CN215354721U - Steel-making deoxidizer linear vibration screening machine - Google Patents

Abstract

The utility model discloses a steelmaking deoxidizer linear vibration screening machine, belonging to the technical field of screening machines, and the technical scheme is as follows: the supporting component comprises a bottom plate, supporting columns are fixedly installed at two ends of the top of the bottom plate, the top ends of the supporting columns are fixedly connected with a top plate, a first sleeve seat and a second sleeve seat are fixedly installed at the top end of the bottom plate, a first spring is arranged in an inner cavity of the first sleeve seat, a first inserted rod is inserted into the inner wall of the first sleeve seat, and a second spring is arranged in an inner cavity of the second sleeve seat, and the supporting component has the advantages that: through setting up supporting component, can realize that screening case left end is less than the right-hand member, also can realize that the right-hand member is less than the left end to realized thoroughly sieving completely of granule, through setting up first hose and first case, second hose and second case, third hose and the third case that gathers materials, realized the categorised recovery of the granule of different particle diameters after the screening, improved screening speed can efficiency greatly, shortened the screening time.

Description

Steel-making deoxidizer linear vibration screening machine

Technical Field

The utility model relates to the technical field of screening machines, in particular to a steelmaking deoxidizer linear vibration screening machine.

Background

When the molten steel is solidified, redundant oxygen in the molten steel is combined with other elements in the steel to generate non-metallic inclusions, so that the continuity of a steel matrix is damaged, various mechanical properties such as strength limit, impact toughness and elongation of the steel, magnetic conductivity, welding performance and the like are reduced, the oxygen content in the molten steel is too high, and the oxygen reacts with carbon in the steel again in the casting process to generate CO gas, so that the defects of air holes, looseness, even rising and the like of a steel ingot are generated.

The existing deoxidizer screening device has incomplete screening, slow screening speed and poor effect.

Therefore, the utility model of the steel-making deoxidizer linear vibration screening machine is necessary.

SUMMERY OF THE UTILITY MODEL

Therefore, the steel-making deoxidizer linear vibration screening machine provided by the utility model is provided with the screening device and the supporting assembly, so that the deoxidizer is screened on the inclined screen, and one end of the screening box is inclined and the other end of the screening box is inclined, so that the screening is more thorough, the screening speed is increased, and the problems of incomplete screening, low screening speed and poor effect of the conventional deoxidizer screening device are solved.

In order to achieve the above purpose, the utility model provides the following technical scheme:

steelmaking deoxidier linear vibration screening machine, including supporting component, supporting component includes the bottom plate, bottom plate top both ends fixed mounting support column, support column top fixed connection roof, first cover seat of bottom plate top fixed mounting and second cover seat, be equipped with first spring in the first cover seat inner chamber, first inserted bar of first cover seat inner wall grafting, be equipped with the second spring in the second cover seat inner chamber, second cover seat inner wall grafting second inserted bar, second inserted bar top is through round pin axle swing joint electric telescopic handle, still includes: a screening device located below the top plate; and

the discharging bin is positioned above the screening device;

the screening device comprises a screening box, a vibrator is fixedly arranged at the top of the screening box, an inclined plate is fixedly arranged on the inner wall of the screening box, the top end of the screening box is provided with a feeding port, the inner wall of the screening box is fixedly provided with a first screen and a second screen, the two ends of the bottom of the inner cavity of the first screen mesh, the second screen mesh and the screening box are respectively provided with a discharge hole, the discharge holes at the two sides of the first screen mesh are fixedly connected with a first hose, the discharge ports on two sides of the second screen are fixedly connected with a second hose, the discharge ports on two sides of the bottom of the inner cavity of the screening box are fixedly connected with a third hose, the bottom end of the first hose is fixedly connected with a first material collecting box, the bottom end of the second hose is fixedly connected with a second material collecting box, the bottom end of the third hose is fixedly connected with a third material collecting box, the bottom of the screening box is movably connected with an electric telescopic rod, and the top end of the first inserted bar is movably connected with the screening box.

