CN219377983U - Automatic ore dressing device for iron ore - Google Patents

Abstract

The utility model belongs to the technical field of ore washing and dressing, and particularly relates to an automatic ore dressing device for iron ore. According to the utility model, the ore is screened, the small-volume ore is leaked into the first screening cavity to be cleaned, the large-volume ore enters into the second screening cavity to be cleaned, the level adjustment of ore screening is realized, the screening mechanism can rotate in the cleaning process, the cleaning angle and area are enlarged, and the cleaning efficiency and effect are improved.

Description

Automatic ore dressing device for iron ore

Technical Field

The utility model belongs to the technical field of ore washing and dressing, and particularly relates to an automatic ore dressing device for iron ores.

Background

Mineral products generally refer to any natural mineral or rock resource that is buried underground (or distributed over the earth's surface, or rock weathered, or rock deposited) for human use. Mineral products can be classified into metal, nonmetal, combustible organic and other categories, and are non-renewable resources. Wherein the metal is metal mineral product such as iron ore, copper ore, lead ore, zinc ore, lead zinc ore, etc. from which metal elements can be extracted.

In the process of exploiting iron ores, the exploited iron ores need to be screened, namely the treatment flow of ore dressing.

But in the process of current ore dressing, the ore is selected the back, and ore itself carries a large amount of dust, causes subsequent ore quality poor, and the effect is poor, and the level of inconvenient screening to the ore is adjusted simultaneously, and the practicality is poor.

Disclosure of Invention

The utility model aims to provide an automatic ore dressing device for iron ores, which can realize the level adjustment of ore screening, enlarge the cleaning angle and area and improve the cleaning efficiency and effect.

The aim of the utility model is realized by the following technical scheme:

the utility model relates to an automatic mineral processing device for iron ores, which is characterized by comprising a main body, a first screening cavity and a second screening cavity which are arranged at two sides in the main body, a screen frame which is arranged above the inside of the first screening cavity, a screen moving mechanism which is arranged inside one side of the first screening cavity and is used for driving the screen frame, a baffle plate which is arranged between the first screening cavity and the second screening cavity, baffle plate adjusting mechanisms which are arranged at two ends of the baffle plate and are used for adjusting the heights of the baffle plate, two screening mechanisms which are respectively arranged at the bottoms of the first screening cavity and the second screening cavity, a plurality of cleaning pipe interfaces which are positioned outside the first screening cavity and the second screening cavity and are uniformly distributed, and two side baffle plates which are arranged at two sides of the main body and are positioned outside the screening mechanisms.

The screening mechanism comprises a bottom plate, a toothed ring seat arranged at the axis of the upper part of the bottom plate, a collecting basket arranged above the toothed ring seat, a funnel ring arranged outside the top of the collecting basket, a first motor arranged above the bottom plate and positioned outside the toothed ring seat, and power teeth arranged at the power output end of the first motor, wherein the power teeth are meshed and connected outside the toothed ring seat.

The screening mechanism comprises a second motor positioned at one side of a first screening cavity in the main body, a transmission disc connected with the power output end of the second motor, a first connecting rod with one end connected with the transmission disc, a second connecting rod connected with the other end of the first connecting rod, a limit sleeve positioned at the outer side of the transmission disc in the main body, the second connecting rod is slidingly connected in the limit sleeve,

the screen frame sliding grooves are formed in two sides above the inside of the first screening cavity, the screen frame sliding blocks are arranged on two sides of the screen frame and are in sliding connection with the inside of the screen frame sliding grooves, and the other end of the second connecting rod is connected with the lower portion of the screen frame sliding blocks.

The screening device is characterized in that a slot is formed between the second screening cavity and the first screening cavity, trapezoidal sliding grooves are formed in two sides of the interior of the slot, a plurality of positioning holes are uniformly distributed in the interior of the trapezoidal sliding grooves, and the baffle adjusting mechanism is inserted into the slot.

