CN114132664B - Decoration material transfer device based on dynamic and static combination principle - Google Patents

Abstract

The invention discloses a decoration material transfer device based on a dynamic and static combination principle, which comprises a transfer main body, a lever type coiling type feeding mechanism, a staggered occlusion type gravel collecting mechanism, an expansion type elastic deformation blanking mechanism, a cutting type rotational flow sand cleaning device and a local quality adjusting structure. The invention belongs to the technical field of decorative material transfer based on a dynamic and static combination principle, and particularly relates to a decorative material transfer device based on the dynamic and static combination principle; the staggered occlusion type sand collecting mechanism is creatively provided based on the pre-acting and one-dimensional and multidimensional principle, and when the bucket contacts a sand pile, the whole sand can be easily collected through the mutual matching of the impact type collecting structure and the staggered sand block reclamation structure; meanwhile, in order to further improve the practicability and the popularization, the invention creatively provides a lever type winding type feeding mechanism based on a lever principle, and sand in the bucket is loaded into the trolley through the conveying groove by utilizing the lever principle, so that the time and the labor are saved.

Description

Decoration material transfer device based on dynamic and static combination principle

Technical Field

The invention belongs to the technical field of decorative material transfer based on a dynamic and static combination principle, and particularly relates to a decorative material transfer device based on the dynamic and static combination principle.

Background

In the decoration construction, the use of sand is indispensable, but the sand is generally the placing of a big heap, then need to load the sand and transport to the assigned position, people all transport the sand with the hopper car usually, because of weather reason, especially winter, the sand heap is generally harder, people need hoe the sand into the hopper car with the spade bit by bit, then transport the sand to the construction position, people then need to lift the slope of hopper car's dipper with the hand and pour out the sand, it is harder, and the hopper car still remains easily after pouring out the sand, lead to the waste of sand, so people can let hopper car oneself slope pour out the sand, and the reuse broom clears up in the hopper after the sand is poured out, so operating efficiency is low, and easy damage equipment, there is the potential threat to constructor's safety.

Disclosure of Invention

Aiming at the situation and overcoming the defects of the prior art, the invention provides a decorative material transfer device based on a dynamic and static combination principle, aiming at solving the problems that due to weather, especially in winter, sand piles are generally hard, people need to hoe sand into a trolley by a shovel a little, time and labor are wasted, the invention creatively provides a staggered occlusion type sand gravel collecting mechanism based on the pre-action and one-dimensional and multi-dimensional principle, and when a bucket contacts the sand piles, the whole sand can be easily collected through the mutual matching of an impact type collecting structure and a staggered sand block reclamation structure; meanwhile, in order to further improve the practicability and the popularization, the invention creatively provides a lever type winding type feeding mechanism based on the lever principle, and sand in the bucket is loaded and transported into the trolley through the conveying groove by utilizing the lever principle, so that the time and the labor are saved; in order to facilitate the sand to be poured out of the hopper car, the invention creatively provides an expansion type elastic deformation blanking mechanism based on the dynamic characteristic and the composite material principle, and not only can the stable transportation of the transportation main body be realized, but also the inclination of the transportation main body during blanking can be realized through the change of the volume of the inner tube air bag, so that the sand can be conveniently put down; in order to better avoid the waste of sand, the invention creatively provides the cutting type rotational flow sand cleaning device based on the intermediary principle, and effectively solves the technical problem that the sand is easy to remain after being poured out.

The technical scheme adopted by the invention is as follows: the invention provides a decorative material transfer device based on a dynamic and static combination principle, which comprises a transfer main body, a lever-type coiling type feeding mechanism, a staggered occlusion type gravel collecting mechanism, an expansion type elastic deformation blanking mechanism, a cutting type rotational flow sand cleaning device and a local quality adjusting structure, wherein the lever-type coiling type feeding mechanism is arranged on the transfer main body, the staggered occlusion type gravel collecting mechanism is arranged on the lever-type coiling type feeding mechanism, the expansion type elastic deformation blanking mechanism is arranged on the transfer main body, the cutting type rotational flow sand cleaning device is arranged in the transfer main body, and the local quality adjusting structure is arranged in the transfer main body.

