KR102228197B1 - Tower for supporting overhead line of electric power transmission and distribution - Google Patents

Abstract

The present invention relates to a pylon equipped with a tension balance maintenance control device of an overhead distribution line which extends the safety and lifespan of the pylon by maintaining balance of left and right tensions. The pylon equipped with the tension balance maintenance control device of the overhead distribution line comprises a first tension control piston, a second tension control piston, a third tension control piston, a first tension control triangle lever, a second tension control triangle lever, and a tension control unit.

Description

Tower for supporting overhead line of electric power transmission and distribution}

The present invention relates to a steel tower equipped with a tension balance control device of an overhead distribution line among the technologies in the power distribution field, and more specifically, to independently monitor the tension of the distribution lines installed on the left and right sides of the pylon, and balance the tension. Maintaining the balance of the tension of the overhead power distribution line that increases the safety and life of the steel tower by maintaining the connection strength of each junction stably and maintaining the balance of the left and right tensions by independently adjusting the support position of the jump line while adjusting the respective tension so that the corresponding tension is maintained. It relates to a pylon equipped with a control device.

In general, electricity generated in a power plant is transformed into high-voltage, extra-high-voltage, or ultra-high voltage electricity suitable for transmission at a substation, and is transmitted to a destination through an overhead electric wire fixedly supported in an insulated state through a number of insulators on a pylon installed at regular intervals on the ground. .

A pylon that supports the transmission path of electricity in the air must be installed in a long span with the standard tower used for the standard span, depending on the length of the span (the distance between the tower and the wire support points between the pylon and other standards). It is classified as a special steel tower that is installed in places where the use of the steel tower cannot be used.

Standard pylons are divided into square pylons, square pylons, gantry towers, headed pylons, rotating pylons, and MC (Motor Columbus) pylons.

In addition, according to the purpose of use, it is divided into straight tower, angle tower, anchor tower, and strain tower.

In the case of Korea, among the standard steel towers that are generally applied to short spans, square steel towers designed to have the same strength as the direction of the electric wire path are mainly used, because the design is easy and the safety is high.

Square steel towers have four main posts that are fixed by anchor material in a concrete block at the bottom of the ground, a horizontal material and a sand material that connects and reinforces the main material, an auxiliary material for reinforcement, and horizontally installed on the main material. It consists of a plurality of arms (Arm).

Both ends of an overhead transmission line are supported in an insulated state at the bottom of a suspension insulator installed on the arm of an adjacent steel tower.

In this way, the overhead transmission line supported by the transmission tower is stretched and contracted according to changes in temperature, resulting in a change in tension. That is, in summer, it is elongated due to high temperature, and in winter, it is contracted due to low temperature, resulting in a change in tension.

Therefore, conventionally, as shown in FIG. 1, the tension relief device 20 is mounted on the arm 10 of the transmission tower, and the connection member 21 provided in the tension relief device 20 is connected to the insulator 22 through an insulator 22. Tension relief device for transmission tower of overhead transmission line that connects the overhead transmission line 30 and adjusts the tension applied to the overhead transmission line 30 by pulling the overhead transmission line 30 when the temperature is high and loosening the overhead transmission line when the temperature is low. Is being used.

However, the conventional tension relief device is prone to damage due to long-time use and external force, and cannot promptly respond because it is not possible to immediately check whether the damage has occurred, and there is a problem in that the damaged state persists and affects power transmission.

