CN114274573B - Scrap iron purchasing, flattening and weighing integrated equipment - Google Patents

Abstract

The application relates to the field of scrap iron recovery, in particular to scrap iron purchasing, flattening and weighing integrated equipment, which comprises a bearing table, a material transferring mechanism arranged on the bearing table, a material discharging mechanism and a weighing mechanism, wherein the material transferring mechanism comprises a material transferring disc, a plurality of circumferentially equidistantly distributed material cavities are formed in the material transferring disc, and the flattening mechanism, the discharging mechanism and the weighing mechanism are arranged above the leftmost material cavity. According to the application, through the rotary tray provided with the bearing table, the material cavities distributed at equal intervals on the circumference, the extruding disc, the first hydraulic cylinder, the unloading plate, the second driving mechanism and the weighing belt conveyor, the iron product is compressed and then transferred through the rotary tray, and then the iron product is unloaded onto the weighing belt conveyor through the unloading plate for weighing, compression and weighing are realized in the same equipment, long-distance material transfer among different equipment in a traditional mode is replaced, the operation is simplified, and the waste iron recovery efficiency is improved.

Description

Scrap iron purchasing, flattening and weighing integrated equipment

Technical Field

The application relates to the field of scrap iron recovery, in particular to scrap iron purchasing, flattening and weighing integrated equipment.

Background

In the scrap iron recycling process, the waste shapes of various iron are different from each other, so that follow-up transportation and weighing are not facilitated, the scrap iron is required to be compressed in the recycling process so as to be convenient for follow-up weighing and transportation, the traditional compression equipment and the weighing equipment are two independent equipment, compression is generally required, then compressed discus is transferred to the weighing equipment by using a lifting device or a forklift to weigh, and the operation is complex and consumes longer time.

Thus, there is a need for a compression and weighing integrated device.

Disclosure of Invention

The application aims to provide scrap iron purchasing, flattening and weighing integrated equipment so as to solve the problems in the background technology.

In order to achieve the above purpose, the present application provides the following technical solutions:

an integrated equipment of weighing is flattened in scrap iron purchase, includes:

the device comprises a base, a bearing table fixedly arranged on the base, and a top plate arranged above the bearing table and fixedly connected with the base through a central supporting rod;

the material transferring mechanism is arranged on the bearing table and comprises a material transferring disc rotatably arranged on the upper end surface of the bearing table and rotatably connected with the central supporting rod and a first driving mechanism for driving the material transferring disc to rotate, and a plurality of material cavities which are circumferentially distributed at equal intervals and penetrate through the material transferring disc are arranged on the material transferring disc;

the flattening mechanism is arranged above the leftmost material cavity and comprises a guide cylinder fixedly connected with the bearing table and positioned above the leftmost material cavity, a pressing disc nested in the guide cylinder and slidingly connected with the inner cavity of the guide cylinder, and a first hydraulic cylinder connected with the pressing disc and fixedly connected with the top plate;

the discharging mechanism is symmetrically arranged with the flattening mechanism and comprises a discharging hole which is arranged on the bearing table and is opposite to the rightmost material cavity, a group of discharging plates which are arranged in the discharging hole and are in mirror symmetry, and a second driving mechanism for driving the group of discharging plates to open back;

and the weighing mechanism is arranged on the base and is opposite to the discharge hole.

Preferably, the first driving mechanism comprises a sleeve fixedly connected with the rotary tray and sleeved on the central supporting rod, a transmission shaft which is rotationally connected with the supporting plate vertically fixed with the top plate and parallel to the top plate, a first transmission gear set which is connected with the sleeve and the transmission shaft, a ratchet gear arranged at the left end part of the transmission shaft, a first rack plate meshed with the ratchet gear and vertically arranged, and a fixing rod vertically fixed with the first rack plate and fixedly connected with a first piston rod of the first hydraulic cylinder.

Preferably, the second driving mechanism comprises a group of rotating shafts fixedly connected with the unloading plates and extending to the outer side of the bearing table, a group of driven gears arranged on the outer side of the rotating shafts, a second rack plate arranged between the driven gears and meshed with the driven gears, and a second hydraulic cylinder connected with the second rack plate and arranged on the top plate.

