KR102606521B1 - Earth leakage prevention device for transmission lines and steel towers and its installation method - Google Patents

Abstract

The present invention relates to an electric leakage prevention device for power transmission lines and steel towers and a method of installing the same. More specifically, it relates to a method of installing an earth leakage prevention device that is provided on a steel tower and prevents electric leakage from occurring by supporting a cable that is a transmission line. Installation step of the steel tower safety locking part to prevent tools or parts from falling during the process of installing the electric leakage prevention device by further installing a safety locking part consisting of safety shafts and a safety net on the lower side of the installation location where the electric leakage prevention device is installed. and an electric leakage prevention device installation step of installing an earth leakage prevention device on the steel tower to support the cable, which is a transmission line, and applying an external force to the earth leakage prevention device installed on the tower to check whether it is separated from the tower and whether it moves. It consists of a prevention device installation inspection step and an electric leakage prevention device cable connection step of connecting the cable, which is a transmission line, to the electric leakage prevention device installed on the steel tower. One end of the safety shafts is screwed and fixed to the tower, and The safety net connects the safety sharps and is screwed and fixed. In the installation stage of the steel tower electric leakage prevention device, the work situation on site is identified by continuous confirmation work guidance means, and a continuous confirmation work guidance stage is provided to transmit a danger signal when an emergency situation occurs. It is further included to stably support and secure the transmission line, preventing it from being derailed or moved from the tower by wind or external forces, thereby improving the convenience and safety of maintenance, ensuring reliability in power supply. It has the effect of increasing.

Description

Earth leakage prevention device for transmission lines and steel towers and its installation method { Earth leakage prevention device for transmission lines and steel towers and its installation method }

The present invention relates to a device for preventing electric leakage of power transmission lines and pylons in the field of power transmission technology and to an installation method thereof. More specifically, the present invention relates to a device for preventing electric leakage of power transmission lines and pylons, and more specifically, to stably support and fix power transmission lines to prevent them from being derailed or moved from the pylon by wind or external forces. It relates to a device for preventing electric leakage of power transmission lines and towers and a method of installing the same, which improves the reliability of power supply by preventing and improving the convenience and safety of maintenance.

In general, the shape of the steel tower used as a support for transmission lines varies depending on the transmission power, voltage, and topography of the line, and some are as high as 60m.

The steel tower of a transmission line usually supports two three-phase lines, or six wires, with insulators.

The distance between steel towers is 20 to 30 m, and the minimum height from the ground level of overhead wires installed on steel towers is determined by electrical equipment technology. For example, in the case of a 150,000 V overhead line, the minimum height is 6 m from the ground.

Usually, when a track crosses a wide river or a deep valley, the span is long and the tension of the wire increases, so a particularly strong structure is needed.

Even for power transmission lines, there are small-scale ones, or pontoons that are built on a single foundation as support for distribution or telephone lines.

These transmission line steel towers connect multiple transmission lines to each other, and due to the nature of these overhead transmission lines being installed at high altitudes, they are greatly affected by climate such as wind, snow, and rain, and are therefore installed under conditions where vibration or amplitude is likely to occur. do.

Therefore, after a certain period of time, a sagging phenomenon occurs in the transmission lines, which causes the transmission lines to shake violently up and down when a strong wind blows, causing friction between them, as well as causing major safety accidents such as short circuits or power outages.

In addition, external forces or wind cause the transmission line to rub against the tower and the covering is peeled off, causing safety accidents due to short circuits and the inconvenient problem of frequent maintenance.

The above-described invention refers to the background art of the technical field to which the present invention pertains, and does not mean prior art.

Registered Patent No. 10-0904199

The present invention was devised to solve the above-described conventional problems. The present invention stably supports and fixes the transmission line, preventing it from being moved by friction with the steel tower due to wind or external force, or the coating being peeled off due to friction, thereby preventing electric leakage. The purpose is to provide a leakage prevention device and installation method for transmission lines and towers that improve reliability in power supply by preventing occurrence of leakage and improving convenience and safety in maintenance.

