CN210387499U - Processingequipment in micrite alloy material area - Google Patents

Abstract

The utility model discloses a processing device of a microcrystal alloy material belt, which relates to the technical field of microcrystal alloy processing equipment, the technical scheme is characterized by comprising a base, wherein an intermediate frequency furnace for melting microcrystalline alloy is arranged at the upper end of the base, a cooling roller is rotatably connected at the lower end of the base, an accommodating seat positioned above the cooling roller is also arranged on the base, the lower end of the base is provided with a fixed seat positioned on one side of the cooling roller, the fixed seat is rotatably connected with a horizontal screw rod, the screw rod is connected with a sliding seat in a threaded manner, the inner side of the sliding seat is attached to the side wall of the base, leave the clearance between sliding seat lower extreme and fixing base, install one side on the sliding seat with the tangent unloading seat in cooling drum surface, the utility model discloses have and to avoid micrite alloy material to take the adhesion on the cooling drum surface, make material area and cooling drum ability quickly separating's effect.

Description

Processingequipment in micrite alloy material area

Technical Field

The utility model relates to a technical field of micrite alloy processing equipment, more specifically say, it relates to a processingequipment in micrite alloy material area.

Background

The microcrystal alloy is a casting alloy material with metal crystal grains refined to micron level, and the alloy with the ultramicro microcrystal grains can show more excellent comprehensive mechanical property and mechanical property, super-strong performance stability and dimensional stability, excellent antifriction property and good wear resistance compared with other similar alloys.

In the prior art, when the microcrystalline alloy is processed, the microcrystalline alloy is usually melted by an intermediate frequency furnace, when the intermediate frequency furnace works, high-density magnetic lines can be generated in an induction coil, a metal material contained in the induction coil is cut, a large eddy current is generated in the metal material, and the metal is heated and melted by utilizing the electromagnetic induction principle; pouring the microcrystalline alloy from the medium frequency furnace to the containing seat after the microcrystalline alloy is molten, wherein a cooling roller is arranged below the containing seat, the molten microcrystalline alloy flows out of a discharge port of the containing seat to the surface of the cooling roller, and the cooling roller can rapidly cool the microcrystalline alloy melt due to the fact that the width of the discharge port of the containing seat is thin, so that the microcrystalline alloy forms a material strip shape; along with the rotation of cooling drum, micrite alloy material area will with cooling drum surface separation, form that the banding micrite alloy of material can be more convenient collect and transport.

However, when the microcrystalline alloy material strip is subjected to blanking, when the temperature of the surface of a part of the material strip is too high, the material strip will be attached to the surface of the cooling roller and is difficult to be smoothly separated from the surface of the cooling roller, the material strip attached to the cooling roller will affect the cooling effect of the cooling roller and also cause mutual adhesion between the material strips, and the quality of a final finished product is affected, so that the problem still needs to be improved and solved.

SUMMERY OF THE UTILITY MODEL

Not enough to prior art exists, the utility model provides a processingequipment in micrite alloy material area has and to avoid micrite alloy material area adhesion on the cooling drum surface, makes the material area and cooling drum ability quickly separating's effect.

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

the utility model provides a processingequipment in micrite alloy material area, includes the base, and the intermediate frequency furnace that is used for melting micrite alloy is installed to the base upper end, and the base lower extreme rotates and is connected with the cooling drum, still installs the seat that holds that is located the cooling drum top on the base, the base lower extreme is installed and is located the fixing base of cooling drum one side, it is connected with the horizontally lead screw to rotate on the fixing base, threaded connection has the sliding seat on the lead screw, the sliding seat inboard with the laminating of base lateral wall, leave the clearance between sliding seat lower extreme and fixing base, install one side on the sliding seat with the tangent unloading seat in cooling drum surface.

