CN223534211U - Logistics double-fork arm lifter - Google Patents

Abstract

The utility model discloses a logistics double-fork arm lifter which comprises a base and a lifting platform arranged on the base and driven by a driving piece, wherein the lifting platform is connected with a bearing piece through an adjusting component, the bearing piece comprises a first conveying belt and a second conveying belt which are movably connected, one side of the first conveying belt is movably connected with the lifting platform, and when the logistics double-fork arm lifter works, the first conveying belt is inclined on the lifting platform along with the support of an auxiliary rod in the adjusting component to one side of the first conveying belt. Through the support that the first conveyer belt that sets up on lift platform passes through the auxiliary rod, make first conveyer belt can become tilt state in the level to make the article that is located first conveyer belt top carry out slip transport, the second conveyer belt of rethread swing joint first conveyer belt passes through the removal of support piece on the supporting shoe, makes second conveyer belt also adapt first conveyer belt and will carry the article on first conveyer belt through adjusting inclination and lead, and then improves the mode of use more convenient for the user.

Description

Logistics double-fork arm lifter

Technical Field

The utility model relates to the technical field of logistics transportation, in particular to a logistics double-fork arm lifter.

Background

The logistic double-fork arm lifter is industrial transportation equipment widely applied to warehouse, logistics and manufacturing industries, and has the main function of realizing vertical lifting of goods through double-shear arms and a hydraulic system. Such equipment is typically made of strong steel and has high load carrying capacity and stability, and is suitable for use in locations where heavy goods are required to be handled frequently.

Along with the development of logistics systems, the quantity of articles which are put into operation every day in a storage station is very huge, the huge quantity of articles brings about the diversity of demands, and the conventional logistics double-fork lifter is basically horizontally and vertically adjusted for planar conveying and cannot adapt to special scenes, for example, articles with height differences are conveyed onto a logistics conveying line, and the logistics double-fork lifter which is vertically adjusted cannot be achieved.

Disclosure of utility model

In view of the above, the present utility model aims at overcoming the drawbacks of the prior art, and its main objective is to provide a dual-fork lifter for logistics, which solves the problems that the conventional dual-fork lifter for logistics is basically horizontal and up-down adjustable and planar, and cannot adapt to some special situations, such as conveying objects with height difference onto a logistics conveying line, and the dual-fork lifter for logistics with up-down adjustment cannot be achieved.

In order to achieve the aim, the technical scheme is that the logistics double-fork arm lifter comprises a base and a lifting platform arranged on the base and driven by a driving piece, wherein the lifting platform is connected with a bearing piece through an adjusting component, the bearing piece comprises a first conveying belt and a second conveying belt which are movably connected, and one side of the first conveying belt is movably connected with the lifting platform;

when the lifting platform works, the first conveyer belt is inclined on the lifting platform along with the support of the auxiliary rod in the adjusting assembly on one side of the first conveyer belt;

When the conveying direction of the articles is required to be changed, the inclination angle of the second conveying belt is changed to be matched with the first conveying belt along with the movement of the supporting piece on the supporting block in the adjusting assembly.

Further, the adjusting component comprises a plug cylinder arranged on the upper end face of the lifting platform, the auxiliary rod can be plugged into the inner cavity of the plug cylinder, and the auxiliary rod is movably connected with the lower end face of the first conveying belt.

Further, the supporting block is arranged on the lower end face of the lifting platform, an opening is formed in the middle of the supporting block in a lath shape, and a rod body connected with the supporting piece is arranged in the opening.

Further, the support piece is long, a plurality of clamping grooves which are clamped with the rod body are formed in the lower end of the support piece at equal intervals, and one end, away from the rod body, of the support piece is movably connected with the second conveying belt.

Further, the clamping groove comprises a first opening at the lower side edge of the support piece and an extension opening extending beside the first opening, and the rod body is clamped with the extension opening.

Further, the first conveyor belt and the second conveyor belt respectively comprise a first plate frame and a second plate frame which are opposite to each other, and a rotating roller arranged between the two first plate frames and the two second plate frames.

