CN214648481U - Material transfer device for civil engineering - Google Patents

Abstract

The utility model discloses a material transfer device for civil engineering, which comprises a base, a support column, a movable damping component, a material box, an in-out lifting component, a buffering component and a clamping and fixing component, wherein the movable damping component is connected with the lower end of the connecting base; the movable shock absorption assembly comprises a buffer plate, a T-shaped column and a universal wheel. The utility model belongs to the technical field of the material is transported, specifically provide a simple structure, can satisfy high altitude construction, efficiency and flexibility ratio are higher, reduce workman's intensity of labour, and the material is transported efficiently, has shockproof protect function in the transportation again, less because the transportation causes the material to damage material transfer device for civil engineering.

Description

Material transfer device for civil engineering

Technical Field

The utility model belongs to the technical field of the material is transported, specifically indicate a material transfer device for civil engineering.

Background

Along with the rapid development of science and technology, the transportation technique of material is also becoming mature day by day, need transport regions such as operation place after material production is accomplished, and the material is transported the technique and is transported from initial manual work, develops the supplementary manual work of the transportation instrument of selecting at the back and transports the material.

Among the prior art, transfer device often mechanical structure is complicated, and efficiency and flexibility ratio are lower, and intensity of labour is big, and the material is transported inefficiency, often can lead to the material to damage in the transportation.

SUMMERY OF THE UTILITY MODEL

To the above situation, for overcoming prior art's defect, the utility model provides a simple structure, can satisfy high altitude construction, efficiency and flexibility ratio are higher, reduce workman's intensity of labour, and the material is transported efficiently, has shockproof protect function in the transportation again, less because the transportation causes the material to damage material transfer device for civil engineering.

The utility model adopts the following technical scheme: the utility model relates to a material transfer device for civil engineering, including base, support column, removal damper assembly, material case, business turn over and carry the lifting assembly, cushion the subassembly and centre gripping fixed subassembly, the removal damper assembly is connected and is located the lower extreme that links the base, support column and material case are all connected and are located the upper end of base, the one end connection of business turn over and carry the lifting assembly is located the upper end of support column, centre gripping fixed subassembly and cushion the subassembly and connect gradually and locate the inside of material case from top to bottom; the movable shock absorption assembly comprises a buffer plate, a T-shaped column and a universal wheel, a first limiting hole, a second limiting hole and a third limiting hole are sequentially arranged at the bottom of the base from bottom to top, the first limiting hole, the second limiting hole and the third limiting hole are communicated, two ends of the third limiting hole are provided with buffer connecting columns, the two ends of the buffer plate are sleeved outside the two buffer connecting columns, the outer sides of the buffer connecting columns are sleeved with first buffer springs, the first buffer spring is connected between the buffer plate and the inner top of the third limiting hole, the upper end of the T-shaped column is arranged in the second limiting hole, the lower end of the T-shaped column is arranged below the base in a way of penetrating through the first limiting hole, the outer side of the T-shaped column is sleeved with a second buffer spring, the second buffer spring is connected and arranged inside the second limiting hole, and the universal wheel is connected and arranged at the lower end of the T-shaped column; the in-out lifting assembly comprises a lifting support box, a rotating screw rod, a lifting sliding plate, a lifting support plate and a lifting rotating shaft, the lifting support box is connected to the upper end of the support column, the rotating screw rod is horizontally connected to the inside of the lifting support box, the upper end of the lifting sliding plate is sleeved on the outer side of the rotating screw rod, the lower end of the lifting sliding plate penetrates through the lifting support box and is arranged below the lifting support box, the lifting support plate is connected to the lower end of the lifting sliding plate, the lifting support plate is arranged in an n-shaped mode, the lifting rotating shaft is connected between two side plates of the lifting support plate, a winding shaft is sleeved on the outer side of the lifting rotating shaft and is arranged in an H-shaped mode, a pulling wire is sleeved on the outer side of the winding shaft, and a pulling hook is connected to the lower end of the pulling wire.