The present invention is a method of installing an electric leakage prevention device that is provided on a steel tower, supports a cable that is a transmission line, and is made of an insulator to prevent electric leakage from occurring. Safety shafts are installed below the installation location where the electric leakage prevention device is installed on the tower. A step of installing a safety locking part on a steel tower to prevent tools or parts from falling during the process of installing the electric leakage prevention device by further installing a safety locking part made of a safety net, and installing an electric leakage prevention device to support the cable, which is a transmission line, on the steel tower. An electric leakage prevention device installation step, an electric leakage prevention device installation inspection step of applying an external force to the electric leakage prevention device installed on the tower to check whether it is separated from the tower and whether it moves, and a transmission line to the electric leakage prevention device installed on the tower. It consists of a cable connection step with an electric leakage prevention device connecting the cables, one end of the safety shafts is screwed and fixed to the tower, the safety net connects the safety shafts and is screwed and fixed, and the tower prevents electric leakage. The prevention device installation step is characterized by further including a continuous confirmation work guidance step to identify the work situation on site by means of continuous confirmation work guidance means and to transmit a danger signal when an emergency situation occurs.

The present invention is an electric leakage prevention device that is provided on a steel tower, supports a cable that is a transmission line, and is made of an insulator to prevent electric leakage from occurring, comprising: a bracket member whose one side is connected to and fixed to the lower part of a suspension rock formed on the transmission tower; A connection support bar whose upper end is connected and fixed to the bottom of the bracket member installed on the transmission tower, a fixation frame unit connected to and fixed to the lower end of the connection support bar connected to the bracket member, and the fixation frame unit connected to the connection support bar. It consists of a connecting frame member fitted and fixed inside, an elastic cushioning ring fitted and fixed inside the connecting frame member and into which the cable is inserted, and the bracket member supports the fixing frame unit into which the cable is inserted. In addition, a retractable guide support means is further provided for fixation, and the retractable guide support means includes an extension shaft whose ends are connected and fixed to the bracket member, and each of the extension shafts fastened to the bracket member. It consists of an interval shaft whose upper end is respectively connected and fixed to the bottom surface, an upper end of which is connected and fixed to the lower end of the interval shaft fastened to the extension shaft, and an angle cap that supports the upper part of the fixing frame unit, wherein the angle cap is the above. It is characterized in that the connecting frame member into which the cable is inserted supports and fixes the fastened fixed frame unit.

The present inventor's device for preventing electric leakage of transmission lines and steel towers and its installation method stably supports and fixes transmission lines to prevent them from being derailed or moved from the tower by wind or external forces, thereby improving the convenience and safety of maintenance. This has the effect of increasing the reliability of power supply.

Figure 1 is a diagram showing the installed state of the electric leakage prevention device of the transmission line and steel tower according to the present invention.
Figure 2 is a diagram showing an electric leakage prevention device for a transmission line and steel tower according to the present invention.
Figure 3 is a cross-sectional view showing a device for preventing electric leakage of a transmission line and steel tower according to the present invention.
Figure 4 is a diagram showing a retractable guide support means in the electric leakage prevention device for transmission lines and steel towers according to the present invention.
Figure 5 is a diagram showing a state in which a cable is connected to an electric leakage prevention device for a transmission line and a steel tower according to the present invention.
Figure 6 is a diagram showing the elastic buffer support means of the electric leakage prevention device for transmission lines and steel towers according to the present invention.
Figure 7 is a diagram showing the continuous confirmation work guidance means of the electric leakage prevention device of the transmission line and steel tower according to the present invention.
Figure 8 is a diagram showing another embodiment of the continuous confirmation operation guide means for the electric leakage prevention device of the transmission line and steel tower according to the present invention.
Figure 9 is a conceptual diagram showing the continuous confirmation work guidance means of the electric leakage prevention device of the transmission line and steel tower according to the present invention.

Since the description of the present invention is only an example for structural or functional explanation, the scope of the present invention should not be construed as limited by the examples described in the text. In other words, since the embodiments can be modified in various ways and can have various forms, the scope of rights of the present invention should be understood to include equivalents that can realize the technical idea.

Meanwhile, the meaning of the terms described in the present invention should be understood as follows.

Terms such as “first” and “second” are used to distinguish one component from another component, and the scope of rights should not be limited by these terms. For example, a first component may be named a second component, and similarly, the second component may also be named a first component.