Further, the main part of transporting includes outer car hopper, interior car hopper, door, chassis, pushing hands, supporting leg, universal wheel and power, outer car hopper is located and is transported in the main part, interior car hopper is located in the outer car hopper, the door opens and shuts and locates on the outer car hopper, the lower extreme of outer car hopper is located on the chassis, the pushing hands is located on the outer car hopper, the lower extreme of pushing hands is located to the supporting leg, the lower extreme of supporting leg is located to the universal wheel, the lower extreme on chassis is located to the power.

Further, the lever-type winding-up feeding mechanism comprises a lever frame, a conveying groove, a scraper pan, a first rotating shaft, a limiting part, a first motor, a first wire coil and a rope, wherein the first rotating shaft is arranged on the outer car hopper, the lever frame is arranged on the first rotating shaft, the wire coil is arranged on the side wall of the outer car hopper, the first motor is arranged on the wire coil, one end of the rope is wound on the wire coil, the other end of the rope is arranged at the upper end of the lever frame, the conveying groove is arranged on the lever frame, the scraper pan is arranged at the lower end of the conveying groove in a penetrating mode, the limiting part is arranged on the outer car hopper, when broken sand enters the scraper pan, the first motor is started, the output end of the first motor rotates to drive one end of the rope to wind, and one end of the lever frame moves downwards towards the direction of the wire coil pan until the tilted sand falls into the inner car hopper.

Further, dislocation interlock formula grit is collected the mechanism and is included impacted style and collect structure and dislocation sand block reclamation structure, the impacted style is collected the structure and is located on the lever type feed mechanism of rolling up, dislocation sand block reclamation structure is located on the conveyer trough.

Further, the impact type collecting structure comprises a first spring, an expansion piece and a transverse vibrator, one end of the first spring is arranged on the lever frame, the other end of the first spring is arranged on the conveying groove, one end of the expansion piece is arranged on the lever frame, the other end of the expansion piece is arranged on the conveying groove, one end of the transverse vibrator is arranged on the lever frame, and the other end of the transverse vibrator is arranged on the conveying groove.

Further, the dislocation sand block reclamation structure comprises a motor II, a rotating shaft II, a gear I, a crushing roller I, a bearing I, a fixed shaft I, a bearing II, a crushing roller II, a fixed shaft II, a gear I, a gear II, a fixed shaft III, a gear III, a bearing III, a rotating shaft III, a crushing roller III and a gear IV, wherein the motor II is arranged on the inner side wall of the conveying groove, the rotating shaft II is arranged at the output end of the motor II, the gear is sleeved on the rotating shaft II, the crushing roller is sleeved on the rotating shaft II, the bearing I is arranged at one end of the crushing roller I, one end of the fixed shaft I is arranged on the bearing I, the other end of the bearing I is arranged on the other inner side wall of the conveying groove, the bearing is sleeved on the fixed shaft I, the crushing roller is sleeved on the crushing roller II, the fixed shaft II is arranged on the fixed shaft I, the second gear is rotatably arranged at one end of the second fixed shaft, the first gear block is arranged on one side of the first crushing roller in an annular array manner, the second gear block is arranged on one side of the second crushing roller in an annular array manner, the first gear block is rotatably connected with the second gear block in a meshing manner, the second gear block is rotatably connected with the second gear block in a meshing manner, the third fixed shaft is arranged on the inner side wall of the conveying groove, the third gear is rotatably arranged at one end of the third fixed shaft, the third bearing is arranged on the inner side wall of the conveying groove, one end of the third rotating shaft is arranged on the third bearing, the fourth gear is sleeved on the third rotating shaft, the third crushing roller is sleeved on the third rotating shaft, the first gear and the third gear are rotatably connected in a meshing manner, the third gear and the fourth gear are rotatably connected in a meshing manner, the transverse vibrator is started, the conveying groove and the bucket start reciprocating vibration left and right, the output end of the second motor drives the first gear and the first crushing roller to rotate, one rotation of crushing roller drives tooth piece one and rotates, and tooth piece one rotates and drives gear two and rotate, and gear two rotates and drives tooth piece two and rotate, and tooth piece two rotates and drives crushing roller two and rotate, and gear one rotates and drives gear three and rotates, and gear three rotates and drives gear four and rotates, and gear four rotates and drives axis of rotation three and rotates, and axis of rotation three rotates and drives crushing roller three and rotate, carries out broken collection to the harder condition of sand heap winter.

