阅读说明：本技术 支柱 (Support post ) 是由 陶山和夫 永井弘 村上晋平 末永和也 于 2020-03-26 设计创作，主要内容包括：一种支柱,具备多个棒状体、束缚多个棒状体的环状构件、以及对被束缚的多个棒状体进行支承而使其立起地设置的基座。(A support column is provided with a plurality of rod-shaped bodies, a ring-shaped member for restraining the rod-shaped bodies, and a base for supporting and standing the restrained rod-shaped bodies.)

1. A column, comprising:

a plurality of rods;

a ring member for binding the plurality of rod-shaped bodies; and

and a base which supports and stands up the plurality of rod-shaped bodies bound by the annular member.

2. The strut of claim 1,

at least any one of the plurality of rods is arcuately curved.

3. The strut of claim 1 or 2,

the rod-shaped body is further provided with a holder for holding the upper end portions of the plurality of rod-shaped bodies.

4. The strut of claim 3,

the rod-shaped bodies each have: a 1 st rotation restricting portion protruding outward in a radial direction at an upper portion of the rod-shaped body; and a 2 nd rotation restricting portion projecting outward in a radial direction at a lower portion of the rod-shaped body,

the holder has a groove portion to be engaged with the 1 st rotation restricting portion, and the base has a groove portion to be engaged with the 2 nd rotation restricting portion.

5. The strut as in any one of claims 1 to 4,

the plurality of rod-shaped bodies are arranged such that a central portion of the support column bulges outward in the radial direction.

6. The strut as in any one of claims 1 to 5,

the rod-shaped body has at least one flange portion projecting outward in a radial direction of the rod-shaped body,

the at least one flange portion is disposed below the annular member and configured to restrict downward movement of the annular member.

7. The strut of claim 6,

the rod-shaped bodies each have a plurality of the flange portions,

the rod-shaped bodies each have the same number of annular members as the flange portions.

8. The strut as in any one of claims 1 to 7,

the device further includes a support portion connected to the annular member and configured to restrict upward movement of the annular member.

9. The strut as in any one of claims 1 to 8,

the wand is formed from a fibrous material.

10. The strut as in any one of claims 1 to 9,

the trolley is also provided with a pulley for suspending a stringing for the gathering stringing.

Technical Field

The present invention relates to an assembled pillar.

Background

Jp 1-244807 a discloses a steel pipe column constructed by arranging a plurality of longitudinal reinforcements in a casing and then pouring concrete. When the steel pipe column is constructed, the spiral lateral reinforcements are engaged with hooks provided to protrude from the inner surface of the casing, and the longitudinal reinforcements are arranged in parallel along the inner sides of the lateral reinforcements.

Disclosure of Invention

In a stringing and collecting system for conveying timber harvested in a forest, a relatively large support column is erected (erected) in the forest. The work of erecting the support in a forest is not easy.

The invention provides a support column capable of easily performing vertical operation.

A strut according to one aspect of the present invention includes: a plurality of rods; an annular member for binding the plurality of rod-shaped bodies; and a base provided to support the plurality of bound rod-shaped bodies so as to stand up.

According to the present invention, a support column that can be easily erected can be provided.

Drawings

Features, advantages, and technical and industrial significance of exemplary embodiments of the present invention will be described below with reference to the accompanying drawings, in which like reference numerals represent like elements, and wherein:

fig. 1 is a diagram for explaining an overhead wire harness system.

Fig. 2 is a perspective view of the strut of the embodiment.

Fig. 3 is a perspective view of the wand.

Detailed Description

Fig. 1 is a diagram for explaining an overhead wire harness system 1. The overhead wire harness system 1 includes: the first support 10a, the second support 10b, the third support 10c, the fourth support 10d (referred to as "support 10" when they are not distinguished), the first main rope 12a, the second main rope 12b (referred to as "main rope 12" when they are not distinguished), the first working rope 14a, the second working rope 14b, the third working rope 14c, the fourth working rope 14d, the fifth working rope 14e, the fourth working rope 14f (referred to as "working rope 14" when they are not distinguished), the first moving device 16a, the second moving device 16b (referred to as "moving device 16" when they are not distinguished), the holding device 18, the guide pulley 22, and the skidder 24.

The overhead wire harness system 1 is a so-called H-type overhead wire harness system for lifting a timber 20 cut in a forest by a main rope 12 and a working rope 14 that are opened in the air and transporting the timber to the vicinity of a harness yard 26. This enables the timber 20 to be transported from the forest without constructing a road.

The four support columns 10 are provided upright at positions suitable for erection determined by the arrangement of trees and the position of the yard 26. The support column 10 is set to a size of about 5 to 10 meters depending on the size of the overhead wire harness system 1.

The main rope 12 and the working rope 14 are fixed to the support column 10 as overhead wires or are hung on pulleys of the support column 10. The 1 st main cable 12a is fixed to the 1 st support column 10a and the 2 nd support column 10b, and the 2 nd main cable 12b is fixed to the 3 rd support column 10c and the 4 th support column 10d, and functions as a track in the air. The 1 st main rope 12a and the 2 nd main rope 12b are arranged so as not to intersect. The length of the main rope 12 is about 300 to 1500 meters.