Further, auxiliary rod swing joint is in first grillage lower extreme, and support piece swing joint is in second grillage lower extreme.

Further, a friction cylinder is sleeved on the rotary roller, and the surface of the friction cylinder is rough.

Further, the driving piece comprises a driving cylinder and a cross connecting rod which are arranged on the base, and an output shaft of the driving cylinder is connected with the cross connecting rod.

Further, wheels are arranged at the bottom of the base.

Compared with the prior art, the utility model has obvious advantages and beneficial effects, in particular, according to the technical scheme, the first conveying belt is supported by the auxiliary rod through the first conveying belt arranged on the lifting platform, so that the first conveying belt can be changed into an inclined state in the horizontal direction, articles above the first conveying belt are subjected to sliding conveying, and then the second conveying belt movably connected with the first conveying belt can adapt to the first conveying belt and guide articles conveyed on the first conveying belt through adjusting the inclined angle through the movement of the supporting piece on the supporting block, so that a more convenient use mode is improved for users.

In order to more clearly illustrate the structural features and efficacy of the present utility model, the present utility model will be described in detail below with reference to the accompanying drawings and examples.

Drawings

Fig. 1 is a perspective view showing embodiment 1 of the present utility model.

Fig. 2 is a side view showing embodiment 1 of the present utility model.

Fig. 3 is a side cross-sectional view of an adjustment assembly of embodiment 1 of the present utility model.

Fig. 4 is an explanatory view of the support of embodiment 1 of the present utility model.

The attached drawings are used for identifying and describing:

10 base, 11 wheels;

20 driving pieces, 21 driving cylinders and 22 crossed connecting rods;

30 lifting platforms;

40 adjusting component, 41 auxiliary rod, 42 supporting piece, 4211 first opening, 4212 extending opening, 43 supporting block, 431 opening, 432 rod body, 44 cartridge;

50 carriers, 51 first conveyor belts, 511 first grillage, 52 second conveyor belts, 521 second grillage, 53 rotating rollers and 531 friction cylinders.

Detailed Description

Referring to fig. 1-4, a specific structure of a first preferred embodiment of the present utility model is shown, which is a logistic double-fork lifter, comprising a base 10 and a lifting platform 30 arranged on the base 10 and driven by a driving member 20, wherein the lifting platform 30 is connected with a bearing member 50 through an adjusting assembly 40, the bearing member 50 comprises a first conveying belt 51 and a second conveying belt 52 which are movably connected, and one side of the first conveying belt 51 is movably connected with the lifting platform 30;

When in operation, the first conveyor belt 51 is inclined on the lifting platform 30 along with the support of the auxiliary rod 41 on one side of the first conveyor belt 51 in the adjusting assembly 40;

When the conveying direction of the articles needs to be changed, the inclination angle of the second conveying belt 52 is changed to match with the first conveying belt 51 along with the movement of the supporting piece 42 on the supporting block 43 in the adjusting assembly 40. Compared with the existing logistics double-fork arm lifter, the lifting platform can only be adjusted horizontally up and down to transport goods. According to the double-fork arm lifter, the first conveying belt 51 is supported by the auxiliary rod 41 through the first conveying belt 51 arranged on the lifting platform 30, so that the first conveying belt 51 can be changed into an inclined state in the horizontal direction, articles above the first conveying belt 51 are slidingly conveyed, the second conveying belt 52 movably connected with the first conveying belt 51 moves on the supporting block 43 through the supporting piece 42, the second conveying belt 52 can adapt to the first conveying belt 51 through adjusting the inclination angle, the articles conveyed on the first conveying belt 51 are guided, and the use mode more convenient for a user is improved.

It should be noted that, the lifting platform 30 is driven by the output shaft of the driving member 20 to move up and down horizontally, so that the first conveying belt 51 on the lifting platform 30 can be adapted to other logistics transportation devices, so as to facilitate the transportation of the articles.