Furthermore, the expansion type elastic deformation blanking mechanism comprises a first air pump, a fourth bearing, a protective rubber sheet, an inner tube air bag, an elastic memory alloy block, a telescopic block, a sliding groove, a pulley, a fourth rotating shaft and a first air vent, wherein the first air pump is arranged in the chassis, the fourth bearing is arranged on the side wall of the chassis in a penetrating manner, the fourth bearing is arranged at the output end of the first air pump in a penetrating manner, the fourth rotating shaft is arranged on the fourth bearing in a penetrating manner, the first air vent is arranged on the fourth rotating shaft, the inner tube air bag is sleeved on the fourth rotating shaft, the telescopic block is arranged on the inner tube air bag in a sliding manner, the elastic memory alloy block is arranged on the telescopic block in a sliding manner, the sliding groove is arranged in the elastic memory alloy block, one end of the pulley is arranged in the sliding groove in a sliding manner, the other end of the pulley is arranged on the telescopic block, the protective rubber sheet is arranged on the elastic memory alloy block, and when sand is transported to a decoration place, and opening the vehicle door, exhausting air by the air pump, reducing the air bag of the inner tire, reducing the telescopic blocks and the elastic memory alloy blocks at equal intervals until the telescopic blocks are mutually attached, starting the air pump II, expanding the auxiliary air bag, extending the sleeve out of the telescopic cavity, and assisting in discharging sand.

Further, the cutting type rotational flow sand cleaning device comprises a second spring, a shielding cap, a windmill, a connecting shaft, a cleaning hairbrush, a second air vent and an air outlet, wherein one end of the second spring is arranged on the inner wall of the outer car hopper, the other end of the second spring is arranged on the outer wall of the inner car hopper, the second air vent is arranged on the chassis, the connecting shaft is rotatably arranged on the bottom wall of the inner car hopper, the shielding cap is arranged at one end of the connecting shaft, the windmill is arranged at the other end of the connecting shaft, the cleaning hairbrush is arranged on the shielding cap, the air outlet is arranged on the shielding cap, when part of sand is left, air flow drives the windmill to rotate through the second air vent, the windmill rotates to drive the connecting shaft to rotate, the connecting shaft rotates to drive the shielding cap to rotate, the shielding cap rotates to drive the cleaning hairbrush to rotate, and the residual sand in the inner car hopper is cleaned, so that waste is avoided.

Further, local quality adjustment structure includes air pump two, supplementary gasbag, sleeve pipe and flexible chamber, flexible chamber is located in the supporting leg, air pump two is located on the supporting leg inner wall, supplementary gasbag link up the output of locating air pump two, flexible intracavity is located in the sleeve pipe slides, the sheathed tube lower extreme is located to the universal wheel, supplementary unloading.

Further, a motor electricity power, two electricity power of air pump, horizontal electromagnetic shaker electricity power, two electricity power of motor, an air pump electricity power.

The invention with the structure has the following beneficial effects: the invention provides a decoration material transfer device based on a dynamic and static combination principle, which realizes the following beneficial effects:

(1) in order to solve the problem that people need to hoe sand into a trolley little by using a shovel to waste time and labor due to weather reasons, particularly in winter, the invention creatively provides a staggered occlusion type gravel collecting mechanism based on the principle of pre-action and one-dimensional to multi-dimensional change, and when a bucket contacts the sand pile, the whole sand can be easily collected through the mutual matching of an impact type collecting structure and a staggered sand block reclamation structure.

(2) Meanwhile, in order to further improve the practicability and the popularization, the invention creatively provides a lever type winding type feeding mechanism based on a lever principle, and sand in the bucket is loaded into the trolley through the conveying groove by utilizing the lever principle, so that the time and the labor are saved.