Preferably, the second sockets are provided with two groups, and the two groups of the second sockets are symmetrically arranged relative to the first socket.

Preferably, the bottom ends of the first spring and the second spring are fixedly connected with the bottom plate, the top end of the first spring is fixedly connected with the bottom of the first inserted bar, and the bottom end of the second spring is fixedly connected with the bottom end of the second inserted bar.

Preferably, the bottom of the discharging bin is provided with two groups of discharging pipes.

Preferably, a first electromagnetic valve is installed on the discharge port, and a second electromagnetic valve is fixedly installed on the discharging pipe.

Preferably, the feeding ports are arranged in two groups, the left end of each feeding port is connected with the left end of the discharging pipe through a guide pipe, and the right end of each feeding port is connected with the right end of the discharging pipe through a guide pipe.

Preferably, the discharging bin is fixedly installed on the top plate, and the inclined plate is located below the feeding port.

The utility model has the beneficial effects that:

1. by arranging the supporting component, the left end of the screening box is lower than the right end, and the right end of the screening box is lower than the left end, so that complete screening of particles is realized;

2. by arranging the first hose and the first material collecting box, the second hose and the second material collecting box, and the third hose and the third material collecting box, classified recovery of particles with different particle sizes after screening is realized;

3. greatly improving the screening speed and efficiency and shortening the screening time.

Drawings

FIG. 1 is a schematic structural view provided by the present invention;

FIG. 2 is an enlarged view of the utility model at A in FIG. 1;

FIG. 3 is an enlarged view at B of FIG. 1 in accordance with the present invention;

fig. 4 is an enlarged view of the utility model at C in fig. 1.

In the figure: the device comprises a supporting component 1, a supporting column 10, a bottom plate 11, a top plate 12, a first sleeve seat 13, a first spring 14, a second inserted rod 15, a first inserted rod 16, an electric telescopic rod 17, a second sleeve seat 18, a second spring 19, a screening device 2, a third hose 20, a screening box 21, a feeding port 22, a loading inclined plate 23, a vibrator 24, a first screen 25, a second screen 26, a first hose 28, a first material collecting box 281, a second hose 29, a second material collecting box 291, a discharging port 200, a third material collecting box 201, a first electromagnetic valve 202, a discharging bin 3, a discharging pipe 31 and a second electromagnetic valve 32.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are described herein for the purpose of illustration and explanation and not limitation.

Referring to the attached drawings 1-4 of the specification, the steelmaking deoxidizer linear vibration screening machine provided by the embodiment includes a supporting component 1, the supporting component 1 includes a bottom plate 11, supporting columns 10 are fixedly installed at two ends of the top of the bottom plate 11, a top end of each supporting column 10 is fixedly connected with a top plate 12, a first sleeve base 13 and a second sleeve base 18 are fixedly installed at the top end of the bottom plate 11, a first spring 14 is arranged in an inner cavity of the first sleeve base 13, a first inserted bar 16 is inserted into an inner wall of the first sleeve base 13, a second spring 19 is arranged in an inner cavity of the second sleeve base 18, a second inserted bar 15 is inserted into an inner wall of the second sleeve base 18, and the top end of the second inserted bar 15 is movably connected with an electric telescopic bar 17 through a pin shaft, and further includes: a screening device 2 located below said top plate 12; and

the discharging bin 3 is positioned above the screening device 2;

the screening device 2 comprises a screening box 21, a vibrator 24 is fixedly installed at the top of the screening box 21, an inclined plate 23 is fixedly installed on the inner wall of the screening box 21, a feeding hole 22 is formed in the top end of the screening box 21, a first screen 25 and a second screen 26 are fixedly installed on the inner wall of the screening box 21, discharge holes 200 are formed in the two ends of the bottom of the inner cavity of the first screen 25, the two ends of the bottom of the inner cavity of the second screen 26 and the two ends of the bottom of the inner cavity of the screening box 21, the discharge holes 200 in the two sides of the first screen 25 are fixedly connected with a first hose 28, the discharge holes 200 in the two sides of the second screen 26 are fixedly connected with a second hose 29, the discharge holes 200 in the two sides of the bottom of the inner cavity of the screening box 21 are fixedly connected with a third hose 20, the bottom of the first hose 28 is fixedly connected with a first material collecting box 281, the bottom of the second hose 29 is fixedly connected with a second material collecting box 291, the bottom of the third hose 20 is fixedly connected with a third material collecting box 201, and the bottom of the screening box 21 is movably connected with an electric telescopic rod 17, the top end of the first inserted bar 16 is movably connected with the screening box 21; the first screen 25 has larger apertures than the second screen 26.