As shown in fig. 2, the adjusting assembly 40 includes a socket 44 disposed on an upper end surface of the lifting platform 30, the auxiliary rod 41 is pluggable into an inner cavity of the socket 44, and the auxiliary rod 41 is movably connected with a lower end surface of the first conveyor belt 51. When the first conveyer belt 52 needs to incline to match with other logistics equipment, the inserting cylinder 44 is installed at the upper end face of the lifting platform 30 and away from the position on one side of the second conveyer belt 52, and the opening of the inserting cylinder 44 corresponds to the first conveyer belt 51, so that an operator can take the auxiliary rod 41 movably connected below the first conveyer belt 51 to insert into the inserting cylinder 44, the first conveyer belt 51 is changed into an inclined state from the horizontal state, and the inserting cylinder 44 is arranged on the lifting platform 30, so that the first conveyer belt 51 is supported.

As shown in fig. 4, for example, the supporting block 43 is disposed on the lower end surface of the lifting platform 30, the supporting block 43 is in a shape of a slat, an opening 431 is disposed in the middle of the supporting block 43, and a rod 432 connected to the supporting member 42 is disposed in the opening 431. In order to enable the supporting member 42 to move on the supporting block 43, the inclination of the second conveying belt 52 is adjusted, the supporting block 43 is in a lath shape and is longitudinally arranged, an opening 431 is formed in the middle of the supporting block 43, a rod 432 is fixed in the opening 431, and the supporting member 42 supports the second conveying belt 52 through clamping with the rod 432.

It should be noted that, there are no fewer than two rods 432, and the distance between the two rods 432 is enough for the support member 42 to insert and move, so that the support member 42 can perform inclination adjustment on the second conveyor belt 52 better.

As shown in fig. 3, the supporting member 42 is in an exemplary strip shape, the lower end of the supporting member is provided with a plurality of clamping grooves 421 which are clamped with the rod 432 at equal intervals, and one end of the supporting member 42 away from the rod 432 is movably connected with the second conveying belt 52. In order to make the supporting member 42 capable of being clamped with the rod 432, the supporting member 42 is also arranged to be a strip capable of passing through the opening 431, and the bottom wall of the supporting member 42 is provided with a plurality of clamping grooves 421 distributed at equal intervals, when the supporting member 42 moves on the supporting block 43, the rod 432 is clamped with the clamping grooves 421 to position the supporting member 42 after the position is adjusted.

As shown in fig. 3, the clamping groove 421 includes a first opening 4211 at a lower side edge of the support member 42 and an extension opening 4212 extending beside the first opening 4211, and the rod 432 is clamped with the extension opening 4212. In order to make the clamping connection between the clamping groove 421 and the rod body 432 more compact, no accidental falling occurs, the clamping groove 421 is provided with a first opening 4211 and an extension opening 4212 which are mutually communicated, and the extension opening 4212 is positioned at one side of the first opening 4211 adjacent to the stress direction of the supporting member 42, so that when the supporting member 42 is extruded by the second conveying belt 52, the inner wall of the extension opening 4212 is in contact with the rod body 432 to support the second conveying belt 52.

As shown in fig. 3, the first conveyor belt 51 and the second conveyor belt 52 illustratively include two opposing first rack 511 and second rack 521, respectively, and a roller 53 disposed between the two first rack 511 and the two second rack 521. Compared with a belt conveyer belt, the conveyer belt adopting the rotating rollers 53 has the advantages that the rotating rollers 53 are arranged at equal intervals, and each rotating roller 53 is independent, so that after the first conveyer belt 51 and the second conveyer belt 52 incline, articles on the conveyer belt are easier to move along with the rotation of the rotating rollers 53. In addition, the rotating roller 53 may not require additional drives, and belt transport sometimes requires additional drives, reducing the cost of the article transport.

As shown in fig. 3, for example, the auxiliary rod 41 is movably connected to the lower end of the first frame 511, the supporting member 42 is movably connected to the lower end of the second frame 521, and the auxiliary rod 41 and the supporting member 42 may be connected to the first frame 511 and the second frame 521 through connecting rods, respectively, so that the auxiliary rod 41 and the supporting member 42 may be rotated about the connecting rods while being positioned.

