WO2021045357A1 - Enclosure of power line device and installation apparatus therefor, and power line device comprising same - Google Patents

Abstract

An enclosure of a power line device, according to the present invention, comprises: a body having a first groove on the upper side thereof; an upper cover which is provided on the body, is rotatable as one side thereof is hingedly coupled to the body so as to open or block the top of the body, and has a second groove on the lower side thereof; a clamp which is rotatable as one side thereof is connected to the hingedly coupled portion of the body and the upper cover, wherein when the other side thereof rotates upward by a predetermined interval, the clamp comes into contact with the upper cover and rotates the upper cover so as to open the top of the body; and a first spring which provides an elastic force such that the upper cover rotates in the direction of closing the top of the body. When being installed on a power line, the first groove and the second groove are connected to each other while the upper cover closes the top of the body by means of the elastic force of the first spring, and the power line can be seated by passing through spaces of the first groove and the second groove connected to each other.

Description

Enclosure of equipment for power lines and installation devices thereof, and equipment for power lines equipped with the same

The present invention relates to an enclosure of a power line device, a device for installing the same, and a device for a power line having the same, and more particularly, a fault detector for a power line that can be installed by a live wire operation on a power line of an overhead transmission line and a distribution line. And an enclosure of a device such as a sensor and an installation mechanism thereof, and a power line device having the same.

Stable operation of the power system without power outages has become an essential requirement for the daily life of the people as well as the high-quality production of each national industry. In order to stabilize the power system, various remote monitoring and control technologies for power using IT technologies such as smart grid and wireless communication type sensor technologies of the fourth industry have been introduced in various ways.

In order to practically use these technologies, it is necessary to be able to easily install various sensors, such as a fault detector, on a power line without a power outage. In particular, it is necessary to install various sensors such as a fault detector for quick fault location expression and power supply service recovery when a power line fault occurs.

However, in the related art, when various sensors are to be installed on a power line, there is a problem in that the power line must be cut off for safety of workers. In this way, the work on the power line that is performed in a power outage state is referred to as “power outage work”, and on the contrary, the work on the power line that is performed during normal power supply to the power line without a power outage is referred to as “live line work”.

That is, in the conventional case, in order to install various sensors on multiple branch lines of a distribution line, a power outage operation must be performed, but the power supply service may be greatly disrupted due to a power outage, and thus the installation operation was practically impossible.

In order to solve the problems of the prior art as described above, the present invention is to install various sensors such as failure detectors by live wire work without power outages on power lines such as transmission lines or distribution lines that are being operated, or various types of sensors installed on the power lines. It is an object of the present invention to provide an enclosure of a power line device having a structure that enables removal of a sensor, an installation mechanism thereof, and a power line device having the same.

However, the problem to be solved by the present invention is not limited to the problems mentioned above, and other problems that are not mentioned will be clearly understood by those skilled in the art from the following description.

The enclosure of a power line device according to an embodiment of the present invention for solving the above problems includes: a body having a first groove on an upper side; An upper cover provided on the body, one side of which is hingedly coupled to the body and rotatable to open or block an upper portion of the body, and having a second groove at the lower side; A clamp capable of rotating the upper cover to open the upper part of the body by contacting the upper cover when the other side is rotated by a predetermined interval in the upper direction by connecting one side to the hinged portion of the body and the upper cover. ; And a first spring providing an elastic force so that the upper cover rotates in a direction closing the upper portion of the body.

When the enclosure of the power line device according to an embodiment of the present invention is installed on the power line, the first groove and the second groove are connected to each other while the upper cover closes the upper portion of the body by the elastic force of the first spring. , The power line may pass through the spaces of the first and second grooves connected to each other to be seated.

The enclosure of a power line device according to an embodiment of the present invention has a core and a coil wound around the core, so that it is possible to accommodate a current transformer that generates power by an electromagnetic induction method when combined on a power line. It is possible.

The body can accommodate a lower core having a groove corresponding to the first groove, and the upper cover can accommodate an upper core having a groove corresponding to the second groove.

In the case of a power line device according to an embodiment of the present invention, when installed on the power line, the upper core and the lower core can be combined, but the space formed by the groove of the upper core and the groove of the lower core is formed by the power line. Can penetrate.

The enclosure of the device for a power line according to an embodiment of the present invention may be installed on the power line to accommodate a device using power through a current transformer.

The device may perform a function of a sensor or a fault detector that detects a state of a power line or surroundings.

The enclosure for a power line according to an embodiment of the present invention may further include a second spring that provides an elastic force so that the clamp rotates in the body direction.

The power line enclosure according to an embodiment of the present invention, when installed on the power line, passes through the spaces of the first groove and the second groove while rotating the clamp toward the body by the elastic force of the second spring. It can be fixed by pressing the upper part of the furnace.

The body may further include a locking part provided to enable locking and fastening with the first hanger of the installation mechanism.

In the case of a power line device according to an embodiment of the present invention, before being installed on the power line, the first hanger of the installation mechanism is engaged with the locking portion and the second hanger of the installation mechanism is engaged with the clamp. The cover can open the top of the body.

When the enclosure of the device for a power line according to an embodiment of the present invention is installed on the power line, the first hanger and the second hanger are disengaged so that the upper cover may close the upper portion of the body.

