efficiency of metal ball, and then has improved the recovery efficiency of nickel, cobalt, molybdenum.

4. Through the setting of precooling mechanism, the cold water that spouts from the precooling pipe precools fused nickel, cobalt, molybdenum to reduce the particle size of the metal ball that forms, so increased the surface area of metal ball in the unit weight, improved the cooling rate of metal ball, reduced the metal ball moreover and cooled into the heap, the transport of the metal ball of being convenient for.

Drawings

Fig. 1 is an overall structural view of the related art;

FIG. 2 is a schematic diagram of the overall structure of an embodiment of the present invention;

FIG. 3 is a schematic view of the structure of a material guide plate according to an embodiment of the present invention;

fig. 4 is a schematic view of the entire structure of the discharging mechanism according to the embodiment of the present invention.

Description of reference numerals: 110. a recovery tank; 120. a material collecting plate; 121. a baffle plate; 122. a notch; 123. lifting lugs; 200. a recycling bin; 210. a discharge outlet; 220. a discharge chute; 300. a material guiding mechanism; 310. a first drive motor; 320. a material guide plate; 330. a partition plate; 340. a separation tank; 400. a discharge mechanism; 410. a chain; 411. a material carrying plate; 420. a sprocket; 430. a second drive motor; 500. a pre-cooling mechanism; 510. a material guide chute; 520. a pre-cooling tube; 600. a circulating mechanism; 610. a first water pump; 620. a cooling water tank; 630. and a second water pump.

Detailed Description

The invention is described in further detail below with reference to figures 1-4.

Referring to fig. 1, in the related art, a recycling apparatus for nickel, cobalt, and molybdenum includes a recycling tank 110, the recycling tank 110 is filled with cooling water, and molten nickel, cobalt, and molybdenum need to be poured into the recycling tank 110 for cooling, and then solidified into metal balls. The recovery tank 110 is provided with a material collecting plate 120 for collecting materials, the material collecting plate 120 is disposed in the cooling water during use, and the outer peripheral surface of the material collecting plate 120 abuts against the inner peripheral surface of the recovery tank 110. A plurality of lifting lugs 123 are welded on the upper end face of the material collecting plate 120, and an operator can lift the material collecting plate 120 by matching a lifting hook through lifting equipment, so that the material collecting plate 120 is placed into the recovery tank 110 or the material collecting plate 120 is taken out from the recovery tank 110.

Referring to fig. 1, after the material collecting plate 120 is placed in the recycling tank 110, molten nickel, cobalt and molybdenum can be poured into the recycling tank 110, the nickel, cobalt and molybdenum are cooled by water to form metal balls, the metal balls fall on the material collecting plate 120 under the action of gravity, and after the nickel, cobalt and molybdenum are cooled, the material collecting plate 120 is taken out of the recycling tank 110. The baffle 121 is welded on the upper end face of the material collecting plate 120, and a notch 122 is formed in the baffle 121. The material collecting plate 120 is taken out from the recovery tank 110, so that the cooling water on the material collecting plate 120 can flow out from the notch 122, only the metal balls are left on the material collecting plate 120 at the moment, and finally the metal balls can be taken out from the notch 122.

Referring to fig. 1, when the molten nickel, cobalt, and molybdenum are cooled, the collection plates 120 are required to be removed from the recovery pond 110 once the collection plates 120 are filled with the metal balls, and thus the cooling of the molten nickel, cobalt, and molybdenum must be suspended, and thus the molten nickel, cobalt, and molybdenum must be cooled in batches. The molten nickel, cobalt and molybdenum are cooled in batches, so that the recovery efficiency of the nickel, cobalt and molybdenum is reduced, and the molten nickel, cobalt and molybdenum need to be continuously heated when the material collecting plate 120 is replaced, otherwise the molten nickel, cobalt and molybdenum can be solidified, and the energy consumption is increased.

Therefore, the embodiment of the application discloses a waste catalyst smelting and recycling device. Referring to fig. 2, the waste catalyst smelting and recovering device includes a recovery barrel 200 for containing cooling water, a material guiding mechanism 300 disposed in the recovery barrel 200 and guiding metal balls, a discharging mechanism 400 disposed outside the recovery barrel 200 and conveying the metal balls, a pre-cooling mechanism 500 disposed at an upper portion of the recovery barrel 200 and pre-cooling the molten nickel, cobalt and molybdenum, and a circulating mechanism 600 for recycling the cooling water in the recovery barrel 200.

