BR102012005034A2 - ground switch - Google Patents

Abstract

METHOD AND PORTABLE EQUIPMENT FOR READING, MONITORING AND MANAGEMENT OF WELDING VERES FOR WELDING EQUIPMENT. The present invention relates to a portable method and equipment for reading, monitoring and managing welding variables, especially welding variables from spot welding or resistance welding procedures, characterized in that it gathers in a single method and corresponding portable device, the functions of storing predetermined welding parameters, measuring all important welding process variables, evaluating the measured welding variables and comparing them to the parameters, generating output signals to an equipment imaging device and to a equipment interface device capable of digitally communicating with the welding machine, correcting welding machine setting parameters in real time, monitoring and promoting the interlocking of welding machines, and storing the corrected data obtained by generating a report capable of representing the history of at least 1,000 welding operations.

Description

“GROUNDING KEY”

Background of the invention

1. Field of the invention

The present invention relates to a grounding switch and, in particular, to a safety apparatus capable of restricting the handling of a grounding switch under a condition not permitted in a cooperative grounding switch with a vacuum circuit breaker.

2. Background of the invention

A vacuum circuit breaker is a type of electrical equipment used for switching and protecting a high and ultra high voltage electrical circuit due to the excellent arc flash quenching performance capable of rapidly extinguishing the arc. voltage generated at the circuit breaker where the connection and separation between the contacts are performed within a vacuum container.

The vacuum circuit breaker is usually built into a power distribution board, in conjunction with various measuring units and relays, such as digital relay, and the like, for operation, monitoring and control at a power station and a substation. The vacuum circuit breaker generally includes a cradle and a main circuit breaker body. The cradle has terminals that movably support the main circuit breaker body and are connectable to the load side and external power source circuits, and is attached to a power distribution board compartment. The main circuit breaker body includes terminals connected to or separate from the cradle terminals, a main circuit part that has vacuum switches, each provided with a moving contact and a stationary contact, a switching mechanism to drive the moving contact of the switch to vacuum to a close position or an open position in order to close or open the circuit, and a controller to detect an occurrence of a fault current such as short circuit current in a circuit and to control the switching mechanism under detection of fault current to interrupt the circuit.

In addition, the breaker main body may be movable to three positions, including a connection position, where the breaker main body terminals are connected to the cradle terminals according to the movement of a movable transport over which the circuit breaker main body is charged, a test position where the main circuit is disconnected due to the separation of the breaker main body terminals from the cradle terminals, but electrical power is supplied to the controller for a body switching test main circuit breaker, and a disconnect position where the main circuit is disconnected due to the separation of the main body terminals from the cradle terminals and the electrical supply to the controller for the switching test is broken. Here, in the disconnect position, the main circuit of the main circuit breaker body is disconnected from the cradle and power supplied to the controller for the switching operation test is interrupted, thus protecting the circuit against a safety accident. . At the connection position, the controller on the vacuum circuit breaker detects a fault current, such as a short circuit current or a ground current, upon its occurrence, and triggers the switching mechanism to interrupt a circuit, thus protecting the circuit and a user against the accident. However, in the test position, no safety element is present, therefore a ground switch is additionally arranged to ensure the safety of the user in the test position.

The vacuum circuit breaker is installed in a cubic type enclosure in the power distribution board to be cooperative with the earthing switch. Consequently, in a closed position, a grounded movable ground switch contactor is connected to a terminal (ie the cradle terminal) connected to the main circuit on either the power supply side or the electrical load side, grounding, thus the main circuit. In addition, in an open position, the grounding switch moving contactor is detached from the terminal connected to the main circuit on the power supply side or the load side, thereby disconnecting the main circuit from ground.

However, in the related art, the earthing switch is capable of being manipulated at any time, even in the connection position, as well as in the test position, which causes a ground fault accident in relation to the main circuit.

Summary of the invention

Therefore, an object of the present invention is to provide a grounding switch capable of preventing a safety-related failure by allowing the grounding switch to be accessed by the user to a drive shaft, only when grounding switch handling is permitted. (left).

To achieve this and other advantages as incorporated and widely described herein, a grounding wrench is provided, for the purpose of the present disclosure, which has a rotary drive shaft for manipulating a position thereof, and

a handling shaft which has a swiveling protection plate in one position to allow the connection of a handling cable to the drive shaft and a position to restrict its connection,

characterized in that the earthing switch comprises: a restraint plate connected to the handling shaft to be rotatable in conjunction with the handling shaft; and

an electromagnetic lock assembly installed adjacent the restriction plate, wherein the electromagnetic lock assembly has a projection lock position at a location of the restriction plate rotation to restrict rotation of the restriction plate and a position of clearance removal from the restriction plate rotation location to allow rotation of the restriction plate.