Further, the buffering subassembly is including buffering connecting axle and lift drive case, the interior bottom of locating the material case is connected to the buffering connecting axle, the outside at buffering connecting axle both ends is all overlapped and is equipped with third buffer spring, two third buffer spring's the other end is all connected and is equipped with the buffering sliding block, the outside of buffering connecting axle is located to the bottom of two buffering sliding blocks all overlaps, the double-phase of material case all is equipped with spout from top to bottom on the lateral wall, the inside of spout about the both ends of lift drive case are slided respectively and are located, the outer bottom of lift drive case is equipped with the connecting block, all articulate between two buffering sliding blocks and the connecting block and be equipped with the connecting plate.

Further, the fixed subassembly of centre gripping includes centre gripping driving motor, motor backup pad, driving gear, two-way lead screw, driven gear and grip block, centre gripping driving motor and motor backup pad are all connected and are located the interior bottom of lift drive case, one side of motor backup pad is located to centre gripping driving motor's output shaft, driving gear cover is located on centre gripping driving motor's the output shaft, the inside of lift drive case is located to two-way lead screw horizontal connection, the middle part in the two-way lead screw outside is located to the driven gear cover, driven gear is connected with driving gear engagement, the outside of two-way lead screw is located to the bottom cover of grip block, the top of lift drive case is located to the upper end link up lift drive case of grip block.

Furthermore, the upper end of the lifting driving box is provided with a clamping sliding groove, the clamping plates are slidably arranged in the clamping sliding groove, and the two groups of clamping plates are symmetrically arranged in the material box relative to the driven gear.

Furthermore, one side of the lifting support box is connected with a lifting moving motor box, a lifting moving motor is arranged in the lifting moving motor box, and an output shaft of the lifting moving motor is connected to one end of the rotating screw rod.

Furthermore, a lifting motor box is arranged on one side of the lifting support plate, a lifting motor is arranged in the lifting motor box, and an output shaft of the lifting motor is connected to one end of the lifting rotating shaft.

Furthermore, the lower end of the lifting support box is provided with a lifting moving chute, and the lifting sliding plate is slidably arranged in the lifting moving chute.

Furthermore, the aperture of the first limiting hole, the aperture of the second limiting hole and the aperture of the third limiting hole are sequentially increased.

Furthermore, a pushing handle is connected and arranged on one side, far away from the material box, of the supporting column, and anti-skid grains are arranged on the pushing handle.

Adopt above-mentioned structure the utility model discloses the beneficial effect who gains as follows: this scheme is material transfer device for civil engineering, through first buffer spring and second buffer spring's use, the device cushions the protection of taking precautions against earthquakes to the device when walking on rugged road, through third buffer spring's use, cushion the protection to the material when the material is placed, through the use of grip block, the grip block is with material centre gripping post, prevent that the material from removing at the in-process that transports, carry out spacing protection to the material, carry out the use of carrying the subassembly through the business turn over, the workman for high altitude construction provides convenience.

Drawings

FIG. 1 is a schematic view of the overall structure of a material transfer device for civil engineering of the present invention;

FIG. 2 is a schematic view of the connection of the bobbin in the material transfer device for civil engineering of the present invention;

FIG. 3 is an enlarged view of a portion A of FIG. 1;

fig. 4 is a partially enlarged schematic view of a portion B in fig. 1.

Wherein, 1, a base, 2, a support column, 3, a movable damping component, 4, a material box, 5, an in-out lifting component, 6, a buffer component, 7, a clamping fixing component, 8, a buffer plate, 9, a T-shaped column, 10, a universal wheel, 11, a first limit hole, 12, a second limit hole, 13, a third limit hole, 14, a buffer connecting column, 15, a first buffer spring, 16, a second buffer spring, 17, a lifting support box, 18, a rotating screw rod, 19, a lifting sliding plate, 20, a lifting support plate, 21, a lifting rotating shaft, 22, a winding shaft, 23, a stay wire, 24, a drag hook, 25, a buffer connecting shaft, 26, a lifting driving box, 27, a third buffer spring, 28, a buffer sliding block, 29, a connecting block, 30, a connecting plate, 31, a clamping driving motor, 32, a motor support plate, 33, a driving gear, 34, a bidirectional screw rod, 35, a driven gear, 36. a clamping plate 37, a lifting moving motor box 38, a lifting moving motor 39, a lifting motor box 40, a lifting motor 41 and a push handle.