Referring to fig. 2, when the recycling apparatus is used, the recycling bin 200 is filled with cooling water, then the molten nickel, cobalt and molybdenum are poured onto the pre-cooling mechanism 500, the pre-cooling mechanism 500 pre-cools the molten nickel, cobalt and molybdenum, then the molten nickel, cobalt and molybdenum flow into the recycling bin 200 for final cooling, so that the molten nickel, cobalt and molybdenum are solidified into metal balls, then the material guiding mechanism 300 conveys the metal balls to the feeding position of the discharging mechanism 400, and then the discharging mechanism 400 continuously conveys the metal balls to the storage area of the metal balls for storage. The circulation mechanism 600 circulates the cooling water in the recovery tub 200 to keep the cooling water at a low temperature all the time, thereby improving the cooling efficiency.

Referring to fig. 2, due to the arrangement of the material guiding mechanism 300 and the material discharging mechanism 400, the formation and discharge of the metal balls are not affected, and the melted nickel, cobalt and molybdenum in the heating furnace can be directly poured into the recovery device for recovery, so that the melted nickel, cobalt and molybdenum can be continuously cooled, the recovery efficiency of the nickel, cobalt and molybdenum is improved, and the energy consumption is reduced.

Referring to fig. 2, the pre-cooling mechanism 500 includes a guide chute 510 for guiding the molten nickel, cobalt, and molybdenum, and a pre-cooling pipe 520 for supplying cooling water, the guide chute 510 is welded to the upper end of the recovery tank 200, and one end of the guide chute 510 close to the inside of the recovery tank 200 is lower than one end far from the recovery tank 200. The pre-cooling pipe 520 is arranged on the side wall of the recycling bin 200 in a penetrating way, and the pre-cooling pipe 520 continuously sprays cooling water into the recycling bin 200, and the water outlet end of the pre-cooling pipe 520 is aligned to the bottommost end of the material guide groove 510.

Referring to fig. 2, the molten nickel, cobalt, and molybdenum are poured into the material guide chute 510, and under the action of gravity, the molten nickel, cobalt, and molybdenum gradually flow into the recycling bin 200, and when leaving the material guide chute 510, the molten nickel, cobalt, and molybdenum are in contact with the cooling water sprayed from the pre-cooling pipe 520, so that the molten nickel, cobalt, and molybdenum can be primarily cooled. Under the spraying action of the cooling water, the molten nickel, cobalt and molybdenum which continuously flow are dispersed, and the molten nickel, cobalt and molybdenum can be solidified into metal balls with smaller particle sizes after falling into the recycling bin 200, so that the probability of the nickel, cobalt and molybdenum adhering to the inner wall of the recycling bin 200 is reduced, the probability of the metal balls adhering to each other is reduced, and the metal balls can be guided and conveyed conveniently in the following process.

Referring to fig. 2, the circulation mechanism 600 includes a first water pump 610, a cooling water tank 620, and a second water pump 630, wherein a water inlet end of the first water pump 610 is communicated with the lowermost end of the recycling bin 200, a water outlet end of the first water pump 610 is communicated with the cooling water tank 620, a water inlet end of the second water pump 630 is communicated with the cooling water tank 620, and a water outlet end of the second water pump 630 is communicated with a water inlet end of the pre-cooling pipe 520. The water in the recycling bin 200 is continuously conveyed into the cooling water tank 620 by the first water pump 610 for cooling, the cooling water in the cooling water tank 620 is continuously conveyed into the pre-cooling pipe 520 by the second water pump 630, and the cooling water flows into the recycling bin 200 after pre-cooling the molten nickel, cobalt and molybdenum, so that the cooling water can be recycled.

Referring to fig. 2 and 3, the material guiding mechanism 300 includes a material guiding plate 320 for driving the metal balls to move and a first driving motor 310 for driving the material guiding plate 320 to rotate, the material guiding plate 320 is disposed in a conical shape, the material guiding plate 320 is coaxially disposed in the recycling bin 200, and an outer circumferential surface of the material guiding plate 320 abuts against an inner circumferential surface of the recycling bin 200, so that the metal balls are not easy to pass through the material guiding plate 320 and enter a bottom of the recycling bin 200. The first driving motor 310 is fixedly connected to the recycling bin 200 through a bolt, and an output shaft of the first driving motor 310 is connected to the material guiding plate 320 through a transmission rod, so that the material guiding plate 320 can rotate along the axis of the material guiding plate under the driving action of the first driving motor 310. A plurality of partition plates 330 are welded to the upper end surface of the material guide plate 320, the partition plates 330 are disposed on one side of the material guide plate 320 away from the axis of the material guide plate, the partition plates 330 are uniformly disposed along the circumference of the material guide plate 320, and a partition groove 340 is formed between two adjacent partition plates 330.