(3) In order to facilitate sand pouring out of the hopper car, the invention creatively provides an expansion type elastic deformation blanking mechanism based on the dynamic characteristic and the composite material principle, and not only realizes stable transportation of a transportation main body, but also realizes inclination during blanking of the transportation main body and facilitates sand dropping through the change of the volume of an inner tube air bag.

(4) In order to better avoid the waste of sand, the invention creatively provides the cutting type rotational flow sand cleaning device based on the intermediary principle, and effectively solves the technical problem that the sand is easy to remain after being poured out.

(5) The auxiliary air bag is arranged, so that the pushing hands can be conveniently pulled out in a trembling mode, the labor is saved, and the labor intensity is reduced.

(6) The elastic memory alloy block can deform according to the change of the volume of the inner tube air bag, so that the inner tube air bag is close to the shape of a tire to be transported, and when the inner tube air bag contracts, the elastic memory alloy block recovers to be in an arc state, so that a transport wheel is reduced, and unloading is convenient.

(7) Set up the spring between outer car hopper and the interior car hopper, possessed on the one hand and transported main part shock-absorbing function, on the other hand has possessed the function that prevents to turn on one's side in transporting the main part transportation.

Drawings

FIG. 1 is a front sectional view of a decorative material transfer device based on a dynamic and static combination principle, which is provided by the invention;

FIG. 2 is a loading state diagram of a decorative material transfer device based on a dynamic and static combination principle, which is provided by the invention;

FIG. 3 is a cross-sectional view of the movement state of the decorative material transfer device based on the dynamic and static combination principle according to the present invention;

FIG. 4 is a diagram of a state of the decoration material transfer device based on the dynamic and static combination principle;

FIG. 5 is a right side view of a decorative material transfer device based on dynamic and static combination principle according to the present invention;

FIG. 6 is a right sectional view of a decorative material transfer device based on dynamic and static combination principle according to the present invention;

FIG. 7 is a schematic view of a staggered sand reclamation structure;

FIG. 8 is a schematic view of an expansion state of an expansion type elastic deformation blanking mechanism;

fig. 9 is a partial enlarged view of a portion a in fig. 8;

FIG. 10 is an enlarged view of a portion B of FIG. 1;

fig. 11 is a partially enlarged view of a portion C in fig. 3.

Wherein, 1, a transferring main body, 2, a lever type coiling type feeding mechanism, 3, a staggered occlusion type gravel collecting mechanism, 4, an expansion type elastic deformation blanking mechanism, 5, a cutting type rotational flow sand cleaning device, 6, a local quality adjusting structure, 7, an outer car hopper, 8, an inner car hopper, 9, a car door, 10, a chassis, 11, a pushing hand, 12, a supporting leg, 13, a universal wheel, 14, a power supply, 15, a lever frame, 16, a conveying groove, 17, a bucket, 18, a first rotating shaft, 19, a limiting part, 20, a first motor, 21, a wire coil, 22, a rope, 23, an impact type collecting structure, 24, a staggered sand block reclaiming structure, 25, a first spring, 26, a telescopic part, 27, a transverse vibrator, 28, a second motor, 29, a second rotating shaft, 30, a first gear, 31, a first crushing roller, 32, a first bearing, 33, a first fixed shaft, 34, a second bearing, 35, a second crushing roller, 36. the device comprises a second fixed shaft 37, a second gear 38, a first tooth block 39, a second tooth block 40, a third fixed shaft 41, a third gear 42, a third bearing 43, a third rotating shaft 44, a third crushing roller 45, a fourth gear 46, a first air pump 47, a fourth bearing 48, a protective rubber sheet 49, an inner air bag 50, an elastic memory alloy block 51, a telescopic block 52, a chute 53, a pulley 54, a fourth rotating shaft 55, a first vent hole 56, a second spring 57, a shielding cap 58, a windmill 59, a connecting shaft 60, a cleaning brush 61, a second vent hole 62, an air outlet hole 63, a second air pump 64, an auxiliary air bag 65, a sleeve 66 and a telescopic cavity.

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "top", "bottom", "inner", "outer", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience in describing the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus should not be construed as limiting the present invention.

