CN216037172U - Supporting structure for transferring multiple cabs by elevator - Google Patents

Abstract

The utility model discloses a supporting structure for a plurality of cabs transported by an elevator, which comprises an elevator (1) arranged on a conveyor belt; the elevator (1) is provided with a supporting component for supporting a cab, the supporting component comprises a first supporting structure and a second supporting structure, a gap is formed between the first supporting structure and the second supporting structure, and a height drop exists between the first supporting structure and the second supporting structure; the extending ends of the first supporting structure and the second supporting structure are respectively provided with a first shock absorption piece (2) and a second shock absorption piece (3); the first supporting structure comprises a first rotating arm (4) fixed in the output end of the elevator (1), and the first damping part (2) is arranged at the output end of the first rotating arm (4). The utility model has the advantage of more stable and safe operation when the cab is transported.

Description

Supporting structure for transferring multiple cabs by elevator

Technical Field

The utility model relates to the field of cab assembly and processing, in particular to a supporting structure for a lifter to transfer various cabs.

Background

At present, the cabs produced by the capital large-capacity automobile are mainly four, the widths of the cabs are respectively (1735/1835/1995/2250), the lengths of the cabs are single-row and half-row, the width sizes of the bottom plate longitudinal beam structures are four, and the bottom plate longitudinal beams of the 2250 cab are different from other bottom plate longitudinal beams in structure, appearance and size; the elevator in the general assembly workshop is used for safely conveying the coated cab to the inner decoration line plate chain from the power and free chain lifting appliance, but the following defects exist in the transfer process:

four supporting legs for placing the cab on the elevator are all horizontal plane supports, so that some cabs are not easy to place and transfer; the front vehicle receiving point of the cab, the front part of a front floor beam of the cab, a horizontal support and the rear vehicle receiving point of the cab, and the rear part of a longitudinal beam of a floor of the cab 2250 are supported by an inclined plane, so that the phenomenon of forward sliding of about 80mm can occur, which indicates that the four support points are unbalanced, and the phenomenon of forward sliding of the cab from the inclined plane occurs due to the gravity and vibration of the cab, so that the cab is unsafe to slide and fall on the elevator.

SUMMERY OF THE UTILITY MODEL

The utility model aims to overcome the defects of the prior art and provide a supporting structure which supports multiple cab transportation and is safer.

The purpose of the utility model is realized by the following technical scheme:

a supporting structure for an elevator to transport multiple cabs comprises an elevator arranged on a conveyor belt.

The elevator is provided with a support assembly for supporting a cab, the support assembly comprises a first support structure and a second support structure, a gap is formed between the first support structure and the second support structure, and a height drop exists between the first support structure and the second support structure; the extension ends of the first supporting structure and the second supporting structure are respectively provided with a first shock absorbing piece and a second shock absorbing piece.

Furthermore, first bearing structure is including being fixed in the first rocking arm in the lift output, first shock attenuation piece sets up on the output of first rocking arm.

Furthermore, the second support structure comprises a second rotating arm fixed in the output end of the elevator, and the second damping piece is arranged at the output end of the second rotating arm.

Further, the overall height of the first rotating arm is higher than the overall height of the second rotating arm.

Furthermore, the extension ends of the first rotating arm and the second rotating arm are respectively provided with a first mounting seat and a second mounting seat, and the first damping piece and the second damping piece are respectively fixed on the first mounting seat and the second mounting seat.

Furthermore, a driving assembly for controlling the rotation angle of the first rotating arm and the second rotating arm is fixed on the outer side surface of the lifter.

The utility model has the beneficial effects that:

the supporting structure for transporting various cabs by the elevator can safely convey the coated cabs to the inner decoration wire plate chain from the elevator, meets the transportation function of cabs with four widths, solves the unsafe problem that the cabs slide and fall off when transported on the elevator, and achieves the effect of protecting products in the transportation process of the cabs; through the height difference between the first rotating arm and the second rotating arm, the first damping part is positioned in the common area plane of the cab bottom plate longitudinal beam, and the second damping part is positioned in the common area plane of the cab bottom, so that the supporting point is balanced, the cab cannot slide forwards from a large inclined plane, and the safety problem that the cab slides and falls on the elevator is solved; the supporting structure is combined with the first damping piece and the second damping piece, and plays a role in preventing the cab from sliding, scratching and damping.