Preferably, a pushing plate is arranged above the rightmost material cavity, and the pushing plate is fixedly connected with the second rack plate through a mounting rod.

Preferably, the ratchet gear comprises a gear ring meshed with the first rack plate and provided with a pawl groove at the inner side, a rotating disc nested in the gear ring and rotationally connected with the gear ring, a pawl rotationally connected with the inner wall of the rotating disc through a hinge shaft, a limiting block abutted with the upper end of the pawl and fixedly connected with the rotating disc, and a spring piece abutted with the lower end of the pawl and fixedly connected with the rotating disc; the pawl is clamped in the pawl groove.

Preferably, the material transferring disc is a disc, and the material cavity is a square through hole.

Preferably, the guide cylinder is a square cylinder with an opening at the lower end, and the cross section area of the guide cylinder is equal to that of the inner cavity of the material cavity; the extrusion disc is a square block.

Preferably, the first drive gear set comprises a set of mutually perpendicular and intermeshing bevel gears.

Preferably, the weighing mechanism is a platform scale or a belt scale.

Preferably, the rear side of the first rack plate is slidingly connected with a sliding rail with a T-shaped cross section, the upper end of the sliding rail is fixedly connected with the top plate, and the lower end of the sliding rail is fixedly connected with the guide cylinder.

Compared with the prior art, the application has the beneficial effects that: according to the application, through the rotary tray provided with the bearing table, the material cavities distributed at equal intervals on the circumference, the extruding disc, the first hydraulic cylinder, the unloading plate, the second driving mechanism and the weighing belt conveyor, the iron product is compressed and then transferred through the rotary tray, and then the iron product is unloaded onto the weighing belt conveyor through the unloading plate for weighing, compression and weighing are realized in the same equipment, long-distance material transfer among different equipment in a traditional mode is replaced, the operation is simplified, and the waste iron recovery efficiency is improved.

Drawings

Fig. 1 is a schematic perspective view of a left side view of an integrated equipment for purchasing, flattening and weighing scrap iron.

Fig. 2 is a schematic perspective view of a right side view of the scrap iron purchasing, flattening and weighing integrated device.

Fig. 3 is a schematic diagram of a cross-sectional structure of a transfer tray and a carrying table in the scrap iron purchasing, flattening and weighing integrated equipment.

Fig. 4 is a schematic diagram of a three-dimensional assembly structure of a transfer tray in an integrated equipment for purchasing, flattening and weighing scrap iron.

Fig. 5 is a schematic diagram of an assembly structure of a loading table and a stripper plate in the scrap iron purchasing, flattening and weighing integrated equipment.

Fig. 6 is an exploded construction view of a ratchet gear in the scrap iron purchasing, flattening and weighing integrated apparatus.

Fig. 7 is an assembly structure diagram of a rotating disc in the scrap iron purchasing, flattening and weighing integrated device.

In the figure: 1. a base; 2. a carrying platform; 201. a discharge port; 3. a material transferring disc; 301. a material cavity; 4. an extrusion plate; 5. a guide cylinder; 6. a first piston rod; 7. a first hydraulic cylinder; 8. a top plate; 9. a center support bar; 10. a sleeve; 11. a drive gear set; 12. a transmission shaft; 13. a ratchet gear; 1301. a gear ring; 1302. a pawl slot; 1303. a rotating disc; 1304. a pawl; 1305. a hinge shaft; 1306. a limiting block; 1307. a spring piece; 14. a first rack plate; 15. a fixed rod; 16. a stripper plate; 17. a rotating shaft; 18. a driven gear; 19. a second rack plate; 20. a second piston rod; 21. a second hydraulic cylinder; 22. a pushing plate; 23. a mounting rod; 24. a weighing mechanism; 25. a slide rail.

Detailed Description

The following description of the embodiments of the present application will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present application, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the application without making any inventive effort, are intended to be within the scope of the application.