According to the Korean Patent Registration No. 10-0809063 (registered on February 25, 2008) as a conventional technology that partially improved these problems, it is installed on the arm member of the transmission tower according to the "Tension Relief Device for Transmission Towers of Overhead Transmission Lines". In the tension relief device connected to the insulator arranged at the rear to adjust the tension of the overhead wire connected to the insulator, the cylinder is installed on the arm member so that the rear end faces the insulator; A piston that divides the insertion part into a gas receiving part in the rear and a first spring receiving part in the front, a gas that is accommodated in the gas receiving part and pressurizes the piston to advance, and a first spring installed in the first spring receiving part to pressurize the piston to retreat , Tension control mechanism consisting of a connecting member with one end connected to the rear of the piston and the other end extended to the rear of the piston and connected to the insulator; a locking groove is formed at the tip, and a warning plate and a warning plate are rotated in which the base end is rotatably fixed to the cylinder. A display device composed of an elastic member that elastically supports it to be installed; a light-emitting lamp installed on a warning sign or cylinder; a control unit that controls the operation of the light-emitting lamp; a detection sensor connected to the control unit; a protrusion is provided at one end and the warning sign is caught at the other end A locking protrusion is formed to horizontally fix the warning plate by meshing with the groove, and a locking member that is slidably installed on the cylinder to turn on the detection sensor when reversing, and a second spring that is connected to the locking member to elastically press the locking groove and the locking jaw to engage with each other. Locking mechanism consisting of; A long hole is formed on the outer surface in the longitudinal direction, one end is fixed to the front of the piston, the other end is a moving member that extends outside the cylinder, fixedly coupled to the fixing hole so that the position is movable, and pressing the protrusion when reversing the locking member A locking release mechanism consisting of a contact member that moves the device in the rearward direction; by using the expansion force of the gas, automatically adjusting the tension of the overhead wire, and in case of damage, it can be immediately recognized from the outside, so that it can be quickly restored. There is an advantage.

In addition, according to the “line tension maintenance device for transmission and distribution pylons” of Korean Patent Registration No. 10-0978139 (registered on August 19, 2010) as another improved conventional technology, it is installed on one side of the pylon to adjust the tension of the distribution line. unit; Optical signal main modules respectively installed on one side and the other side of the pylon to which both ends of the distribution line are connected; A tension sensing unit including an optical signal auxiliary module and a light reflection module installed on the line; A control unit for driving the driving unit according to the sensing information in the tension sensing unit; It automatically detects when deflection of the line occurs by the characteristic of the line, and by pulling the line so that the line is maintained at an appropriate tension, it effectively prevents the occurrence of a short circuit and power failure due to the line's sag, and one side of the line to maintain the tension of the line. When the end is pulled, there is an advantage that safe maintenance of the line is possible by preventing the line from being pulled excessively.

The distribution line consists of left and right distribution lines supported by suspension insulators on the left and right sides of the pylon, and jump lines connecting each distribution line.The improved prior technologies only consider the tension of each distribution line, and each distribution line is too stretched, so the corresponding distribution line In the case of increasing the tension by pulling, the jump line connecting each distribution line is stretched and the jump line is violently shaken by the influence of the wind, and the power is concentrated at the connection part of the jump line, resulting in poor connection or dropout.

In addition, when the tension of the left and right distribution lines increases and it is necessary to relieve the tension, the tension of the jump line increases, and the increased tension of the jump line is concentrated in the connection part with the distribution line, causing connection failure or dropout. have.

On the other hand, it is possible to consider a method of fixing the upper end of the LP insulator to the arm of the steel tower and supporting the jump line at the bottom of the LP insulator, but in this case, the jump line is stretched because the support point of the jump line by the LP insulator is at a fixed position. There remains a problem in that the jump line is not supported smoothly because it is not possible to adequately cope with the increase in the and tension. In addition, if the tension of the left and right distribution lines is kept constant or the balance is not maintained, it can be a serious problem in the stability of the pylon.

Therefore, it is necessary to develop a technology that increases the stability line of the pylon while being able to adjust the tension of the left and right distribution lines, and supporting the jump line at an appropriate position according to the situation.

Republic of Korea Patent Registration No. 10-0809063 (Registered on February 25, 2008) "Tension relaxation device for transmission tower of overhead transmission line" Republic of Korea Patent Registration No. 10-0978139 (registered on August 19, 2010) "Tension maintenance device for transmission and distribution pylons" Republic of Korea Patent Registration No. 10-1782937 (registered on September 22, 2017) "Steel tower structure fixing the processing distribution line"

The present invention conceived to solve the problems and necessity of the prior art as described above is to control the tension of the left and right distribution lines, respectively, and appropriately adjust the position and tension of the jump lines connected to the distribution lines to stably maintain the distribution lines while maintaining the stability of the pylons. It is an object of the present invention to provide a steel tower equipped with a tension balance control device for an overhead distribution line that improves stability and safety.

The present invention provides a steel tower structure for fixing an overhead distribution line that adjusts the tension of the left distribution line and the tension of the right distribution line differently and adjusts the tension of the left and right distribution lines regardless of the tension control of the left and right distribution lines even when the support position of the jump line is adjusted. That is the purpose.