As shown in fig. 3, the friction cylinder 531 is illustratively sleeved on the rotary roller 53, and the surface of the friction cylinder 531 is rough. Because the surface of the rotating roller 53 is smooth, when some special articles are conveyed, the rotation of the rotating roller 53 accelerates the conveying speed of the articles, so that some articles can be damaged, the friction cylinder 531 is sleeved on the rotating roller 53, friction between the articles contacted with the friction cylinder 531 is increased through rough textures on the surface of the friction cylinder 531, and the conveying speed of the articles is reduced, so that the damage to the articles caused by the excessively high conveying speed of the articles is avoided.

The driving member 20 includes a driving cylinder 21 mounted on the base 10 and a cross connecting rod 22, and an output shaft of the driving cylinder 21 is connected to the cross connecting rod 22.

Wheels 11 are arranged at the bottom of the base 10.

The foregoing description is only a preferred embodiment of the present utility model, and is not intended to limit the technical scope of the present utility model, so any minor modifications, equivalent changes and modifications made to the above embodiments according to the technical principles of the present utility model are still within the scope of the technical solutions of the present utility model.

Claims (10)

1. The logistics double-fork arm lifter comprises a base (10) and a lifting platform (30) arranged on the base (10) and driven by a driving piece (20), and is characterized in that the lifting platform (30) is connected with a bearing piece (50) through an adjusting component (40), the bearing piece (50) comprises a first conveying belt (51) and a second conveying belt (52) which are movably connected, and one side of the first conveying belt (51) is movably connected with the lifting platform (30);

When the lifting platform works, the first conveying belt (51) is inclined on the lifting platform (30) along with the support of the auxiliary rod (41) in the adjusting assembly (40) on one side of the first conveying belt (51);

When the conveying direction of the articles is required to be changed, the inclination angle of the second conveying belt (52) is changed to be matched with the first conveying belt (51) along with the movement of the supporting piece (42) on the supporting block (43) in the adjusting assembly (40).

2. The logistic double-fork arm lifter according to claim 1, characterized in that the adjusting assembly (40) comprises a plug cylinder (44) arranged on the upper end face of the lifting platform (30), the auxiliary rod (41) can be plugged into an inner cavity of the plug cylinder (44), and the auxiliary rod (41) is movably connected with the lower end face of the first conveying belt (51).

3. The logistic double-fork arm lifter according to claim 1, characterized in that the supporting block (43) is arranged on the lower end face of the lifting platform (30), the supporting block (43) is in a strip shape, an opening (431) is arranged in the middle of the supporting block, and a rod body (432) connected with the supporting piece (42) is arranged in the opening (431).

4. The logistic double-fork arm lifter according to claim 3, characterized in that the supporting member (42) is in a strip shape, a plurality of clamping grooves (421) which are clamped with the rod body (432) are arranged at the lower end of the supporting member at equal intervals, and one end, away from the rod body (432), of the supporting member (42) is movably connected with the second conveying belt (52).

5. The logistic double-fork lifter according to claim 4, characterized in that the clamping groove (421) comprises a first opening (4211) formed in the lower side edge of the supporting member (42) and an extension opening (4212) extending beside the first opening (4211), and the rod body (432) is clamped with the extension opening (4212).

6. A logistic double fork arm elevator according to claim 1, wherein the first conveyor belt (51) and the second conveyor belt (52) respectively comprise two opposite first plate frames (511) and second plate frames (521), and a rotating roller (53) arranged between the two first plate frames (511) and the two second plate frames (521).

7. A logistical double fork arm elevator according to claim 6, characterized in that said auxiliary lever (41) is movably connected to the lower end of said first plate frame (511), and said support member (42) is movably connected to the lower end of said second plate frame (521).

8. The logistic double-fork arm lifter according to claim 6, characterized in that a friction cylinder (531) is sleeved on the rotating roller (53), and the surface of the friction cylinder (531) is rough.

9. A logistic double fork arm elevator according to claim 1, characterized in that the driving member (20) comprises a driving cylinder (21) mounted on the base (10) and a cross connecting rod (22), the output shaft of the driving cylinder (21) being connected with the cross connecting rod (22).

10. A logistical double fork arm lifter according to claim 1 characterized in that the bottom of the base (10) is provided with wheels (11).