Drawings

FIG. 1 is a front view of the present invention;

FIG. 2 is a left side view of the present invention;

fig. 3 is a top view of the present invention.

In the figure, 1-an elevator, 2-a first damping member, 3-a second damping member, 4-a first rotating arm, 5-a second rotating arm, 6-a first mounting frame, 7-a second mounting frame, 8-a first lifting block, 9-a second lifting block, 10-a first mounting block, 11-a first supporting column, 12-a third mounting block, 13-a second supporting column, 14-a fourth mounting block, and 15-a rotating shaft.

Detailed Description

In order to more clearly understand the technical features, objects, and effects of the present invention, embodiments of the present invention will now be described with reference to the accompanying drawings.

First embodiment, in the present embodiment, as shown in fig. 1 to 3, a supporting structure of an elevator for transferring various cabs includes an elevator 1 disposed on a conveyor. The elevator 1 is provided with a support assembly for supporting a cab, the support assembly comprises a first support structure and a second support structure, a gap is formed between the first support structure and the second support structure, and a height drop exists between the first support structure and the second support structure; the extending ends of the first supporting structure and the second supporting structure are respectively provided with a first shock absorbing part 2 and a second shock absorbing part 3.

In this embodiment, the elevator includes a first mounting bracket 6 and a second mounting bracket 7 fixed on both sides of the conveyor belt, the first mounting bracket 6 and the second mounting bracket 7 are arranged opposite to each other, a first lifting block 8 and a second lifting block 9 are slidably arranged on the inner sides of the first mounting bracket 6 and the second mounting bracket 7, and the first lifting block 8 and the second lifting block 9 are driven by a lifting motor; the supporting assembly is arranged on the inner side surfaces of the first lifting block 8 and the second lifting block 9; first damper 2 and second damper 3 are the shock pad for can not harm the driver's cabin, first damper 2 and second damper 3 all are the rectangle structure, the area of first damper 2 is greater than the area of second damper 3, first damper 2 and second damper 3 adopt polyurethane material to make.

The embodiment is further configured as follows: the first supporting structure comprises a first rotating arm 4 fixed in the output end of the elevator 1, and the first damping piece 2 is arranged on the output end of the first rotating arm 4.

In the embodiment, the first rotating arm 4 is formed by assembling and welding a cantilever steel structure, and is made of DN108 seamless steel tube in order to prevent deformation after long-term use; the whole first rotating arm 4 is of a straight structure, so that the supporting force of the supporting component to the cab is enhanced; the two first rotating arms 4 are oppositely arranged and are respectively fixed on the inner sides of the first lifting block 8 and the second lifting block 9.

The embodiment is further configured as follows: the second support structure comprises a second pivoted arm 5 fixed in the output end of the elevator 1, the second damping member 3 being arranged on the output end of the second pivoted arm 5.

In the embodiment, the second rotating arm 5 is formed by assembling and welding a cantilever steel structure, and is made of DN108 seamless steel tube in order to prevent deformation after long-term use; the second rotating arm is provided with a rectangular bending part which is sunken downwards, so that a cab cannot be damaged; the two second rotating arms 5 are oppositely arranged and fixed on the inner sides of the first lifting block 8 and the second lifting block 9 respectively.

The embodiment is further configured as follows: the overall height of the first swivel arm 4 is higher than the overall height of the second swivel arm 5.

In this embodiment, the first damping member 2 is located in the common area plane of the bottom plate longitudinal beam of the cab and the second damping member 3 is located in the common area plane of the bottom of the cab through the height difference between the first rotating arm 4 and the second rotating arm 5, so that the supporting points are balanced, the cab cannot slide forward from a large inclined plane, and the safety problem that the cab slides and falls on the elevator is solved.

The embodiment is further configured as follows: the extension of first rocking arm 4 and second rocking arm 5 is served and is equipped with first mount pad and second mount pad respectively, first damper 2 with second damper 3 be fixed in respectively on first mount pad and the second mount pad.