The work wire 14 functions as a traveling wire that is wound up by the traveling device 16 or the skidder 24. The 1 st, 2 nd, 3 rd, and 4 th working cables 14a, 14b, 14c, and 14d are hung on pulleys provided on the support column 10, and one end is connected to the moving device 16, and the other end is connected to the skidder 24. The 1 st work wire 14a is connected from the skidder 24 to the 1 st traveling device 16a via the 2 nd support 10b and the 1 st support 10 a. The 2 nd work wire 14b is connected from the skidder 24 to the 1 st traveling device 16a via the 2 nd support 10 b. The 3 rd work wire 14c is connected from the skidder 24 to the 2 nd traveling device 16b via the 4 th support 10d and the 3 rd support 10 c. The 4 th work wire 14d is connected from the skidder 24 to the 2 nd traveling device 16b via the 4 th support 10 d. The 5 th and 6 th working cables 14e and 14f are connected to the moving device 16 and the holding device 18.

The 1 st moving device 16a and the 2 nd moving device 16b are supported by the 1 st main cable 12a and the 2 nd main cable 12b, respectively, and are movable along the 1 st main cable 12a and the 2 nd main cable 12 b. The 1 st, 2 nd, and 5 th working cables 14a, 14b, 14e are connected to the 1 st traveling device 16a, and the 3 rd, 4 th, and 6 th working cables 14c, 14d, 14f are connected to the 2 nd traveling device 16 b. The 5 th work cable 14e connects the 1 st moving device 16a to the holding device 18, and the 6 th work cable 14f connects the 2 nd moving device 16b to the holding device 18. The traveling device 16 has a function of winding up the 5 th work wire 14e and the 6 th work wire 14f in response to a wireless instruction signal.

The holding device 18 has hooks for gripping the timber 20. The wire may be further extended from the holding device 18 or may be wound up by the holding device 18. This enables the hook of the holding device 18 to move up and down.

The guide pulley 22 changes the direction of the suspended working cable 14. The skidder 24 functions as a hoist for winding up the work wire 14, and includes a roller for winding up or unwinding each work wire 14 and a drive source.

The operation of the overhead wire harness system 1 will be described. The skidder 24 moves the 1 st moving device 16a along the 1 st main wire 12a by winding up one of the 1 st work wire 14a and the 2 nd work wire 14b and unwinding the other. Further, the skidder 24 moves the 2 nd moving device 16b along the 2 nd main wire 12b by winding up one of the 3 rd and 4 th work wires 14c and 14d and unwinding the other. Thereby, the holding device 18 is displaced along the main rope 12.

The moving device 16 winds up one of the 5 th and 6 th working wires 14e and 14f and unwinds the other, thereby moving the holding device 18 between the 1 st and 2 nd moving devices 16a and 16 b. Thus, the holding device 18 can move in two dimensions in the area surrounded by the four support columns 10, and can convey the timber 20 harvested in the area.

Since the support column 10 is a large-sized implement required to have a load-bearing capacity of several thousand kilograms, it is not easy to transport the support column to an erection site in a forest where there is no road. Therefore, the column 10 of the embodiment is of an assembly type, and the components of the column 10 are transported to a vertical installation site and assembled. Thus, when a simple overhead line to the erection site is opened using an unmanned aerial vehicle or the like, the components of the support column 10 can be easily transported using the overhead line.

Fig. 2 is a perspective view of the pillar 10 of the embodiment. The support column 10 includes a plurality of rod-shaped bodies 30, a 1 st annular member 32a, a 2 nd annular member 32b, a 3 rd annular member 32c (which will be referred to as "annular members 32" unless distinguished from each other), a base 34, a holder 36, a plurality of support portions 38, and pulleys 40.

The plurality of rod-shaped bodies 30 are bound by the ring-shaped member 32, and are provided so as to stand up via the base 34 and the support portion 38. The rod-shaped body 30 will be described with reference to fig. 3.

Fig. 3 is a perspective view of the rod 30. The rod-like member 30 includes a 1 st flange portion 42a, a 2 nd flange portion 42b, and a 3 rd flange portion 42c (referred to as "flange portions 42" when they are not distinguished), a 1 st rotation restricting portion 44a, and a 2 nd rotation restricting portion 44b (referred to as "rotation restricting portions 44" when they are not distinguished).

The rod-like body 30 is formed in a bow shape from a fiber material such as glass fiber. By forming the rod-shaped body 30 with a fiber material, the weight of the column 10 can be about half or less as compared with a column formed with a metal material. Further, by forming the rod-like body 30 into a bow shape, the annular member 32 can be pressed radially in an assembled state, so that the annular member 32 is less likely to fall off, and the support column 10 can be stably erected by continuously applying a load. The degree of bending of the rod-shaped body 30 is not limited to the form shown in fig. 3, and may be set in a form different from that shown in fig. 3 by an experiment or the like.

