CN213967044U - Device for treating vanadium-nitrogen alloy bonding - Google Patents

Abstract

The utility model provides a device for treating vanadium-nitrogen alloy bonding, which belongs to the field of vanadium-nitrogen alloy production and comprises a storage bin, a first vibrating screen, a crusher, a second vibrating screen and a belt conveyor; the feed bin is provided with a feed inlet and a discharge outlet; the first vibrating screen is obliquely arranged below the storage bin, and one end of the first vibrating screen is positioned below the discharge port; the crusher is positioned on one side of the first vibrating screen, which is far away from the bin, and below the other end of the first vibrating screen, and is used for crushing oversize materials of the first vibrating screen; the second vibrating screen is positioned below the crusher, and the sieve pores on the second vibrating screen are smaller than the sieve pores on the first vibrating screen; the belt feeder is located the below of first shale shaker, and one end is located the top of second shale shaker for transport the undersize thing of first shale shaker to on the second shale shaker. The utility model provides a handle device that vanadium nitrogen alloy bonded has alleviateed intensity of labour, has improved production efficiency, realizes mass production.

Description

Device for treating vanadium-nitrogen alloy bonding

Technical Field

The utility model belongs to the technical field of vanadium nitrogen alloy production, more specifically say, relate to a handle device that vanadium nitrogen alloy bonded.

Background

The vanadium-nitrogen alloy is a novel alloy additive and can replace ferrovanadium to be used for microalloying production. The main flow process for producing vanadium nitride is to use vanadium oxide, carbon powder and activator as raw materials, press them into balls and then fire them in a continuous push plate kiln at high temperature.

However, during the process of firing the raw material balls of the vanadium-nitrogen alloy into finished products, mutual adhesion among the finished product balls inevitably exists, and the adhesion phenomenon can disperse a plurality of small blocks and independent finished product balls through external force extrusion. If the bonded vanadium nitride is manually treated, not only is the operation efficiency low and the labor intensity large, but also excessive powder is generated, and further screening is needed.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a handle device that vanadium nitrogen alloy bonded, the manual work efficiency of handling alloy powder particle that aims at solving and exists among the above-mentioned prior art is low, technical problem that intensity of labour is big.

In order to achieve the above object, the utility model adopts the following technical scheme: provided is an apparatus for treating vanadium-nitrogen alloy bonding, comprising:

the storage bin is provided with a feeding hole and a discharging hole;

the first vibrating screen is obliquely arranged below the storage bin, and one end of the first vibrating screen is positioned below the discharge port;

the crusher is positioned on one side of the first vibrating screen, which is far away from the storage bin, is positioned below the other end of the first vibrating screen, and is used for crushing oversize materials of the first vibrating screen;

the second vibrating screen is positioned below the crusher, and the sieve pores on the second vibrating screen are smaller than the sieve pores on the first vibrating screen;

the belt feeder is located the below of first shale shaker, and one end is located the top of second shale shaker is used for with the undersize thing of first shale shaker transports to on the second shale shaker.

As another embodiment of the application, a flow guide structure for guiding undersize to fall on the belt conveyor is arranged on the first vibrating screen.

As another embodiment of the present application, the flow guide structure includes:

the undersize collection box is fixedly arranged at the lower end of the first vibrating screen;

the guide plate is located the undersize and collects the box and keep away from the one end of discharge gate, and the box intercommunication is collected with the undersize to the upper end, and the lower extreme is located the belt feeder top.

As another embodiment of the present application, an outer cover is fixedly disposed on the flow guide plate, and a passage for passing undersize materials is formed between the flow guide plate and the outer cover.

As another embodiment of the application, the number of the first vibrating screens is two, and the first vibrating screens are sequentially arranged on one side of the storage bin; the two crushers are respectively arranged between the two first vibrating screens and between the first vibrating screen and the second vibrating screen which are far away from the storage bin.

As another embodiment of the present application, the discharge particle size of the crusher between the two first vibrating screens is larger than the discharge particle size of the crusher between the first vibrating screen and the second vibrating screen which are far away from the silo.

As another embodiment of the application, the lower end of the second vibrating screen is provided with a storage chamber for storing undersize of the second vibrating screen.

As another embodiment of the application, the lower end of the storage chamber is provided with a valve for discharging.

As another embodiment of this application, all be equipped with on first shale shaker with the second shale shaker and be used for the blanking plate that the thing was sieved out on the sieve, the both sides of blanking plate are equipped with the baffle, two distance between the baffle is close to certainly first shale shaker or the second shale shaker reduces to keeping away from first shale shaker or the one end of second shale shaker gradually.

As another embodiment of the present application, the second vibrating screen is disposed obliquely.