When a component is said to be “connected” to another component, it should be understood that it may be directly connected to the other component, but that other components may also exist in between. On the other hand, when a component is referred to as being “directly connected” to another component, it should be understood that there are no other components in between. Meanwhile, other expressions that describe the relationship between components, such as "between" and "immediately between" or "neighboring" and "directly neighboring" should be interpreted similarly.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as “comprise” or “have” refer to implemented features, numbers, steps, operations, components, parts, or them. It is intended to specify the existence of a combination, and should be understood as not excluding in advance the possibility of the presence or addition of one or more other features, numbers, steps, operations, components, parts, or combinations thereof.

For each step, identification codes (e.g., a, b, c, etc.) are used for convenience of explanation. The identification codes do not explain the order of each step, and each step clearly follows a specific order in context. Unless specified, events may occur differently from the specified order. That is, each step may occur in the same order as specified, may be performed substantially simultaneously, or may be performed in the opposite order.

All terms used herein, unless otherwise defined, have the same meaning as commonly understood by a person of ordinary skill in the field to which the present invention pertains. Terms defined in commonly used dictionaries should be interpreted as consistent with the meaning they have in the context of the related technology, and cannot be interpreted as having an ideal or excessively formal meaning unless clearly defined in the present invention.

Figure 1 is a diagram showing the installed state of the electric leakage prevention device of the transmission line and steel tower according to the present invention. Figure 2 is a diagram showing an electric leakage prevention device for a transmission line and steel tower according to the present invention. Figure 3 is a cross-sectional view showing a device for preventing electric leakage of a transmission line and steel tower according to the present invention. Figure 4 is a diagram showing a retractable guide support means in the electric leakage prevention device for transmission lines and steel towers according to the present invention. Figure 5 is a diagram showing a state in which a cable is connected to an electric leakage prevention device for a transmission line and a steel tower according to the present invention. Figure 6 is a diagram showing the elastic buffer support means of the electric leakage prevention device for transmission lines and steel towers according to the present invention. Figure 7 is a diagram showing the continuous confirmation work guidance means of the electric leakage prevention device of the transmission line and steel tower according to the present invention. Figure 8 is a diagram showing another embodiment of the continuous confirmation operation guidance means of the electric leakage prevention device of the transmission line and steel tower according to the present invention. Figure 9 is a conceptual diagram showing the continuous confirmation work guidance means of the electric leakage prevention device of the transmission line and steel tower according to the present invention.

As shown in the drawing, the present invention's electric leakage prevention device 10 for transmission lines and steel towers (hereinafter referred to as earth leakage prevention device for convenience of explanation) is provided on the tower, supports the cable 200, which is a transmission line, and is an insulator or insulator. It is an electric leakage prevention device (10) made of material to prevent electric leakage from occurring. Accordingly, such electric leakage prevention device (10) includes a bracket member (20), a connecting support bar (30), a fixing frame unit (40), and a connecting frame member. It consists of (50) and an elastic cushioning ring (60). Hereinafter, in order to prevent electric leakage, it is natural that it is made of an insulator, so redundant explanation will be omitted.

The bracket member 20 is fixed to the lower part of the suspension rock formed on the transmission tower 100 by screwing its upper surface.

The bracket member 20 has a panel structure and is made of metal or synthetic resin.

The connection support bar 30 is fixed by screwing its upper end to the bottom of the bracket member installed on the transmission tower 100.

The connection support bar 30 is formed in a circular or square bar shape and is made of metal or synthetic resin.

The fixing frame unit 40 is screwed and fixed to the lower end of the connecting support bar 30 connected to the bracket member 20.

The fixing frame unit 40 is formed in a circular frame structure, and is made of metal or synthetic resin.

The connecting frame member 50 is fitted and fixed inside the fixing frame unit 40 connected to the connecting support bar 30.

The connecting frame member 50 is formed as a circular frame structure and is made of metal or synthetic resin.

The connecting frame member 50 is inserted into the connecting frame member 50 and then fixed by screwing.

