KR102918748B1 - Lightweight tublar pole type tower - Google Patents

Abstract

The present invention discloses a lightweight tubular steel tower. According to one embodiment of the present invention, a tubular steel tower is provided, wherein a plurality of plates including at least two or more bent or curved plates are continuously provided on both sides to form a column having an internal space, wherein the plates extend toward the internal space at least at one of the two ends and include a connecting portion having at least one fastening hole perforated therein, and adjacent plates are fastened with bolts through the fastening holes.

Description

Lightweight tubular pole type tower

The present invention relates to a lightweight tubular steel tower, and more particularly, to a lightweight tubular steel tower that can improve durability and facilitate transportation.

Typically, high-voltage electricity generated at power plants is transmitted to substations through transmission lines, and at each substation, the transmitted electricity is transformed and supplied to each region and consumer through wires.

Here, transmission lines are power facilities that supply high-voltage electricity produced at power plants to substations.

Transmission lines are constructed by supporting transmission lines on transmission towers installed along the power supply route. Typically, transmission towers are installed at an appropriate distance apart to stably support transmission lines, i.e. high-voltage power lines, between power plants and substations.

Additionally, since transmission towers are structures where power lines that transmit high-voltage electricity are installed, they are mainly installed in mountainous areas far from general facilities.

Transmission towers installed along power lines require a robust structure, as the tension of the power lines is extremely high. Traditionally, angle towers, constructed primarily of angles bolted together, were used. However, these towers are bulky, making installation space difficult and disrupting the surrounding landscape. Therefore, transmission towers utilizing tubular supports, or pipes, have recently been proposed and installed.

As a prior art patent document related to a column in the form of a tubular support used in a conventional transmission tower, there is Utility Model Publication No. 20-0387799 (June 15, 2005), which discloses a method of assembling a tubular support of a desired height by connecting a plurality of pipes extended vertically and horizontally using a flange joint and fastening method (flange fastening type).

Meanwhile, the general column form used in transmission towers as described above is a tubular support form, and can be constructed by connecting multiple cylindrical or square pipes using the flange fastening type mentioned above or a known slim assembly type.

However, conventional tubular supports used as columns in transmission towers have the following problems.

In order to construct a flange-fastened type or slip-assembled type tubular support, large pipes prefabricated in the factory must be transported to the installation site and then connected using equipment.

The pipes used to construct conventional tubular supports are thick and heavy, bulky materials.

Transmission towers are often installed in mountainous areas. Consequently, large pipes are often transported to mountainous areas, and their size and weight make transportation difficult.

In particular, pipes frequently have to pass through tunnels when transporting in mountainous areas. If the tunnel diameter is smaller than the pipe diameter, the pipes cannot be transported through the tunnel, forcing workers to find alternative routes, increasing transport time. Pipes may be transported through unpaved mountainous areas, bypassing tunnels. This necessitates constructing a paved transport route in the mountainous area, further increasing the cost and time required for pipe transport.

Furthermore, the joints between pipes are easily damaged or corroded by external factors (such as rain, snow, or dirt), weakening the joints. Therefore, tubular steel towers manufactured by connecting pipes are prone to defects in the joints due to external factors, weakening their durability.

Embodiments of the present invention aim to provide a lightweight tubular steel tower that can improve durability by preventing corrosion or defects from occurring even in a harsh external environment and is configured to be easily transported in mountainous areas.

According to one aspect of the present invention, a pipe may be provided, which includes at least two or more bent or folded plates, a connecting portion extending in one direction at at least one of both ends of the plates and having at least one fastening hole perforated therein, and a bolt fastened through the fastening hole.

Embodiments of the present invention can improve the durability of tubular steel towers that are always exposed to the outside, even in harsh external environments.

Additionally, embodiments of the present invention can be more easily transported in unpaved mountainous areas through reduced weight pipes and provide ease of passage through narrow tunnels, thereby reducing the effort of workers who search for alternative routes and pave routes.

Figure 1 is a perspective view showing an embodiment according to the present invention;
Figure 2 is an enlarged view of the flange nut and connecting part in the embodiment of Figure 1.
Figure 3a is a perspective view showing the pipes according to the present invention connected vertically.
Figure 3b is an internal perspective view of the above Figure 4a;
Figure 4 is a plan view showing another embodiment according to the present invention;
Figure 5 is a front view showing a tubular steel tower according to the present invention.