The pylon 900 provided with the tension balance control device of the overhead distribution line of the present invention devised to achieve the above object and necessity is suspended left and right on both sides of the pylon arm (A) and the pylon arm (A). Of overhead distribution lines including left and right distribution lines (L1, L2) that are processed and installed through insulators (1, 2), and jump lines (L3) that are connected to each distribution line (L1, L2) through connection ports (5, 6). In the pylon equipped with a tension balance control device, one end of the pylon arm (A) is rotated and fixed to a first fixed hinge point 930 formed on an upper part of the fixed base plate 920 installed at one end of the pylon arm (A). A first tension control piston 1000 for compressing and elongating the first piston rod 1010 by a control signal; A second tension control piston (2000) for which one end of the first fixed hinge point 930 is rotationally fixed and compresses and extends the second piston rod 2010 by a corresponding control signal; A third tension control piston that is rotated and fixed at one end to a second fixed hinge point 940 formed on a lower portion of the fixed base plate 920 and compresses and extends the third piston rod 3010 by a corresponding control signal. 3000); One end is rotationally fixed to a first moving hinge point 1020 formed at an end of the first piston rod 1010, and a third fixed hinge point 950 formed at a left central part of the fixed base plate 920 A first tension control triangular lever 4000 to which the center portion of the wirer shape is rotated and fixed; A first tension adjustment hinge part 4100 formed at the first moving hinge point 1020 of the first tension adjustment triangular lever 4000 and the other end of the horizontal line and pivotally connected to the end of the left suspension insulator 1 ); The first connecting rod 4020 of the first elastic auxiliary part 4010 formed at the lower end of the first tension adjusting triangular lever 4000 and supporting the compressive force and elongation of the first tension adjusting piston 1000 A second tension adjustment hinge part 4200 which is pivotally connected to the end of the second connection rod 4040 of the second elastic support part 4030, respectively; One end is rotationally fixed to a second moving hinge point 2020 formed at an end portion of the second piston rod 2010, and a fourth fixed hinge point 960 formed at a right central part of the fixed base plate 920 A second tension control triangular lever 5000 to which the center portion of the wirer shape is rotationally fixed; A third tension adjustment hinge part 5100 formed at the second moving hinge point 2020 of the second tension adjustment triangular lever 5000 and the other end of the horizontal line and pivotally connected to the end of the right suspension insulator 2 ); The end of the third connecting rod 5020 of the third elastic auxiliary part 5010 formed at the lower end of the second tension adjusting triangular lever 5000 and supporting the compressive force and elongation force of the second tension adjusting piston 2000 A fourth tension adjustment hinge part 5200 which is pivotally connected to the end of the fourth connection rod 5040 of the fourth elastic support part 5030, respectively; The first tension control piston 1000, the second tension control piston 2000, and the third tension control piston 3000 are fixedly installed on a part of the pylon arm (A) and according to the built-in program, operation data, and detected data. It may include a tension control unit 6000 each connected to each output to each of the corresponding control signal for compression and stretching.

The present invention increases the stability and safety of the pylon while maintaining a stable distribution line by adjusting the tension of the left and right distribution lines respectively, and balancing the position and tension of the jump line connected to the distribution line, and prevents safety accidents. It has the advantage of extending the life expectancy of the steel tower.

In the present invention, the tension of the left distribution line and the right distribution line are adjusted to suit the situation and to maintain the tension of the distribution line, but they are adjusted differently, and the tension of the left and right distribution lines is adjusted even when the support position of the jump line is adjusted. It has the advantage of being adjusted regardless of the relationship.

1 is a functional configuration diagram of a pylon equipped with a tension balance control device of an overhead distribution line according to an embodiment of the prior art;
2 is a functional configuration diagram illustrating a pylon equipped with a tension balance control device of an overhead distribution line according to an embodiment of the present invention;
And
3 is a diagram illustrating a connection configuration of a control circuit unit according to an embodiment of the present invention.

Since the present invention can apply various transformations and have various embodiments, specific embodiments will be illustrated in the drawings and will be described in detail in the detailed description. However, this is not intended to limit the present invention to a specific embodiment, it should be understood to include all conversions, equivalents, or substitutes included in the spirit and scope of the present invention. In describing the present invention, when it is determined that a detailed description of a related known technology may obscure the subject matter of the present invention, a detailed description thereof will be omitted.

2 is a functional configuration diagram illustrating a pylon equipped with a tension balance control device of an overhead distribution line according to an embodiment of the present invention, and FIG. 3 is a connection configuration of a control circuit unit according to an embodiment of the present invention. Is also.