The baffle adjusting mechanism comprises an inserting block, a trapezoid inserting block and a locating pin, wherein the inserting block is arranged on two sides of the baffle, the inserting block is inserted into the slot, spring grooves are formed in two sides of the inside of the inserting block, one end of a fastening spring is connected to the inside of each spring groove, the other end of the fastening spring is connected with the trapezoid inserting block, the locating pin is connected to the outer side of the trapezoid inserting block, and the trapezoid inserting block and the locating pin are respectively connected to the inside of the trapezoid sliding groove and the locating hole.

The spring groove is characterized in that limit grooves are formed in two sides of the inside of the spring groove, limit blocks are connected in a sliding mode in the limit grooves, and the other ends of the limit blocks are connected to the outer sides of the trapezoid inserting blocks.

The utility model has the advantages that:

the automatic ore dressing device for the iron ore is provided with the first screening cavity, the second screening cavity, the screening mechanism and the baffle, wherein the first screening cavity and the second screening cavity are matched with the screening mechanism to be used for screening the ore, the small-volume ore is leaked into the first screening cavity to be cleaned, the large-volume ore enters the second screening cavity to be cleaned, and meanwhile, the baffle is matched with the baffle adjusting mechanism to be used for adjusting the size of an opening to realize the level adjustment of ore screening, and the screening mechanism can be rotated in the cleaning process to enlarge the cleaning angle and area and improve the cleaning efficiency and effect.

Drawings

Fig. 1 is a schematic structural view of the present utility model.

Fig. 2 is a schematic view of the screening mechanism of the present utility model.

Fig. 3 is a schematic structural view of the screening mechanism of the present utility model.

Fig. 4 is an enlarged view of the utility model at a of fig. 1.

Fig. 5 is a schematic structural view of a baffle adjusting mechanism of the present utility model.

Detailed Description

Specific embodiments of the present utility model are further described below with reference to the accompanying drawings.

As shown in fig. 1 to 5, the automatic ore dressing device for iron ore of the present utility model is characterized by comprising a main body 1, a first screening cavity 3 and a second screening cavity 2 arranged at both sides of the inside of the main body 1, a screen frame 10 arranged above the inside of the first screening cavity 3, a screen motion mechanism 6 arranged inside one side of the first screening cavity 3 and used for driving the screen frame 10, a baffle 4 arranged between the first screening cavity 3 and the second screening cavity 2, baffle adjusting mechanisms 9 arranged at both ends of the baffle 4 and used for adjusting the heights of the baffle, two screening mechanisms 5 respectively arranged at the bottoms of the first screening cavity 3 and the second screening cavity 2, a plurality of cleaning pipe interfaces 8 which are uniformly distributed and positioned outside the first screening cavity 3 and the second screening cavity 2, and two side baffles 7 arranged at both sides of the main body 1 and positioned outside the screening mechanisms 5.

The screening mechanism 5 comprises a bottom plate 501, a toothed ring seat 502 arranged at the upper axial center of the bottom plate 501, a collecting basket 505 arranged above the toothed ring seat 502, a funnel ring 506 arranged outside the top of the collecting basket 505, a first motor 503 arranged above the bottom plate 501 and positioned outside the toothed ring seat 502, and power teeth 504 arranged at the power output end of the first motor 503, wherein the power teeth 504 are meshed and connected outside the toothed ring seat 502.

The screening mechanism 6 comprises a second motor 601 positioned at one side of a first screening cavity 3 in the main body 1, a driving disc 602 connected with the power output end of the second motor 601, a first connecting rod 603 with one end connected with the driving disc 602, a second connecting rod 605 connected with the other end of the first connecting rod 603, a limiting sleeve 604 positioned at the outer side of the driving disc 602 in the main body 1, the second connecting rod 605 is slidingly connected inside the limiting sleeve 604,

the two sides above the inside of the first screening cavity 3 are provided with a screen frame sliding groove 11, two sides of the screen frame 10 are provided with screen frame sliding blocks 12, the screen frame sliding blocks 12 are in sliding connection with the inside of the screen frame sliding groove 11, and the other end of the second connecting rod 605 is connected with the lower part of the screen frame sliding blocks 12.