By adopting the technical scheme, when the microcrystalline alloy material belt is processed, the melt melted by the intermediate frequency furnace is poured into the containing seat, the melt flows out of the opening at the lower end of the containing seat to the surface of the cooling roller, the flowing-down melt can be rapidly cooled by the cooling roller due to the thin width of the opening of the containing seat, and the melt cooled by the cooling roller forms a thin material belt; because unloading seat one side is tangent with the cooling drum surface, when the material area is attached to the cooling drum surface, can shovel down adnexed material area through the unloading seat, help material area can be more smooth with the separation of cooling drum to can drive the sliding seat through rotating the lead screw and slide along the lead screw direction, thereby can adjust the position of unloading seat, adjust the unloading seat and enable the separation effect in material area after suitable position better.

The utility model discloses further set up to: the lead screw one end is worn out from fixing base one side, and the back of wearing out be provided with the worm wheel on the lead screw, install the servo motor who is located worm wheel one side on the base, be provided with on the servo motor output shaft with worm wheel one side engaged with worm.

By adopting the technical scheme, one end of the screw rod is connected with the output shaft of the servo motor through the worm gear and the worm, and the screw rod can rotate forward or backward under the driving of the servo motor, so that the left and right movement of the sliding seat can be realized; the blanking seat arranged on the sliding seat moves along with the movement of the sliding seat, and the position of the blanking seat is conveniently adjusted through the servo motor.

The utility model discloses further set up to: the fixing seat is provided with a limiting column located below the screw rod, the limiting column is located at two ends of the sliding seat respectively, and the height of the limiting column is larger than a gap between the lower end of the sliding seat and the fixing seat.

Through adopting above-mentioned technical scheme, when the sliding seat removed along the lead screw when moving, because the clearance between high being greater than sliding seat lower extreme and fixing base of spacing post, can restrict the displacement range of sliding seat through spacing post, avoid the excessive removal of sliding seat.

The utility model discloses further set up to: the blanking device is characterized in that a connecting rod is arranged on one side of the sliding seat, a vertical through hole is formed in one end of the connecting rod, the upper end of the blanking seat penetrates through the connecting rod through the through hole, and the upper end of the blanking seat is screwed in the through hole through a bolt.

Through adopting above-mentioned technical scheme, can adjust the height of unloading seat after unscrewing the bolt, through the height of adjusting the unloading seat from top to bottom to can come to adjust the tangent department of unloading seat and cooling drum according to the production condition of reality, make the separation effect better with the different situation of adaptation.

The utility model discloses further set up to: the blanking seat comprises a first connecting rod vertically penetrating through the through hole, a second connecting rod horizontally arranged at the lower end of the first connecting rod in a sliding manner and a cutting block arranged at one end of the second connecting rod; the second connecting rod is screwed at the lower end of the first connecting rod through a bolt, and the cutting block is positioned on one side of the cooling roller and is tangent to the surface of the cooling roller.

Through adopting above-mentioned technical scheme, because the second connecting rod is screwed up at first connecting rod lower extreme through the bolt, through with the bolt unscrew the back alright remove the position of second connecting rod, the separation effect that can make the stripping and slicing through the position adjustment with the second connecting rod to the suitable position is better to the position through adjusting the second connecting rod about can also compensate the problem of sliding seat displacement range undersize, make stripping and slicing on the second connecting rod can be better separate material area and cooling drum surface.

The utility model discloses further set up to: and a U-shaped pipe is arranged at one end of the second connecting rod, and the lower end of the cutting block is rotatably connected to the U-shaped pipe.

By adopting the technical scheme, as the side wall of the cutting block is tangent to the surface of the cooling roller, the side wall of the cutting block is continuously worn in the long-term use process, and the worn cutting block is difficult to be attached to the surface of the cooling roller, so that the separation effect is reduced; when one side of the cut block is abraded, the cut block is turned over by rotating the cut block, so that the side wall of the other side of the cut block is attached to and tangent to the surface of the cooling roller, and the service life of the cut block can be prolonged.