The utility model provides a handle device that vanadium nitrogen alloy bonded's beneficial effect lies in: the vanadium-nitrogen alloy blocks enter the first vibrating screen through the bin, the vanadium-nitrogen alloy blocks smaller than the meshes of the screen of the first vibrating screen fall onto the belt conveyor through the screen, and the belt conveyor conveys the vanadium-nitrogen alloy blocks onto the second vibrating screen for screening again. The vanadium-nitrogen alloy mass on the screen of the second vibrating screen is qualified products, and the vanadium-nitrogen alloy mass on the screen of the second vibrating screen is collected by workers and then packaged. The device for treating the vanadium-nitrogen alloy bonding reduces the labor intensity, ensures the granularity of the vanadium-nitrogen alloy and realizes batch production.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings required for the embodiments or the prior art descriptions will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without inventive labor.

Fig. 1 is a schematic structural diagram of a device for treating vanadium-nitrogen alloy bonding provided by the embodiment of the present invention.

Wherein, in the figures, the respective reference numerals:

1. a storage bin; 2. a first vibrating screen; 3. a crusher; 4. a second vibrating screen; 5. a belt conveyor; 6. a flow guide structure; 61. a screen underflow collection box; 62. a baffle; 7. a storage chamber; 71. a valve; 8. and a blanking plate.

Detailed Description

In order to make the technical problem, technical solution and advantageous effects to be solved by the present invention more clearly understood, the following description is given in conjunction with the accompanying drawings and embodiments to illustrate the present invention in further detail. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Referring to fig. 1, the apparatus for treating vanadium-nitrogen alloy adhesion provided by the present invention will now be described. The device for treating the vanadium-nitrogen alloy bonding comprises a stock bin 1, a first vibrating screen 2, a crusher 3, a second vibrating screen 4 and a belt conveyor 5; the feed bin 1 is provided with a feed inlet and a discharge outlet; the first vibrating screen 2 is obliquely arranged below the storage bin 1, and one end of the first vibrating screen is positioned below the discharge port; the crusher 3 is positioned on one side of the first vibrating screen 2, which is far away from the bin 1, and below the other end of the first vibrating screen 2, and is used for crushing oversize materials of the first vibrating screen 2; the second vibrating screen 4 is positioned below the crusher 3, and the screen holes on the second vibrating screen 4 are smaller than those on the first vibrating screen 2; the belt conveyor 5 is located below the first vibrating screen 2, and one end of the belt conveyor is located above the second vibrating screen 4, and is used for conveying undersize of the first vibrating screen 2 onto the second vibrating screen 4.

The utility model provides a handle device that vanadium nitrogen alloy bonded compares with prior art, and vanadium nitrogen alloy piece enters into first shale shaker 2 through feed bin 1, and the vanadium nitrogen alloy piece that is less than first shale shaker screen cloth mesh falls into belt feeder 5 through the screen cloth on, and belt feeder 5 screens the vanadium nitrogen alloy piece once more on transporting to second shale shaker 4. The big piece vanadium nitrogen alloy on first shale shaker 2 enters into breaker 3 and breaks, gets into second shale shaker 4 after broken, and the screen cloth mesh of second shale shaker 4 is less than the screen cloth size of first shale shaker 2, and the vanadium nitrogen alloy piece on the screen cloth of second shale shaker 4 is qualified product, and the staff packs after collecting. The device for treating the vanadium-nitrogen alloy bonding reduces the labor intensity, ensures the granularity of the vanadium-nitrogen alloy and realizes batch production.