Hereinafter, a pipe according to an embodiment of the present invention will be described in detail with reference to the attached drawings.

FIG. 1 is a perspective view showing an embodiment (100) according to the present invention (pipe), showing a pipe (100) having a roughly cylindrical shape as a configuration forming a tubular steel tower.

The plate (110) is a component forming the pipe (100), and in the above embodiment (100), both ends of the plate (110) include a connecting portion (120) extending toward the inside of the pipe (100), and a pair of plates (110) are fastened through the connecting portion (120).

The shape of the above plate (110) is similar to the shape of a curved plate with a cross-section in the form of a round arc, so the pipe (100) may have a roughly cylindrical shape as in the above embodiment, but the shape of the plate is not necessarily limited thereto. That is, the plate may have an angular shape, and the pipe formed by connecting each plate may take the shape of a polygonal column with a cross-section in the form of a polygon.

The above connecting portion (120) is a configuration for fastening plates (110) and is provided on both ends of the plates (110). A plurality of plates (110) are in contact with each other at their respective side ends and surround a specific point, thereby forming a pipe (100) having a roughly columnar shape.

The above connecting portion (120) includes at least one fastening hole. In the above embodiment, a pair of plates (110) facing each other and having connecting portions (120) in contact are fastened by inserting bolts into each fastening hole, thereby forming a pipe (100) forming a tubular steel tower.

The above connecting portion (120) is formed on both ends of the plate (110) and is configured for fastening the plates (110), and is not limited to a shape protruding toward the inside of the pipe (100). However, in the above embodiment (100), the connecting portion (120) has a shape that is bent from the plate and extends in one direction. That is, the connecting portion extends in a direction toward the center in the cross section of the columnar pipe formed by fastening the plates.

For example, the pipe (100) illustrated in Fig. 1 is in the form of a cylinder, with a cross-section that represents a circle, and its center is the midpoint of the diameter (hereinafter referred to as the "center of the pipe"). Accordingly, in Fig. 1, the connecting portion (120) extends from both ends of the plate (110) in a direction toward the center of the circle.

In the above embodiment (100), as illustrated in FIG. 3b attached to the present application, the connecting portion (120) has a shape that is bent and extended from the plate (110), and extends from both ends of the plate (110) to a constant length from the upper and lower entire areas, so that the ends of the connecting portion (120) have a flat shape. That is, the connecting portion (120) in the above embodiment (100) does not have a shape that extends roughly in a rod shape only in a part from both ends of the plate (110). However, the shape of the connecting portion is not necessarily limited thereto, and thus, in other embodiments of the present invention, the shape in which the connecting portion extends may be formed in a long rod shape or a sawtooth shape. Therefore, in the above embodiment (100), the connecting portion (120) has a shape that extends in a shape similar to a narrow plate.

The connecting portion (120) extending toward the center of the pipe member is located inside the pipe member (100) formed by fastening the plates (110) and can be protected from the outside. The connecting portion is shielded from the outside by the plates, thereby preventing corrosion of the connecting portion due to rain, dust, etc. Accordingly, the fastening force of the pipe member is maintained, and the durability of the tubular steel tower formed by assembling the pipe member can be improved.

In addition, since the bolted connection is not visible from the outside due to the plate material, the aesthetic appearance of the tubular column tower formed by assembling the pipe material can be maintained. If the bolted connection is on the outside or exposed to the outside, the aesthetic appearance of the tubular column tower will be impaired, and the viewer will not be able to feel the aesthetic appeal of the tubular column tower. The pipe material of the present invention has the connection part in the internal space, so that the viewer can only see the surface of the plate material and not the rough and unclean connection part due to the bolted connection. Therefore, the tubular column tower formed of the pipe material of the present invention can maintain its aesthetic appearance by revealing a consistent and neat column shape with a flat surface.

In the above embodiment (100), the connecting portion (120) extends horizontally toward the center of the pipe (100), so that the connecting portions (120) that are fastened and in contact with each other within the pipe (100) do not include empty space.