The utility model discloses further set up to: be provided with vertical support frame on the base, the support frame upper end articulates there is the swing span, the intermediate frequency furnace both ends are fixed the swing span is inboard, be provided with vertical telescopic cylinder who just is located support frame one side on the base, telescopic cylinder lower extreme articulates on the base, telescopic cylinder output shaft upwards just articulates the swing span outside.

By adopting the technical scheme, when the output shaft of the telescopic cylinder stretches upwards, the swing frame rotates around the hinged part, the intermediate frequency furnace arranged on the inner side of the swing frame inclines along with the rotation of the swing frame, and the microcrystalline alloy melt in the intermediate frequency furnace gradually flows out to the accommodating seat along with the continuous inclination of the intermediate frequency furnace; when the telescopic cylinder output shaft contracts, the swing span drives the intermediate frequency furnace to gradually return, and the flow of molten liquid can be controlled according to the actual production condition through the telescopic cylinder by workers, so that smooth production of the material belt is ensured.

The utility model discloses further set up to: a drainage seat positioned on one side of the intermediate frequency furnace is arranged on the base, a vertical and penetrating drainage groove is formed in the drainage seat, a funnel is arranged at the upper end of the drainage seat, an opening at the upper end of the funnel extends to one side of the intermediate frequency furnace, and an opening at the lower end of the funnel is aligned with the drainage groove; the lower end of the drainage groove is aligned with the containing seat.

By adopting the technical scheme, when the medium-frequency furnace pours the molten liquid into the funnel, the opening at the upper end of the funnel extends to one side of the medium-frequency furnace, so that the molten liquid can be prevented from flowing down from the drainage seat when the molten liquid is poured, and the molten liquid can more accurately flow into the funnel from the opening at the upper end of the funnel; the melt flows into the drainage groove after being drained by the funnel, and then flows into the containing seat through the drainage groove.

To sum up, the utility model discloses following beneficial effect has:

the melt cooled by the cooling roller forms a thinner material belt; one side of the cutting block is tangent to the surface of the cooling roller, so that when the material belt is attached to the surface of the cooling roller, the attached material belt can be shoveled down through the cutting block, and the material belt can be smoothly separated from the cooling roller; when the position of stripping and slicing needs be adjusted, the lead screw is rotated through starting the servo motor, the sliding seat can slide along the direction of the lead screw along with the rotation of the lead screw, so that the position of the stripping and slicing can be moved left and right, the stripping and slicing can be better after being adjusted to a proper position, the microcrystalline alloy material belt is prevented from being stuck on the surface of the cooling roller, and the rapid separation of the material belt and the surface of the cooling roller is realized.

Drawings

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view showing a partial structure of the drainage seat and the funnel;

FIG. 3 is a schematic view showing a partial structure of the swing seat of the present invention;

FIG. 4 is an exploded view of the local structure of the position-limiting frame;

fig. 5 is a schematic view of the whole structure of the back wind seat of fig. 1;

FIG. 6 is a schematic view showing a partial structure of the slide plate and the rotary screw rod of the present invention;

fig. 7 is a schematic view showing a partial structure of the discharging seat of the present invention.

Reference numerals: 1. a base; 2. an intermediate frequency furnace; 3. cooling the drum; 4. an accommodating seat; 5. a fixed seat; 6. a screw rod; 7. a sliding seat; 8. a blanking seat; 9. a worm gear; 10. a servo motor; 11. a worm; 12. a connecting rod; 13. perforating; 14. a first link; 15. a second link; 16. cutting into blocks; 17. a support frame; 18. a swing frame; 19. a telescopic cylinder; 20. a drainage seat; 21. a drainage groove; 22. a funnel; 23. a limiting column; 24. a U-shaped tube; 111. a swing seat; 112. a limiting frame; 113. a slot; 114. a heating device; 115. an electromagnetic heating coil; 116. a base; 117. a telescopic rod; 118. adjusting the bolt; 119. a transverse screw rod; 120. a first motor; 121. a machine platform; 122. a support pillar; 123. a longitudinal screw rod; 124. a transverse bolt; 125. a second motor; 201. a wind seat; 202. an air inlet pipe; 203. a brush; 204. a slide plate; 205. a slide rail; 206. a connecting plate; 207. a drive motor; 208. rotating the screw rod; 209. a limiting block; 210. a wind guide seat; 211. a cambered surface; 212. an asynchronous motor; 213. placing a seat; 401. a limiting strip; 402. fixing the bolt; 403. a limiting groove; 404. a handle.