In addition, an element in the present disclosure may be referred to as being "fixed" or "disposed" on another element or being directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Referring to fig. 1-7, in an embodiment of the present application, a scrap iron purchasing, flattening and weighing integrated device includes:

the device comprises a base 1, a bearing table 2 fixedly arranged on the base 1, and a top plate 8 arranged above the bearing table 2 and fixedly connected with the base 1 through a central supporting rod 9;

the material transferring mechanism is arranged on the bearing table 2 and comprises a material transferring disc 3 rotatably arranged on the upper end surface of the bearing table 2 and rotatably connected with the central supporting rod 9, and a first driving mechanism for driving the material transferring disc 3 to rotate, wherein a plurality of material cavities 301 which are distributed at equal intervals in circumference and penetrate through the material transferring disc 3 are formed in the material transferring disc 3;

the flattening mechanism is arranged above the leftmost material cavity 301 and comprises a guide cylinder 5 fixedly connected with the bearing table 2 and positioned above the leftmost material cavity 301, an extrusion disc 4 nested in the guide cylinder 5 and slidingly connected with the inner cavity of the guide cylinder 5, and a first hydraulic cylinder 7 connected with the extrusion disc 4 and fixedly connected with the top plate 8;

the discharging mechanism is symmetrically arranged with the flattening mechanism and comprises a discharging hole 201 which is arranged on the bearing table 2 and is opposite to the rightmost material cavity 301, a group of discharging plates 16 which are arranged in the discharging hole 201 and are in mirror symmetry, and a second driving mechanism for driving the group of discharging plates 16 to open back;

and a weighing mechanism 24 which is arranged on the base 1 and is opposite to the discharge hole 201.

Specifically, the waste iron product to be recovered is dumped into a material cavity 301 positioned at one station on the extrusion mechanism, then a first driving mechanism is started, then the first driving mechanism is started, the first driving mechanism drives a material rotating disc 3 to rotate, the material rotating disc 3 drives the material cavity 301 filled with waste iron to move to the lower part of the material pressing mechanism, a first hydraulic cylinder 7 drives an extrusion disc 4 in a guide cylinder 5 to move downwards through a first piston rod 6, the waste iron product in the material cavity 301 is compressed into a cake shape, then the first hydraulic cylinder 7 returns to the initial position, the first driving mechanism drives the material rotating disc 3 to rotate one station again, the material pressing mechanism again performs material pressing operation, and in the material pressing process, the dumping filling of the waste iron product can be performed on the material cavity positioned at the last station of the material pressing station, and the intermittent material pressing operation is realized;

when the rotating tray 3 drives the discus in the material cavity 301 to move to the position of the discharge hole 201, the second driving mechanism drives the group of discharge plates 16 to open back, in particular, in the opening process, the group of discharge plates 16 rotate back, gaps between the discharge plates 16 are gradually enlarged, in the intermittent enlarging process of the discharge plates 16, the discus slides down along the inner wall of the discharge plates 16, and slides onto the weighing mechanism 24 along the inner wall of the discharge plates 16, so that the discus is prevented from falling down quickly and colliding with the weighing mechanism 24 to damage the weighing mechanism 24, and weighing operation is performed.

In this embodiment, the material transferring disc 3 is a disc, and the material cavity 301 is a square through hole.

Specifically, the square through-hole shaped material cavity 301 facilitates filling of scrap iron products.

In this embodiment, the guide cylinder 5 is a square cylinder with an opening at the lower end, and the cross-sectional area of the guide cylinder is equal to that of the inner cavity of the material cavity 301; the squeeze plate 4 is a square block.

Specifically, the first hydraulic cylinder 7 drives the extrusion disc 4 to move towards the material cavity 301 in the guide cylinder 5, so that the stability and the extrusion effect of extrusion are guaranteed, and square discus formed by extrusion is convenient to discharge and stack.

In this embodiment, the weighing mechanism 24 is a platform scale or a belt scale.

Specifically, different weighing mechanisms can be selected for weighing operation.