The accompanying drawings 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 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 some embodiments of the present invention, not all embodiments; based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

As shown in fig. 1-4, the utility model relates to a material transfer device for civil engineering, including base 1, support column 2, removal damper assembly 3, material case 4, business turn over lifting assembly 5, buffer assembly 6 and centre gripping fixed subassembly 7, removal damper assembly 3 connects and locates the lower extreme that links base 1, support column 2 and material case 4 are all connected and are located the upper end of base 1, the one end connection of business turn over lifting assembly 5 locates the upper end of support column 2, centre gripping fixed subassembly 7 and buffer assembly 6 connect gradually from the top down and locate the inside of material case 4; the movable damping component 3 comprises a buffer plate 8, a T-shaped column 9 and a universal wheel 10, wherein a first limiting hole 11, a second limiting hole 12 and a third limiting hole 13 are sequentially arranged at the bottom of the base 1 from bottom to top, the first limiting hole 11, the second limiting hole 12 and the third limiting hole 13 are all communicated, buffer connecting columns 14 are arranged at the two ends of the third limiting hole 13, the two ends of the buffer plate 8 are sleeved outside the two buffer connecting columns 14, a first buffer spring 15 is sleeved outside the buffer connecting columns 14, the first buffer spring 15 is connected between the inner tops of the buffer plate 8 and the third limiting hole 13, the upper end of the T-shaped column 9 is arranged inside the second limiting hole 12, the lower end of the T-shaped column 9 penetrates through the first limiting hole 11 and is arranged below the base 1, a second buffer spring 16 is sleeved outside the T-shaped column 9, the second buffer spring 16 is connected inside the second limiting hole 12, the universal wheel 10 is connected with the lower end of the T-shaped column 9; the in-out pulling assembly 5 comprises a pulling support box 17, a rotating screw rod 18, a pulling sliding plate 19, a pulling support plate 20 and a pulling rotating shaft 21, the lifting support box 17 is connected with the upper end of the support column 2, the rotary screw rod 18 is horizontally connected with the inner part of the lifting support box 17, the upper end of the lifting sliding plate 19 is sleeved outside the rotating screw rod 18, the lower end of the lifting sliding plate 19 penetrates through the lifting support box 17 and is arranged below the lifting support box 17, the pulling support plate 20 is connected with the lower end of the pulling sliding plate 19, the pulling support plate 20 is arranged in an n shape, the pulling rotary shaft 21 is connected between the two side plates of the pulling support plate 20, the outer side of the pulling rotary shaft 21 is sleeved with a winding shaft 22, the winding shaft 22 is arranged in an H shape, a pull wire 23 is sleeved on the outer side of the winding shaft 22, and a pull hook 24 is connected to the lower end of the pull wire 23.

Wherein, buffering subassembly 6 is including buffering connecting axle 25 and lift drive case 26, buffering connecting axle 25 is connected and is located the interior bottom of material case 4, the outside at buffering connecting axle 25 both ends is all overlapped and is equipped with third buffer spring 27, two third buffer spring 27's the other end is all connected and is equipped with buffering sliding block 28, the outside of buffering connecting axle 25 is all located to the bottom of two buffering sliding blocks 28 cover, material case 4 is double-phase all to be equipped with upper and lower spout on the lateral wall, the inside of spout about the both ends of lift drive case 26 slide respectively locate, lift drive case 26's outer bottom is equipped with connecting block 29, all articulate between two buffering sliding block 28 and the connecting block 29 and be equipped with connecting plate 30.

