KR20110103675A - Switching structure for automatic trans switch - Google Patents

Abstract

The present invention relates to an automatic transfer switch (ATS).
In the automatic power supply switching device, a serious problem may occur in contact failure. In the case of the conventional method of rotating the bar-shaped terminal rotation shaft on one side, even force is not transmitted to the terminal rotation shaft. There was a possibility that a defect could occur.
The present invention is to provide a stable operating environment by configuring the power supply automatic switching device in the bottom set type, by transmitting the rotational force in the center of the bar-shaped terminal rotation shaft to ensure that a uniform rotational force is transmitted to the terminal rotation shaft, and also directly to the terminal rotation shaft The driving piece is formed on the terminal rotation shaft, not the method of applying the rotational force, and the rotational force can be applied to the driving piece so that the terminal rotation shaft can be rotated by the driving piece, thereby providing a stable contact with the fixed terminal of the movable terminal. It is to provide an automatic switching device.

Description

Rotating structure of moving terminal of automatic power switch device {SWITCHING STRUCTURE FOR AUTOMATIC TRANS SWITCH}

The present invention relates to an automatic transfer switch (ATS), and more particularly, a power automatic switching switch device for automatically switching (switching) from a commercial power source to an emergency power source so that an emergency power source can be used when a power failure occurs. It relates to a movable terminal rotation structure of.

The automatic power switch (ATS), also known as an emergency power switch, is a normal power source, such as a power failure or undervoltage, when it is composed of a reserve power source (generator or KEPCO reserve line power) in addition to the commercial power source supplied by KEPCO. It is a device that automatically transfers (switches) to reserve power when supply is not made.

In case of large-scale workplaces such as hospitals, factories, research institutes, broadcasting stations, etc., where there is a problem when the power supply is cut off, we have a generator to generate emergency power. ) Is used by installing automatic power switch to supply when there is a problem with commercial power.

The automatic power supply switch is a fixed terminal consisting of a commercial power terminal, an emergency power terminal and a load terminal, and an operation of being electrically connected to the commercial power terminal or the emergency power terminal in an electrically connected state with the load terminal. It consists of terminals.

These automatic power supply switching switch is required for each separate rotation device for rotation from the commercial power terminal to the emergency power terminal, the emergency power terminal to the commercial power terminal.

Therefore, the applicant of the present application has applied for and registered an automatic switching switch having a simple configuration and less likely to malfunction. (Patent registration No. 721270; automatic switching switch)

According to Patent Registration No. 721270, the movable terminals are configured to be coupled to a bar-shaped terminal rotating shaft, the terminal rotating shaft is connected to the manipulator, and the terminal rotating shaft rotates according to the rotation of the manipulator, and the movable terminal is fixed terminal. It is made of a structure that can be contacted and developed.

As shown in FIG. 1, the bar-shaped terminal rotation shaft 2 rotates as the rotation control means 1 rotates, and the movable terminal 3 coupled to the terminal rotation shaft 2 rotates. The contact terminals 3a and 3b formed on the movable terminal 3 come into contact with the fixed terminals formed at corresponding positions.

This structure can be represented as shown in FIG.

As described above, the movable terminal 3 for contacting the fixed terminals for the respective phases R, S, T, and N is coupled to the terminal terminal shaft 2 in the form of a bar, and the rotation control means 1 The rotational force is transmitted to the bar-shaped movable terminal 3 to form a structure in which the movable terminal 3 rotates from side to side and contacts the fixed terminal while the movable terminal 3 rotates.

 However, such a conventional power supply automatic switching device is a position where the rotational force is transmitted to one side so that the rotational force transmitted to each of the movable terminals 3 may appear different contact failure may occur.

That is, the length of the terminal rotation shaft (2) is generally composed of about 600mm bar, as the rotational force is transmitted from one side to the torsion (rotation force) applied to each position of the terminal rotation shaft (2) is changed, the rotation As the position N of the terminal rotation shaft 2 away from the control means 1 increases, there is a high probability of contact failure.

In addition, such a conventional power supply automatic switching device is configured as a wall-mounted type is attached to the wall, the operation may not be made stable as the operation is repeated.