The screen mesh size of the first vibrating screen 2 is 40mm, which can allow vanadium-nitrogen alloy blocks with the granularity less than or equal to 40mm to pass through the screen mesh, and the screen mesh size of the second vibrating screen 4 is 10mm, which can allow vanadium-nitrogen alloy blocks with the granularity less than or equal to 10mm to pass through the screen mesh. The crusher 3 positioned between the two first vibrating screens 2 can crush the vanadium-nitrogen alloy blocks to the granularity of less than or equal to 100mm, and the crusher 3 positioned between the first vibrating screen 2 and the second vibrating screen 4 far away from the storage bin 1 can crush the vanadium-nitrogen alloy blocks to the granularity of less than or equal to 40 mm.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, a flow guiding structure 6 for guiding the undersize to fall on the belt conveyor 5 is disposed on the first vibrating screen 2. The diversion structure 6 can make the vanadium-nitrogen alloy slide to the belt conveyor 5 stably, and the vanadium-nitrogen alloy block can not be broken again due to falling.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, the flow guiding structure 6 includes a screen underflow collecting box 61 and a flow guiding plate 62; the undersize collection box 61 is fixedly arranged at the lower end of the first vibrating screen 2; the guide plate 62 is located the one end that the discharge gate was kept away from to the screen underflow collection box 61, and the upper end and screen underflow collection box 61 intercommunication, the lower extreme is located the belt feeder 5 top. The screen mesh sizes of the two first vibrating screens 2 are both 40mm, vanadium-nitrogen alloy blocks with the granularity of less than or equal to 40mm can be allowed to fall into the undersize collecting box 61 through the screen mesh, the vanadium-nitrogen alloy blocks with the granularity of less than or equal to 40mm falling into the undersize collecting box 61 stably slide to the belt conveyor 5 through the guide plate 62, and then the belt conveyor 5 transports the vanadium-nitrogen alloy blocks with the granularity of less than or equal to 40mm to the second vibrating screen 4 for filtering. In this example, the vanadium-nitrogen alloy blocks with the grain size of 10-40mm are required as products, and the vanadium-nitrogen alloy blocks with the grain size of less than or equal to 40mm falling into the undersize collecting box 61 also comprise vanadium-nitrogen alloy blocks with the grain size of less than or equal to 10 mm. The second vibrating screen 4 is provided with a 10mm screen, and the 10mm screen allows vanadium-nitrogen alloy blocks with the granularity less than or equal to 10mm to fall into the storage chamber 7 through the 10mm screen. The belt conveyor 5 avoids the crusher 3 to directly convey the vanadium-nitrogen alloy blocks with the granularity less than or equal to 40mm to the second vibrating screen 4, further damage to the vanadium-nitrogen alloy blocks with the granularity less than or equal to 40mm is avoided, more useless vanadium-nitrogen alloy blocks with the granularity less than or equal to 10mm are generated, the product percent of pass is improved, and energy consumption is reduced.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, an outer cover is fixedly disposed on the flow guide plate 62, and a channel for passing undersize materials is formed between the flow guide plate 62 and the outer cover. The guide plate 62 is fixedly provided with the outer cover, so that the guide structure 6 is firmer, deformation is prevented, and meanwhile, dust in the vanadium-nitrogen alloy block can be prevented from diffusing into the air to cause environmental pollution. Prevent the vanadium-nitrogen alloy blocks rolled off from the guide plate 62 from falling out of the belt conveyor 5.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, two first vibrating screens 2 are sequentially disposed on one side of a storage bin 1; the two crushers 3 are respectively arranged between the two first vibrating screens 2 and between the first vibrating screen 2 and the second vibrating screen 4 far away from the storage bin 1. The crusher 3 positioned between the two first vibrating screens 2 can crush the vanadium-nitrogen alloy blocks into vanadium-nitrogen alloy blocks with the granularity of less than or equal to 100mm, the crusher 3 positioned between the first vibrating screen 2 and the second vibrating screen 4 far away from the stock bin 1 can crush the vanadium-nitrogen alloy blocks into vanadium-nitrogen alloy blocks with the granularity of less than or equal to 40mm, the required vanadium-nitrogen alloy blocks with the granularity of 10-40mm can be kept as much as possible in the crushing process by means of classified crushing, the vanadium-nitrogen alloy blocks with the granularity of less than or equal to 40mm are prevented from being crushed again, more vanadium-nitrogen alloy blocks with the granularity of less than or equal to 10mm are generated, and the yield of the vanadium-nitrogen alloy.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, the discharge particle size of the crusher 3 located between the two first vibrating screens 2 is larger than the discharge particle size of the crusher 3 located between the first vibrating screen 2 and the second vibrating screen 4 far away from the storage bin 1. The two crushers 3 are respectively arranged between the two first vibrating screens 2 and between the first vibrating screen 2 and the second vibrating screen 4 far away from the storage bin 1. The crusher 3 positioned between the two first vibrating screens 2 can crush the vanadium-nitrogen alloy blocks into vanadium-nitrogen alloy blocks with the granularity of less than or equal to 100mm, the crusher 3 positioned between the first vibrating screen 2 and the second vibrating screen 4 far away from the stock bin 1 can crush the vanadium-nitrogen alloy blocks into vanadium-nitrogen alloy blocks with the granularity of less than or equal to 40mm, the required vanadium-nitrogen alloy blocks with the granularity of 10-40mm can be reserved in the crushing process as much as possible through graded crushing, the vanadium-nitrogen alloy blocks with the granularity of less than or equal to 40mm are prevented from being crushed again, more vanadium-nitrogen alloy blocks with the granularity of less than or equal to 10mm are generated, and the yield of the vanadium-nitrogen alloy blocks is improved.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, a storage chamber 7 for storing undersize materials of the second vibrating screen 4 is disposed at the lower end of the second vibrating screen 4. Vanadium-nitrogen alloy blocks less than or equal to 10mm are collected to the storage chamber 7 for temporary storage for other requirements, and the waste of products is avoided.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, a valve 71 for discharging is disposed at the lower end of the storage chamber 7. When the vanadium-nitrogen alloy blocks less than or equal to 10mm in the storage chamber 7 are full, the worker can collect the vanadium-nitrogen alloy blocks by operating the valve 71.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, the first vibrating screen 2 and the second vibrating screen 4 are both provided with a blanking plate 8 for screening out oversize materials, two sides of the blanking plate 8 are provided with baffles, and the distance between the two baffles is gradually reduced from the position close to the first vibrating screen 2 or the second vibrating screen 4 to the position far away from the first vibrating screen 2 or the second vibrating screen 4. The baffle of 8 both sides of blanking plate can prevent that vanadium nitrogen alloy piece from falling outside first shale shaker 2, causing the waste. The distance between the two baffles is gradually reduced, so that the vanadium-nitrogen alloy blocks can fall into the crusher 3 more accurately.