In this embodiment, the extending ends of the first rotating arm 4 and the second rotating arm 5 have extending portions bent ninety degrees inward, the first mounting seat and the second mounting seat are fixed on the extending portions, the first mounting seat includes a first mounting block 10 and a second mounting block fixed on the extending portion of the first rotating arm 4, the second mounting block is located on the end face of the extending end of the extending portion of the first rotating arm 4, two first supporting columns 11 are fixed on the second mounting block, a third mounting block 12 is fixed on the first supporting columns 11, and the first damper 2 is fixed on the third mounting block 12; the second mounting base comprises a second supporting column 13 fixed on the extension part of the second rotating arm 5, a fourth mounting block 14 is fixed on the second supporting column 13, and the second shock absorber 2 is fixed on the fourth mounting block 14.

The embodiment is further configured as follows: and a driving assembly for controlling the rotating angles of the first rotating arm 4 and the second rotating arm 5 is also fixed on the outer side surface of the lifter 1. Through the driving assembly, the width can be automatically adjusted when different cabs are replaced for machining.

In this embodiment, four rotating shafts 15 are vertically installed on the inner sides of the first lifting block 8 and the second lifting block 9, and the first rotating arm 4 and the second rotating arm 5 are respectively sleeved on the corresponding rotating shafts 15 and fixed by bolts; the driving assembly comprises a driving air cylinder fixed on a first lifting block 8 and a second lifting block 9, connecting pieces are arranged on the first rotating arm 4 and the second rotating arm 5, and the driving air output end is hinged and fixed with the connecting pieces.

In the second embodiment, the present embodiment discloses a supporting structure for an elevator to transport various cabs, which comprises an elevator 1 disposed on a conveyor belt. The elevator 1 is provided with a support assembly for supporting a cab, the support assembly comprises a first support structure and a second support structure, a gap is formed between the first support structure and the second support structure, and a height drop exists between the first support structure and the second support structure; the extending ends of the first supporting structure and the second supporting structure are respectively provided with a first shock absorbing part 2 and a second shock absorbing part 3.

In this embodiment, the elevator includes a first mounting bracket 6 and a second mounting bracket 7 fixed on both sides of the conveyor belt, the first mounting bracket 6 and the second mounting bracket 7 are arranged opposite to each other, a first lifting block 8 and a second lifting block 9 are slidably arranged on the inner sides of the first mounting bracket 6 and the second mounting bracket 7, and the first lifting block 8 and the second lifting block 9 are driven by a lifting motor; the supporting assembly is arranged on the inner side surfaces of the first lifting block 8 and the second lifting block 9; the first damping member 2 and the second damping member 3 are damping pads so that a cab is not damaged, the first damping member 2 and the second damping member 3 are both rectangular structures, and the area of the first damping member 2 is larger than that of the second damping member 3; the first damping piece 2 and the second damping piece 3 are fixed through screws and glue, countersunk holes are formed in the first damping piece 2 and the second damping piece 3, and the screws are located in the countersunk holes.

The embodiment is further configured as follows: the first supporting structure comprises a first rotating arm 4 fixed in the output end of the elevator 1, and the first damping piece 2 is arranged on the output end of the first rotating arm 4.

In the embodiment, the first rotating arm 4 is formed by assembling and welding a cantilever steel structure, and is made of DN108 seamless steel tube in order to prevent deformation after long-term use; the whole first rotating arm 4 is of a straight structure, so that the supporting force of the supporting component to the cab is enhanced; the two first rotating arms 4 are oppositely arranged and are respectively fixed on the inner sides of the first lifting block 8 and the second lifting block 9.

The embodiment is further configured as follows: the second support structure comprises a second pivoted arm 5 fixed in the output end of the elevator 1, the second damping member 3 being arranged on the output end of the second pivoted arm 5.

In the embodiment, the second rotating arm 5 is formed by assembling and welding a cantilever steel structure, and is made of DN108 seamless steel tube in order to prevent deformation after long-term use; the second rotating arm is provided with a rectangular bending part which is sunken downwards, so that a cab cannot be damaged; the two second rotating arms 5 are oppositely arranged and fixed on the inner sides of the first lifting block 8 and the second lifting block 9 respectively.

The embodiment is further configured as follows: the overall height of the first swivel arm 4 is lower than the overall height of the second swivel arm 5.