The present invention is to provide a stable operating environment by configuring the power supply automatic switching device in the bottom set type, by transmitting the rotational force in the center of the bar-shaped terminal rotation shaft to ensure that a uniform rotational force is transmitted to the terminal rotation shaft, and also directly to the terminal rotation shaft The driving piece is formed on the terminal rotation shaft, not the method of applying the rotational force, and the rotational force can be applied to the driving piece so that the terminal rotation shaft can be rotated by the driving piece, thereby providing a stable contact with the fixed terminal of the movable terminal. It is to provide an automatic switching device.

The movable terminal rotation structure of the automatic power switch device of the present invention is a commercial power terminal or an emergency power terminal connected to the emergency power source and the terminal for contact switching with the load terminal connected to the load, and the movable terminal part to rotate the commercial In the automatic switching switch comprising a rotation control means for contacting the power supply fixed terminal or the emergency power fixed terminal,

Transmitting the rotational force to the center position of the terminal shaft so that the rotational force can be applied with equal force to each of the terminal rotating shaft rotatably installed on the inner wall of the main body through the central portion of the movable terminal portion and each of the movable terminal connected to the terminal rotating shaft And a control link unit for transmitting the rotational force provided from the rotation control unit to the terminal rotating shaft through the rotating link unit to rotate the terminal rotating shaft.

According to the present invention, in the structure for rotating the terminal rotation shaft for switching the contact with the fixed terminal portion by rotating the movable terminal portion at once, the force is applied to each movable terminal portion evenly by transmitting the rotational force to the center position By being transmitted, problems such as poor contact can be prevented.

On the other hand, even in the transmission of force to the terminal axis of rotation to connect the triangular drive piece so that the same force is transmitted to the upper and lower side to the terminal axis of rotation by forming a connection link so that the force is transmitted to the upper and lower sides of the drive piece rotation of the terminal axis of rotation By making it more accurate, it is possible to provide a switching structure that can provide accurate contact and prevent contact failure of the movable terminal portion.

In addition, according to the structure of the present invention by providing a structure suitable for the settled form, it is possible to provide an environment required for more stable switching than the method of attaching to the wall.

1 is a view showing the structure of a conventional power automatic switching switch.
Figure 2 is a view schematically showing the operation of the conventional power supply automatic switching switch.
Figure 3 is a schematic view showing the operation of the automatic power switch device according to the present invention
4 is a view showing the connection structure of the rotary link unit and the terminal rotary shaft in the movable terminal rotation structure of the present invention automatic power switch device (cover coupled state).
5 is a view for showing the operation of the rotary connecting portion and the terminal rotary shaft in accordance with the position of the control moving shaft in the present invention.
Figure 6 is a view for showing the operation of the rotary connecting portion and the terminal rotary shaft in accordance with the position of the control moving shaft in the present invention.
7 is a view showing an embodiment of a rotation control unit in the present invention.
Figure 8 is an exploded perspective view of Figure 7 in the present invention.
9 is a view showing the operating state of the movable terminal portion in the present invention. (Commercial power connection status)
10 is a view showing the operating state of the movable terminal portion in the present invention. (Emergency Power Connection)
11 is a view showing a main body case rear surface of an automatic power supply switching device in the present invention.
12 to 16 are views showing the operation of the rotation control unit in the present invention.

Referring to the embodiment shown in Figures 3 to 16 attached to the movable terminal rotation structure of the automatic power switch device according to the present invention will be described the structure and operation process as follows.

A fixed terminal part consisting of a commercial power terminal 10 connected to a commercial power source, an emergency power terminal 20 connected to an emergency power source and a load terminal 30 connected to a load, and electrically connected to the load terminal 30. And the movable terminal unit 40 selectively contacted with the commercial power supply terminal 10 or the emergency power supply terminal 20 and electrically connected to the commercial power terminal 10 according to the operation control of the rotation control unit 90. Switching means for selectively electrically connecting the power terminal 10 or the emergency power terminal 20;

The switching means includes a terminal rotation shaft 50 rotatably installed on the inner wall of the main body 80 through the center of each movable terminal portion 40, and a rotation link unit 60 for transmitting rotational force to the terminal rotation shaft 50. And, a control link unit 70 for rotating the terminal rotation shaft 50 through the rotary link unit 60, and a rotation control unit 90 for controlling the switching of the movable terminal unit 40 by driving the control link unit 70. It is configured to include).