Referring to fig. 2 and 3, the molten nickel, cobalt, and molybdenum fall into the recycling bin 200 and are completely cooled by the cooling water to form metal balls, and the metal balls fall into the separation groove 340 under the action of gravity, and rotate together with the material guide plate 320 when the material guide plate 320 is driven to rotate by the first driving motor 310. The lateral wall of the recycling bin 200 is provided with a discharge outlet 210, the peripheral surface of the recycling bin 200 is welded with a discharge groove 220, the discharge groove 220 is communicated with the discharge outlet 210, and one end of the discharge groove 220 close to the discharge outlet 210 is lower than the discharge outlet 210. When the metal balls rotate to the discharge opening 210 along with the guide plate 320, the metal balls roll down from the discharge opening 210 to the discharge chute 220 under the action of gravity. Since the discharge groove 220 communicates with the inside of the recovery tank 200 through the discharge opening 210 and the recovery tank 200 is filled with cooling water, the upper end surface of the discharge groove 220 is higher than the water level in the recovery tank 200. In order to prolong the cooling time of the metal balls, the discharge opening 210 is formed at the rear end of the lowermost end of the guide chute 510, so that the metal balls can roll down from the discharge opening 210 to the discharge chute 220 only after rotating one turn along with the guide plate 320.

Referring to fig. 2 and 4, the discharging mechanism 400 includes a chain 410, a sprocket 420, and a second driving motor 430 for driving the chain 410 to rotate, the sprocket 420 is rotatably connected to the side wall of the discharging groove 220, the chain 410 is sleeved on the sprocket 420, the second driving motor 430 is fixedly connected to the outer side wall of the discharging groove 220 through a bolt, and an output shaft of the second driving motor 430 is coaxially connected to any one of the sprockets 420 through a shaft coupling. The end of the chain 410 near the discharge opening 210 is the feeding end of the discharge mechanism 400, and the end of the chain 410 far from the discharge opening 210 is the discharging end of the discharge mechanism 400. The material loading end of the discharging mechanism 400 is lower than the material outlet 210, and the metal balls rolled from the material outlet 210 fall on the chain 410. Since the discharge groove 220 is filled with cooling water, the discharge end of the discharge mechanism 400 is higher than the water level in the discharge groove 220 in order to take the metal balls out of the cooling water.

Referring to fig. 2 and 4, arc-shaped strip plates 411 are welded to the outer circumferential surface of the chain 410, the strip plates 411 are opposite to the moving direction of the strip plates 411, and both ends of the strip plates 411 respectively abut against the side walls of the discharge chute 220. The metal balls rolled from the discharge opening 210 fall on the chain 410, and the belt plate 411 drives the metal balls to move when the chain 410 rotates. Because take flitch 411 to be the arc setting, the metal ball that rolls on chain 410 is difficult to roll back to the recycling bin 200 from bin outlet 210 in, and take the both ends of flitch 411 respectively with the both sides wall butt of blow off groove 220 for the difficult roll back phenomenon that takes place of metal ball has improved the efficiency of unloading.

The implementation principle of the waste catalyst smelting and recycling device in the embodiment of the application is as follows:

the melted nickel, cobalt and molybdenum are poured into the material guiding groove 510, and under the guiding action of the material guiding groove 510, the melted nickel, cobalt and molybdenum gradually flow into the recycling bin 200, and when the melted nickel, cobalt and molybdenum leave the material guiding groove 510, the cooling water sprayed from the pre-cooling pipe 520 pre-cools the melted nickel, cobalt and molybdenum, so as to reduce the probability that the melted nickel, cobalt and molybdenum are bonded with each other; then, the molten nickel, cobalt and molybdenum fall into the recycling bin 200 to be completely cooled, the cooled nickel, cobalt and molybdenum form metal balls, the metal balls roll into the separating groove 340 under the action of gravity, and then the metal balls roll onto the chain 410 from the discharge opening 210 under the action of the rotation of the material guide plate 320; under the driving action of the chains 410 and the belt material plates 411, the metal balls are gradually removed from the cooling water and are conveyed to a storage position of the metal balls by the chains 410. In the process of cooling the molten nickel, cobalt and molybdenum, the formation and the discharge of metal balls are not affected, and the molten nickel, cobalt and molybdenum can be directly poured into the recovery device for recovery in a heating furnace, so that the molten nickel, cobalt and molybdenum can be continuously cooled, the recovery efficiency of the nickel, cobalt and molybdenum is improved, and the energy consumption is reduced.

The above are all preferred embodiments of the present invention, and the protection scope of the present invention is not limited thereby, so: all equivalent changes made according to the structure, shape and principle of the invention are covered by the protection scope of the invention.