As shown in fig. 1, 2 and 3, the invention provides a decorative material transfer device based on a dynamic and static combination principle, which comprises a transfer main body 1, a lever type coiling type feeding mechanism 2, a staggered occlusion type gravel collecting mechanism 3, an expansion type elastic deformation blanking mechanism 4, a cutting type rotational flow sand cleaning device 5 and a local quality adjusting structure 6, wherein the lever type coiling type feeding mechanism 2 is arranged on the transfer main body 1, the staggered occlusion type gravel collecting mechanism 3 is arranged on the lever type coiling type feeding mechanism 2, the expansion type elastic deformation blanking mechanism 4 is arranged on the transfer main body 1, the cutting type rotational flow sand cleaning device 5 is arranged in the transfer main body 1, and the local quality adjusting structure 6 is arranged in the transfer main body 1.

As shown in fig. 1 and 3, the transfer main body 1 includes an outer car hopper 7, an inner car hopper 8, a car door 9, a chassis 10, a push handle 11, a support leg 12, a universal wheel 13 and a power supply 14, the outer car hopper 7 is arranged on the transfer main body 1, the inner car hopper 8 is arranged in the outer car hopper 7, the car door 9 is opened and closed and arranged on the outer car hopper 7, the chassis 10 is arranged at the lower end of the outer car hopper 7, the push handle 11 is arranged on the outer car hopper 7, the support leg 12 is arranged at the lower end of the push handle 11, the universal wheel 13 is arranged at the lower end of the support leg 12, and the power supply 14 is arranged at the lower end of the chassis 10.

As shown in fig. 1 and 2, the lever-type winding-up feeding mechanism 2 includes a lever frame 15, a conveying trough 16, a bucket 17, a first rotating shaft 18, a limiting member 19, a first motor 20, a wire coil 21 and a rope 22, wherein the first rotating shaft 18 is disposed on the outer hopper 7, the lever frame 15 is disposed on the first rotating shaft 18, the wire coil 21 is disposed on a side wall of the outer hopper 7, the first motor 20 is disposed on the wire coil 21, one end of the rope 22 is wound on the wire coil 21, the other end of the rope 22 is disposed at the upper end of the lever frame 15, the conveying trough 16 is disposed on the lever frame 15, the bucket 17 penetrates through the lower end of the conveying trough 16, and the limiting member 19 is disposed on the outer hopper 7.

As shown in fig. 1 and 5, the malposed meshed gravel collecting mechanism 3 includes an impact collecting structure 23 and a malposed sand reclamation structure 24, the impact collecting structure 23 is disposed on the lever type reclamation feeding mechanism 2, and the malposed sand reclamation structure 24 is disposed on the conveying trough 16.

As shown in fig. 1 and 10, the impact type collecting structure 23 includes a first spring 25, a telescopic member 26 and a transverse vibrator 27, one end of the first spring 25 is disposed on the lever frame 15, the other end of the first spring 25 is disposed on the conveying trough 16, one end of the telescopic member 26 is disposed on the lever frame 15, the other end of the telescopic member 26 is disposed on the conveying trough 16, one end of the transverse vibrator 27 is disposed on the lever frame 15, and the other end of the transverse vibrator 27 is disposed on the conveying trough 16.