The rotary link unit 60 is connected to the center position of the terminal rotation shaft 50, the drive piece 61 for transmitting a rotational force to the terminal rotation shaft 50, and the control moving shaft 72a operation of the control link unit 70 According to the present invention, the upper and lower sides of the driving piece 61 are moved forward and backward so as to rotate the terminal rotation shaft 50.

The control link unit 70 is coupled to the fixed shaft 71 in a rotatable structure and includes a control link 72 including a control moving shaft 72a that moves according to the operation of the rotation controller 90 about the fixed shaft 71. And a guide panel 73 for guiding the movement of the control movement shaft 72a so that the fixed shaft 71 is fixed and the control movement shaft 72a is rotatable about the fixed shaft 71.

The cover 75 may further include a cover 75 for preventing the flow of the connection link 63 operated on the guide panel 73.

The guide panel 73 is installed and fixed to the upper and lower body frames 81 and 82, and the control moving shaft 72a moving around the fixed shaft 71 of the control link unit 70 is fitted therein, and the fixed shaft 71 is fixed. The guide slot 74 is formed in an arc shape having a predetermined angle about the fixed shaft 71 to guide the movement path of the control movement shaft 72a moving to the center.

The link portion 62 is coupled to the control movement shaft 72a coupled to the guide slot 74 of the guide panel 73 at the upper portion thereof, and the slot 64 is movable along the path moving on the guide slot 74. Is formed and the control link axis (72a) is moved along the guide slot 74 when the link link 63 and the rotation center axis 65 of the structure that rotates about the rotation center axis 65, the center The upper link 66 and the lower link 67 having a rotatable coupling structure for rotating the terminal rotation shaft 50 by moving the upper and lower sides of the drive piece 61 as it rotates.

The present invention is connected to the center of the movable terminal unit configured for each phase (R, S, T, N) to connect the movable terminal to the terminal rotation shaft and to rotate the terminal rotation shaft to contact the commercial power terminal or emergency power terminal In order to selectively switch the power supply by connecting to the load terminal, by rotating the terminal rotating part from the center of the terminal rotating shaft to rotate the terminal rotating shaft by the distribution of equal force, the possibility of poor contact can be minimized. It is characterized by that.

As shown in FIGS. 9 and 10, as the terminal rotation shaft 50 rotates, the movable terminal unit 40 has a commercial power terminal 10 and an emergency power terminal 20 configured at positions corresponding to upper and lower sides, respectively. The conductive contact terminals 41 and 42 of the movable terminal 44 are in contact with each other, and the load connecting terminal 43 is connected to each of the contact terminals 41 and 42.

The number of the contact terminals 41 and 42 may be configured differently depending on the wiring type (2-wire, 3-wire, 4-wire).

The fixed terminal unit includes a commercial power terminal 10 connected to a commercial power source, an emergency power terminal 20 connected to an emergency power source, and a load terminal 30 connected to a load.

The commercial power terminal 10 is a fixed terminal connected to the Korea Electric Power side, the emergency power terminal 20 is composed of a fixed terminal connected to the emergency generator, the fixed terminal is a type of commercial power (single phase, three phase), wiring It may be applied differently depending on the type (2-wire, 3-wire, 4-wire, etc.).

The switching means operates the terminal rotating shaft 50 for rotating the movable terminal unit 40, the rotary link unit 60 for rotating the terminal rotating shaft 50, the control link unit 70, and the control link unit 70. It is configured to include a rotation control unit 90 for.

The terminal rotation shaft 50 is connected to each center of the movable terminal 44 is made of a structure installed in a rotatable structure to the main body (80).

That is, as the terminal rotation shaft 50 rotates, the contact terminals 41 and 42 of the movable terminal portion 40 move forward to come into contact with the fixed terminal portion to supply the corresponding power.

The rotary link unit 60 is a link unit for rotating the terminal rotating shaft 50 by operating the drive piece 61 and the driving piece 61 connected to the terminal rotating shaft 50, in order to rotate the terminal rotating shaft 50. And (62).

The driving piece 61 has a structure connected to the center position of the terminal rotation shaft 50 so that an even force may be applied to the terminal rotation shaft during rotational force transmission.