Detailed Description

The present invention will be further explained with reference to the accompanying drawings.

A processing device for a microcrystal alloy material strip is shown in figure 1 and comprises a base 1, wherein an intermediate frequency furnace 2 which is used for melting microcrystal alloy and is in a barrel shape is installed at the upper end of the base 1, two vertical and opposite support frames 17 are fixedly installed on the base 1, and the intermediate frequency furnace 2 is located between the two support frames 17.

As shown in FIG. 1, the top ends of the two support frames 17 are hinged with a swing frame 18 located on one side of the intermediate frequency furnace 2, two ends of the intermediate frequency furnace 2 are respectively welded on the inner side wall of the corresponding swing frame 18, and the intermediate frequency furnace 2 is located at one end of the swing frame 18 far away from the support frames 17. When the angle between the swing frame 18 and the support frame 17 is ninety degrees, the intermediate frequency furnace 2 is in a vertical state.

As shown in figure 1, two vertical telescopic cylinders 19 are mounted on the base 1 below the swing frame 18, the two telescopic cylinders 19 are respectively located on two sides of the intermediate frequency furnace 2, the lower ends of the telescopic cylinders 19 are hinged on the base 1, and the output shafts of the telescopic cylinders 19 face upwards and are hinged on the outer side wall of one end of the swing frame 18, which is far away from the supporting frame 17. The two telescopic cylinders 19 keep synchronous telescopic, when the output shafts of the telescopic cylinders 19 are stretched upwards, the swing frame 18 rotates around the hinged part, the intermediate frequency furnace 2 arranged on the inner side of the swing frame 18 inclines along with the rotation of the swing frame 18, and the microcrystalline alloy melt in the intermediate frequency furnace 2 gradually flows out from the furnace mouth along with the continuous inclination of the intermediate frequency furnace 2.

As shown in fig. 1 and 2, a horizontal drainage seat 20 is fixedly connected to the base 1 and located on one side of the intermediate frequency furnace 2, a horizontal funnel 22 is fixedly mounted at the upper end of the drainage seat 20, an upper end opening of the funnel 22 extends to one side of the intermediate frequency furnace 2, and the inner side wall of the funnel 22 is in a curved arc shape. The drainage seat 20 is provided with a vertical and through drainage groove 21, and the lower end opening of the funnel 22 is aligned with the upper opening of the drainage groove 21. The melt flowing out of the intermediate frequency furnace 2 can accurately flow down through the drainage action of the funnel 22 and the drainage groove 21.

As shown in fig. 1 and fig. 3, a cylindrical machine table 121 is installed at the bottom of the base 1, a vertical supporting column 122 is rotatably connected to the machine table 121, and the supporting column 122 is located on one side of the drainage seat 20. The support column 122 is provided with a swing seat 111 which is arranged in a sliding manner along the vertical direction, and the swing seat 111 is arranged horizontally and is perpendicular to the support column 122. One end of the swing seat 111 extends to the lower end of the drainage seat 20. The upper end of the supporting column 122 is rotatably connected with a vertical longitudinal screw rod 123, and the lower end of the longitudinal screw rod 123 is penetrated through and is in threaded connection with the swing seat 111.