The enclosure of the device for a power line according to an embodiment of the present invention can be installed on a power line through a live line operation without a power outage of the power line.

An installation device according to an embodiment of the present invention is an installation device used when the enclosure of the device for a power line is installed on a power line, comprising: a first hanger that can be fastened to a locking portion provided in the body of the enclosure; And a second hook capable of being fastened to the clamp of the enclosure.

In the installation device according to an embodiment of the present invention, before the enclosure is installed on the power line, the first hanger is engaged with the locking portion and the second hanger is engaged with the clamp. The top can be opened.

In the installation device according to an embodiment of the present invention, when the enclosure is installed on the power line, the first and second hangers are disengaged, so that the upper cover of the enclosure may close the upper portion of the body of the enclosure.

An installation apparatus according to an embodiment of the present invention includes: a main body in which the first hanger is located on one side, the second hanger is located on the other side, and has an opening at the top to accommodate the housing in the opening; A third spring installed on the bottom surface of the opening of the main body and fixing the case in the main body by providing an elastic force when the first and second hangers are engaged with the case accommodated in the main body; And an insulating rod connected to a lower portion of the main body.

The installation device according to an embodiment of the present invention may further include an insertion locking portion insertable into the main body.

The installation device according to an embodiment of the present invention restricts the upward movement of the housing by engaging the body surface of the housing received through the opening of the main body when the housing installed on the power line is removed. Thereafter, when the housing whose upward movement is restricted is moved in the downward direction through the insulating rod, the upper cover of the housing may be opened from the body of the housing.

The insertion locking portion may limit the horizontal rotational movement of the housing accommodated in the main body by a protrusion provided on the body surface of the housing.

* An apparatus for a power line according to an embodiment of the present invention includes a current transformer having a core and a coil wound around the core, and generating power in an electromagnetic induction method when coupled on the power line; And an enclosure accommodating the current transformer, and uses the power generated by the current transformer.

In the device for a power line according to an embodiment of the present invention, the enclosure includes: a body having a first groove at an upper side and accommodating a lower core having a groove corresponding to the first groove; An upper cover provided on the body and having one side hingedly coupled to the body and rotatable so as to open or block an upper portion of the body, and having a second groove at the lower side, and accommodating an upper core having a groove corresponding to the second groove; A clamp capable of rotating the upper cover to open the upper part of the body by contacting the upper cover when the other side is rotated by a predetermined interval in the upper direction by connecting one side to the hinged portion of the body and the upper cover. ; And a first spring providing an elastic force so that the upper cover rotates in a direction closing the upper portion of the body.

When the device for a power line according to an embodiment of the present invention is installed on the power line, the first groove and the second groove are connected to each other while the upper cover closes the upper part of the body by the elastic force of the first spring. The core and the lower core are coupled to each other, and the power line may pass through the spaces of the first and second grooves connected to each other, and may be seated through the space formed by the groove of the upper core and the groove of the lower core.

The device for a power line according to an embodiment of the present invention may perform a function of a sensor or a fault detector that detects a state of the power line or its surroundings.

The present invention constituted as described above has the advantage of enabling the installation of various sensors such as a fault detector or the removal of various sensors installed in the corresponding power line through live wire work without power failure in power lines such as transmission lines or distribution lines in operation. There is this.

That is, the present invention has the advantage of enabling easy installation or removal of various sensors, such as a wireless communication type fault detector, which allows a remote current measurement of a power line or a fault location to be quickly determined, to a required place of a power line.

In addition, since the present invention enables various sensors to be practically installed on a power line, there is an advantage of contributing to the improvement of the quality of power supply and stable power supply through the sensor.

In addition, since the housing of the present invention has a structure that is difficult to remove without a separate installation mechanism proposed, there is an advantage of preventing theft.

The effects that can be obtained in the present invention are not limited to the above-mentioned effects, and other effects not mentioned can be clearly understood by those of ordinary skill in the art from the following description. will be.

1 is a perspective view of an enclosure of a power line device according to an embodiment of the present invention.

2 is a plan view of an enclosure of a power line device according to an embodiment of the present invention.

3 is a front view of an enclosure of a power line device according to an embodiment of the present invention.

4 is a side view of an enclosure of a power line device according to an embodiment of the present invention.

5 is a rear view of the enclosure of the power line device according to an embodiment of the present invention.

6 is a cross-sectional view of an enclosure of a power line device according to an embodiment of the present invention.

7 is a perspective view of an installation device according to an embodiment of the present invention.

8 is a cross-sectional view of an installation device according to an embodiment of the present invention.

9 is a perspective view showing a ready state in which a case of a power line device according to an embodiment of the present invention is inserted into an installation mechanism for installation on a power line.

10 is a cross-sectional view showing a state in which the enclosure of the power line device according to an embodiment of the present invention is inserted into an installation mechanism in order to remove it from the power line.

