KR100332540B1 - Whold direction conveyor carrier - Google Patents

Abstract

The present invention provides an omni-directional conveyor conveying body that can be commonly used in the turning area of the conveyor system. This invention is provided with a bearing 11 for supporting a conveyed object and a spherical symmetric concave surface 12 covering the lower half region of the steel ball, and a bearing ball 13 filled with the steel ball 11 in the concave surface. The steel ball 11 and the bearing ball 13 can be rolled in all directions while supporting and distributing the load on the concave surface, and a foreign substance discharge hole 14 is provided at the lower end of the concave surface 12, and the concave surface composition 12a ) Is supported on the cylindrical support (15), the steel ball 11 and the support (15) to the housing 21, the steel ball 11 is projected over the window 24 of the cover, steel ball (11) The annular circulation passage 25 between the steel ball 11 and the cover 23 so that the circulation action of the ball 13, which supplies the bearing balls 13 that escape from the concave surface 12 to the opposite side of the concave surface when rolling, is smooth. ) Is an omni-directional conveyor conveyer.

Description

Omni-directional conveyor conveyance {WHOLD DIRECTION CONVEYOR CARRIER}

The present invention relates to a WHOLD DIRECTION CONVEYOR CARRIER, and more particularly, to propose an omnidirectional free conveying body used for a line intermediate direction turning part of a conveyor system.

The commodity management equipment of the mass production line and the mass logistics system of the goods is based on the conveyor system. Conveyor system (C) is installed on the production line for the horizontal movement or tilt movement of the product or cargo and basically has a structure in which the drive roll (r) is arranged on the upper surface of the bed. Conveyor systems along curved lines are constructed by properly connecting linear orbital conveyors with circumferential orbital conveyors. The circumferential raceway conveyor arrange | positions a driving roll radially on the circumferential fan-shaped upper surface like FIG. In the circumferential orbital conveyor, the driving roll cr on the fan-shaped top surface calculates the trajectory angular transfer amount corresponding to the orbital curvature radius to determine the inner and outer diameters of the roll. As the radius of curvature, the inner and outer diameter ratios of the rolls cr are different. This situation increases conveyor design costs and equipment costs. However, the use of the omni-directional conveyor conveying body in the turning part of the conveyor can reduce the installation cost of the conveyor line.

Conventional conveyers for conveyers support a conveying object supporting steel ball on the concave surface, and insert a bearing ball between the steel ball and the concave surface to transfer the conveyed material to the rolling of the steel ball, or because the circulation of the bearing ball within the concave surface is not smooth. Was causing the cloud disorder.

The present invention is to provide an omni-directional conveyor conveying body in the rolling of the steel ball smoothly in the omni-directional conveyor conveying body to be used in common in the turning area of the conveyor system.

1 is a cross-sectional detail view of the present invention

2 is an exploded perspective view of the present invention

Figure 3 is a plan view of the installation state in the 90 ° corner of the present invention

Figure 4 is a plan view of the installation state in the 45 ° corner of the present invention

5 is a plan view of the installation state in the 180 ° corner of the present invention

Figure 6 is a plan view of the corner of the conventional conveyor system

<Description of Drawing Major Symbols>

11: Steel ball 12: Concave 14: Hole 15: Support 21: Housing 22: Stopper 23: Cover 24: Window 25: Circulation passage 26: Bracket

In the case where the metal sphere is supported in the housing so as to be rolled in all directions and used as a carrier, a ball for transporting the conveyed object 11 is supported on a spherical symmetric concave surface 12 with a bearing ball ( 13). Specifically, the bearing ball 13 is inserted between the concave surface 12 and the steel ball 11 covering the lower half region of the steel ball 11 so that the steel ball 11 can be rolled in all directions on the concave surface of the bearing ball 13. Support The bearing ball 13 distributed on the entire surface of the concave surface distributes the load applied from the steel ball 11 to the concave surface. Install the foreign matter discharge hole 14 at the bottom of the concave surface (12). The concave surface composition 12a is supported by the cylindrical support 15. The height (h) of the support (15) is set so as to be spaced between the lower end of the concave surface composition (12a) and the mounting bottom (b) with the support (15) to attach the peripheral outer surface to the housing (21) Configure it to be possible. The steel balls 11 and the support 15 are coupled to the housing 21. Specifically, the support 15 is inserted into the housing 21 by forcibly inserting the support 15 into the hole 21a of the housing 21 so that the upper portion of the cylindrical support 15 contacts the upper annular stopper 22 of the housing 21. Attach. Alternatively, a screw is formed at the connection portion between the support 15 and the housing 21 to join the two members. The annular cover 23 is attached to the stopper 22 and installed. The steel balls 11 are projected onto the cover 23 through the window 24 of the cover 23 so that the steel balls 11 are directly connected to the conveyor conveyed materials so that the conveyed materials can be supported while bearing the load of the conveyed materials. An annular circulation passage 25 is formed between the steel balls 11 and the cover 23. Circulation path 25 is the circulation action of the ball 13 to move to the opposite side of the concave surface to the bearing ball 13 which is moved together with the steel ball 11 when the steel ball 11 is rolled off from one side of the concave surface (12) This is to keep it smooth. Therefore, the steel balls 11 are supported on the steel balls 11 filled with the concave surface 12 at any time, and the steel balls 11 and the bearing balls 13 interlock with each other and the circulation of the bearing balls 13 through the passage 25. The smooth rolling of the steel balls 11 is ensured by the smooth operation of the steel balls 11. Further, the steel balls 11 are separated from the passage 25 by bringing the outer end of the forward conveyer passage window 24 to the upper half of the steel balls 11. To prevent foreign substances from entering the passage 25 and the concave surface 12 through the steel ball 11 surface. The bracket 26 is installed at the lower end of the housing 21. The bracket 26 is for attaching the omnidirectional conveyer to the conveyor support bottom b. In the attached state, the bracket 26 is in close contact with the conveyor support, and the bottom end of the cylindrical concave support 15 is in close contact with the bottom b to increase load resistance, and due to the high load, the support 15 and the housing 21 It is to prevent the assembly from being deformed. Unexplained code g is a conveyor guide.

The concave surface composition and the housing of the present invention can be press-molded from a steel plate or a mold product as shown in the accompanying drawings.

As described above, the present invention provides an omni-directional conveyor conveying body in which the rolling of the steel balls is smoothly designed in the omni-directional conveyor conveying body which can be commonly used in the turning area of the conveyor system.

Claims (1)

(Correction) A bearing ball 13 having a steel ball 11 for supporting a conveyed object and a spherical symmetric concave surface 12 covering the lower half region of the steel ball, and having the steel ball 11 filled with the concave surface. The steel ball 11 and the bearing ball 13 can be rolled in all directions while supporting and distributing the load on the concave surface, and a foreign substance discharge hole 14 is provided at the lower end of the concave surface 12, and the concave surface composition 12a ) Is supported on the cylindrical support 15, the steel ball 11 and the support 15 to the housing 21, the steel ball 11 is projected over the window 24 of the cover, When the steel ball 11 rolls, a bearing ball 13 which is separated from one side of the concave surface 12 is supplied to the opposite side of the concave surface so that the steel ball 11 can be rolled smoothly between the steel ball 11 and the cover 23. The omni-directional conveyor conveying body which formed the annular circulation passage 25.