That is, when the movable terminal portion 40 for R, S, T, and N is formed on the terminal rotation shaft, the driving piece is positioned at the position where the movable terminal portion 40 for R, S and the movable terminal portion 40 for T, N are divided. It constitutes 61.

The driving piece 61 is formed in a triangular shape having three corner portions, one corner portion is connected to the terminal rotation shaft 50, and the other two corners are respectively the upper link 66 and the lower link of the link link 63 ( 67 is made of a structure connected to the drive piece 61 in accordance with the movement of the upper link 66 and the lower link (67).

The connecting link 63 is a connecting link coupled to the guide panel 73 in a structure rotatable about the upper link 66 and the lower link 67 connected to the driving piece 61, and the rotation center axis 65. 63).

The link link 63 has a structure in which the control movement shaft 72a rotates about the rotation center axis 65 while moving along the guide slot 74, and the upper link 66 and the lower link 67 rotate. The upper link 66 and the lower link 67 is configured to rotate forward and backward in a different direction as the link link 63 rotates. .

The control link unit 70 is coupled to the control shaft (72a) and the fixed shaft (71) which moves about the fixed shaft (71) by the force applied from the rotation control unit (90) and around the fixed shaft (71). It comprises a guide panel 73 for guiding the moving control movement shaft (72a).

The guide panel 73 is configured with a guide slot 74 for guiding the control movement shaft 72a, and the guide slot 74 has an arc shape having a constant angle with respect to the position where the fixed shaft 71 is coupled. .

The cover 75 is configured to prevent the flow of the connection link 63 that is operated on the guide panel 73 as the control movement shaft 72a is moved by the elastic means so that an impact may occur during the movement.

The control movement shaft 72a is inserted into the slot 64 of the link link 63 to move the link link 63 together while moving in the guide slot 74 to operate the upper link 66 and the lower link 67. To help.

The rotation control unit 90 may have various forms of transmitting power so that the control movement shaft 72a is rotated about the fixed shaft 71.

In the present embodiment will be described with an embodiment applying the applicant's patent registration No. 721270 shown in Figs.

The rotation control unit 90 includes a pressurizing unit 91 for applying an elastic force to one of the ends of the guide slot 74 by the control link unit 70 about the fixed shaft 71, and the control movement shaft 72a. It comprises a movement control means for moving from one end of the guide slot 74 to the other end.

One end of the pressing portion 91 is installed in a rotatable structure to an installation panel 93 fixed to the fixing panel 92 and the guide panel 73, and the other end thereof is connected to the control movement shaft 72a and has a length thereof. The variable link 94 and an elastic member 95 for pushing the control movement shaft 72a may be configured.

Here, the fixing panel 92 and the guide panel 73 serve as an installation and case of the rotation control unit 90.

In this case, the elastic member 95 is a coil spring and is coupled to the variable link 94 in a state where the variable link 94 is fitted.

The variable link 94 is hinged to the installation panel 93 so as to smoothly rotate by the movement of the control movement shaft 72a.

Although the rotation control unit 90 is not shown, a lever for pressing the pressing unit 91 to rotate the control movement shaft 72a so that the user can manually move the control movement shaft 72a may be installed separately. have.

The movement control unit is configured such that the control movement shaft 72a rotates from one end to the other end along the guide slot 74 about the fixed shaft 71.

The movement control unit includes a hooking link 96, a rotation link unit and a rotation unit 97.

The hooking link 96 is rotatably coupled to the fixed shaft 71, and comprises a pair of hooking protrusions (96a, 96b) formed to catch the control movement shaft (72a).

The rotating link unit rotates the hooking link 96 by rotating the hooking link 96 about the fixed shaft 71 so that the control moving shaft 72a caught by the hooking protrusions 96a and 96b rotates. To this end, a first support link (98) rotatably installed at one end of the installation panel (93), and a second support link (99) rotatably coupled to the other end of the first support link (98). A pin guide slot 101 is formed to insert the link pin 100 coupled to the other end of the second support link 99 and is fixedly connected to the hooking link 96 by the coupling shaft 102 to the hooking. And a cam link 103 that rotates with the link 96.

The first support link 98 is rotatably supported by a hinge member fixed to the installation panel 93.