In another embodiment of the present application, the first driving mechanism includes a sleeve 10 fixedly connected to the rotary tray 3 and sleeved on the central supporting rod 9, a driving shaft 12 rotatably connected to a supporting plate vertically fixed to the top plate and parallel to the top plate, a first driving gear set 11 connecting the sleeve 10 and the driving shaft 12, a ratchet gear 13 mounted at a left end portion of the driving shaft 12, a first rack plate 14 meshed with the ratchet gear 13 and vertically arranged, and a fixing rod 15 vertically fixed to the first rack plate 14 and fixedly connected to the first piston rod 6 of the first hydraulic cylinder 7.

Specifically, through the first driving mechanism which is linked with the first piston rod 6 of the first hydraulic cylinder 7, the upward movement is continuously realized after the extrusion disc 4 returns to the guide cylinder 5 after extrusion is finished, the first piston rod 6 drives the first rack plate 14 to move upwards through the fixed rod 15, the first rack plate 14 drives the transmission shaft 12 to rotate through the ratchet gear 13, the transmission shaft 12 drives the sleeve 10 to rotate through the first transmission gear set 11, the sleeve 10 drives the material rotating disc 3 to rotate, and further the discus movement is realized; when the first piston rod 6 moves downwards, the first rack plate 14 cannot drive the transmission shaft 12 to rotate through the ratchet gear 13;

in addition, it should be noted that the transmission ratio of the first transmission gear set 11 and the specifications of the first rack plate 14 and the ratchet gear 13 are related to the number of the material cavities 301 provided on the rotating tray 3, and a person skilled in the art can increase or decrease the number of the material cavities 301 according to the need, and select an appropriate first transmission gear set 11, ratchet gear 13 and first rack plate 14, which are not described in detail herein.

In this embodiment, the ratchet gear 13 includes a gear ring 1301 meshed with the first rack plate 14 and having a pawl groove 1302 on the inner side, a rotating disc 1303 nested in the gear ring 1301 and rotationally connected with the gear ring, a pawl 1304 rotationally connected with the inner wall of the rotating disc 1303 through a hinge shaft 1305, a stopper 1306 abutting against the upper end of the pawl 1304 and fixedly connected with the rotating disc 1303, and a spring piece 1307 abutting against the lower end of the pawl 1304 and fixedly connected with the rotating disc 1303; the pawl 1304 is snapped into the pawl slot 1302.

Specifically, when the first piston rod 6 moves upwards, the first rack plate 14 drives the gear ring 1301 to rotate, the gear ring 1301 drives the rotating disc 1303 to rotate through the pawl 1304, the rotating disc 1303 drives the transmission shaft 12 to rotate, and at this time, the pawl 1304 is clamped in the pawl groove 1302 of the gear ring 1301; when the first piston rod 6 moves downward, the first rack plate 14 drives the gear ring 1301 to rotate, the gear ring 1301 cannot drive the pawl 1304 to rotate, and the pawl 1304 cannot drive the rotating disc 1303 to rotate.

In this embodiment, the first drive gear set 11 comprises a set of bevel gears that are perpendicular to each other and that mesh.

In this embodiment, a sliding rail 25 having a T-shaped cross section is slidingly connected to the rear side of the first rack plate 14, the upper end of the sliding rail 25 is fixedly connected to the top plate 8, and the lower end of the sliding rail is fixedly connected to the guide cylinder 5.

Specifically, by providing the slide rail 25 having a T-shaped cross section, the first rack plate 14 is kept linear when moving up and down, and further, is ensured to be in meshing contact with the ratchet gear 13.

In another embodiment of the application, the second driving mechanism comprises a set of rotating shafts 17 fixedly connected to a set of the discharge plates 16 and extending to the outside of the carrying table 2, a set of driven gears 18 mounted on the outside of the set of rotating shafts 17, a second rack plate 19 mounted between and in engagement with the set of driven gears 18, and a second hydraulic cylinder 21 connected to the second rack plate 19 and mounted on the top plate 8.