If the connecting portion extends in a direction other than the center of the pipe, the connected portion may contain voids. Specifically, if the connecting portion extends toward the inner area of the plate, as shown in Fig. 1, the connected portion will have a roughly "V" shape when viewed from above by a worker, and will contain voids. Furthermore, the "inner area" of the plate refers to the space formed by stacking the plates around each other.

At least two or more plates, each of which includes a connecting portion at each end, may be joined through their respective connecting portions to form a tubular member similar to a column, enclosing a center and forming an internal space. The tubular member may be stacked from the ground as a component of a tubular steel tower supporting high-voltage power lines, forming a tubular steel tower having a roughly columnar shape.

Considering the stacking of the pipes, the upper and lower surfaces of the pipes (100) can be fastened so that the plates (110) are maintained in a flat state without being tilted, as shown in FIG. 1.

The above connecting portion (120) may include at least one fastening hole for strong fastening of the plates (110). In addition, the fastening holes may be formed in multiple numbers and perforated to form at least one row, so that the fastening force may be applied to a wider area, thereby improving the fastening force between the connecting portions (120).

In the above embodiment (100), the connecting portions (120) are provided on both ends of the plate (110) and are formed as a pair, and at least one connecting portion (120) is connected to a reinforcing portion (130) extending in a different direction. That is, the pair of connecting portions (120) have a shape extending in one direction toward the center of the pipe, and at least one connecting portion (120) additionally includes a reinforcing portion (130) extending in the other direction.

The above reinforcing portion (130) extends in the opposite direction compared to the one direction in which the connecting portion (120) extends, and in the above embodiment (100), the reinforcing portion (130) has a shape that is bent approximately perpendicular to the connecting portion (120) extending in one direction, so that the connecting portion (120) including the reinforcing portion (130) has an approximately 'L' shape as illustrated in FIG. 1.

The above reinforcing member (130) is a configuration for reinforcing the fastening between the plates (110), and is fastened to the reinforcing plate (140) described later to help maintain the joint structure of the plates (110) that are stably fastened even under a strong load.

*In addition, the above-described reinforcing member (130) not only strengthens the fastening force of the plates (110) but also enables pre-assembly of the reinforcing plate (140) to be described later, thereby reducing the labor of workers on site. That is, rather than fastening the reinforcing plate (140) to the reinforcing member (130) after a plurality of plates (110) are fastened at the work site, the plates (110) are transported with the reinforcing plate (140) fastened to the reinforcing member (130) before being transported to the work site after the plates (110) are manufactured, so that only fastening between the plates (110) is performed at the work site, thereby reducing the labor of fastening at the work site.

In addition, since the reinforcing plate (140) to be described later has a fastening hole formed in a square shape, even if a bolt is rotated and inserted into a flange nut (150) fastened to the fastening hole of the reinforcing plate (140), the flange nut (150) having a square body is engaged with the square fastening hole of the reinforcing plate (140), thereby preventing rotation of the flange nut (150).

In the above embodiment (100), the adjacent plates (110) have a reinforcing portion (130) formed only in one of the connecting portions (120) among a pair of connecting portions (120) that are in contact with each other as illustrated in FIG. 1. Therefore, the above embodiment (100) has a shape that appears to be point-symmetrical with respect to the center of the pipe (100). Since the pipe (100) to which the reinforcing portion (130) and the reinforcing plate (140) described later are connected is structurally point-symmetrical, the strong fastening force by the reinforcing portion (130) and the reinforcing plate (140) is not biased, so that the fastening force can be appropriately distributed throughout the pipe (100) and the structure of the pipe (100) can be stably preserved.

The reinforcing plate is configured to strengthen the connection between the plates, and is fastened to the connecting portion (120) in which the reinforcing portion (130) is formed, as shown in the embodiment illustrated in Fig. 1.

Although the type or shape of the above reinforcing plate is not limited, in the above embodiment (100), the reinforcing plate (140) having an ‘L’ shape is fastened to the connecting portion (120) and the reinforcing portion (130) to strengthen the fastening between the plates (110).

The present invention may further include a flange nut having a body having an angular shape to strengthen the fastening force between plates.