The additional scope of the applicability of this application will become more apparent from

from the detailed description given later in this document. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, as various changes and modifications within the spirit and scope of the invention will become apparent to the elements skilled in the art from the detailed description.

Brief Description of Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated into and form part of this specification, illustrate exemplary embodiments and together with the description serve to explain the principles of the invention.

In the drawings:

Figure 1 is a front view showing a grounding switch, a power distribution board and a vacuum circuit breaker according to the present disclosure;

Figure 2 is a front perspective view of the grounding switch, the switchgear

power distribution and vacuum circuit breaker;

Figure 3 is a rear perspective view of the grounding switch, power distribution board, and vacuum circuit breaker;

Figure 4 is a front perspective view showing the grounding switch, power distribution board, and vacuum circuit breaker after removal of a main circuit breaker body from the vacuum circuit breaker;

Figure 5 is a perspective view showing a disallowed bar connection state relative to a drive shaft in a grounding switch front handling unit;

Figure 6 is a perspective view showing a bar connection state.

permissible with respect to the drive shaft in the earthing switch front handle unit;

Figure 7 is a view showing an operating state when the busbar is being connected in the allowed busbar connection state with respect to the drive shaft in the earthing switch front handling unit;

Figure 8 is a perspective view showing the non-permissible busbar connection state in which a drive shaft busbar connection hole is closed by a guard plate in the earthing switch front handling unit;

Figure 9 is a perspective view showing the permissible busbar connection state in which the guard plate closing the drive shaft busbar connection hole is opened in the earthing switch front handling unit;

Figure 10 is a perspective view showing an installed state of a

electromagnetic lock assembly for ground switch and control signal lines and simultaneously shows a projected state of a lock pin of the electromagnetic lock assembly;

Figure 11 is a perspective view showing an indented (withdrawn) state of the lock pin of the electromagnetic lock assembly on the ground switch;

Figure 12 is a perspective view showing the relatively installed positions of the electromagnetic lock assembly, a restraint plate, a manipulation shaft and a drive shaft in the earthing switch;

Figure 13 is an enlarged perspective view showing the configuration of the electromagnetic lock assembly and restriction plate and, simultaneously, a view showing an operating state of restricting the manipulation axis from being rotated to the connection state of bar allowed;

Figure 14 is a state showing an operating state of allowing the manipulation axis to be rotated to the permitted busbar connection state; and Figure 15 is a sectional view showing the details of the lock assembly.

electromagnetic.

Detailed Description of the Invention

A detailed description of the exemplary embodiments will now be given with reference to the accompanying drawings. For the sake of brief description with reference to the drawings, the same or equivalent components will be provided with the same reference numerals and the description thereof will not be repeated.

Later in this document a description will be given of a general configuration of a power distribution board having a grounding switch with reference to Figures 1 to 4.

The power distribution board 100 which has a grounding switch 30 of

According to one exemplary embodiment, it includes a compartment 10 (called a cubicle). A main circuit breaker body 20 of a vacuum circuit breaker may be received within a central part of housing 10 in a length direction, and the earthing switch 30 is received on one side of a lower part of housing 10. 35 Figure 1 or 2 shows the front of the grounding switch 30, and Figure 4 shows the inner side of housing 10 and a cradle 50 with the main breaker body 20 removed.

The cradle 50 supports the breaker main body 20 movably and includes cradle terminals 50a and 50b (see Figures 2 to 4) connected to the breaker main body 20 and external power supply side and electrical side circuits. . Each cradle terminal 50a and 50b can be electrically or mechanically connected to the circuit on the side of the external power source or the side of the electrical load, respectively. The lower cradle terminal 50b of cradle terminals 50a and 50b has a terminal extension portion 50b-1 made of an electrically conductive material.

A reference numeral 34 in FIG. 3 designates a grounding switch power transfer mechanism 30 for transferring a rotational driving force from a drive shaft 31, which will be explained later, to thereby rotate the 10 contact arms ( contactors) so that the contact arms can move to a close position (ground position) to contact cradle terminals 50b or to an open position (non-ground position) to be separated from terminals of cradle 50b. Here, the energy transfer mechanism

34 includes a cam, connecting rod, pivot shaft, contact arm bar, and the like, all without reference numerals.