[Explanation of code]

100: clamp locking portion 101: upper cover

102, 103: second spring 104: spring guide

105: bottom cover 106: body

107: second protrusion 108: first protrusion

109: clamp 110: locking portion

111: spring holder 112: groove for the track

112a: first groove 112b: second groove

113: body side hinge 114: upper cover side hinge

115: first spring 116: hinge bar

117: substrate 118: waterproof rubber ring

119: cover fixing bolt 120: cover fixing embedded nut

121: coil 122: core

122a: lower core 122b: upper core

123: core holder 123a: lower core holder

123b: upper core holder 200: first arm

201: third spring 202: second arm

203: second hook 204: insertion hook portion

205: arm fixing bolt 206: second arm

207: main body 208: first hanging

209: fourth spring 210: insulation rod thread

211: insulation rod

The above objects and means of the present invention and effects thereof will become more apparent through the following detailed description in connection with the accompanying drawings, and accordingly, those of ordinary skill in the technical field to which the present invention pertains to facilitate the technical idea of the present invention. I will be able to do it. In addition, in describing the present invention, when it is determined that a detailed description of a known technology related to the present invention may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted.

The terms used in the present specification are for describing exemplary embodiments, and are not intended to limit the present invention. In the present specification, the singular form also includes the plural form in some cases unless specifically stated in the phrase. In the present specification, terms such as "include", "include", "to prepare" or "have" do not exclude the presence or addition of one or more other elements other than the mentioned elements.

In the present specification, terms such as “or” and “at least one” may represent one of words listed together, or a combination of two or more. For example, “or B” “at least one of “and B” may include only one of A or B, and may include both A and B.

In this specification, the description following “for example” may not exactly match the information presented, such as the recited characteristic, variable, or value, and tolerances, measurement errors, limitations of measurement accuracy, and other commonly known factors. It should not be limited to the embodiments of the invention according to the various embodiments of the present invention to effects such as modifications, including.

In the present specification, when a component is described as being'connected' or'connected' to another component, it may be directly connected or connected to the other component, but other components exist in the middle. It should be understood that it may be possible. On the other hand, when a component is referred to as being'directly connected' or'directly connected' to another component, it should be understood that there is no other component in the middle.

In the present specification, when a component is described as being'on' or'adjacent' of another component, it may be directly in contact with or connected to another component, but another component exists in the middle. It should be understood that it is possible. On the other hand, when a component is described as being'directly above' or'directly' of another component, it may be understood that another component does not exist in the middle. Other expressions describing the relationship between elements, for example,'between' and'directly,' can be interpreted as well.

In the present specification, terms such as'first' and'second' may be used to describe various elements, but the corresponding elements should not be limited by the above terms. In addition, the terms above should not be construed as limiting the order of each component, and may be used for the purpose of distinguishing one component from another component. For example, the'first element' may be named'second element', and similarly, the'second element' may also be named'first element'.

Unless otherwise defined, all terms used in the present specification may be used with meanings that can be commonly understood by those of ordinary skill in the art to which the present invention belongs. In addition, terms defined in a commonly used dictionary are not interpreted ideally or excessively unless explicitly defined specifically.

In the accompanying drawings, for convenience of explanation, the size of the components is enlarged compared to the actual one, and the ratio of each component may be exaggerated or reduced.

Hereinafter, a preferred embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

1 to 6 show an enclosure of a power line device according to an embodiment of the present invention. That is, for the enclosure of a power line device according to an embodiment of the present invention, FIG. 1 is a perspective view, FIG. 2 is a plan view, FIG. 3 is a front view, FIG. 4 is a side view, FIG. 5 is a rear view, and FIG. Each of the cross-sectional views is shown.

7 and 8 show an installation mechanism according to an embodiment of the present invention. That is, for the installation mechanism according to an embodiment of the present invention, Figure 7 is a perspective view, Figure 8 is a cross-sectional view, respectively. In addition, Figure 9 shows a perspective view of a state in which the enclosure of a power line device according to an embodiment of the present invention is inserted into an installation mechanism for installation on a power line, and Figure 10 is a view showing the present invention for removal from the power line. It shows a cross-sectional view of a state in which the enclosure of a power line device according to an embodiment of is inserted into an installation device.

The enclosure of the power line device according to an embodiment of the present invention (hereinafter, referred to as “the main enclosure”) has a feature that can be installed on a power line such as a transmission line or a distribution line by a live line operation without a power outage. This enclosure may be a power line enclosure capable of accommodating a current transformer. In this case, the enclosure may be an enclosure for accommodating power line devices (hereinafter referred to as “the device”) such as electricity and electronics that use power generated by a current transformer as it is installed on the power line.

In this case, the device may be a device that performs a function of a sensor or a fault detector that detects the state of the power line or its surroundings, and the electronic circuit configuration for performing this function is a substrate 117 such as a printed circuit board (PCB). ) Can be provided.

For example, the sensor may sense current, sense vibration, sense temperature, sense humidity, sense air volume, sense an image, sense a partial discharge, or sense an electromagnetic wave, or detect a combination thereof. In particular, in the case of a fault detector, it is necessary to be installed on the power line for smooth power supply service, but it was not possible to install it by live line work as described above in the prior art, but it can be installed by live line work by this enclosure. .

This device may include a power supply unit or the like. In this case, the power supply unit generates power using an electromagnetic induction method, and may include a current transformer and a power converter. That is, when a current flows through a power line, a magnetic field is generated around the power line by the right-hand rule of the ampere's law, and an induced electromotive force is generated in the current transformer for power generation according to the magnetic field generated by the faraday's law. By doing so, power can be generated. That is, a small current proportional to a large current of the power line may be generated in the current transformer.