Here, a ring bearing is press-fitted into the fixing frame unit 40 and the connecting frame member 50 is inserted into the ring bearing to rotate, so that the cable 200 and the connecting frame member ( 50) are preferably rotated together to reduce friction between the cable and the connecting frame member 50.

The elastic cushioning ring 60 is made of an elastic synthetic resin material, is fitted and fixed inside the connecting frame member 50, and is inserted through the cable 200.

The elastic cushioning ring 60 is inserted into the connecting frame member 50 and then fixed by adhesive or screw fastening.

The elastic cushioning ring 60 is formed into a circular ring structure.

That is, the elastic cushioning ring 60, the connecting frame member 50, and the fixing frame unit 40 support the cable 200 to prevent it from being moved by wind or external force.

In addition, the elastic shock ring 60 is made of an elastic synthetic resin material to cushion the impact and prevent the coating of the cable 200 from being damaged or peeled off due to friction, thereby preventing the cable 200 from being moved by external force. This prevents the sheath of the cable 200 from being damaged or peeled off due to excessive friction and causing a short circuit.

In addition, the cable 200 is inserted into the support frame member and the elastic cushioning ring 60 so that when the connecting frame member 50 is damaged, the fixation frame unit 40 is connected to the cable ( 200) is supported to prevent the cable 200 from moving again, and external shock can be cushioned.

The bracket member 20 is further provided with retractable guide support means 70 to support and fix the fixing frame unit 40 into which the cable 200 is inserted.

The retractable guide support means 70 includes an extension shaft 71 whose ends are screwed and fixed to both sides of the bracket member 20, and an extension shaft 71 fastened to the fixing frame unit 40. A spacing shaft 72 whose upper end is screwed and fixed to the bottom, an upper end of which is screwed and fixed to the lower end of the spacing shaft 72 fastened to the extension shaft 71, and the upper side of the fixing frame unit 40. It consists of an angle cap 73 of an angle structure that is inserted into the corner and supports the upper part of the fixing frame unit 40, and the angle cap 73 is connected to the connecting frame member 50 into which the cable 200 is inserted. By supporting and fixing the fastened fixation frame unit 40, the cable and the fixation frame unit 40 are prevented from moving due to external force or wind, and the support and fixation power of the cable are improved.

Here, an elastic pad made of an elastic synthetic resin material is further attached and fixed to the inner surface of the angle cap 73, thereby cushioning the transmission of shock to the fixing frame unit 40 by the elasticity of the elastic pad and friction. It is desirable to prevent this from happening.

Here, the connecting frame member 50 is further provided with pressure-type elastic support fixing means 80 to press and secure the inserted cable 200 by elasticity and support it.

The pressure-type elastic support fixing means 80 includes an operating groove 81 formed on the inner surface of the connecting frame member 50, and an elastic pressure coil whose one end is inserted into the operating groove 81 and fixed by screwing. A spring 82, a pressure panel 83 whose one side is screwed and fixed to the other end of the elastic pressure coil spring 82, and a synthetic resin material with elasticity that is attached and fixed to the other side of the pressure panel 83. It consists of an elastic pressure support panel 84 and an inlet groove 85 formed on the front part of the elastic pressure support panel 84 so that a part of the cable 200 is inserted, and the elastic pressure coil spring 82 It is preferable to press and support the cable 200 by the elasticity of the elastic pressure support panel 84 to prevent it from being moved by external force and to cushion the transmission of external force or vibration.

The method of installing the electric leakage prevention device (10) of the transmission line and steel tower configured as described above further installs a safety lock consisting of safety shafts and a safety net below the installation position where the electric leakage prevention device (10) is installed on the tower, Step (S1) of installing a steel tower safety lock to prevent tools or parts from falling during the installation of the earth leakage prevention device (10), and installing the earth leakage prevention device (10) to support the cable, which is a transmission line, on the tower. The steel tower earth leakage prevention device 10 goes through the installation step (S2).

Afterwards, an external force is applied to the electric leakage prevention device 10 installed on the steel tower to check whether it is separated from the tower and whether it is moved (S3), and the electric leakage prevention device 10 installed on the tower ( By going through the cable connection step (S4) of the electric leakage prevention device 10, which connects the cable, which is a transmission line, to 10), a series of processes are completed.