As shown in fig. 1 and 7, the dislocated sand reclamation structure 24 includes a second motor 28, a second rotating shaft 29, a first gear 30, a first crushing roller 31, a first bearing 32, a first fixed shaft 33, a second bearing 34, a second crushing roller 35, a second fixed shaft 36, a second gear 37, a first toothed block 38, a second toothed block 39, a third fixed shaft 40, a third gear 41, a third bearing 42, a third rotating shaft 43, a third crushing roller 44 and a fourth gear 45, wherein the second motor 28 is disposed on the inner side wall of the conveying trough 16, the second rotating shaft 29 is disposed at the output end of the second motor 28, the first gear 30 is sleeved on the second rotating shaft 29, the first crushing roller 31 is sleeved on the second rotating shaft 29, the first bearing 32 is disposed at one end of the first crushing roller 31, one end of the first fixed shaft 33 is disposed on the first bearing 32, the other end of the first bearing 32 is disposed on the other inner side wall of the conveying trough 16, the second bearing 34 is sleeved on the first fixed shaft 33, the second crushing roller 35 is sleeved on the second crushing roller 35, the second fixed shaft 36 is arranged on the first fixed shaft 33, the second gear 37 is rotatably arranged at one end of the second fixed shaft 36, a first gear block 38 annular array is arranged on one side of the first crushing roller 31, a second gear block 39 annular array is arranged on one side of the second crushing roller 35, the first gear block 38 and the second gear block 37 are connected in a meshing rotation mode, the second gear block 37 and the second gear block 39 are connected in a meshing rotation mode, a third fixed shaft 40 is arranged on the inner side wall of the conveying groove 16, a third gear 41 is rotatably arranged at one end of the third fixed shaft 40, a third bearing 42 is arranged on the inner side wall of the conveying groove 16, one end of a third rotating shaft 43 is arranged on a third bearing 42, a fourth gear 45 is sleeved on the third rotating shaft 43, the third crushing roller 44 is sleeved on the third rotating shaft 43, the first gear 30 and the third gear 41 are connected in a meshing rotation mode, and the third gear 41 and the fourth gear 45 are connected in a meshing rotation mode.

As shown in fig. 6, 8 and 9, the expansion type elastic deformation blanking mechanism 4 comprises a first air pump 46, a fourth bearing 47, a protective rubber sheet 48 and an inner tube air bag 49, the air pump I46 is arranged in the chassis 10, the bearing IV 47 is arranged on the side wall of the chassis 10 in a penetrating mode, the bearing IV 47 is arranged at the output end of the air pump I46 in a penetrating mode, the rotating shaft IV 54 is arranged on the bearing IV 47 in a penetrating mode, the vent I55 is arranged on the rotating shaft IV 54, the inner tube air bag 49 is arranged on the rotating shaft IV 54 in a sleeved mode, the expansion block 51 is arranged on the inner tube air bag 49, the elastic memory alloy block 50 is arranged on the expansion block 51 in a sliding mode, the sliding groove 52 is arranged in the elastic memory alloy block 50, one end of the pulley 53 is arranged in the sliding groove 52 in a sliding mode, the other end of the pulley 53 is arranged on the expansion block 51, and the protective rubber sheet 48 is arranged on the elastic memory alloy block 50.

As shown in fig. 1, 3 and 11, the cutting type rotational flow sand cleaning device 5 includes a second spring 56, a shielding cap 57, a windmill 58, a connecting shaft 59, a cleaning brush 60, a second vent hole 61 and an air outlet hole 62, wherein one end of the second spring 56 is arranged on the inner wall of the outer hopper 7, the other end of the second spring 56 is arranged on the outer wall of the inner hopper 8, the second vent hole 61 is arranged on the chassis 10, the connecting shaft 59 is rotatably arranged on the bottom wall of the inner hopper 8, the shielding cap 57 is arranged at one end of the connecting shaft 59, the windmill 58 is arranged at the other end of the connecting shaft 59, the cleaning brush 60 is arranged on the shielding cap 57, and the air outlet hole 62 is arranged on the shielding cap 57.

As shown in figure 1, the local mass adjusting structure 6 comprises a second air pump 63, an auxiliary air bag 64, a sleeve 65 and a telescopic cavity 66, wherein the telescopic cavity 66 is arranged in the supporting leg 12, the second air pump 63 is arranged on the inner wall of the supporting leg 12, the auxiliary air bag 64 is arranged at the output end of the second air pump 63 in a penetrating manner, the sleeve 65 is arranged in the telescopic cavity 66 in a sliding manner, and the universal wheel 13 is arranged at the lower end of the sleeve 65.