As shown in fig. 1 and 3, a second motor 125 with an output shaft vertically downward is fixedly mounted at the top of the supporting column 122, and the output shaft of the second motor 125 is rotatably connected with the upper end of the longitudinal screw 123. After the second motor 125 is started, the longitudinal screw 123 can be driven to rotate forward or backward, and the swing seat 111 can move up and down along the direction of the longitudinal screw 123.

As shown in fig. 3 and 4, the swing base 111 is further rotatably connected with a horizontal transverse screw rod 119, one end of the swing base 111 close to the support column 122 is fixedly provided with a first motor 120 for driving the transverse screw rod 119 to rotate, and an output shaft of the first motor 120 is meshed with one end of the transverse screw rod 119. The end of the swing seat 111 far away from the support column 122 is provided with a limit frame 112 in a sliding manner, the side wall of one end of the limit frame 112 is attached to the side wall of the swing seat 111, the limit frame 112 is arranged in a penetrating manner and is in threaded connection with the transverse screw rod 119, and the limit frame 112 can move along the direction of the transverse screw rod 119 when the transverse screw rod 119 rotates.

As shown in fig. 2 and 4, a slot 113 is formed at one end of the limiting frame 112 away from the swinging seat 111, a rectangular accommodating seat 4 is fixed in the slot 113, the accommodating seat 4 is moved to the lower side of the drainage groove 21 by rotating the swinging seat 111 during operation, and the melt flowing out of the drainage groove 21 flows in from an upper end opening of the accommodating seat 4.

As shown in fig. 3 and 4, a circumferential and horizontal limiting strip 401 is formed on an outer side wall of the accommodating seat 4, and the accommodating seat 4 is placed on the limiting frame 112 through the limiting strip 401. The upper end of the limiting strip 401 is in threaded connection with four fixing bolts 402, the four fixing bolts 402 are two-by-two in a group and are respectively located at two ends of the accommodating seat 4, and the fixing bolts 402 are vertically arranged and screwed on the limiting frame 112. The two end side walls of the limiting frame 112 are both connected with symmetrical transverse bolts 124 through threads, the two transverse bolts 124 are respectively located at the two ends of the accommodating seat 4, the transverse bolts 124 are inserted and screwed on the limiting frame 112 along the horizontal direction, and the screwed transverse bolts 124 are abutted against the side walls of the accommodating seat 4.

As shown in fig. 3 and 4, two horizontal handles 404 are welded to the position-limiting strip 401, and the two handles 404 are respectively located on the side walls of the accommodating seat 4 that are away from each other. The length of two handles 404 all exceeds the lateral wall of the spacing 112 that corresponds separately, when needs will hold seat 4 and take out from spacing 112, owing to hold seat 4 lateral wall and can leave the waste heat, can not only make things convenient for the staff will hold seat 4 through handle 404 and take out, and longer handle 404 can avoid the waste heat to scald the staff to play certain guard action to the staff.

As shown in fig. 1 and 4, the bottom of the base 1 is further provided with a heating device 114 located at one side of the swing seat 111, and the heating device 114 includes a base 116 placed on the base 1 and a telescopic rod 117 slidably disposed on the base 116. The telescopic rod 117 is vertically placed on the base 116, and is connected with an adjusting bolt 118 through threads, and the telescopic rod 117 is screwed on the base 116 through the adjusting bolt 118. When the adjusting bolt 118 is loosened, the height of the telescopic rod 117 can be adjusted up and down. An electromagnetic heating ring 115 for heating the bottom of the accommodating seat 4 is mounted at the upper end of the telescopic rod 117.

As shown in fig. 4, hold seat 4 bottom and be formed with inside sunken spacing recess 403, will hold seat 4 through swing seat 111 before the start of work and roll out to heating device 114 top, insert electromagnetic heating circle 115 upper end in spacing recess 403 again, because it is the metal material to hold seat 4 after circular telegram for electromagnetic heating circle 115, hold seat 4 bottom and will produce the vortex, can heat holding seat 4 bottom with the electromagnetic induction principle, thereby can help solid microcrystalline alloy to accelerate its melting, avoid partial solid microcrystalline alloy to block up the discharge gate that holds seat 4.