The screening device is characterized in that a slot 15 is formed between the second screening cavity 2 and the first screening cavity 3, trapezoidal sliding grooves 13 are formed in two sides of the interior of the slot 15, a plurality of positioning holes 14 are uniformly distributed in the trapezoidal sliding grooves 13, and the baffle adjusting mechanism 9 is inserted into the interior of the slot 15.

The baffle adjusting mechanism 9 comprises an inserting block 901, a trapezoid inserting block 902 and a locating pin 903, wherein the inserting block 901 is arranged on two sides of the baffle 4, the inserting block 901 is inserted into the slot 15, spring grooves 904 are formed in two sides of the inside of the inserting block 901, one ends of fastening springs 907 are connected to the inner parts of the spring grooves 904, the other ends of the fastening springs 907 are connected with the trapezoid inserting block 902, the locating pin 903 is connected to the outer side of the trapezoid inserting block 902, and the trapezoid inserting block 902 and the locating pin 903 are respectively connected to the inside of the trapezoid sliding groove 13 and the locating hole 14.

Limiting grooves 905 are formed in two sides of the inside of the spring groove 904, limiting blocks 906 are connected inside the limiting grooves 905 in a sliding mode, and the other ends of the limiting blocks 906 are connected to the outer sides of the trapezoid inserting blocks 902.

Referring to fig. 1-5, an automatic ore dressing device for iron ore according to a preferred embodiment of the present utility model includes a main body 1, a first screening cavity 3 and a second screening cavity 2 are respectively provided at two sides of the inside of the main body 1, a screen frame 10 is installed above the inside of the first screening cavity 3, a screen mechanism 6 for screening the screen frame 10 is installed inside the inside of the main body 1 at one side of the first screening cavity 3, a baffle 4 is installed between the first screening cavity 3 and the second screening cavity 2, baffle adjusting mechanisms 9 for adjusting the height of the baffle 4 are installed at two ends of the baffle, screening mechanisms 5 are installed at two sides of the bottom of the first screening cavity 3 and the bottom of the second screening cavity 2, a plurality of cleaning tube interfaces 8 are uniformly distributed and opened at two sides of the outside of the first screening cavity 3 and the second screening cavity 2, the first screening cavity 3 and the second screening cavity 2 are matched with the screen mechanism 6 to realize screening of ore, the small-volume ore is filtered to the inside of the first screening cavity 3, the cleaning mechanism is enlarged, and the cleaning angle of the second screening cavity 2 is enlarged, and the cleaning effect of the cleaning mechanism is enlarged, and the cleaning effect of the ore is improved in the process is realized.