Later in this document the description of a configuration and operation of a grounding switch front handling unit will be given with reference to Figures 5 to 9.

As shown in Figures 5 and 6, an earthing switch front handling unit according to the present disclosure includes a drive shaft connecting hole portion 31a and a handling shaft lever 32a.

Referring to Figures 8 or 9, a guard plate 33 may be fitted to the rear of a front plate of the front handle unit to be coaxial with the handle shaft lever 32a. The guard plate 33 is integrally or separately connected to the manipulation lever 32a based on the manipulation axis 32 as a rotational axis.

Referring to Figure 5 or Figure 8, when the manipulation shaft lever 32a is rotated toward the drive shaft connection hole portion 31a, the guard plate 33 closes the drive shaft connection hole portion 31a. . As a result, a handling cable H may not be connected to the front of the drive shaft 31 through the drive shaft connecting hole portion 31a, i.e. located in a restricted handling position (i.e. it is in a restricted handling state) where it is not permitted to manipulate the grounding switch 30 to a close position (ground position) or an open position (non-ground position).

In addition, with reference to Figure 6 or Figure 9, when the manipulation shaft lever 32a is rotated in a counterclockwise direction from the position of the drive shaft connecting hole portion 31a by a predetermined angle ( eg about 90 °), the guard plate 33 may open the drive shaft connecting hole portion 31a. As the guard plate 33 opens the front of the drive shaft 31, the handling cable H can be connected to the drive shaft 5 31 through the drive shaft connecting hole portion 31a, ie located at a permissible handling position (i.e. permissible handling state) where it is permissible to manipulate the grounding switch 30 to the close position (ground position) or the open position (non-ground position).

Here, the grounding key 30 is operable to the manipulated state allowed at any time by virtue of manipulation of the manipulating lever 32a. However, when the grounding switch 30 is manipulated to a grounding position under the conditions under which the terminals (not shown) of the main circuit breaker body 20 are connected to cradle terminals 50a and 50b (i.e., the connection position). circuit-breaker) and the moving contactors and stationary contactors for each phase within 15 of the main circuit breaker body 20 contact each other (ie, the closing position of the contactors), may cause a risk of a occurrence of ground fault.

Accordingly, the earthing switch 30, according to the preferred embodiment of the present disclosure, includes apparatus for allowing manipulation of a manipulation shaft 32 only when control electrical power is supplied under the conditions of the connection position. from the main circuit breaker body 20 and the contactor closing position, the manipulation shaft 32 may be restricted from being rotated and the earthing switch 30 may therefore be restricted from being manipulated to the closing (grounding) or opening position (not grounding), resulting in a guarantee of reliability 25 due to avoiding a safety-related electrical accident.

Later in this document, a description of the configuration and operation of an apparatus will be given as a characteristic component to allow manipulation of the manipulation axis only when control energy is supplied, with reference to Figures 10 to 15.

An earthing switch, according to an exemplary embodiment, includes

a rotary drive shaft 31 for manipulating a position of the earthing switch 30, and a manipulation shaft 32 having a guard plate 33 which is rotatable to a position to allow connection of the handling cable H relative to the axis 31 and a prohibited connection position therewith.

The grounding key 30, according to the preferred embodiment of the present

description further includes a restraint plate 60 shown in Figures 12 to 14, and an electromagnetic lock assembly 40 shown in Figures 10 to 15. The earthing switch 30 may additionally include a housing 41 to accommodate and support the electromagnetic lock assembly 40.

Restraint plate 60, as shown in Figures 12 to 14, is coupled to the manipulation axis 32 so that it is rotatable in conjunction with the manipulation axis 32. The manipulation axis 32 may be in the form of an angular axis having a plurality of flat surfaces. Restraint plate 60, as shown in Figures 13 and 14, includes a first flat portion 60a coupled to one of a plurality of flat surfaces, for example by screws in a surface contact state, and a second flat portion 60b extending from the first surface portion 60a by a predetermined angle (e.g. 90 °) and having at least one surface contactable with the electromagnetic lock assembly 40.

Restraint plate 60 may additionally include a third planar portion 60c extending from the second planar portion 60b by a predetermined angle (e.g. 90 °) and having at least one surface contactable with the mounting arrangement. electromagnetic lock 40.

Referring to Figures 12 to 14, the electromagnetic lock assembly 40 is installed adjacent to the restriction plate 60. According to whether or not electrical power is supplied, the electromagnetic lock assembly 40 has a lock position where it moves in. of a restriction plate 60 rotation location to restrict rotation of the restriction plate 60 and a release position where it moves away from the restriction plate rotation location 60 to allow rotation of the restriction plate 60.