On the other hand, the rotating part is configured to rotate the first support link 98 about the hinge member, and as shown, the coupling rod 105 is coupled between both ends of the first support link 98 In addition, the coupling rod 105 may be configured to include a pressing device 106 to push the upper support link 98 is rotated around the hinge member.

The pressurizing device 106 is configured to allow the coupling rod 105 to move linearly. In particular, the pressurizing device 106 may be a solenoid.

When the pressurizing device 106 is used as a solenoid, it may be operated by applying only a momentary voltage, and the coupling rod 105 may be configured as a part of the solenoid.

Rotating control unit 90 is not limited to the configuration as described above, and a variety of constituting the power transmission means to move the control movement axis (72a) at a predetermined angle in the downward direction about a fixed fixed axis 71 from the upper side It can be configured in the form.

On the other hand, the above configuration including the rotation control unit is configured to configure the main body case is built inside, Figure 11 is a view showing the back of the automatic switching switch embedded in the case in this embodiment of the present invention.

Referring to the operation of the automatic switching device according to the present invention having such a configuration in detail as follows.

The automatic switching switch device is installed between the load and the power consisting of commercial power and emergency power to supply power to the load.

That is, as shown in Figure 11 is installed by connecting the commercial power, emergency power, load to the fixed terminal portion formed in the rear portion of the main body case.

9, the contact terminal 41 of the movable terminal 44 is brought into contact with the commercial power supply terminal 10 so that the commercial power is supplied to the load, and thus the load terminal 30 and the commercial power supply terminal 10 are normally supplied. To remain electrically connected.

At this time, the contact terminal 42 and the emergency power supply terminal 20 of the movable terminal 44 is maintained in an open state.

On the other hand, when emergency power is required, such as a power failure, the movable terminal 44 is electrically switched as shown in FIG. 10 so that the emergency power terminal 20 and the load terminal 30 are electrically connected. The contact terminal 42 of) should be in contact with the emergency power supply terminal 20, the commercial power supply terminal 10 should be opened.

Here, this operation can be enabled by the operation of the automatic control device or the user using the sensing means.

By the rotation control unit 90, the control movement shaft 72a is moved around the fixed shaft 71 in the guide slot 74 of the guide panel 73 to move the position to both ends.

Usually, as shown in FIG. 5, the control movement shaft 72a is positioned at 'A'.

When the control movement shaft 72a is in the position of 'A', the position of the control movement shaft 72a is biased toward the movable terminal portion 40 than the rotation center axis 65 of the connection link 63, so that the connection link 63 ) Is inclined toward the movable terminal portion 40.

Therefore, the upper link 66 connected to the connection link 63 is closer to the movable terminal portion 40 side, the lower link 67 is located at a position further away from the movable terminal portion 40.

Accordingly, as shown in FIG. 5 by the upper link 66 and the lower link 67, the driving piece 61 is inclined, and as shown in FIG. 9 while the terminal rotation shaft 50 is rotated, The contact terminals 41 and 42 of the movable terminal unit 40 remain in contact with the commercial power supply terminal 10.

On the other hand, when emergency power is needed, the control movement shaft 72a is moved by the rotation generator 90 along the guide slot 74 about the fixed shaft 71 to the position of 'B'. do.

When the control movement shaft 72a moves to the position of 'B', the upper portion of the connection link 63 connected to the control movement shaft 72a moves to the opposite side of the movable terminal portion 40 and the upper link of the connection link 63 66 is moved away from the movable terminal portion 40, the lower link 67 is inclined in the form of the lower portion of the drive piece 61 is pushed toward the movable terminal portion 40 as the movable terminal portion 40 approaches.

Accordingly, as the terminal rotation shaft 50 connected to the driving piece 61 rotates, as shown in FIG. 10, the lower contact terminal 42 of the left and right sides RS (TN) movable terminal portion 40 of the driving piece is inward. While inclined in a pushed form, the contact terminal 42 of the movable terminal 44 contacts the emergency power terminal 20 to form a structure in which the emergency power terminal 20 is connected to the load.

In order to designate the contact position of the movable terminal portion 40, the control movement shaft 72a is positioned at both ends in the guide slot 74 of the guide panel 73, and the control movement shaft 72a is moved from 'A' to ' The rotation controller 90 is configured to move from 'B' to 'A' as B '.