The flange portion 42 is formed to have a large diameter in the middle of the rod-shaped body 30 and to protrude outward in the radial direction. Thus, in the assembled state, the annular member 32 is suspended from the flange portion 42, and downward movement of the annular member 32 can be restricted.

The rotation restricting portions 44 are formed to protrude outward in the radial direction at both end portions of the rod-shaped body 30. The 1 st rotation restricting portion 44a is located at an upper portion of the rod-shaped member 30, and the 2 nd rotation restricting portion 44b is located at a lower portion of the rod-shaped member 30. In the assembled state, the rotation restricting portion 44 abuts against the base 34 or the holder 36 to restrict the rotation of the rod-like body 30 about the axis. The flange portion 42 and the rotation restricting portion 44 may be formed integrally with the main body of the rod-shaped member 30, or may be formed separately from the main body of the rod-shaped member 30.

Returning to fig. 2. The annular member 32 surrounds and constrains the plurality of rods 30. The 1 st ring member 32a is suspended from the 1 st flange 42a, the 2 nd ring member 32b is suspended from the 2 nd flange 42b, and the 3 rd ring member 32c is suspended from the 3 rd flange 42 c. The diameter of the ring member 32 is reduced in the order of the 1 st ring member 32a, the 2 nd ring member 32b, and the 3 rd ring member 32 c. The annular member 32 may be an annular member having a predetermined diameter, or may be a member formed into an annular shape by fastening a wire or the like and fixing an end portion thereof with a fixing tool.

The plurality of rod-shaped bodies 30 are arranged so as to be equally spaced in the circumferential direction, and are provided so that the central portions of the support columns 10 bulge outward in the radial direction to define a long elliptical shape. Thus, when a load is applied to the upper portion of the support column 10, the rod-shaped bodies 30 can press the annular member 32 in the radial direction.

The base 34 is provided to support and erect lower portions of the plurality of bundled rod-shaped bodies 30. The base 34 has a plurality of fixing holes 34a for fixing to the floor and an insertion hole 34b into which the plurality of rod-shaped bodies 30 are inserted. The fixing holes 34a are formed at four corners of the base 34, and the base 34 is fixed to the ground by driving pins into the fixing holes 34 a.

The insertion hole 34b has a plurality of groove portions that engage with the 2 nd rotation restricting portion 44b of the rod-shaped member 30, and restricts the rotation of the rod-shaped member 30 about the axis. The insertion hole 34b may be formed individually for each rod-shaped body 30.

The holder 36 is formed in a disk shape and holds the upper end portions of the plurality of rod-shaped bodies 30. The holder 36 is formed with a plurality of rotation limiting holes 36a into which the upper end portions of the rod-shaped bodies 30 can be inserted. In the rotation restricting hole 36a, a groove portion that engages with the 1 st rotation restricting portion 44a of the rod-shaped member 30 is formed along the axial direction. The posture of the column 10 can be stabilized by holding the rod-shaped body 30 by the base 34 and the holder 36 and restricting the rotation of both end portions of the rod-shaped body 30.

One end of each of the support portions 38 is connected to the 1 st annular member 32a, and the other end is driven into the ground. The support portion 38 restricts upward movement of the 1 st annular member 32a, so that the 1 st annular member 32a is less likely to be separated upward. In fig. 2, the support portion 38 is provided on the 1 st ring member 32a, but the support portions 38 may be provided on the 2 nd ring member 32b and the 3 rd ring member 32c, respectively.

The retainer 36 is formed with a coupling portion 36b for coupling the main rope 12 to the strut 10. Further, a pulley 40 for suspending the working wire 14 is attached to the 3 rd ring member 32 c. Further, the pulley 40 may be attached to the holder 36. Further, another member for supporting the main cable 12 and the work cable 14 by the support column 10 may be provided at the upper portion of the support column 10.

The present invention has been described above with reference to the embodiments. The embodiments are merely examples, and those skilled in the art will understand that: various modifications are possible for the combination of the respective components and the respective processing steps, and such modifications are also within the scope of the present invention.

The embodiment shows a scheme in which the rod 30 is formed in an arcuate shape from a fiber material, but is not limited to this scheme. For example, the rod 30 may be formed of a metal material. The rod-shaped body 30 may be formed linearly. In any case, the column 10 is of an assembled type, and is easy to transport in a state before assembly.

In the embodiment, a plurality of rod-shaped bodies 30 are arranged in a long elliptical shape. In addition to the plurality of arcuate rod-shaped bodies 30, a linear rod-shaped body may be provided on the center axis of the support column 10. By connecting the upper end portion of the rod-shaped body of the central shaft to the upper end portion of the arcuate rod-shaped body 30, the support column 10 can be stabilized, and the load resistance can be improved.

In addition, in the embodiment, a scheme of using the support column 10 for the wire harness system 1 is shown, but the scheme is not limited to this, and may be used for other systems supporting the wire.