As shown in fig. 5 and 6, the lower end of the base 1 is rotatably connected with a cooling roller 3 for cooling the microcrystalline alloy strip, and the cooling roller 3 is located right below the drainage seat 20 and horizontally placed. A motor for driving the cooling roller 3 to rotate is mounted on the base 1, and one end of the cooling roller 3 is connected with an output shaft of the motor through a belt. In operation, the containing seat 4 (see fig. 3) is rotated to the upper part of the cooling roller 3 through the swinging seat 111, so that the discharge port at the lower end of the containing seat 4 is aligned with the upper surface of the cooling roller 3, and the flowing-down melt can be cooled through the cooling roller 3.

As shown in fig. 5 and 6, an air seat 201 is installed on the bottom of the base 1 and located on one side of the cooling roller 3, and an air outlet of the air seat 201 is aligned with the surface of the cooling roller 3. The one end welding that cooling drum 3 was kept away from to wind seat 201 has induced air seat 210, and induced air seat 210 front end is cylindrically, and its rear end diameter is gradually to keeping away from 3 direction increases of cooling drum, the inside and wind seat 201 intercommunication of induced air seat 210, and the terminal cover of induced air seat 210 is equipped with air-supply line 202, can accelerate the separation on material area and cooling drum 3 surface through wind seat 201.

As shown in fig. 5 and 6, a horizontal brush 203 is rotatably connected to the inner side wall of the wind base 201, and one end of the brush 203 contacts with the side wall of the cooling drum 3. The wind base 201 is bent inward toward the sidewall of one end of the cooling drum 3 to form an arc surface 211, and a certain gap is left between the arc surface 211 and the cooling drum 3. The two ends of the brush 203 are rotatably connected to the inner side wall of the air seat 201, the placing seat 213 is installed on one side of the air seat 201, the asynchronous motor 212 with an output shaft fixedly connected with the axis of the brush 203 is fixedly installed in the placing seat 213, and the brush 203 continuously rotates after the asynchronous motor 212 is started, so that the surface of the cooling roller 3 can be cleaned. And the rotation direction of the fur brush 203 is opposite to the rotation direction of the cooling drum 3, so that the cleaning effect of the fur brush 203 can be better.

As shown in fig. 6, two transverse sliding rails 205 disposed opposite to each other are fixedly disposed on the base 1, the two transverse sliding rails 205 are both located below the wind seat 201 and the placement seat 213, a horizontal sliding plate 204 is slidably disposed on the two sliding rails 205, and two ends of the sliding plate 204 are respectively slidably disposed on the sliding rails 205. The wind seat 201 and the placing seat 213 are both fixedly connected to the upper side wall of the sliding plate 204 and are both vertically placed.

As shown in fig. 5 and 6, a connecting plate 206 that is vertical and faces the sliding plate 204 is fixedly connected to one side of the sliding rail 205, and a horizontal driving motor 207 is fixedly installed on a side wall of one end of the connecting plate 206 that faces away from the sliding plate 204. An output shaft of the driving motor 207 is inserted into an inner sidewall of the connection plate 206 and is rotatably connected to the connection plate 206. A horizontal rotating screw rod 208 is fixedly connected to an output shaft of the driving motor 207, the rotating screw rod 208 is arranged on the sliding plate 204 in a penetrating way, and the sliding plate 204 is in threaded connection with the rotating screw rod 208. After the driving motor 207 is started, the wind seat 201 and the placing seat 213 can be slidably arranged on the sliding rail 205 through the sliding plate 204, so that the position of the wind outlet of the wind seat 201 can be adjusted.