In the accompanying drawings, screws or bolts for fastening and fixing are omitted from the drawings for simplicity of the drawings, but are replaced with descriptions.

Hereinafter, when described in detail with reference to all the accompanying drawings, the pylon 900 provided with the tension balance control device of the overhead distribution line is a pylon arm (A), left and right suspension insulators (1) on both sides of the pylon arm (A). Maintaining the balance of tension of overhead distribution lines including left and right distribution lines (L1, L2) that are installed overhaul through, 2), and jump lines (L3) connected to each distribution line (L1, L2) through connection ports (5, 6) In a pylon equipped with an adjustment device, a first tension adjustment piston 1000, a second tension adjustment piston 2000, a third tension adjustment piston 3000, a first tension adjustment triangular lever 4000, and a first tension adjustment The hinge part 4100, the second tension adjustment hinge part 4200, the second tension adjustment triangular lever 5000, the third tension adjustment hinge part 5100, the fourth tension adjustment hinge part 5200, and the tension control control part ( 6000).

Although not shown in the drawing, it is very natural that the other end of the pylon arm (A) is provided with the same configuration as that of one end.

The first tension control piston 1000, the second tension control piston 2000, and the third tension control piston 3000 use hydraulic pressure or pneumatic pressure, and the configuration for generating and supplying hydraulic or pneumatic pressure is general. In the drawings, detailed configurations, descriptions and drawings will be omitted, and a simple description will be made as a configuration operated by the corresponding control signal.

The first tension control piston 1000 is fixedly installed at one end of the first fixed hinge point 930 formed on the upper part of the fixed base plate 920 installed at one end of the pylon arm (A) in a rotating state, and It is a configuration in which the first piston rod 1010 is compressed and elongated according to the corresponding control signal of the tension control unit 6000.

Six screw holes 901 are formed at the ends of the pylon arm A, and screw holes 902 corresponding to the six screw holes 901 are also formed on the fixed base plate 920.

A reinforcing plate 910 for reinforcing the fixed state is interposed between the fixed base plate 920 that is fixedly installed at the end of the pylon arm (A) by screwing, and is fixed by screwing, and the reinforcing plate 910 ) Is formed with a screw hole 903 corresponding to the screw hole 901 and the screw hole 902, respectively.

The cross-sectional area of the end portion of the pylon arm (A) is relatively small, and the cross-sectional area of the fixed base plate 920 fixedly installed at the end portion of the pylon arm (A) is relatively wide. A plate 910 is interposed and installed, and this structure is a technology well known to those skilled in the art, and by this structure, the fixed base plate 920 is a first tension control piston 1000 and a second tension control piston fixedly installed on the front side. (2000) and the third tension adjustment piston (3000), the first tension adjustment triangular lever (4000), the first tension adjustment hinge part (4100), the second tension adjustment hinge part (4200) and the second tension adjustment triangular lever ( 5000), the third tension control hinge part 5100, the fourth tension control hinge part 5200, and the tension control control part 6000 are all stably fixed to form a sufficient space for smooth normal operation. It will be explained and understood as being fixed and maintained in a stable state at the end of A).

The reinforcing plate 910 and the fixed base plate 920 are made of an iron plate and are mechanically described and understood as a configuration having sufficient strength or support. Here, the screws or bolts fixed by screwing are described as having sufficient mechanical strength and configuration for fixing, and drawings will be omitted for simplicity of the drawings and easier understanding of the drawings, and the same applies hereinafter. do.

The first fixing hinge point 930 is formed on a portion of the upper portion of the central portion of the fixed base plate 920, and is a portion of the upper portion of the central portion of the reinforcing plate 910 and a first fixing hinge formed at a corresponding position to stabilize the fixed state. It is in communication with the penetration point 931, and the end of one end of the first tension control piston 1000 is fixedly installed in a rotating state by a corresponding screw or bolt, and the end of one end of the second tension control piston 2000 is in a rotating state. It is fixedly installed.

The first piston rod 1010 protrudes from the other side of the first tension control piston 1000 by the corresponding control signal of the tension control unit 6000 and is extended or inserted in a state that increases in length, and is compressed in a state that decreases the length. Configuration. A first moving hinge point 1020 is formed at an end portion from which the first piston rod 1010 extends. The hinge is a structure that is coupled in a rotating state, and since it is well known, a detailed description of the configuration and operation will be omitted.