The current transformer may be composed of a core 122 and a coil 121 wound around the core. At this time, the core 122 is made of a metal material such as iron, and may be a clamp type structure including a lower core 122a and an upper core 122b to enable installation/disassembly on a power line. That is, the lower core 122a has a groove in the upper side and the upper core 122b has a groove in the lower side, and these cores 122a and 122b are combined with each other to form a ring shape and function as one core. Or, it can be separated and the core function can be stopped. When the cores 122a and 122b are coupled to each other, the grooves of the cores 122a and 122b are connected to each other, and a power line may be seated in the space of the connected grooves.

The core 122 may transform a line voltage of a high voltage and a high current into a low voltage and a low current according to the number of windings of the coil 121. However, in order to prevent problems such as water leakage due to the structure of the present housing, it may be preferable that the coil 121 is wound only on the lower core 122b, but is not limited thereto.

This housing may include a body 106, an upper cover 101, a clap 109, a first spring 115, and the like.

The body 106 is provided with a first groove (112a) on the upper side, it is possible to accommodate the lower core (122a). In this case, the lower core 122a may be accommodated in the body 106 so that the groove formed on the upper side thereof corresponds to the first groove 112a. That is, the body 106 may have a lower core holder 123a on its upper side corresponding to the shape of the lower core 122a to accommodate the lower core 122a. That is, referring to FIGS. 6, 9, and 10, the lower core holder 123a surrounds the lower core 122a, and a portion of the lower core 122a for contact coupling with the upper core 122b (hereinafter, (Referred to as "lower core exposed area") can be exposed.

The upper cover 101 is provided with a second groove 112b at the lower side, is provided on the body 106 to cover the body 106, and accommodates the upper core 122b. In this case, the upper core 122b may be accommodated in the upper cover 101 so that the groove formed at the lower side thereof corresponds to the second groove 112b. That is, the upper cover 101 may have an upper core holder 123b accommodating the upper core 122b corresponding to the shape of the upper core 122b on the lower side thereof. That is, referring to FIGS. 6, 9 and 10, the upper core holder 123b surrounds the upper core 122b, and a portion of the upper core 122b for contact coupling with the lower core 122a (hereinafter, (Referred to as “upper core exposed area”) can be exposed. However, in order to show the structure more clearly, the upper core 122b and the lower core holder 123a are omitted in FIG. 6, and these configurations 122b and 123a may be referred to FIGS. 9 and 10.

In particular, one side of the upper cover 101 is hingedly coupled to the body 106 to be rotatable, and the upper portion of the body 106 can be opened or blocked according to the rotation.

The body 106 and the upper cover 101 may be hingedly fastened through a hinge bar 116. That is, a body-side hinge 113 having a hinge groove into which the hinge bar 116 can be inserted may be formed on one side of the body 106. In addition, an upper cover side hinge 114 may be formed on one side of the upper cover 101 in which a hinge groove into which the hinge bar 116 can be inserted is formed. Accordingly, the hinge bar 116 is inserted into each hinge groove of the body-side hinge 113 and the upper cover-side hinge 114 to be hinged, so that the hinge bar 116 is the axis of the upper cover 101 and Since the space between the body 106 may be separated or contacted, the upper portion of the body 106 may be opened or blocked by the upper cover 101. That is, the body-side hinge 113 and the upper cover-side hinge 114 may provide a function of opening or closing the upper cover 101 of the body 106.

The clamp 109 is a hinged portion of the body 106 and the upper cover 101, that is, one side of which is connected to a hinge bar 116 so as to be rotatable. In particular, the clamp 109 may be caught by contacting the clamping portion 100 of the upper cover 101 when the other side thereof rotates by a predetermined interval in the upper direction. Accordingly, in a state in which the clamp 109 is caught in the clamping portion 100, when a continuous upward rotational force is applied to the clamp 109, the clamp 109 rotates the upper cover 101 upward. While making it possible to open the upper part of the body 106. That is, the clamp 109 is configured to transmit a rotational force in an upward direction with respect to the upper cover 101 so that the upper portion of the body 106 can be opened.

The first spring 115 provides a first elastic force so that the upper cover 101 keeps the upper part of the body 106 closed. That is, the first elastic force may provide a rotational force to the upper cover 101 in a direction in which the upper cover 101 closes the upper portion of the body 106. The first spring 115 has one end connected to the upper cover 101 and the other end connected to the body 106, thereby providing a first elastic force. For example, the first spring 115 may be fastened to the center of the hinge bar 116, but is not limited thereto.

The housing may be installed on a power line by live wire work through the configuration of the body 106, the upper cover 101, the clasp 109, and the first spring 115. That is, when the housing is installed on the power line, the upper cover 101 closes the upper portion of the body 106 by the first elastic force of the first spring 115, and the first groove 112a and the second groove (112b) may be connected to each other. That is, the first and second grooves 112a and 112b form one power line groove 112.