As shown in fig. 6, still fixedly connected with is located the stopper 209 between slide 204 and the connecting plate 206 on the base 1, and stopper 209 is rectangle and vertical the placing, rotates lead screw 208 and wears to establish on stopper 209 to it connects on stopper 209 to rotate lead screw 208, can play the spacing effect of support to rotate lead screw 208 through stopper 209.

As shown in fig. 7, a fixing seat 5 located on one side of the cooling drum 3 is fixedly installed at the lower end of the base 1, a horizontal screw rod 6 is rotatably connected to the fixing seat 5, one end, away from the cooling drum 3, of the screw rod 6 penetrates out from one end of the fixing seat 5, and a worm wheel 9 is fixedly connected to the penetrated screw rod 6. A servo motor 10 positioned on one side of the worm wheel 9 is installed at the corresponding position of the base 1, a worm 11 meshed with the worm wheel 9 is fixedly connected to an output shaft of the servo motor 10, and the screw rod 6 can be driven to rotate forwards or reversely through the servo motor 10.

As shown in fig. 7, a rectangular sliding seat 7 is connected to the screw rod 6 by a thread, a side wall of one end of the sliding seat 7 is attached to a side wall of the base 1, and a gap is left between a lower side wall of the sliding seat 7 and the fixed seat 5. The sliding seat 7 can move in the direction of the screw 6 when the screw 6 rotates. Two vertical limiting columns 23 are fixedly connected to the fixing seat 5, and the two limiting columns 23 are located under the screw rod 6 and located at two ends of the sliding seat 7 respectively. The height of spacing post 23 is greater than the clearance between 7 lower extremes of sliding seat and fixing base 5, can restrict the displacement range of sliding seat 7 through spacing post 23, avoids sliding seat 7 excessive movement.

As shown in fig. 7, a connecting rod 12 is disposed on one side of the sliding seat 7 away from the base 1, a vertical through hole 13 is disposed at one end of the connecting rod 12 away from the sliding seat 7, and the connecting rod 12 is movably connected to the blanking seat 8 through the through hole 13. The blanking seat 8 comprises a first connecting rod 14 vertically penetrating through the through hole 13, a second connecting rod 15 horizontally slidably arranged at the lower end of the first connecting rod 14, and a cutting block 16 which is arranged at one end of the second connecting rod 15 and is conical. The first link 14 is screwed into the through hole 13 by a bolt, and when the height of the blanking base 8 needs to be adjusted, the position of the first link 14 can be moved up and down by screwing the bolt out of the through hole 13.

As shown in fig. 7, the second link 15 is also screwed to the lower end of the first link 14 by a bolt, and when the position of the second link 15 needs to be adjusted, the position of the second link 15 can be adjusted left and right by loosening the bolt. One end of the second connecting rod 15 close to the cooling roller 3 is fixedly connected with a U-shaped pipe 24, and the lower end of the cutting block 16 is rotatably connected to the U-shaped pipe 24. The cutting block 16 is positioned on one side of the cooling roller 3 and tangent to the surface of the cooling roller 3, and the material belt attached to the cooling roller 3 can be effectively shoveled down through the cutting block 16, so that the material belt can be smoothly separated from the cooling roller 3.

The concrete effects of this embodiment:

the melt after the cooling of cooling drum 3 will form thinner material area, because the stripping 16 one side is tangent with cooling drum 3 surface, when the material area is attached to cooling drum 3 surface, can shovel down adnexed material area through stripping 16, help the material area more smooth with cooling drum 3 separation. When the position of the cutting block 16 needs to be adjusted, the screw rod 6 is rotated by starting the servo motor 10, the sliding seat 7 can slide along the direction of the screw rod 6 along with the rotation of the screw rod 6, so that the position of the cutting block 16 can be moved left and right, the separation effect of the material belt can be better after the cutting block 16 is adjusted to a proper position, the microcrystalline alloy material belt is prevented from being adhered to the surface of the cooling roller 3, and the rapid separation of the material belt and the surface of the cooling roller 3 is realized.