One end of the safety shafts is screwed and fixed to the tower, and the safety net connects the safety shafts and is screwed and fixed.

The safety net is formed into a net structure made of synthetic fiber material or metal material.

At this time, in the steel tower electric leakage prevention device installation step (S2), the continuous confirmation work guidance step (S2-1) is performed to determine the work situation on site by the continuous confirmation work guidance means (90) and to transmit a danger signal when an emergency situation occurs. More included.

The continuous confirmation operation guide means 90 includes a connection fixing module unit 91 that is screwed and fixed to the transmission tower 100, and a lower end connected to the upper surface of the connection fixing module unit 91. A pair of guide shafts 92, a first panel transfer module 931, a second panel transfer module 932, and a first panel transfer module 931 and a second panel transfer module 932 that are inserted through the guide shaft 92 and are guided along the guide shaft 92. A transfer module unit 93 consisting of three panel transfer modules 933 and a lower end are screwed and fixed to the upper surface of the connection fixing module unit 91, and the lifting shaft is attached to the bottom of the first panel transfer module 931. A first lifting guide unit 941 is screwed and fixed to the upper surface of the first panel transfer module 931, and the lower part is screwed and fixed to the upper surface of the first panel transfer module 931, and the lifting shaft is fixed to the bottom of the second panel transfer module 932. A second lifting guide unit 942 is screwed and fixed, and a lower end is screwed and fixed to the upper surface of the second lifting guide unit 942, and the lifting shaft is fixed to the bottom of the third panel transfer module 933. A lifting guide unit 94 consisting of a third lifting guide unit 943 that is screwed and fixed to the bottom of the first panel transfer module 931 and screwed and fixed to the bottom of the first panel transfer module 931, and a first rotation module unit ( The first rotation guide units 951 (951-1) are screwed together, the second panel transfer module (932) is screwed and fixed to the bottom, and the second rotation module unit (952-1) is screwed to the rotation axis. The third rotation guide unit (952) and the third panel transfer module (933) are screwed and fixed to the bottom and the third rotation module unit (953-1) is screwed to the rotation axis. 953), first situation photography units 961 screwed and fixed to the bottom of the first rotation module unit 951-1, and the second rotation module unit (953). Second situation photography units 962 that are screwed and fixed to the bottom of the third rotation module unit (953-1), and a third situation photography unit (963) that is screwed and fixed to the bottom of the third rotation module unit (953-1). It is screwed and fixed to the situation photographing unit 96 and the connection fixing module unit 91, and is electrically connected to and controlled by the lifting guide unit 94 and the rotation guide unit 95. A control unit 97 that receives shooting information of the first situation photography unit 961, the second situation photography unit 962, and the third situation photography unit 963, and a screw on the third panel transfer module 933. A transmitting and receiving unit that is fastened and fixed and transmits the shooting information of the first situation photography unit 961, the second situation photography unit 962, and the third situation photography unit 963 transmitted from the control unit 97. It consists of (98) and a status information speaker (99) that is screwed and fixed to the third panel transfer module (933) and receives a signal from the control unit (97) to guide a voice or generate an alarm.

The connection fixing module unit 91 is made of a panel structure made of metal and is placed on the ground.

The first panel transfer module 931, the second panel transfer module 932, and the third panel transfer module 933 are formed of metal or synthetic resin panels and are inserted into the guide shaft 92. A transfer hole is formed.

The first lifting guide unit 941, the second lifting guiding unit 942, and the third lifting guiding unit 943 are cylinders, and the first rotating guiding unit 951 and the second rotating guiding unit ( 952) and the third rotation guide unit 953 are motors, and the first situation photography units 961, the second situation photography units 962, and the third situation photography unit 963 are cameras.

Additionally, the first rotation module unit 951-1, the second rotation module unit 952-1, and the third rotation module unit 953-1 are formed in a circular or square panel structure.

The first situation photography units 961, the second situation photography units 962, and the third situation photography units 963 include the first lifting and lowering guidance unit 941 and the second lifting and lowering guidance unit 942. ) and the driving of the third lifting guide unit 943, the height can be changed, and it is possible to take pictures of field conditions or risk factors on the ground or ground.