The fixed subassembly 7 of centre gripping includes centre gripping driving motor 31, motor support plate 32, driving gear 33, two-way lead screw 34, driven gear 35 and grip block 36, centre gripping driving motor 31 and motor support plate 32 are all connected and are located the interior bottom of lift drive case 26, one side of motor support plate 32 is located to centre gripping driving motor 31's output shaft, on the output shaft of centre gripping driving motor 31 was located to driving gear 33 cover, the inside of lift drive case 26 is located to two-way lead screw 34 horizontal connection, the middle part in the two-way lead screw 34 outside is located to driven gear 35 cover, driven gear 35 is connected with driving gear 33 meshing, the outside of two-way lead screw 34 is located to the bottom cover of grip block 36, the top of lift drive case 26 is located to the upper end through lift drive case 26 of grip block 36.

The upper end of the lifting driving box 26 is provided with a clamping sliding chute, the clamping plates 36 are slidably arranged in the clamping sliding chute, and two groups of the clamping plates 36 are symmetrically arranged in the material box 4 around the driven gear 35; a lifting moving motor box 37 is connected to one side of the lifting support box 17, a lifting moving motor 38 is arranged in the lifting moving motor box 37, and an output shaft of the lifting moving motor 38 is connected to one end of the rotating screw rod 18; a lifting and descending motor box 39 is arranged on one side of the lifting and descending support plate 20, a lifting and descending motor 40 is arranged in the lifting and descending motor box 39, and an output shaft of the lifting and descending motor 40 is connected with one end of the lifting and descending rotating shaft 21; the lower end of the lifting support box 17 is provided with a lifting moving sliding chute, and the lifting sliding plate 19 is slidably arranged in the lifting moving sliding chute; the diameters of the first limiting hole 11, the second limiting hole 12 and the third limiting hole 13 are sequentially increased; the side, far away from the material box 4, of the support column 2 is connected with a push handle 41, and anti-skid grains are arranged on the push handle 41.

When the lifting device is used specifically, the lifting motor 40 is started, the lifting motor 40 drives the lifting rotating shaft 21 to rotate, the lifting rotating shaft 21 rotates to drive the winding shaft 22 to rotate, the winding shaft 22 rotates to drive the pull wire 23 and the drag hook 24 to move downwards, so that the height of the drag hook 24 reaches the height of a material to be transported, the material is connected with the drag hook 24, the lifting motor 40 is reversely rotated to lift the material, the lifting moving motor 38 is started, the lifting moving motor 38 drives the rotating lead screw 18 to rotate, the rotating lead screw 18 drives the lifting sliding plate 19 to move towards the direction close to the material box 4, when the material is right above the material box 4, the lifting motor 40 drives the material to move downwards, the material is placed at the upper end of the lifting driving box 26, the clamping driving motor 31 is started, the clamping driving motor 31 drives the driving gear 33 to rotate, and the driving gear 33 drives the driven gear 35 and the bidirectional lead screw 34 to rotate, the materials are clamped by the two clamping plates 36, the first buffer spring 15 and the second buffer spring 16 are used for buffering and shockproof protection of the device when the device walks on a rugged road, the materials are buffered and protected when placed by the third buffer spring 27, the materials are clamped by the clamping plates 36 through the clamping plates 36, the materials are prevented from moving in the conveying process, and the materials are limited and protected.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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 the embodiments thereof have been described above, but the description is not limited thereto, and the embodiment shown in the drawings is only one of the embodiments of the present invention, and the actual structure is not limited thereto. In summary, those skilled in the art should understand that they should not be limited to the embodiments described above, and that they can design the similar structure and embodiments without departing from the spirit of the invention.

Claims (9)