In this case, the power line may be seated through the space of the first and second grooves 112a and 112b connected to each other, that is, the power line groove 112. Accordingly, by releasing the holding force for the upper cover 101 after placing the main body with the body 106 open on the power line by supporting the upper cover 101 in the upper direction through an installation mechanism, etc. This enclosure can be installed on the power line more easily by live line work.

In particular, when installed on a power line, the housing can be combined with the lower core 122a and the upper core 122b (that is, the contact bonding of the exposed portion of the lower core and the exposed portion of the upper core). The space formed by the groove of the lower core 122a and the groove of the upper core 122b may be penetrated. As a result, the device included in the present enclosure can be driven by using a power source for which a current transformer generates power in an electromagnetic induction method. That is, when installed on the power line, the lower core 122a and the upper core 122b are brought into contact with each other by the first elastic force, thereby performing the role of the core 122.

In addition, the housing may further include second springs 102 and 103 that provide a second elastic force so that the clamp 109 rotates in a direction toward the body 106. The second springs 102 and 103 have one end connected to the clamp 109 and the other end connected to the body 106, thereby providing a second elastic force. For example, the second springs 102 and 103 may be fastened to both sides of the hinge bar 116, but are not limited thereto. In addition, the housing may further include a spring holder 111 for fixing the lower portion of the second spring 102 to the body 106.

When the housing is installed on the power line, the second springs 102 and 103 may rotate the clamp 109 so that the clamp 109 faces the body 106 by providing a second elastic force. As a result, due to the second elastic force, the clamp 109 is a power line through which the spaces of the first groove 112a and the second groove 112b respectively have both sides of the clamp 109 provided with the upper cover 101 therebetween. The power line can be fixed by applying a force to the upper part of the power line in the lower direction while contacting the upper part of the power line. That is, the power line may be fixed by the second elastic force while being positioned between the first groove 112a of the body 106 located at the lower side and the both sides of the clamp 109 located at the upper side thereof. The enclosure can be more rigidly installed on the power line.

For example, if the other end of the clamp 109 is rotated upward by about 30 degrees for the power line, the clamp locking part 100 is caught by the clamp 109 and the upper cover 101 is raised together. You lose. Thereafter, when the clamp 109 is rotated in the opposite direction so that the power line is engaged at the position of the groove 112 for the line, the clamp 109 is caused by the second elastic force of the second springs 102 and 103. Depending on the size of the diameter, the power line is pressed and fixed. At this time, the upper cover 101 rotates downward by the first elastic force of the first spring 115 and descends, so that the lower core 122a and the upper core 122b come into contact with each other.

In addition, a first protrusion 108 may be formed on the bottom surface of the first groove 112a. In this case, when the clamp 109 applies pressure to the power line in the direction of the body 106, it is possible to improve the fixing force of the main body with respect to the power line by raising the coefficient of friction. As a result, it is possible to increase the fixing efficiency between the power line and the main body, and the main body may not be easily shaken on the power line even by the wind direction of the wind.

A spring guide 104 is provided between the clamp 109 and the hinge bar 116 to increase the diameter of the second springs 102 and 103. As a result, it is possible to further increase the second elastic force, so that the main body can be installed on the power line with a more fixed force. For example, the spring guide 104 may be made of an insulating material such as plastic, but is not limited thereto.

On the other hand, the housing may further include a bottom cover 105 that covers the bottom of the body 106 but that is detachable from the body 106. That is, when the bottom cover 105 is removed, it is possible to assemble and inspect the substrate 117 and other components provided in the body 106. By inserting and fixing the floor cover 105 on the bottom of the body 106 by inserting a plurality of bolts and a waterproof rubber ring 118, a waterproof and dustproof function for the body 106 may be possible. In addition, through adhesive fixing and curing between the lower core 122a and the body 106 on the inner side of the body 106 with a solution epoxy resin, etc., waterproofing and dustproof treatment between the body 106 and the lower core 122a is possible. It can be possible. In addition, a bottom cover 105 may be employed on the body 106 by using a plurality of pairs of cover fixing embedded nuts 120 and a cover fixing bolt 119 fastened thereto.

In addition, a space for installation of the substrate 117 of the device, an antenna, and a backup storage battery may be provided in the inner space of the body 106.

Next, an installation mechanism according to an embodiment of the present invention will be described.

The installation mechanism according to an embodiment of the present invention (hereinafter referred to as “the installation mechanism”) is to install the main body on a power line or remove the installed main body from the power line by live wire work without power failure. It is an instrument used.

This installation mechanism may include a main body 207, a first hanger 208, a second hanger 203, a third spring 201, an insulating rod 211, and the like. In addition, to enable the use of this installation mechanism, the housing may further include a locking portion 110 formed on the body 106. For example, the locking portion 110 may have a shape protruding or concave from the body 106, but is not limited thereto.

The main body 207 has an opening in the upper portion, and the body 207 can be accommodated in the opening. At one side of the main body 207, a first hanger 208 configured to be fastened to the locking portion 110 of the main body 207 may be positioned. In addition, a second hanger 203 configured to be fastened to the clamp 109 of the main body 207 may be positioned on the other side of the main body 207.

The first hanger 208 is engaged with the locking portion 110 of the main housing, and may be configured to connect and fix the main housing and the installation mechanism. In addition, the second hanger 203 may be fastened with the clamp 109 to allow the clamp 109 and the upper cover 101 to be opened from the upper portion of the body 106.