To secure the electromagnetic lock assembly 40 to the position adjacent the restraint plate 60, a support bracket 42 having a predetermined height may be attached to a support base (reference number not given) of the earthing switch 30 in order to of 25 support the electromagnetic lock assembly 40. The electromagnetic lock assembly 40 may be coupled to an upper surface of the support bracket 42 by means of a set screw.

Referring to Figure 15, the electromagnetic lock assembly 40 includes a coil 40b, a lock pin 40a and a spring 40d. In addition, the electromagnetic lock assembly 40 may additionally include a carriage 40c surrounded by coil 40b.

Coil 40b configures an electromagnet, which is magnetized when a control electrical signal, that is, electrical energy is applied through signal lines L1 and L2 and a connector C shown in Figures 10 and 11, and demagnetized under no electricity supply. Referring to Figures 10 and 11, signal lines L1 and 35 L2 and connector C may be connected to electromagnetic lock assembly 40. Signal lines L1 and L2 consist of a control electrical line from a controller (not shown), such as a circuit breaker main body overcurrent relay 20, and a control power line connected between the Cea connector and the electromagnetic lock assembly 40, ie coil 40b (see Figure 15). Connector C is an element for connecting both control power lines and includes an inner conductive part and an outer insulating part.

Referring to Figure 15, lock pin 40a is installed to be movable for

in and out of bovine 40b. When coil 40b is magnetized, lock pin 40b is attracted by a magnetic force from coil 40b to be retracted (withdrawn) to the release position relative to restriction plate 60. In contrast, when coil 40b is demagnetized, lock pin 40b may be depressed by an elastic spring force 40d to be projected to the lock position with respect to restraint plate 60.

Still referring to Figure 15, spring 40d can apply tensile force to lock pin 40a to project to the lock position relative to restraint plate 60 when coil 40b is demagnetized.

Later in this document, a description of an operation of a restraint device for restricting the manipulation of the earthing key, especially rotation of the manipulation axis according to the exemplary embodiment, will be given with reference to Figures 10 to 15.

Firstly, a manipulation axis rotation restriction operation will be described with reference to Figures 10 and 13.

When the control electric signal, ie the electric power is not su

Through the signal lines L1 and L2 and connector C, coil 40b (see Figure 15) is degaussed.

Therefore, spring 40d presses locking pin 40a. Lock pin 40a is then designed for a location of restriction plate 60 rotation as shown in Figure 13.

Accordingly, even if one attempts to manipulate the manipulation shaft 32 at a predetermined angle (e.g. 90 °) by rotating the manipulation shaft lever 32a in a counterclockwise direction, the locking pin 40a restricts the rotation. from the third flat portion 60c of the restriction plate 60, thus counterclockwise rotation of the manipulation axis 32 by the corresponding angle cannot be permitted. Consequently, the guard plate 33 shown in Figure 8 avoids approaching, that is, the connection of the handling cable H with respect to the drive shaft 31, thus rendering the earthing switch 30 unable to be manipulated to a position of close (ground) or an open (non-ground) position. Therefore, even when the vacuum circuit breaker is in the plug-in position and the internal contacts are in the close position, the earthing switch 30 is unable to be manipulated to the earthing position, which may result in the avoidance of a occurrence of ground fault.

Later in this document, a description will be given of an operation of rotating the handling shaft when the vacuum circuit breaker is in a test position, ie when the terminals of the main circuit breaker body are separated from the cradle, but control energy is applied with reference to Figures 11 and 14.

When the control electrical signal, ie electrical power is applied through signal lines L1 and L2 and connector C, coil 40b (see Figure 5) is magnetized.

As lock pin 40a is then attracted by a magically attractive force

In the case of coil 40b, the lock pin 40a is moved back by overcoming the spring tensile force 40d (see Figure 15). Accordingly, the lock pin 40a, as shown in Figure 14, is withdrawn to a position outside the rotation plate restraint location 60.

Accordingly, under manipulation of the manipulation shaft 32 by a predetermined angle 15 (e.g. 90 °) by rotating the manipulation shaft lever 32a in a counterclockwise direction, the locking pin 40a does not interrupt the rotation of the third flat portion 60c of the restriction plate 60 so that the manipulation shaft 32 can be rotated counterclockwise by the corresponding angle. Accordingly, the guard plate, as shown in Figure 9, is turned in the counterclockwise direction 20 to open the drive shaft connecting hole portion 31a to allow approach, that is, the connection of the power cable. manipulation H with respect to the drive shaft 31. Consequently, the earthing switch 30 can be manipulated to the closing (grounding) position or the opening (non-grounding) position.