Referring to fig. 1, as a specific embodiment of the device for treating vanadium-nitrogen alloy adhesion provided by the present invention, a second vibrating screen 4 is disposed in an inclined manner. The end of the second vibrating screen 4 close to the crusher 3 is higher, and the inclined arrangement can enable the vanadium-nitrogen alloy block to smoothly go to the next link through self gravity, so that the energy is saved by utilizing the self gravitational potential energy.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents and improvements made within the spirit and principle of the present invention are intended to be included within the scope of the present invention.

Claims (10)

1. An apparatus for treating vanadium-nitrogen alloy bonding, comprising:

the storage bin is provided with a feeding hole and a discharging hole;

the first vibrating screen is obliquely arranged below the storage bin, and one end of the first vibrating screen is positioned below the discharge port;

the crusher is positioned on one side of the first vibrating screen, which is far away from the storage bin, is positioned below the other end of the first vibrating screen, and is used for crushing oversize materials of the first vibrating screen;

the second vibrating screen is positioned below the crusher, and the sieve pores on the second vibrating screen are smaller than the sieve pores on the first vibrating screen;

the belt feeder is located the below of first shale shaker, and one end is located the top of second shale shaker is used for with the undersize thing of first shale shaker transports to on the second shale shaker.

2. The apparatus for treating vanadium-nitrogen alloy bonding according to claim 1, wherein the first vibrating screen is provided with a flow guiding structure for guiding undersize to fall on the belt conveyor.

3. The apparatus for treating vanadium-nitrogen alloy bonding according to claim 2, wherein the flow guide structure comprises:

the undersize collection box is fixedly arranged at the lower end of the first vibrating screen;

the guide plate is located the undersize is collected the box and is kept away from the one end of discharge gate, and the upper end with undersize is collected the box intercommunication, and the lower extreme is located the belt feeder top.

4. The apparatus for treating vanadium-nitrogen alloy bonding according to claim 3, wherein the deflector is fixedly provided with an outer cover, and a channel for passing undersize materials is formed between the deflector and the outer cover.

5. The apparatus for treating vanadium-nitrogen alloy bonding according to claim 1, wherein the number of the first vibrating screens is two, and the two first vibrating screens are sequentially arranged on one side of the storage bin; the two crushers are respectively arranged between the two first vibrating screens and between the first vibrating screen and the second vibrating screen which are far away from the storage bin.

6. The apparatus for treating vanadium-nitrogen alloy binding according to claim 5, wherein the discharge particle size of the crusher positioned between the two first vibrating screens is larger than the discharge particle size of the crusher positioned between the first vibrating screen and the second vibrating screen far away from the silo.

7. The apparatus for treating vanadium-nitrogen alloy bonding according to claim 1, wherein the lower end of the second vibrating screen is provided with a storage chamber for storing the undersize of the second vibrating screen.

8. The apparatus for treating vanadium-nitrogen alloy binding according to claim 7, wherein the lower end of the storage chamber is provided with a valve for discharging.

9. The device for treating vanadium-nitrogen alloy bonding as claimed in claim 1, wherein the first vibrating screen and the second vibrating screen are both provided with blanking plates for screening oversize materials, the blanking plates are provided with baffle plates on two sides, and the distance between the two baffle plates is gradually reduced from the position close to the first vibrating screen or the second vibrating screen to the position far away from the first vibrating screen or the second vibrating screen.

10. The apparatus for treating vanadium-nitrogen alloy bonding according to claim 1, wherein the second vibrating screen is arranged obliquely.

Images