The second tension control piston 2000 has one end of the first fixed hinge point 930 fixed in a rotating state, and compresses and extends the second piston rod 2010 from the other end according to the corresponding control signal. Configuration.

The second piston rod 2010 protrudes from the other side of the second tension control piston 2000 by the corresponding control signal of the tension control unit 6000 and is extended or inserted in a state of extending its length and is compressed in a state of decreasing its length. Configuration. A second movement hinge point 2020 is formed at an end portion of the second piston rod 2010 extended.

The first tension control piston 1000 and the second tension control piston 2000 are installed in a symmetrical state on the left and right sides of the first fixed hinge point 930, but each end of each side is rotatable. It is fixedly installed.

The third tension adjustment piston 3000 is fixedly installed at a second fixed hinge point 940 formed at a lower portion of the fixed base plate 920 in a rotatable state, and the corresponding control of the tension adjustment control unit 6000 It is a configuration in which the third piston rod 3010 is compressed and extended by a signal.

The second fixing hinge point 940 is formed through the lower portion of the central portion of the fixed base plate 920, and is a portion under the central portion of the reinforcing plate 910 and a second fixing formed at a corresponding position to stabilize the fixed state. It communicates with the hinge penetration point 941, and the end of one end of the third tension control piston 3000 is fixedly installed in a rotating state by a corresponding screw or bolt.

The third piston rod 3010 protrudes from the other side of the third tension control piston 3000 by the corresponding control signal of the tension control unit 6000 and is extended or inserted in a state to increase its length and is compressed to a reduced length. Configuration. A jump line insulator 3020 is connected and installed in a fixed state at the end of the third piston rod 3010 extended.

The first tension adjustment triangular lever 4000 has one end fixedly installed at the first moving hinge point 1020 formed at the end of the first piston rod 1010 in a rotating state, and the left central part of the fixed base plate 920 It is a configuration in which the center portion of the wire shape is fixedly installed in a rotating state at the third fixed hinge point 950 formed in the. The first tension control triangular lever 4000 is formed to be connected in a state in which the three extended leg portions are divided equally at an angle of 120 degrees, respectively, and it is preferable to configure the length of each leg to the same length, but by each leg It is quite natural that the value of the divided angle and the length of each leg can be added or subtracted if necessary.

The third fixing hinge point 950 is a through hole formed in a central part of the left side of the fixed base plate 920 and the central part to which the three legs of the first tension adjustment triangular lever 4000 are connected by a corresponding screw or bolt. It is a structure that is fixedly installed in a rotating state.

The first tension control hinge part 4100 is formed at the end of any one of the three leg parts constituting the first tension control triangular lever 4000 and is formed at the first moving hinge point 1020 and the other end on the horizontal line. It is a hinge configuration that is connected and fixed in a rotational state to one end that connects the left suspension insulator (1).

The second tension control hinge part 4200 is formed at the end of the corresponding leg extended to the lower part of the three leg parts constituting the first tension control triangular lever 4000, and the compressive force of the first tension control piston 1000 The first connecting rod 4020 end of the first elastic auxiliary unit 4010 that assists the elongation force and the second connecting rod 4040 of the second elastic auxiliary unit 4030 are connected and fixed in a rotational state, respectively.

The first elastic auxiliary part 4010 is fixedly connected and installed in a rotating state by a corresponding screw or bolt to the first elastic auxiliary hinge part 4011 formed at a part of the lower left end of the fixed base plate 920 at one end. There is a built-in spring for elasticity, and the elastic force by the spring is output to the first connecting rod 4020, so the first connecting rod 4020 is elongated or compressed to increase in length, and the first connecting rod 4020 The end of which is extended is fixedly connected to the second tension adjustment hinge part 4200 in a rotating state.

The second elastic auxiliary part 4030 is fixedly connected and installed at one end of the second fixed hinge point 940 by a corresponding screw or bolt in a rotating state, and a spring for elasticity is built into the inside, and the elastic force by the spring is Since the second connection rod 4040 is output to the second connection rod 4040, the second connection rod 4040 is elongated or compressed to decrease in length, and the end from which the second connection rod 4040 extends is a second tension adjustment hinge part 4200. ) Is fixedly connected and installed in a rotating state.