In this embodiment, the height difference between the first rotating arm 4 and the second rotating arm 5 enables the second shock absorbing member 3 to be located in the common area plane of the bottom plate longitudinal beam of the cab, and the first shock absorbing member 2 to be located in the common area plane of the bottom of the cab, so that the supporting points are balanced, the cab cannot slide forwards from a large inclined plane, and the safety problem that the cab slides and falls on the elevator is solved.

The embodiment is further configured as follows: the extension of first rocking arm 4 and second rocking arm 5 is served and is equipped with first mount pad and second mount pad respectively, first damper 2 with second damper 3 be fixed in respectively on first mount pad and the second mount pad.

In this embodiment, the first mounting seat and the first rotating arm 4 are integrally formed, and the second mounting seat and the second rotating arm 5 are integrally formed; the extension ends of the first rotating arm 4 and the second rotating arm 5 are provided with extension parts bent to ninety degrees towards the inside, the first mounting seat and the second mounting seat are fixed on the extension parts, the first mounting seat comprises a first mounting block 10 and a second mounting block which are fixed on the extension parts of the first rotating arm 4, the second mounting block is positioned on the end surface of the extension end of the extension part of the first rotating arm 4, two first supporting columns 11 are fixed on the second mounting block, a third mounting block 12 is fixed on the first supporting columns 11, and the first shock absorber 2 is fixed on the third mounting block 12; the second mounting seat comprises a second supporting column 13 fixed on the extension part of the second rotating arm 5, a fourth mounting block 14 is fixed on the second supporting column 13, and the second shock absorber 2 is fixed on the fourth mounting block 14; the first mounting seat and the second mounting seat are welded on the first rotating arm 2 and the second rotating arm 3 by adopting 10# channel steel.

The embodiment is further configured as follows: and a driving assembly for controlling the rotating angles of the first rotating arm 4 and the second rotating arm 5 is also fixed on the outer side surface of the lifter 1.

In this embodiment, four rotating shafts 15 are vertically installed on the inner sides of the first lifting block 8 and the second lifting block 9, and the first rotating arm 4 and the second rotating arm 5 are respectively sleeved on the corresponding rotating shafts 15 and fixed by pins; the driving assembly comprises a driving motor fixed on the first lifting block 8 and the second lifting block 9, and an output shaft of the driving motor is connected with a rotating shaft 15 through a shaft.

The working principle of the utility model is as follows:

the cab coated on the conveying belt is placed on the first shock absorbing piece 2 and the second shock absorbing piece 3 through a mechanical arm or a manual work, and then the cab is transferred to the inner decoration line plate chain through the lifter 1 for subsequent processing.

The foregoing shows and describes the general principles, essential features, and advantages of the utility model. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (6)

1. A supporting structure for an elevator to transport multiple cabs, comprising an elevator (1) arranged on a conveyor belt, characterized in that:

the elevator (1) is provided with a supporting component for supporting a cab, the supporting component comprises a first supporting structure and a second supporting structure, a gap is formed between the first supporting structure and the second supporting structure, and a height drop exists between the first supporting structure and the second supporting structure; the extension ends of the first supporting structure and the second supporting structure are respectively provided with a first shock absorption piece (2) and a second shock absorption piece (3).

2. A support structure for an elevator to transport multiple cabs according to claim 1, wherein: the first supporting structure comprises a first rotating arm (4) fixed in the output end of the elevator (1), and the first damping part (2) is arranged at the output end of the first rotating arm (4).

3. A support structure for an elevator to transport multiple cabs according to claim 2, wherein: the second supporting structure comprises a second rotating arm (5) fixed in the output end of the elevator (1), and the second damping piece (3) is arranged on the output end of the second rotating arm (5).

4. A support structure for an elevator to transport multiple cabs according to claim 3, wherein: the whole height of the first rotating arm (4) is higher than that of the second rotating arm (5).

5. A support structure for an elevator to transport multiple cabs according to claim 3, wherein: the extension of first rocking arm (4) and second rocking arm (5) is served and is equipped with first mount pad and second mount pad respectively, first shock attenuation piece (2) and with second shock attenuation piece (3) be fixed in respectively on first mount pad and the second mount pad.

6. A support structure for an elevator to transport multiple cabs according to claim 1, wherein: and a driving assembly for controlling the rotating angles of the first rotating arm (4) and the second rotating arm (5) is further fixed on the outer side surface of the lifter (1).

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