FIG. 2 is an enlarged view showing a flange nut (150) and a connecting portion (120) fastened to a connecting portion (120) in an embodiment (100) of the present invention. In consideration of engagement with the flange nut (150), the shape of the fastening hole into which the flange nut (150) is inserted is also square. Accordingly, the fastening hole of the flange nut (150) and the connecting portion (120) is formed in a square shape, thereby preventing rotation of the flange nut (150) and maintaining the fastening.

In addition, as illustrated in FIG. 2, in the embodiment (100) of the present invention, the longitudinal direction of the flange nut (150) is formed to be greater than the thickness of the connecting portion (120), thereby widening the fastening portion of the bolt and enhancing the fastening force. In order to enhance the fastening force of the bolt, the thickness of the connecting portion (120) may be increased, but considering the increase in weight due to the increase in the thickness of the connecting portion (120), the fastening force of the bolt may be enhanced by using a flange nut (150) that is longer than the thickness of the connecting portion.

The pipe according to the present invention may include a connecting portion extending in one direction on the upper and lower edges of the plate for vertical fastening, as illustrated in FIGS. 3a and 3b. This may extend toward the center of the pipe, similar to the connecting portion for fastening between plates, and a plurality of pipes may be stacked by being vertically bolted together.

The present invention is a pipe member formed by connecting at least two or more plates to each other through connecting portions formed at both ends. Accordingly, the embodiment (100) illustrated in FIG. 1 comprises a pipe member (100) composed of two plates (110), but the number of plates is not necessarily limited thereto and may range from 2 to N (N being a natural number greater than or equal to 3), and FIG. 4 illustrates a pipe member (200) composed of four plates (210).

As shown in FIG. 4 attached to the present application, when the pipe member (200) is composed of four plates (210), the pipe member (200) has a shape that appears to be divided into four. In addition, since the aforementioned connecting portions are provided on both ends of each plate, the pipe member (200) shown in FIG. 4 is provided with a total of eight connecting portions and is formed by fastening each plate (210).

In addition, in the embodiment illustrated in the above-described Figure 4, the flange nut is not inserted into the connecting portion of the plate (210), but is inserted into only the reinforcing plate. Therefore, the fastening force of the plate (210) can be strengthened by holding the bolt inserted into the connecting portion through the short flange nut.

According to the present invention, a plurality of pipes (100) may be sequentially stacked from the ground to form a tubular steel tower (1000). A plurality of pipes (100) may form one column, and a single pipe (100) may be positioned in one row, thereby forming one tubular steel tower (1000), as illustrated in FIG. 5.

Above, one embodiment of the present invention has been described, but a person having ordinary skill in the art will be able to modify and change the present invention in various ways by adding, changing, deleting or adding components, etc., within the scope that does not depart from the spirit of the present invention described in the claims, and this will also be considered to be included within the scope of the rights of the present invention.

Additionally, the aforementioned terms are defined based on their functions within the present invention, and may vary depending on the intent or custom of the user or operator. Therefore, the definitions of these terms should be based on the contents throughout this specification.

Additionally, when the present invention refers to a component as "including", it does not exclude other components unless specifically stated otherwise, but rather means that other components may be included.

100, 200: Official
110, 210: Sheet
120: Connection
130: Reinforcement
140: Reinforcement plate
150: Flange nut
1000: Tubular steel tower

Claims (1)

A column having an internal space formed by a plurality of the above plates being continuously provided on both sides, including at least two or more plates that are bent or folded;
A pair of connecting portions extending toward the internal space and having at least one fastening hole perforated are respectively arranged on both ends of the above plate, and the adjacent plates are fastened with bolts through the fastening holes.
A reinforcing member is formed at the end of one of the above pair of connecting members, which is bent vertically and extends in one direction, and at least one fastening hole is perforated in the reinforcing member.
A reinforcing plate having at least one fastener perforated therein and having at least one bend;
The above reinforcing plate is placed at the connecting portion where the reinforcing portion is formed among the pair of connecting portions,
A tubular steel tower in which a plurality of pipes are laminated from the ground to form at least one row, wherein the reinforcing plate is in contact with the connecting portion and the reinforcing portion, and bolts are inserted into the fastening holes of the connecting portion and the reinforcing portion and the fastening holes of the reinforcing plate to fasten them.