The above description is only the preferred embodiment of the present invention, and is not intended to limit the present invention, any modification, equivalent replacement, or improvement made within the design concept of the present invention should be included within the protection scope of the present invention.

Claims (8)

1. The utility model provides a processingequipment in micrite alloy material area, includes base (1), and intermediate frequency furnace (2) that are used for melting micrite alloy are installed to base (1) upper end, and base (1) lower extreme rotates and is connected with cooling drum (3), still installs on base (1) to be located the seat (4) that hold of cooling drum (3) top, characterized by: base (1) lower extreme is installed and is located fixing base (5) of cooling drum (3) one side, it is connected with horizontally lead screw (6) to rotate on fixing base (5), threaded connection has sliding seat (7) on lead screw (6), sliding seat (7) inboard with base (1) lateral wall laminating, leave the clearance between sliding seat (7) lower extreme and fixing base (5), install one side on sliding seat (7) with tangent unloading seat (8) in cooling drum (3) surface.

2. The apparatus for processing microcrystalline alloy material strip as claimed in claim 1, wherein: lead screw (6) one end is worn out from fixing base (5) one side, wears out the back be provided with worm wheel (9) on lead screw (6), install servo motor (10) that are located worm wheel (9) one side on base (1), be provided with on servo motor (10) output shaft with worm wheel (9) one side meshing worm (11).

3. The device for processing the microcrystal alloy material strip according to claim 2, wherein: the fixing seat (5) is provided with a limiting column (23) located below the screw rod (6), the limiting column (23) is located at two ends of the sliding seat (7) respectively, and the height of the limiting column (23) is larger than a gap between the lower end of the sliding seat (7) and the fixing seat (5).

4. The device for processing the microcrystal alloy material strip according to claim 2, wherein: sliding seat (7) one side is provided with connecting rod (12), vertical and perforation (13) that run through are seted up to connecting rod (12) one end, material unloading seat (8) upper end is worn to establish through perforation (13) activity on connecting rod (12), just material unloading seat (8) upper end is screwed up in perforation (13) through the bolt.

5. The device for processing the microcrystal alloy material strip according to claim 4, wherein: the blanking seat (8) comprises a first connecting rod (14) vertically penetrating through the through hole (13), a second connecting rod (15) horizontally arranged at the lower end of the first connecting rod (14) in a sliding manner and a cutting block (16) arranged at one end of the second connecting rod (15); the second connecting rod (15) is screwed at the lower end of the first connecting rod (14) through a bolt, and the cutting block (16) is positioned on one side of the cooling roller (3) and is tangent to the surface of the cooling roller (3).

6. The device for processing the microcrystal alloy material strip according to claim 5, wherein: one end of the second connecting rod (15) is provided with a U-shaped pipe (24), and the lower end of the cutting block (16) is rotatably connected to the U-shaped pipe (24).

7. The apparatus for processing microcrystalline alloy material strip as claimed in claim 1, wherein: be provided with vertical support frame (17) on base (1), support frame (17) upper end articulates there is swing span (18), intermediate frequency furnace (2) both ends are fixed swing span (18) inboard, be provided with vertical telescopic cylinder (19) that just are located support frame (17) one side on base (1), telescopic cylinder (19) lower extreme articulates on base (1), telescopic cylinder (19) output shaft upwards just articulates swing span (18) outside.

8. The apparatus for processing microcrystalline alloy material strip as claimed in claim 7, wherein: a drainage seat (20) positioned on one side of the intermediate frequency furnace (2) is arranged on the base (1), a vertical and penetrating drainage groove (21) is formed in the drainage seat (20), a funnel (22) is arranged at the upper end of the drainage seat (20), an opening at the upper end of the funnel (22) extends to one side of the intermediate frequency furnace (2), and an opening at the lower end of the funnel (22) is aligned with the drainage groove (21); the lower end of the drainage groove (21) is aligned with the containing seat (4).

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