As shown in fig. 1, 6, 7 and 10, the first motor 20 is electrically connected with the power supply 14, the second air pump 63 is electrically connected with the power supply 14, the transverse vibrator 27 is electrically connected with the power supply 14, the second motor 28 is electrically connected with the power supply 14, and the first air pump 46 is electrically connected with the power supply 14.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

The present invention and its embodiments have been described above, and the description is not intended to be limiting, and the drawings show only one embodiment of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should appreciate that they can readily use the disclosed conception and specific embodiments as a basis for designing or modifying other structures for carrying out the same purposes of the present invention without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (2)

1. The utility model provides a decoration material transfer device based on sound combines principle which characterized in that: the sand-removing device comprises a transferring main body (1), a lever-type coiling type feeding mechanism (2), a staggered occlusion type sand collecting mechanism (3), an expansion type elastic deformation blanking mechanism (4), a cutting type rotational flow sand removing device (5) and a local quality adjusting structure (6), wherein the lever-type coiling type feeding mechanism (2) is arranged on the transferring main body (1), the staggered occlusion type sand collecting mechanism (3) is arranged on the lever-type coiling type feeding mechanism (2), the expansion type elastic deformation blanking mechanism (4) is arranged on the transferring main body (1), the cutting type rotational flow sand removing device (5) is arranged in the transferring main body (1), and the local quality adjusting structure (6) is arranged in the transferring main body (1); the transfer main body (1) comprises an outer car hopper (7), an inner car hopper (8), a car door (9), a chassis (10), a push handle (11), a supporting leg (12), a universal wheel (13) and a power supply (14), wherein the outer car hopper (7) is arranged on the transfer main body (1), the inner car hopper (8) is arranged in the outer car hopper (7), the car door (9) is opened and closed on the outer car hopper (7), the chassis (10) is arranged at the lower end of the outer car hopper (7), the push handle (11) is arranged on the outer car hopper (7), the supporting leg (12) is arranged at the lower end of the push handle (11), the universal wheel (13) is arranged at the lower end of the supporting leg (12), and the power supply (14) is arranged at the lower end of the chassis (10); the lever type winding type feeding mechanism (2) comprises a lever frame (15), a conveying groove (16), a bucket (17), a first rotating shaft (18), a limiting piece (19), a first motor (20), a wire coil (21) and a rope (22), wherein the first rotating shaft (18) is arranged on the outer car hopper (7), the lever frame (15) is arranged on the first rotating shaft (18), the wire coil (21) is arranged on the side wall of the outer car hopper (7), the first motor (20) is arranged on the wire coil (21), one end of the rope (22) is wound on the wire coil (21), the other end of the rope (22) is arranged at the upper end of the lever frame (15), the conveying groove (16) is arranged on the lever frame (15), the bucket (17) is arranged at the lower end of the conveying groove (16) in a penetrating manner, and the limiting piece (19) is arranged on the outer car hopper (7); the staggered occlusion type gravel collecting mechanism (3) comprises an impact type collecting structure (23) and a staggered sand block reclamation structure (24), the impact type collecting structure (23) is arranged on the lever type coiling feeding mechanism (2), and the staggered sand block reclamation structure (24) is arranged on the conveying trough (16); the impact type collecting structure (23) comprises a first spring (25), an expansion piece (26) and a transverse vibrator (27), one end of the first spring (25) is arranged on the lever frame (15), the other end of the first spring (25) is arranged on the conveying groove (16), one end of the expansion piece (26) is arranged on the lever frame (15), the other end of the expansion piece (26) is arranged on the conveying groove (16), one end of the transverse vibrator (27) is arranged on the lever frame (15), and the other end of the transverse vibrator (27) is arranged on the conveying groove (16); the dislocation sand reclamation structure (24) comprises a second motor (28), a second rotating shaft (29), a first gear (30), a first crushing roller (31), a first bearing (32), a first fixed shaft (33), a second bearing (34), a second crushing roller (35), a second fixed shaft (36), a second gear (37), a first toothed block (38), a second toothed block (39), a third fixed shaft (40), a third gear (41), a third bearing (42), a third rotating shaft (43), a third crushing roller (44) and a