However, the fastening of the first hanger 208 and the second hanger 203 may limit movement in an upward direction with respect to the main body. This first hanger 208 may be connected to be rotatable in the first arm 200 provided on one side of the main body 207, and the second hanger 203 is a second arm 202 provided on the other side of the main body 207 ) Can be connected to be rotatable.

The insulating rod 211 is combined with the main body 207 to enable the installation or removal of the main body by live wire work on the power line at a high position. For example, the coupling of the main body 207 and the insulating rod 211 is a screw connection between the insulating rod connection screw groove 212 formed in the main body 207 and the insulating rod threads 210 formed in the insulating rod 211 You can use

<Installation of this enclosure on the power line: installation mode>

Before being installed on the power line, the present enclosure may be accommodated in the main body 207 of the present installation mechanism. At this time, in a state in which the hinge bar 116 in the main body faces toward the second arm 206 of the main installation mechanism, the lower surface of the main body is placed on the third spring 201 and the main body is placed under it. Press in the direction.

Thereafter, as shown in FIG. 9, the first hanger 208 is engaged with the locking portion 110 of the main housing, and the second hanger 203 is engaged with the clamp 109 of the main housing. . That is, after hooking the first hook 208 to the hooking part 110, the clamp 109 is rotated upward and hooked to the second hook 203.

As a result, the upper cover 101 of the present housing can keep the upper portion of the body 106 open. This state corresponds to the state of preparation for the installation of this enclosure. However, in consideration of the position at which the object to be engaged is provided, the first hanger 208 may be engaged at a lower position than the second hanger 203.

On the other hand, the locking part 110 is a configuration for fixing the main body to the main installation mechanism in order to install the main body on the power line. That is, the locking portion 110 is a configuration for locking the first hanger 208 of the present installation mechanism. At this time, each elastic force required for engaging and fastening the first and second hooks 208 and 203 may be provided by the third spring 201 of the present installation mechanism. That is, the third spring 201 provides an elastic force that pushes the body in the upper direction, thereby providing a locking engagement between the first hanger 208 and the locking portion 110, and the second hanger 203 and It is possible to provide a locking fastening of the clamp 109. Accordingly, the third spring 201 may help the first hanger 208 and the second hanger 203 and the main body to mutually exert a force so that the main body is fixed to the main installation mechanism.

In particular, as the third spring 201 is provided on the bottom surface of the opening of the main body 207, the first hanger 208 and the second hanger 203 for the main body accommodated in the main body 207 of the main body 207 It is possible to provide a third elastic force directed to the upper direction when fastened by the locking. As a result, the first hanger 208 and the second hanger 203 are fastened to limit the movement in the upper direction with respect to the main housing, and the third elastic force provided in the upper direction allows the main housing to be installed when it is ready to be installed. It can be fixed more rigidly within the body 207 of the instrument.

Then, when installed on the power line, the operator is accommodated in the main body 207 of the installation mechanism, but the upper cover 101 maintains the upper part of the body 106 in an open state, the main body 207 It can be brought close to the power line by using the insulating rod 211 connected to the lower part of the. That is, the body may be moved so that the power line is positioned between the first and second grooves 112a and 112b of the body. Thereafter, the first hanger 208 and the second hanger 203 are disengaged so that the main body can be installed on the power line while the upper cover 101 of the body closes the upper part of the body 106. have.

Particularly, after the main body is installed on the power line, disengagement of the locking of the first hanger 208 and the second hanger 203 can be achieved by a worker moving the installation mechanism upward using an insulating rod. That is, when the power line is in contact with the bottom surface of the first groove 112a of the body 106, if the installation mechanism is moved upward, the power line presses the bottom surface of the first groove 112a and the main body The third spring 201 can be compressed.

Thereafter, when the third spring 201 is compressed by a predetermined length, the first hook 208 and the second hook 203, which used to limit the upward movement of the main body, may be released. As a result, the body can be installed on the power line by live line work. That is, the upper cover 101 closes the upper portion of the body 106 by the first elastic force of the first spring 115, and the power line in the space of the first groove 112a and the second groove 112b connected to each other. Is positioned, and the clamp 109 can be fixed while pressing the power line in the direction of the body 106 by the second elastic force of the second springs 102 and 103.

In more detail, if the installation mechanism is raised so that the power line is positioned at the first protrusion 108 of the main body, the installation mechanism is raised so that the power line and the first protrusion 108 abut. 3 As the spring 201 contracts, the housing is accommodated in the main body 207 of the installation mechanism, and the first and second hangers 208 and 203, which have been fastened, are released. At this time, the upper cover 101 and the clamp 109 are rotated in the direction of the body 106 and closed by the elastic force of the first spring 115 and the second spring 102, 103, and the main body is fixedly installed on the power line. Can be.

On the other hand, the installation mechanism may be used when the main body installed on the power line is dismantled. To this end, the housing may further include a second protrusion 107 formed to protrude from the surface of the body 106, and the installation mechanism further includes an insertion locking portion 204 that can be inserted into the body 207. Can include. The plurality of insertion hooks 204 may be connected to the first arm 200 and the second arm 206, and may be engaged with the third hook 213. In this case, a plurality of third hanging hooks 213 may be provided to be connected to the first arm 200 and the second arm 206.