Further, the second sockets 18 are provided with two sets, and the two sets of the second sockets 18 are symmetrically arranged about the first socket 13; the second set of seats 18 provides two better support for the screening box 21, making the screening box 21 more stable.

Further, the bottom ends of the first spring 14 and the second spring 19 are both fixedly connected to the bottom plate 11, the top end of the first spring 14 is fixedly connected to the bottom of the first insertion rod 16, and the bottom end of the second spring 19 is fixedly connected to the bottom of the second insertion rod 15; the first spring 14 and the second spring 19 function to achieve a large amplitude vibration of the sifting box 21, thereby allowing the first screen 25 and the second screen 26 to sift faster and more efficiently.

Further, 3 bottoms in blowing storehouse are equipped with blowing pipe 31, blowing pipe 31 is equipped with two sets ofly, and when screening case 21 left end was higher than the right-hand member, the blowing storehouse 3 of 3 left ends in blowing storehouse pours into the deoxidier that waits to sieve into screening case 21 through the pan feeding mouth 22 of left end into, and when screening case 21 right-hand member was higher than the left end, the deoxidier that waits to sieve was poured into to screening case 21 through the pan feeding mouth 22 of right-hand member into in the blowing storehouse 3 right-hand member in blowing storehouse 3.

Further, a first electromagnetic valve 202 is installed on the discharge port 200, and a second electromagnetic valve 32 is fixedly installed on the discharge pipe 31.

Furthermore, two sets of the feeding ports 22 are arranged, the left end feeding port 22 is connected with the left end discharging pipe 31 through a conduit, the right end feeding port 22 is connected with the right end discharging pipe 31 through a conduit,

further, the discharge bin 3 is fixedly mounted on the top plate 12, and the inclined plate 23 is located below the feeding port 22; the inclined plate 23 is used for enabling the blanking to be more uniform and fast screening.

The implementation scenario is specifically as follows: when the utility model is used, the electric telescopic rod 17 at the left end is contracted, the electric telescopic rod 17 at the right end is extended, so that the right end of the screening box 21 is higher than the left end, the second electromagnetic valve 32 on the discharging pipe 31 at the right end is opened, the deoxidizer in the discharging bin 3 is led into the screening box 21 through the feeding port 22 at the right end, the vibrator 24 is started to vibrate the screening box 21, under the combined action of the first spring 14, the second spring 19 and the vibrator 24, the screening box 21 generates large-amplitude vibration, so that the first screen 25 and the second screen 26 are used for screening, most particles smaller than the aperture of the first screen 25 fall onto the second screen 26, most particles smaller than the aperture of the second screen 26 on the second screen 26 fall onto the bottom of the screening box 21, when the deoxidizer on the first screen 25 and the second screen 26 is positioned at the left side of the screening box 21, the particles smaller than the aperture of the first screen 25 are also doped on the first screen 25 and do not fall onto the second screen 26, the second screen mesh 26 also has particles smaller than the aperture of the second screen mesh 26 which do not fall to the bottom of the screening box 21, the electric telescopic rod 17 at the right end is contracted, the electric telescopic rod 17 at the left end is extended, so that the deoxidizers at the left side of the screening box 21 move to the right side of the screening box 21 for screening again, after several cycles, the screening is complete, the first electromagnetic valve 202 on the discharge port 200 is opened, the particles larger than the aperture of the first screen mesh 25 enter the first collecting box 281 through the first hose 28, the particles smaller than the aperture of the first screen mesh 25 and larger than the aperture of the second screen mesh 26 enter the second collecting box 291 through the second hose 29, and the particles smaller than the aperture of the second screen mesh 26 enter the third collecting box 201 through the third hose 20, so that the complete screening is completed.