The second tension adjustment hinge part 4200 includes three ends of the first connection rod 4020 extending, the second connection rod 4040 extending, and the first tension adjustment triangular lever 4000. The ends of the legs, which are extended to the lower part of the legs, are connected and fixed in a rotating state, respectively.

The first elastic auxiliary part 4010 assists the first tension adjusting piston 1000 to smoothly generate a driving force for extending the first piston rod 1010, and the second elastic auxiliary part 4030 is the first tension adjusting piston ( 1000) assists to smoothly generate a driving force for compressing the first piston rod 1010.

The second tension adjustment triangular lever 5000 has one end fixedly installed at a second moving hinge point 2020 formed at the end of the second piston rod 2010 in a rotating state, and a right central part of the fixed base plate 920 It is a configuration in which the center portion of the wire shape is fixedly installed in a rotating state at the fourth fixed hinge point 960 formed in the. The second tension control triangular lever 5000 is formed to be connected in a state in which three extended leg portions are divided equally at an angle of 120 degrees, respectively, and it is preferable to configure the length of each leg to the same length, but by each leg It is quite natural that the value of the divided angle and the length of each leg can be added or subtracted if necessary.

The fourth fixed hinge point 960 is a through hole formed in the right central part of the fixed base plate 920 and the central part to which the three legs of the second tension adjusting triangular lever 5000 are connected by a corresponding screw or bolt. It is a structure that is fixedly installed in a rotating state.

The third tension control hinge part 5100 is formed at the end of any one of the three leg parts constituting the second tension control triangular lever 5000 and is formed at the second moving hinge point 2020 and the other end on the horizontal line. It is a hinge configuration that is connected and fixed in a rotating state to one end of the right suspension insulator (2).

The fourth tension control hinge part 5200 is formed at the end of the corresponding leg extended to the lower part of the three leg parts constituting the second tension control triangular lever 5000, and the compressive force of the second tension control piston 2000 and The ends of the third connecting rod 5020 of the third elastic auxiliary unit 5010 and the end of the fourth connecting rod 5040 of the fourth elastic auxiliary unit 5030 are connected and fixed in a rotational state, respectively.

The third elastic auxiliary part 5010 is fixedly connected and installed in a rotating state by a corresponding screw or bolt to a third elastic auxiliary hinge part 5011 formed at a part of the lower right end of the fixed base plate 920 at one end. There is a built-in spring for elasticity, and the elastic force by the spring is output to the third connection rod 5020, so the third connection rod 5020 is elongated or compressed to increase the length, and the third connection rod 5020 The end of which is extended is fixedly connected to the fourth tension adjustment hinge part 5200 in a rotating state.

The fourth elastic auxiliary part 5030 is fixedly connected and installed at one end to the second fixed hinge point 940 by a corresponding screw or bolt, and a spring for elasticity is built into the inside, and the elastic force by the spring is Since the fourth connection rod 5040 is output to the fourth connection rod 5040, the fourth connection rod 5040 is elongated or compressed to decrease in length, and the end from which the fourth connection rod 5040 extends is a fourth tension adjustment hinge part 5200. ) Is fixedly connected and installed in a rotating state.

The fourth tension adjustment hinge part 5200 includes three ends of the third connection rod 5020 extending, the end of the fourth connection rod 5040 extending, and the second tension adjustment triangular lever 5000. The ends of the legs, which are extended to the lower part of the legs, are connected and fixed in a rotating state, respectively.

The third elastic auxiliary unit 5010 assists the second tension adjusting piston 2000 to smoothly generate a driving force for extending the second piston rod 2010, and the fourth elastic auxiliary unit 5030 is a second tension adjusting piston ( 2000) assists so that the driving force for compressing the second piston rod 2010 is smoothly generated.

The tension control control unit 6000 is connected to the first tension control piston 1000, the second tension control piston 2000, and the third tension control piston 3000, respectively, and outputs corresponding control signals so that they are independently stretched or compressed. Control and monitor.

The tension control control unit 6000 receives a program that is built-in, installed and operated, and a designated command signal of a corresponding manager or operator connected in various ways from the outside, and receives the first tension control piston 1000 and the second tension control piston 2000. ) And the third tension control piston (3000) are controlled to elongate or compress, respectively.