fourth gear (45), wherein the second motor (28) is arranged on the inner side wall of the conveying trough (16), the second rotating shaft (29) is arranged at the output end of the second motor (28), the first gear (30) is sleeved on the second rotating shaft (29), the first crushing roller (31) is sleeved on the second rotating shaft (29), the first bearing (32) is arranged at one end of the first crushing roller (31), one end of the first fixed shaft (33) is arranged on the first bearing (32), the other end of the first bearing (32) is arranged on the other inner side wall of the conveying groove (16), the second bearing (34) is sleeved on the first fixed shaft (33), the second crushing roller (35) is sleeved on the second crushing roller (35), the second fixed shaft (36) is arranged on the first fixed shaft (33), the second gear (37) is rotatably arranged at one end of the second fixed shaft (36), the first gear block (38) is annularly arrayed at one side of the first crushing roller (31), the second gear block (39) is annularly arrayed at one side of the second crushing roller (35), the first gear block (38) is connected with the second gear block (37) in a meshing rotation mode, the second gear block (37) is connected with the second gear block (39) in a meshing rotation mode, the third fixed shaft (40) is arranged on the inner side wall of the conveying groove (16), and the third gear (41) is rotatably arranged at one end of the third fixed shaft (40), the third bearing (42) is arranged on the inner side wall of the conveying groove (16), one end of the third rotating shaft (43) is arranged on the third bearing (42), the fourth gear (45) is sleeved on the third rotating shaft (43), the third crushing roller (44) is sleeved on the third rotating shaft (43), the first gear (30) is in meshing rotation connection with the third gear (41), and the third gear (41) is in meshing rotation connection with the fourth gear (45); the expansion type elastic deformation blanking mechanism (4) comprises a first air pump (46), a fourth bearing (47), a protective rubber sheet (48), an inner tube air bag (49), an elastic memory alloy block (50), a telescopic block (51), a sliding chute (52), a pulley (53), a fourth rotating shaft (54) and a first vent hole (55), wherein the first air pump (46) is arranged in the chassis (10), the fourth bearing (47) is arranged on the side wall of the chassis (10) in a penetrating manner, the fourth bearing (47) is arranged at the output end of the first air pump (46) in a penetrating manner, the fourth rotating shaft (54) is arranged on the fourth bearing (47) in a penetrating manner, the first vent hole (55) is arranged on the fourth rotating shaft (54), the inner tube air bag (49) is arranged on the fourth rotating shaft (54) in a sleeved manner, the telescopic block (51) is arranged on the inner tube air bag (49), and the elastic memory alloy block (50) is arranged on the telescopic block (51) in a sliding manner, the sliding groove (52) is arranged in the elastic memory alloy block (50), one end of the pulley (53) is arranged in the sliding groove (52) in a sliding mode, the other end of the pulley (53) is arranged on the telescopic block (51), and the protective rubber sheet (48) is arranged on the elastic memory alloy block (50); the cutting type rotational flow sand cleaning device (5) comprises a second spring (56), a shielding cap (57), a windmill (58), a connecting shaft (59), a cleaning brush (60), a second air vent (61) and an air outlet hole (62), wherein one end of the second spring (56) is arranged on the inner wall of the outer hopper (7), the other end of the second spring (56) is arranged on the outer wall of the inner hopper (8), the second air vent (61) is arranged on the chassis (10), the connecting shaft (59) is rotatably arranged on the bottom wall of the inner hopper (8), the shielding cap (57) is arranged at one end of the connecting shaft (59), the windmill (58) is arranged at the other end of the connecting shaft (59), the cleaning brush (60) is arranged on the shielding cap (57), and the air outlet hole (62) is arranged on the shielding cap (57); local mass adjustment structure (6) are including air pump two (63), supplementary gasbag (64), sleeve pipe (65) and flexible chamber (66), flexible chamber (66) are located in supporting leg (12), air pump two (63) are located on supporting leg (12) inner wall, supplementary gasbag (64) link up the output of locating air pump two (63), sleeve pipe (65) slide and locate in flexible chamber (66), the lower extreme of sleeve pipe (65) is located in universal wheel (13).

2. The decorative material transfer device based on dynamic and static combination principle of claim 1, wherein: the utility model provides a motor one (20) electric connection power (14), air pump two (63) electric connection power (14), transverse vibrator (27) electric connection power (14), motor two (28) electric connection power (14), air pump one (46) electric connection power (14).

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