<Demolition of the main body installed on the power line: Demolition Mode>

Before the dismantling of the main housing installed on the power line, the insertion locking portion 204 may be inserted into the main body 207 of the installation mechanism after the third hanger 213 and the locking engagement are released. In this case, the insertion locking portion 204 may be inserted protruding from the inner surface of the body 207 into the inner space, and a plurality of the insertion locking portions 204 may be inserted.

On the other hand, although not described above in the <installation mode>, after the insertion locking portion 204 is engaged with the third hanger 213, the locking of the first hanger 208 and the second hanger 203 may be performed. . That is, by bending the insertion locking portion 204 upward, the third hanger 213 and the insertion locking portion 204 may be engaged. Conversely, in the present <demolition mode>, the third hanger 213 and the insertion locking portion 204 can be unlocked by releasing the insertion locking portion 204 from the third hanger 213 in the opposite direction. .

After releasing the locking of the insertion locking portion 204 and inserting it into the main body 207, the operator can move the main installation mechanism so that the main body installed on the power line is accommodated in the opening of the main body 207 of the main installation unit. have. At this time, as shown in Fig. 10, while the main body is accommodated in the main body 207 of the main body, the insertion locking part 204 inserted into the main body 207 of the main body 207 is on the surface of the body 106 of the main body. By locking, it is possible to limit the upward movement of the body. That is, a portion having an outer diameter larger than that of other regions may be formed on the surface of the body 106 of the present housing, and the insertion locking portion 204 is caught in the region having the larger outer diameter. Such an area having a large outer diameter may be located under the surface of the body 106, as shown in FIG. 10, but is not limited thereto. That is, the insertion locking part 204 may connect and fix the body and the installation mechanism when the body is dismantled.

Thereafter, the main body, whose upward movement is limited, is moved downward through the insulating rod 211 of the present installation mechanism, so that the power line applies a force to the upper cover 101 of the main body in the upper direction. As a result, the upper cover 101 opens the upper portion of the body 106 while the other side thereof rotates upward. In this case, while the clamping portion 100 of the upper cover 101 contacts the clamp 109, the clamp 109 may also be opened while the other side thereof rotates upward as the upper cover 101 rotates.

On the other hand, in a state in which the movement in the upward direction of the housing is restricted, the insulating rod 211 of the installation mechanism may be rotated in the horizontal direction. In this case, while the insertion locking portion 204 is caught by the second protrusion 107 provided on the surface of the body 106 of the body, it is possible to limit the horizontal rotational movement of the body received in the body 207 of the installation mechanism. have. As a result, it is possible to more easily dismantle the main housing provided on the power line.

For example, the insulating rod 211 is rotated by twisting the insulating rod 211 clockwise from the horizontal direction until the second protrusion 107 of the body 106 is caught by the insertion locking portion 204 of the mounting mechanism. ) Can be moved downward. When such a clockwise rotation is added, the main body with limited horizontal rotational movement rotates clockwise together, so that the main body can be removed from the power line.

Thereafter, by pulling out the insertion locking portion 204 inserted into the main body 207 of the present installation mechanism, the dismantled main housing can be separated from the main installation mechanism.

That is, since the second protrusion 107 of the main body has a function of limiting the rotation of the main body installed on the power line in the horizontal direction, it is not possible for others to dismantle the main body arbitrarily without the demolition mechanism. As a result, it is possible to fundamentally prevent theft of the main body installed on the power line.

In case of installing various sensors such as a wireless communication fault detector on the power line to quickly identify the location of the fault in preparation for the occurrence of power line breakdowns and accidents such as the collapse of power towers and poles for power lines in the prior art, live wire work without power outages Was practically impossible due to worker's safety reasons. However, the present invention solves these conventional problems, and installs various sensors such as failure detectors in a live wire operation without a power outage on power lines such as power transmission lines or distribution lines in operation, or removal of various sensors installed on the power lines. It is possible to provide a housing having a structure that enables and an installation mechanism thereof, and a sensor having the same.

That is, the present invention has the advantage of enabling easy installation or removal of various sensors, such as a wireless communication type fault detector, which allows a remote current measurement of a power line or a fault location to be quickly determined, to a required place of a power line. In addition, since the present invention enables various sensors to be practically installed on a power line, there is an advantage of contributing to the improvement of the quality of power supply and stable power supply through the sensor. In addition, since the housing of the present invention has a structure that is difficult to remove without a separate installation mechanism proposed, there is an advantage of preventing theft.

Although specific embodiments have been described in the detailed description of the present invention, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention is not limited to the described embodiments, and should be defined by the claims to be described later and equivalents to the claims.

The present invention is a power line device having a structure that enables the installation of various sensors, such as a fault detector, or the removal of various sensors installed on the corresponding power line by live wire work without a power outage on a power line such as a transmission line or distribution line in operation. Since it relates to the enclosure of the body and its installation mechanism and the equipment for a power line having the same, there is an industrial applicability.