On the other hand, although not shown in the drawing, the corresponding tension is detected between the left power distribution line and the left suspension insulator, between the right power distribution line and the right suspension insulator, and between the jump line and the jump line insulator, and informs the tension control unit 6000, and the tension control unit ( 6000), the left distribution line tension detection indication sensor (LCDS), right distribution line tension detection indication sensor (RCDS), jump line tension detection indication that visually indicates that the tension value was detected in an abnormal state in a color or red specified by the corresponding control signal of Each sensor (JCDS) is installed.

The tension control control unit 6000 is connected to the left distribution line tension detection indication sensor (LCDS), the right distribution line tension detection indication sensor (RCDS), and the jump line tension detection indication sensor (JCDS). If it is judged as an abnormal condition exceeding the allowed range, the corresponding control signal is sent to the corresponding left distribution line tension detection indication sensor (LCDS), right distribution line tension detection indication sensor (RCDS) or jump line tension detection indication sensor (JCDS), respectively. Controls to display warning signs or caution signs that can be visually checked around by output. Therefore, the person passing by, or the worker or manager in question, should be able to visually check the situation and take necessary measures.

On the other hand, the tension control unit 6000 notifies the state of tension failure from any one or more of the left distribution line tension detection indication sensor (LCDS), the right distribution line tension detection indication sensor (RCDS), and the jump line tension detection indication sensor (JCDS). When received, the information message is controlled so that the same contents are simultaneously notified to the designated manager and operator through the location information (coordinate information) and assigned unique number information by GPS through multiple communication paths (multiple communication paths).

The tension control communication unit 7000 is connected to the tension control control unit 6000 and is equipped with both a WiFi type mobile communication radio unit, a CDMA type mobile communication radio unit, a TRS type mobile communication radio unit, and a LAN type wired communication unit at the same time, and are in an active state at the same time. It operates and transmits and receives communication signals of the same contents at the same time. In this way, transmitting and receiving the same signal at the same time through multiple paths can eliminate errors caused by sending and receiving erroneous information due to transmission errors. If the information received in the time unit or packet unit section is not adopted, and there is no transmission error in the signal received through the multipath, the information signal received through any one route can be adopted according to the designated priority. , Since these technologies are well known, further detailed descriptions will be omitted, and the tension control communication unit 7000 transmits communication information through a multi-path by the corresponding control signal of the tension control unit 6000, but communication of a path without transmission errors. Operated to select a signal.

The tension control communication unit 7000 can first test the transmission error of multiple communication paths by the corresponding control signal of the tension control control unit 6000, and select the communication path with no transmission error or the least transmission error, and select the corresponding communication signal. It can also be transmitted.

Multiple communication paths may change the communication environment or communication conditions from moment to moment due to environmental changes such as wind, snow, rain, fog, and lightning generated around each, and the tension control unit 6000 is a designated time unit, as an example, Control and monitor the status of each communication path and change the communication path in one or more selected units selected from 10 minutes, 30 minutes, 1 hour, 6 hour, 12 hour, and 24 hour units. It is very natural that it can be done.

The tension control communication unit 7000 is a command signal that a designated manager or operator accesses and inputs remotely, for example, a first tension control piston 1000, a second tension control piston 2000, and a third tension control piston 3000. Each of the corresponding command signals that control to stretch or compress are received and transmitted to the tension control control unit 6000.

The tension control control unit 6000 can control and monitor all information including the information detected from each sensor and the result controlled by the input command signal to be transmitted to a designated manager or operator via the tension control communication unit 7000. have.

The present invention having the above configuration adjusts the position and tension of the jump line connected to the distribution line while individually adjusting the tension of the left and right distribution lines, so that the tension of each distribution line is maintained in a balanced manner, and the stability and safety of the pylon It increases the safety accidents, extends the life expectancy of distribution lines and pylons, adjusts the tension of the left distribution line and the tension of the right distribution line to suit the situation and maintains the tension of the distribution line, but each can be adjusted differently. In addition, even when adjusting the support position of the jump line, there is an advantage that it can be adjusted regardless of the tension adjustment of the left and right distribution lines.

In the above, the present invention has been described in detail with respect to the described specific examples, but it is obvious to those skilled in the art that various modifications and modifications are possible within the scope of the technical idea of the present invention, and it is natural that such modifications and modifications belong to the appended claims.