The above description is only a preferred embodiment of the present invention, and any person skilled in the art may modify the present invention or modify it into an equivalent technical solution by using the technical solution described above. Therefore, any simple modifications or equivalent substitutions made in accordance with the technical solution of the present invention are within the scope of the claims of the present invention.

Claims (7)

1. Steelmaking deoxidier rectilinear vibration screening machine, including supporting component (1), supporting component (1) includes bottom plate (11), bottom plate (11) top both ends fixed mounting support column (10), support column (10) top fixed connection roof (12), its characterized in that, first cover seat (13) of bottom plate (11) top fixed mounting and second cover seat (18), be equipped with first spring (14) in first cover seat (13) inner chamber, first inserted bar (16) are pegged graft to first cover seat (13) inner wall, be equipped with second spring (19) in second cover seat (18) inner chamber, second inserted bar (15) are pegged graft to second cover seat (18) inner wall, round pin axle swing joint electric telescopic handle (17) are passed through on second inserted bar (15) top, still include: a screening device (2) located below the top plate (12); and

a discharge bin (3) located above the screening device (2);

the screening device (2) comprises a screening box (21), a vibrator (24) is fixedly installed at the top of the screening box (21), inclined plates (23) are fixedly installed on the inner wall of the screening box (21), a feeding hole (22) is formed in the top end of the screening box (21), a first screen (25) and a second screen (26) are fixedly installed on the inner wall of the screening box (21), discharge holes (200) are formed in the two ends of the bottom of the inner cavity of the first screen (25), the two ends of the two sides of the first screen (25), the two ends of the bottom of the inner cavity of the second screen (26) and the two ends of the inner cavity of the screening box (21), a first hose (28) is fixedly connected with the discharge holes (200) in the two sides of the first screen (25), a second hose (29) is fixedly connected with the discharge holes (200) in the two sides of the inner cavity of the second screen (26), a third hose (20) is fixedly connected with the discharge holes (200) in the two sides of the bottom of the inner cavity of the screening box (21), a first collection box (281) is fixedly connected with the bottom of the first hose (28), second hose (29) bottom fixed connection second collection workbin (291), third hose (20) bottom fixed connection third collection workbin (201), screening case (21) bottom is swing joint with electric telescopic handle (17), first inserted bar (16) top with screening case (21) swing joint.

2. The steelmaking deoxidizer linear vibration screening machine of claim 1, characterized in that: the second sleeve seats (18) are provided with two groups, and the two groups of second sleeve seats (18) are symmetrically arranged relative to the first sleeve seat (13).

3. The steelmaking deoxidizer linear vibration screening machine of claim 1, characterized in that: the bottom ends of the first spring (14) and the second spring (19) are fixedly connected with the bottom plate (11), the top end of the first spring (14) is fixedly connected with the bottom of the first insertion rod (16), and the bottom end of the second spring (19) is fixedly connected with the bottom end of the second insertion rod (15).

4. The steelmaking deoxidizer linear vibration screening machine of claim 1, characterized in that: discharging pipes (31) are arranged at the bottom of the discharging bin (3), and two groups of discharging pipes (31) are arranged.

5. The steelmaking deoxidizer linear vibration screening machine of claim 4, characterized in that: a first electromagnetic valve (202) is installed on the discharge port (200), and a second electromagnetic valve (32) is fixedly installed on the discharging pipe (31).

6. The steelmaking deoxidizer linear vibration screening machine of claim 4, characterized in that: the feeding ports (22) are two in number, the left end of each feeding port (22) is connected with the left end of the discharging pipe (31) through a guide pipe, and the right end of each feeding port (22) is connected with the right end of the discharging pipe (31) through a guide pipe.

7. The steelmaking deoxidizer linear vibration screening machine of claim 1, characterized in that: the discharging bin (3) is fixedly arranged on the top plate (12), and the inclined plate (23) is positioned below the feeding port (22).

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