With the configuration, the handling cable H is connected to the drive shaft 31 and the drive shaft 31 is driven to thereby manipulate the earthing switch to the earthing position, thus preventing an electrical accident such as like an electric shock from a test operator.

As mentioned above, the earthing switch according to the present description includes a restraint plate connected to a manipulation axis thereof so that they are rotatable together, and an electromagnetic locking assembly having the locking position, where it projects to a restriction plate rotation location to restrict rotation of the restriction plate and a release position, where it is moved away from the restriction plate rotation location to allow rotation of the restriction plate, according to whether or not electric power is applied. Accordingly, manipulation of the earthing switch handling shaft may be permitted or restricted by magnetizing or demagnetizing the electromagnetic lock assembly. Consequently, under a situation where the vacuum circuit breaker is in a close position (a conductive connection position) and the earthing switch has to be restricted from being manipulated to a close position (grounding position), the Grounding switch handling shaft may not be allowed to operate, thus preventing the ground fault from occurring in advance.

The electromagnetic lock assembly according to the present description includes

a magnetized coil when power is applied and demagnetized when electric power is not applied, an installed locking pin being linearly movable in and out of the coil, with the locking pin being withdrawn to the release position when the coil is magnetized and projected to the locking position when the coil is demagnetized, and a spring to apply an elastic force to the locking pin to project into the locking position. Accordingly, the electromagnetic lock assembly can be effectively controlled or actuated to the lock position and release position to restrict and allow manipulation shaft rotation in a simple manner according to whether electrical power is applied.

The handling shaft for the earthing switch may consist of an angled shaft.

having a plurality of flat surfaces, and the restraining plate may include a first flat portion connected to one of the plurality of flat surfaces of the manipulation axis in a surface contact state, and a second flat portion extending to from the first planar part by a predetermined angle and having at least 20 a surface contactable with the electromagnetic lock assembly. With the configuration, as the first flat portion of the restraint plate is connected to an angled axis surface in the surface contact state, the manipulation axis and the restraint plate can be more firmly connected to each other. Further, the second flat portion may be controlled by the electromagnetic lock assembly such that the restraint plate may be restrained from being rotated or released to be rotated.

The foregoing embodiments and advantages are simply exemplary and should not be construed as limiting the present disclosure. These instructions may be readily applied to other types of apparatus. This description is intended to be illustrative and not to limit the scope of the claims. Many alternatives, modifications, and variations will be apparent to those of skill in the art. The features, structures, methods and other features of the exemplary embodiments described herein may be combined in various ways to obtain additional and / or alternative exemplary embodiments.

As these features can be incorporated into various forms

without departing from the characteristics thereof, it should also be understood that the embodiments described above are not limited by any of the details of the aforementioned description, except where otherwise specified, but should preferably be interpreted broadly within its scope. scope, as defined in the appended claims and, therefore, all changes and modifications that fall within the scope and boundaries of the claims, or the equivalents of such boundaries and boundaries, are therefore intended to be included by the appended claims.

Claims (3)

1. Grounding switch that has a rotary drive shaft to manipulate a position thereof, and a manipulation shaft that has a rotary guard plate for one position to allow connection of a manipulation cable to the drive shaft and a position for restricting the connection thereof, characterized by the fact that the earthing switch comprises: a restriction plate connected to the manipulation axis to be rotatable in conjunction with the manipulation axis; and an electromagnetic lock assembly mounted adjacent the restriction plate, wherein the electromagnetic lock assembly has a projection lock position at a restriction plate rotation location to prohibit a restriction plate rotation and a position release of the restriction plate rotation location to allow rotation of the restriction plate. A key according to claim 1, characterized in that the electromagnetic lock assembly comprises: a magnetized coil when electrical power is supplied and demagnetized when electric power is not supplied; a locking pin installed to be movable linearly into or out of the coil and withdrawn to the release position when the coil is magnetized and projected to the lock position when the coil is demagnetized; and a spring that applies a tensile force to the lock pin to project into the lock position. A key according to claim 1, characterized in that the manipulation axis consists of an angular axis having a plurality of flat surfaces, wherein the restriction plate comprises: a first flat portion connected to one of the plurality of plane surfaces of the manipulation axis in a surface contact state; and a second planar part extending from the first planar part by a predetermined angle and having at least one surface contactable with the electromagnetic lock assembly.