Claims (13)

1. A body having a first groove provided on the upper side and a locking portion capable of engaging with the first hook of the installation mechanism;

   An upper cover provided on the body, one side of which is hingedly coupled to the body and rotatable to open or block an upper portion of the body, and having a second groove at the lower side;

   A clamp capable of rotating the upper cover to open the upper part of the body by contacting the upper cover when the other side is rotated by a predetermined interval in the upper direction by connecting one side to the hinged portion of the body and the upper cover. ; And

   Includes; a first spring that provides an elastic force so that the upper cover rotates in a direction closing the upper portion of the body,

   Before being installed on the power line, the first hanger of the installation mechanism is engaged with the locking portion and the second hanger of the installation mechanism is engaged with the clamp, so that the upper cover opens the upper part of the body,

   When installed on the power line, the first and second grooves are connected to each other while the upper cover closes the upper part of the body by the elastic force of the first spring, and the spaces of the first and second grooves connected to each other are transferred to the power line. The enclosure of the power line device in which the upper cover closes the upper part of the body by releasing the locking fastening of the first hanger and the second hanger.
2. The method of claim 1,

   The enclosure of a power line device capable of accommodating a current transformer that has a core and a coil wound around the core and generates power in an electromagnetic induction method when combined on a power line.
3. The method of claim 2,

   The body is capable of accommodating a lower core having a groove corresponding to the first groove,

   The upper cover may accommodate an upper core having a groove corresponding to the second groove,

   When installed on the power line, the upper core and the lower core can be combined, but the power line can penetrate the space formed by the groove of the upper core and the groove of the lower core.
4. The method of claim 2,

   An enclosure of a power line device installed on the power line and capable of accommodating a device using power generated by a current transformer.
5. The method of claim 4,

   The device is an enclosure of a power line device that performs the function of a sensor or a fault detector that detects the state of the power line or its surroundings.
6. The method of claim 1,

   Further comprising a second spring providing an elastic force so that the clamp rotates in the body direction,

   When installed on the power line, the clamp is rotated toward the body by the elastic force of the second spring, and the power line device capable of pressing the upper portion of the power line penetrating the space of the first groove and the second groove. Enclosure.
7. The method of claim 1,

   Enclosure of a power line device that can be installed on a power line through live line work without power failure of the power line.
8. An installation device used when the enclosure of a power line device according to any one of claims 1 to 7 is installed on a power line,

   A first hook capable of being fastened to a locking part provided in the body of the housing; And

   Includes; a second hook that can be fastened to the clamp of the housing,

   Before the enclosure is installed on the power line, the first hanger is engaged with the locking portion and the second hanger is engaged with the clamp, so that the upper cover of the enclosure opens the upper portion of the body of the enclosure,

   When the enclosure is installed on the power line, the first hanger and the second hanger are disengaged so that the upper cover of the enclosure closes the upper portion of the body of the enclosure.
9. The method of claim 8,

   A main body in which the first hanger is located on one side, the second hanger is located on the other side, and has an opening in the upper portion thereof, so that the housing can be accommodated in the opening portion;

   A third spring installed on the bottom surface of the opening of the main body and fixing the case in the main body by providing an elastic force when the first and second hangers are engaged with the case accommodated in the main body; And

   An insulating rod connected to a lower portion of the main body;

   Installation mechanism further comprising a.
10. The method of claim 9,

    Further comprising an insertion locking portion insertable into the body,

    When the box installed on the power line is removed, the insertion locking part inserted into the main body is caught on the body surface of the box received through the opening of the main body, thereby restricting the upward movement of the box, and then the box with limited upward movement is an insulating rod. An installation mechanism capable of opening the upper cover of the enclosure from the body of the enclosure when it is moved in a downward direction through the enclosure.
11. The method of claim 10,

    An installation mechanism capable of restricting the horizontal rotational movement of the housing accommodated in the main body by the protrusion provided on the body surface of the housing.
12. A current transformer having a core and a coil wound around the core, and generating power in an electromagnetic induction method when coupled on a power line; And

    Including a case containing the current transformer; and using the power generated by the current transformer,

    The enclosure is,

    A body having a first groove provided on the upper side and a locking portion capable of engaging with the first hook of the installation mechanism;

    An upper cover provided on the body, one side of which is hingedly coupled to the body and rotatable to open or block an upper portion of the body, and having a second groove at the lower side;

    A clamp capable of rotating the upper cover to open the upper part of the body by contacting the upper cover when the other side is rotated by a predetermined interval in the upper direction by connecting one side to the hinged portion of the body and the upper cover. ; And

    Includes; a first spring that provides an elastic force so that the upper cover rotates in a direction closing the upper portion of the body,

    Before being installed on the power line, the first hanger of the installation mechanism is engaged with the locking portion and the second hanger of the installation mechanism is engaged with the clamp, so that the upper cover opens the upper part of the body,

    When installed on the power line, the first and second grooves are connected to each other while the upper cover closes the upper part of the body by the elastic force of the first spring, and the spaces of the first and second grooves connected to each other are transferred to the power line. The device for power lines in which the upper cover closes the upper part of the body by being able to be seated through the penetrating and disengaging the locking of the first hanger and the second hanger.
13. The method of claim 12,

    A device for a power line that performs the function of a sensor or a fault detector that detects the state of the power line or its surroundings.

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