The control unit 97 receives the signal received from the transmitter and receiver 98 through the administrator terminal and controls the status guide speaker 99 to transmit a voice or generate an alarm.

In other words, after recognizing the dangerous situation of the phenomenon through the shooting information, it is possible to prevent safety accidents in the field by transmitting a dangerous signal through the status information speaker 99.

In addition, the control unit 97 receives the signal received from the transmitting and receiving unit 98 through the administrator terminal and controls the operation of the lifting guide unit 94 and the rotation guiding unit 95, The positions of the situation photography units 961, the second situation photography units 962, and the third situation photography unit 963 can be changed.

Although the present invention has been described in detail so far, it is clear that the embodiments mentioned in the process are only illustrative and not limiting, and that the present invention is limited to the technical idea or field of the present invention provided by the following patent claims. Changes in components to the extent that they can be handled equally, within the scope of the above, will fall within the scope of the present invention.

10: Earth leakage prevention device 20: Bracket member
30: Connection support bar 40: Fixed frame unit
50: Connection frame member 60: Elastic buffer ring
70: Retractable guide support means 71: Extension shaft
72: Spacing shaft 73: Angle cap
80: Pressurized elastic support fixing means 81: Operating groove
82: elastic pressurizing coil spring 83: pressurizing panel
84: Elastic pressure support panel 85: Inlet groove
90: Continuous confirmation work guidance means 91: Connection fixing module unit
92: Guide shaft 93: Transfer module part
931: 1st panel transfer module 932: 2nd panel transfer module
933: Third panel transfer module 94: Elevating guide unit
941: 1st lifting guide unit 942: 2nd lifting guide unit
943: Third lifting guide unit 95: Rotation guide unit
951: 1st rotation guide unit 951-1: 1st rotation module unit
952: 2nd rotation guide unit 952-1: 2nd rotation module unit
953: Third rotation guide unit 953-1: Third rotation module unit
96: situation photography unit 961: first situation photography unit
962: Second situation photography unit 963: Third situation photography unit
97: Control unit 98: Transmitting and receiving unit
99: Status information speaker 100: Transmission tower
200: cable

Claims (2)

delete It is an electric leakage prevention device that is installed on the transmission tower, supports the cable that is the transmission line, and is made of insulator to prevent electric leakage from occurring.
A bracket member whose one side is connected to and fixed to the lower part of the suspension rock formed on the transmission tower;
A connection support bar whose upper end is connected and fixed to the bottom of the bracket member installed on the transmission tower,
A fixing frame unit connected to and fixed to the lower end of the connection support bar connected to the bracket member,
A connecting frame member fitted and fixed inside the fixing frame unit connected to the connecting support bar,
It is fixed to the inside of the connecting frame member and consists of an elastic cushioning ring into which the cable is inserted,
The bracket member is further provided with retractable guide support means to support and fix the fixing frame unit into which the cable is inserted,
The retractable guide support means,
An extension shaft consisting of two pieces, each end of which is connected and fixed to both sides of the bracket member;
an interval shaft whose upper end is connected to and fixed to each bottom surface of the extension shaft fastened to the bracket member;
The upper end is connected to and fixed to the lower end of the spacing shaft fastened to the extension shaft, and consists of an angle cap supporting the upper part of the fixing frame unit,
The angle cap supports and secures the fixing frame unit to which the connecting frame member with the cable is inserted,
The connection frame member is further provided with pressure-type elastic support means to press and secure the inserted cable by elasticity and support it,
The pressurized elastic support fixing means,
An operating groove formed on the inner surface of the connecting frame member,
An elastic pressurizing coil spring, one end of which is inserted into the operating groove and fixed by screwing,
A pressurizing panel whose one side is screwed and fixed to the other end of the elastic pressurizing coil spring;
an elastic pressure support panel made of an elastic synthetic resin material that is attached and fixed to the other surface of the pressure panel;
Consisting of a lead-in groove formed on the front part of the elastic pressure support panel to allow a part of the cable to be led in,
A transmission line that presses and supports the cable by the elasticity of the elastic press coil spring and the elastic press support panel, preventing movement by external force and buffering the transmission of external force or vibration. Electric leakage prevention device for furnaces and pylons.