900: A pylon equipped with a tension balance control device of an overhead distribution line
1000: first tension control piston 2000: second tension control piston
3000: 3rd tension adjustment piston 4000: 1st tension adjustment triangular lever
4100: first tension adjustment hinge part 4200: second tension adjustment hinge part
5000: second tension adjustment triangular lever 5100: third tension adjustment hinge
5200: fourth tension control hinge part 6000: tension control control part

Claims (1)

In a pylon equipped with a tension balance control device of an overhead distribution line including a pylon arm, left and right distribution lines that are processed through left and right suspension insulators on both sides of the pylon arm, and a jump line connected to each distribution line through a connection port. ,
A first tension control piston for which one end of the one end is pivotally fixed to a first fixed hinge point formed on a portion of the upper portion of the fixed base plate installed at one end of the pylon arm, and compresses and extends the first piston rod according to a corresponding control signal;
A second tension adjusting piston whose one end portion is pivotally fixed to the first fixed hinge point and compresses and extends the second piston rod according to a corresponding control signal;
A third tension control piston for which an end of one end is pivotally fixed to a second fixed hinge point formed on a lower portion of the fixed base plate, and compresses and extends the third piston rod according to a corresponding control signal;
One end is rotationally fixed to a first moving hinge point formed at the end of the first piston rod, and a center portion of the Yiza shape is pivotally fixed to a third fixed hinge point formed at the left central part of the fixed base plate. Tension control triangular lever;
A second end portion is pivotally fixed to a second moving hinge point formed at the end portion of the second piston rod, and a center portion of the Yiza shape is pivotally fixed to a fourth fixed hinge point formed at a right central portion of the fixed base plate. Tension control triangular lever;
Tension that is fixedly installed on a part of the pylon arm and is connected to the first tension control piston, the second tension control piston, and the third tension control piston according to the built-in program, operation data, and detected data, respectively, to output corresponding control signals. An adjustment control unit; Including,
A reinforcing plate interposed between a fixed base plate fixedly installed at the end of the pylon arm by screwing to reinforce a fixed state;
A first tension formed at the end of any one of the three leg portions constituting the first tension control triangular lever and formed at the other end of the first moving hinge point and the horizontal line, and pivotally connected to the end of the left suspension insulator Adjustable hinge portion;
The first connecting rod of the first elastic auxiliary part that is formed at the lower end of the leg extending to the lower part of the three leg parts constituting the first tension control triangular lever and assists the compressive force and elongation force of the first tension control piston A second tension adjustment hinge portion pivotally connected to an end portion and a second connecting rod end portion of the second elastic auxiliary portion;
A third tension formed at the end of any one of the three leg portions constituting the second tension control triangular lever and formed at the second moving hinge point and the other end of the horizontal line, and pivotally connected to the end of the right suspension insulator Adjustable hinge portion;
The third connecting rod of the third elastic auxiliary part is formed at the lower end of the leg extending to the lower part of the three leg parts constituting the second tension adjusting triangular lever and assisting the compressive force and the elongation force of the second tension adjusting piston A fourth tension adjustment hinge portion pivotally connected to an end portion and a fourth connecting rod end portion of the fourth elastic auxiliary portion;
A left distribution line tension detection indication sensor installed between the left distribution line and the left suspension insulator, detecting the corresponding tension, notifying the tension control control unit, and visually indicating that the tension value is detected in an abnormal state by the corresponding control signal of the tension control control unit;
A right distribution line tension detection indication sensor installed between the right distribution line and the right suspension insulator, detecting the corresponding tension, notifying the tension control control unit, and visually indicating that the tension value is detected in an abnormal state by the corresponding control signal of the tension control control unit;
A jump line tension detection display sensor installed between the jump line and the jump line insulator, detecting a corresponding tension, notifying the tension control control unit, and visually indicating that the tension value is detected in an abnormal state by a corresponding control signal of the tension control control unit; Including more,
The first tension control triangular lever is a configuration in which three extended leg portions are connected to each other in a state equally divided at an angle of 120 degrees,
The second tension control triangular lever is a configuration in which three extended leg portions are connected to each other in a state equally divided at an angle of 120 degrees,
It is connected to the tension control unit 6000 and has both a Wi-Fi type mobile communication radio unit, a CDMA type mobile communication radio unit, a TRS type mobile communication radio unit, and a LAN type wired communication unit at the same time, and operates in an active state at the same time, and communicates the same contents. A tension control communication unit 7000 for transmitting and receiving signals at the same time; A steel tower provided with a tension balance control device of the overhead distribution line further comprising a.

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