1. The utility model provides a material transfer device for civil engineering which characterized in that: the material box comprises a base, a supporting column, a movable damping component, a material box, an in-out lifting component, a buffering component and a clamping and fixing component, wherein the movable damping component is connected and arranged at the lower end of the connecting base; the movable shock absorption assembly comprises a buffer plate, a T-shaped column and a universal wheel, a first limiting hole, a second limiting hole and a third limiting hole are sequentially arranged at the bottom of the base from bottom to top, the first limiting hole, the second limiting hole and the third limiting hole are communicated, two ends of the third limiting hole are provided with buffer connecting columns, the two ends of the buffer plate are sleeved outside the two buffer connecting columns, the outer sides of the buffer connecting columns are sleeved with first buffer springs, the first buffer spring is connected between the buffer plate and the inner top of the third limiting hole, the upper end of the T-shaped column is arranged in the second limiting hole, the lower end of the T-shaped column is arranged below the base in a way of penetrating through the first limiting hole, the outer side of the T-shaped column is sleeved with a second buffer spring, the second buffer spring is connected and arranged inside the second limiting hole, and the universal wheel is connected and arranged at the lower end of the T-shaped column; the in-out lifting assembly comprises a lifting support box, a rotating screw rod, a lifting sliding plate, a lifting support plate and a lifting rotating shaft, the lifting support box is connected to the upper end of the support column, the rotating screw rod is horizontally connected to the inside of the lifting support box, the upper end of the lifting sliding plate is sleeved on the outer side of the rotating screw rod, the lower end of the lifting sliding plate penetrates through the lifting support box and is arranged below the lifting support box, the lifting support plate is connected to the lower end of the lifting sliding plate, the lifting support plate is arranged in an n-shaped mode, the lifting rotating shaft is connected between two side plates of the lifting support plate, a winding shaft is sleeved on the outer side of the lifting rotating shaft and is arranged in an H-shaped mode, a pulling wire is sleeved on the outer side of the winding shaft, and a pulling hook is connected to the lower end of the pulling wire.

2. The material transfer device for civil engineering according to claim 1, characterized in that: the buffering subassembly is including buffering connecting axle and lift drive case, the interior bottom of locating the material case is connected to the buffering connecting axle, the outside at buffering connecting axle both ends all is equipped with third buffer spring by the cover, the other end of two third buffer springs all is connected and is equipped with the buffering sliding block, the outside of buffering connecting axle is located to the bottom of two buffering sliding blocks all overlaps, the double-phase of material case all is equipped with spout from top to bottom on the lateral wall, the inside of spout about the both ends of lift drive case are slided respectively and are located, the outer bottom of lift drive case is equipped with the connecting block, all articulate between two buffering sliding blocks and the connecting block and be equipped with the connecting plate.

3. The material transfer device for civil engineering according to claim 2, characterized in that: the fixed subassembly of centre gripping includes centre gripping driving motor, motor backup pad, driving gear, two-way lead screw, driven gear and grip block, centre gripping driving motor and motor backup pad all are connected and are located the interior bottom of lift drive case, one side of motor backup pad is located to centre gripping driving motor's output shaft, on the output shaft of centre gripping driving motor was located to the driving gear cover, the inside of lift drive case is located to two-way lead screw horizontal connection, the middle part in the two-way lead screw outside is located to the driven gear cover, driven gear is connected with the driving gear meshing, the outside of two-way lead screw is located to the bottom cover of grip block, the top of lift drive case is located to the upper end link up lift drive case of grip block.

4. The material transfer device for civil engineering according to claim 3, characterized in that: the upper end of the lifting driving box is provided with a clamping sliding groove, the clamping plates are slidably arranged in the clamping sliding groove, and the two groups of clamping plates are symmetrically arranged in the material box relative to the driven gear.

5. The material transfer device for civil engineering according to claim 1, characterized in that: one side of the lifting support box is connected with a lifting moving motor box, a lifting moving motor is arranged in the lifting moving motor box, and an output shaft of the lifting moving motor is connected with one end of the rotating screw rod.

6. The material transfer device for civil engineering according to claim 1, characterized in that: one side of the lifting support plate is provided with a lifting motor box, a lifting motor is arranged in the lifting motor box, and an output shaft of the lifting motor is connected to one end of the lifting rotating shaft.

7. The material transfer device for civil engineering according to claim 1, characterized in that: the lower end of the lifting support box is provided with a lifting moving sliding chute, and the lifting sliding plate is slidably arranged in the lifting moving sliding chute.

8. The material transfer device for civil engineering according to claim 1, characterized in that: the aperture of the first limiting hole, the aperture of the second limiting hole and the aperture of the third limiting hole are sequentially increased.

9. The material transfer device for civil engineering according to claim 1, characterized in that: the material box is characterized in that one side, far away from the material box, of the supporting column is connected with a pushing handle, and anti-skidding lines are arranged on the pushing handle.

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