The screening mechanism 5 comprises a bottom plate 501, a collecting basket 505 and a first motor 503, a toothed ring seat 502 is arranged at the upper axial center of the bottom plate 501, the collecting basket 505 is arranged above the toothed ring seat 502, the first motor 503 is arranged at the outer side of the toothed ring seat 502 above the bottom plate 501, the power output end of the first motor 503 is connected with a power tooth 504, the power tooth 504 is meshed and connected at the outer side of the toothed ring seat 502, a funnel ring 506 is arranged at the outer side of the top of the collecting basket 505, the collecting basket 505 can collect ores entering the corresponding cleaning cavity, the collecting basket 505 can rotate along with the toothed ring seat 502 in the cleaning process, the cleaning angle is enlarged, the screening mechanism 6 comprises a second motor 601, a transmission disc 602 and a limiting sleeve 604, the second motor 601 is arranged at one side of the first screening cavity 3 inside the main body 1, the power output end of the second motor 601 is connected with a driving disc 602, the disc surface of the driving disc 602 is connected with one end of a first connecting rod 603, the other end of the first connecting rod 603 is connected with one end of a second connecting rod 605, a limiting sleeve 604 is arranged on the outer side of the driving disc 602 in the main body 1, the second connecting rod 605 is slidably connected in the limiting sleeve 604, the first connecting rod 603 and the second connecting rod 605 are matched for use, the reciprocating height of a screen frame sliding block 12 can be adjusted, the screening of the screen frame 10 is realized, ore is dispersed and screened, the screening efficiency is improved, the screen frame sliding grooves 11 are respectively arranged on two sides of the upper part inside a first screening cavity 3, the screen frame sliding blocks 12 are arranged on two sides of the screen frame 10, the screen frame sliding blocks 12 are slidably connected in the screen frame sliding grooves 11, the other end of the second connecting rod 605 is connected under the screen frame sliding blocks 12, the screen frame sliding block 12 is matched with the screen frame sliding groove 11 to limit the movement of the screen frame 10 and prevent the deviation, a slot 15 is arranged between the second screening cavity 2 and the first screening cavity 3, trapezoidal sliding grooves 13 are arranged on two sides of the inside of the slot 15, a plurality of positioning holes 14 are uniformly distributed in the trapezoidal sliding grooves 13, a baffle adjusting mechanism 9 is inserted into the slot 15, the baffle adjusting mechanism 9 comprises an inserting block 901, a trapezoidal inserting block 902 and a positioning pin 903, the inserting block 901 is arranged on two sides of the baffle 4, the inserting block 901 is inserted into the slot 15, spring grooves 904 are arranged on two sides of the inside of the inserting block 901, one end of a fastening spring 907 is connected inside the spring groove 904, the other end of the fastening spring 907 is connected with the trapezoidal inserting block 902, the outer side of the trapezoidal inserting block 902 is connected with the positioning pin 903, and trapezoidal inserted block 902 and locating pin 903 are connected respectively trapezoidal spout 13 and locating hole 14 are inside, and trapezoidal inserted block 902 and locating pin 903 cooperation trapezoidal spout 13 and locating hole 14 use, can switch between locating hole 14 according to the shrink of fastening spring 907, realize high regulation, improved the practicality, spacing groove 905 has been seted up to the inside both sides of spring groove 904, spacing groove 905 inside sliding connection has stopper 906 one end, just the stopper 906 other end is connected trapezoidal inserted block 902 outside, and stopper 906 then can restrict trapezoidal inserted block 902's removal, prevents to appear the skew, main part 1 both sides are located screening mechanism 5 outside all is connected with side shield 7, and side shield 7 can separate splash liquid or silt that produces in the clearance process, has improved the result of use.

The utility model relates to an automatic mineral separation device for iron ores, which comprises: during the use, firstly put into first screening chamber 3 and second screening chamber 2 inside respectively screening mechanism 5, and with side shield 7 closed, the ore that will need screening clearance is thrown into the inside top of first screening chamber 3 in this moment and is passed through external power source and is the inside second motor 601 circular telegram of screening mechanism 6 this moment, the work of second motor 601 drives driving disk 602 and rotates, driving disk 602 then drives quotation's first connecting rod 603 and second connecting rod 605 and reciprocate in stop collar 604 inside, ejecting screen frame slider 12, slide from top to bottom in screen frame spout 11 inside, drive screen frame 10 and reciprocate, screen for the ore, the ore that will small-size ore screen falls to the inside collection basket 505 of screening mechanism 5 inside of first screening chamber 3, afterwards the inside collection basket 505 of large-size ore is dropped to the inside of second screening chamber 2, at this moment is the inside for the inside first motor 503 circular stand is driven to the outside power source, the power tooth 504 rotates, insert the inside all-round clearance pipe 8 to clear up the ore clearance interface, the all-round clearance pipe 8 is inserted to this moment to the inside power tooth stand 504 rotates.