Specifically, the second hydraulic cylinder 21 is started, the second hydraulic cylinder 21 drives the second rack plate 19 to move downwards through the second piston rod 20, and the second rack plate 19 drives the driven gear 18 to rotate back to the front, so that the stripper plate 16 is opened gradually downwards back to the front, and the discus slowly slides downwards.

In this embodiment, the two side walls of the second rack plate 19 facing the driven gear 18 are provided with racks.

In another embodiment of the application, a pusher plate 22 is arranged above the rightmost material chamber 301, the pusher plate 22 being fixedly connected to the second rack plate 19 by means of a mounting bar 23.

Specifically, the discus compressed in the material cavity 301 is prevented from being blocked in the material cavity 301, and the pushing plate 22 moves downwards along with the second rack plate 19 to push the discus possibly blocked in the material cavity 301, so that the normal blanking is ensured.

Working principle:

dumping the waste iron products to be recovered into a material cavity 301 positioned at one station on the extrusion mechanism, starting a first driving mechanism, starting the first driving mechanism, driving a material rotating disc 3 to rotate by the first driving mechanism, driving the material cavity 301 filled with the waste iron to move below a material pressing mechanism by the material rotating disc 3, driving an extrusion disc 4 in a guide cylinder 5 to move downwards by a first piston rod 6 by a first hydraulic cylinder 7, compressing the waste iron products in the material cavity 301 into a cake shape, then returning the first hydraulic cylinder 7 to an initial position, driving the material rotating disc 3 to rotate one station again by the first driving mechanism, and performing material pressing operation again by the material pressing mechanism, wherein the dumping filling of the waste iron products can be performed on the material cavity positioned at the last station of the material pressing station in the material pressing process, and the processes are repeated to realize intermittent material pressing operation;

wherein, through being equipped with the first actuating mechanism that links with the first piston rod 6 of the first pneumatic cylinder 7, realize going back to the guide cylinder 5 after the extrusion disc 4 extrusion finishes and continuing to move upwards, the first piston rod 6 drives the first rack board 14 to move upwards through the dead lever 15, the first rack board 14 drives the transmission shaft 12 to rotate through the ratchet gear 13, the transmission shaft 12 drives the sleeve 10 to rotate through the first transmission gear set 11, the sleeve 10 drives the material turning disc 3 to rotate, and then realize the movement of the discus; when the first piston rod 6 moves downwards, the first rack plate 14 cannot drive the transmission shaft 12 to rotate through the ratchet gear 13,

when the material rotating disc 3 drives the discus in the material cavity 301 to move to the position of the material outlet 201, the second hydraulic cylinder 21 is started, the second hydraulic cylinder 21 drives the second rack plate 19 to move downwards through the second piston rod 20, the second rack plate 19 drives the driven gear 18 to rotate back to further enable the discharge plate 16 to open back gradually downwards, so that the discus slowly slides downwards, in the opening process, a group of discharge plates 16 rotate back to gradually expand the gap between the discharge plates 16, in the intermittent expansion process of the discharge plates 16, the discus slides downwards along the inner wall of the discharge plates 16, the discus slides onto the weighing mechanism 24 along the inner wall of the discharge plates 16, the discus is prevented from falling down fast to collide with the weighing mechanism 24 to cause the damage of the weighing mechanism 24, the weighing operation is performed,

in addition, in order to prevent discus compressed in the material cavity 301 from being blocked in the material cavity 301, the pushing plate 22 moves downwards along with the second rack plate 19 to push discus possibly blocked in the material cavity 301, so that normal discharging is ensured.

It will be evident to those skilled in the art that the application is not limited to the details of the foregoing illustrative embodiments, and that the present application may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the application being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (6)

1. Scrap iron purchase flattening and weighing integrated equipment is characterized by comprising:

the device comprises a base (1), a bearing table (2) fixedly arranged on the base (1), and a top plate (8) arranged above the bearing table (2) and fixedly connected with the base (1) through a central supporting rod (9);

the material transferring mechanism is arranged on the bearing table (2) and comprises a material transferring disc (3) rotatably arranged on the upper end surface of the bearing table (2) and rotatably connected with the central supporting rod (9) and a first driving mechanism for driving the material transferring disc (3) to rotate, and a plurality of material cavities (301) which are circumferentially distributed at equal intervals and penetrate through the material transferring disc (3) are formed in the material transferring disc (3);

the flattening mechanism is arranged above the leftmost material cavity (301) and comprises a guide cylinder (5) fixedly connected with the bearing table (2) and arranged above the leftmost material cavity (301), an extrusion disc (4) nested in the guide cylinder (5) and slidingly connected with the inner cavity of the guide cylinder (5), and a first hydraulic cylinder (7) connected with the extrusion disc (4) and fixedly connected with the top plate (8);

the discharging mechanism is symmetrically arranged with the flattening mechanism and comprises a discharging hole (201) which is arranged on the bearing table (2) and is opposite to the rightmost material cavity (301), a group of discharging plates (16) which are arranged in the discharging hole (201) and are in mirror symmetry, and a second driving mechanism which drives the group of discharging plates (16) to open back;

the weighing mechanism (24) is arranged on the base (1) and is opposite to the discharge hole (201);

the first driving mechanism comprises a sleeve (10) fixedly connected with the rotary tray (3) and sleeved on the central supporting rod (9), a transmission shaft (12) rotatably connected to a supporting plate vertically fixed with the top plate and parallel to the top plate, a first transmission gear set (11) connected with the sleeve (10) and the transmission shaft (12), a ratchet gear (13) arranged at the left end part of the transmission shaft (12), a first rack plate (14) meshed with the ratchet gear (13) and vertically arranged, and a fixed rod (15) vertically fixed with the first rack plate (14) and fixedly connected with a first piston rod (6) of the first hydraulic cylinder (7);

the second driving mechanism comprises a group of rotating shafts (17) fixedly connected with a group of discharging plates (16) and extending to the outer side of the bearing table (2), a group of driven gears (18) arranged on the outer side of the group of rotating shafts (17), a second rack plate (19) arranged between the group of driven gears (18) and meshed with the driven gears, and a second hydraulic cylinder (21) connected with the second rack plate (19) and arranged on the top plate (8);

a pushing plate (22) is arranged above the rightmost material cavity (301), and the pushing plate (22) is fixedly connected with the second rack plate (19) through a mounting rod (23);

the ratchet gear (13) comprises a gear ring (1301) meshed with the first rack plate (14) and provided with a pawl groove (1302) at the inner side, a rotating disc (1303) nested in the gear ring (1301) and rotationally connected with the gear ring, a pawl (1304) rotationally connected with the inner wall of the rotating disc (1303) through a hinge shaft (1305), a limiting block (1306) abutted with the upper end of the pawl (1304) and fixedly connected with the rotating disc (1303), and a spring piece (1307) abutted with the lower end of the pawl (1304) and fixedly connected with the rotating disc (1303); the pawl (1304) is clamped in the pawl groove (1302).

2. The scrap iron purchasing, flattening and weighing integrated device according to claim 1, wherein the material turning disc (3) is a disc, and the material cavity (301) is a square through hole.

3. The scrap iron purchasing, flattening and weighing integrated device according to claim 2, wherein the guide cylinder (5) is a square cylinder with an opening at the lower end and is equal to the cross-sectional area of the inner cavity of the material cavity (301); the extrusion disc (4) is a square block.

4. A scrap iron purchasing flattening and weighing integrated device according to claim 1, wherein said first drive gear set (11) comprises a set of mutually perpendicular and meshing bevel gears.

5. The scrap iron purchasing, flattening and weighing integrated device in accordance with claim 1, wherein the weighing mechanism (24) is a platform scale or a belt scale.

6. The scrap iron purchasing, flattening and weighing integrated device according to claim 1, wherein a sliding rail (25) with a T-shaped cross section is slidingly connected to the rear side of the first rack plate (14), the upper end of the sliding rail (25) is fixedly connected with the top plate (8), and the lower end of the sliding rail is fixedly connected with the guide cylinder (5).