The automatic ore dressing device for the iron ore is provided with the first screening cavity 3, the second screening cavity 2, the screening mechanism 6, the screening mechanism 5 and the baffle 4, wherein the first screening cavity 3 and the second screening cavity 2 are matched with the screening mechanism to be used for screening ores, small-volume ores are screened out to the interior of the first screening cavity 3 to be cleaned, large-volume ores enter the interior of the second screening cavity 2 to be cleaned, and meanwhile, the baffle 4 is matched with the baffle adjusting mechanism 9 to adjust the size of an opening to realize the level adjustment of ore screening, the screening mechanism 5 can rotate in the cleaning process, the cleaning angle and area are enlarged, and the cleaning efficiency and effect are improved.

Claims (6)

1. The utility model provides an automatic ore dressing device for iron ore, its characterized in that includes the main part, sets up first screening chamber and the second screening chamber in this inside both sides of main part, sets up the reel of first screening intracavity portion top, set up the inside screen movement mechanism that is used for driving the reel in first screening chamber one side, set up baffle between first screening chamber and the second screening chamber, set up the baffle adjustment mechanism that is used for adjusting its height at this baffle both ends, set up respectively two screening mechanisms in the bottom of first screening chamber and second screening chamber, be located a plurality of clearance pipe interfaces of outside and evenly distributed in first screening chamber and second screening chamber, set up the main part both sides just are located two side shields in the screening mechanism outside.

2. The automatic mineral processing device for iron ore according to claim 1, wherein the screening mechanism comprises a bottom plate, a toothed ring seat arranged at the axle center above the bottom plate, a collecting basket arranged above the toothed ring seat, a funnel ring arranged outside the top of the collecting basket, a first motor arranged above the bottom plate and positioned outside the toothed ring seat, and power teeth arranged at the power output end of the first motor, wherein the power teeth are meshed and connected outside the toothed ring seat.

3. The automatic ore dressing device for iron ore according to claim 1, wherein the screening mechanism comprises a second motor positioned at one side of the first screening cavity in the main body, a driving disc connected with the power output end of the second motor, a first connecting rod connected with the driving disc at one end, a second connecting rod connected with the other end of the first connecting rod, a limit sleeve positioned at the outer side of the driving disc in the main body, the second connecting rod is slidingly connected in the limit sleeve,

the screen frame sliding grooves are formed in two sides above the inside of the first screening cavity, the screen frame sliding blocks are arranged on two sides of the screen frame and are in sliding connection with the inside of the screen frame sliding grooves, and the other end of the second connecting rod is connected with the lower portion of the screen frame sliding blocks.

4. The automatic ore dressing device for the iron ore is characterized in that a slot is formed between the second screening cavity and the first screening cavity, trapezoidal sliding grooves are formed in two sides of the interior of the slot, a plurality of positioning holes are uniformly formed in the interior of the trapezoidal sliding grooves, and the baffle adjusting mechanism is inserted into the slot.

5. The automatic ore dressing device for iron ore according to claim 4, wherein the baffle adjusting mechanism comprises an inserting block, a trapezoid inserting block and a locating pin, the inserting blocks are arranged on two sides of the baffle, the inserting blocks are inserted into the inserting grooves, spring grooves are formed in two sides of the inner portions of the inserting blocks, one ends of fastening springs are connected to the inner portions of the spring grooves, the other ends of the fastening springs are connected with the trapezoid inserting blocks, the locating pin is connected to the outer sides of the trapezoid inserting blocks, and the trapezoid inserting blocks and the locating pin are respectively connected to the inner portions of the trapezoid sliding grooves and the locating holes.

6. The automatic ore dressing device for iron ore according to claim 5, wherein limiting grooves are formed in two sides of the inner portion of the spring groove, limiting blocks are connected in a sliding mode in the limiting grooves, and the other ends of the limiting blocks are connected to the outer sides of the trapezoid inserting blocks.