As described above, the rotation control unit 90 may be configured in a form in which a sensor or a user manually operates, and the operation may also be performed by a motor and a method of manually operating by a user using a lever. In the present invention, an embodiment using a solenoid is to control the movement of the control shaft to each position by pressing the elastic means by using the elastic means.

Referring to the operation of the rotation control unit is as follows.

First, the pressurizing device 106 of the rotation control unit pushes the coupling rod 105 connected to the first support link 98 upwards, as shown in FIGS. 13 and 14.

As the coupling rod 105 is pushed upward, the first support link 98 rotates about the hinge member 104 and the first support link 98 is rotated by the first support link 98. The second support link 99 rotatably coupled to the end of the push is pushed upwards.

Meanwhile, the link pin 100 coupled to the other end of the second support link 99 pushes the cam link 103, and the cam link 103 rotates around the fixed shaft 71. The hooking link 96 fixedly coupled to the cam link 103 by the rotation of the 103 is also rotated about the fixed shaft 71.

When the hooking link 96 rotates about the fixed shaft 71, the hooking protrusion 96b of the hooking link 96 exerts a force on the control moving shaft 72a, and the control moving shaft 72a is It rotates along the guide slot 74 about the fixed shaft (71).

In addition, by the rotation of the control movement shaft (72a), the elastic member 95 of the pressing unit 91 is contracted while applying an elastic force to the control movement shaft (72a).

The control movement shaft 72a rotates along the guide slot 74 to move from the 'A' position to the position as shown in FIG.

When the control movement shaft 72a passes through the position as shown in FIG. 14, the control movement shaft 72a rapidly moves to the 'B' position by the elastic force applied to the control movement shaft 72a by the elastic member 95 of the pressing unit 91. Will be moved to.

At this time, the pressurizing device 106 stops its operation as soon as the control movement shaft 72a passes the position as shown in FIG. 14, and the coupling rod 105 is lowered downward.

As a result, the control movement shaft 72a moves from the 'A' position to the 'B' position, and the contact terminal 41 is in an open state with the commercial power supply terminal 10, as shown in FIG. 42 is short-circuited with the emergency power supply terminal 20.

On the other hand, the automatic switching switch according to the present invention in the state shown in Figure 12 in the state shown in Figure 15, the contact terminal 41 is a short circuit state with the commercial power terminal 10, the contact terminal 42 is an emergency power terminal A process of changing to the open state with the reference numeral 20 will be described with reference to FIGS. 15 and 16.

The contact terminal 41 is short-circuit with the commercial power supply terminal 10, the process of changing the contact terminal 42 to the open state with the emergency power terminal 20, the control movement shaft 72a is rotated in the 'B' position By moving to the 'A' position.

First, the pressurizing device 106 of the rotation controller 90 pushes the coupling rod 105 connected to the first support link 98 to the upper side, as shown in FIG. 16.

As the coupling rod 105 is pushed upward, the first support link 98 rotates about the hinge member 104 and the first support link 98 is rotated by the first support link 98. The second support link 99 rotatably coupled to the end of the push is pushed upwards.

Meanwhile, the link pin 100 coupled to the other end of the second support link 99 pushes the cam link 103, and the cam link 103 rotates around the fixed shaft 71. The hooking link 96 fixedly coupled to the cam link 103 by the rotation of the 103 is also rotated about the fixed shaft 71.

When the hooking link 96 is rotated about the fixed shaft 71, the hooking protrusion 96b of the hooking link 96 exerts a force on the control moving shaft 72a, and the control moving shaft 72a is The guide shaft 74 is rotated about the fixed shaft 71.

In addition, by the rotation of the control movement shaft (72a), the elastic member 95 of the pressing unit 91 is contracted while applying an elastic force to the control movement shaft (72a).

The control movement shaft 72a rotates along the guide slot 74 to move from the 'B' position to the position as shown in FIG. 16.

When the control movement shaft 72a passes through the position as shown in FIG. 16, the control movement shaft 72a rapidly moves to the 'A' position by the elastic force applied to the control movement shaft 72a by the elastic member 95 of the pressing unit 91. Will be moved to.

At this time, the pressurizing device 106 stops its operation as soon as the control movement shaft 72a passes the position as shown in FIG. 16, and the coupling rod 105 is lowered downward.

As a result, the control movement shaft 72a moves from the 'B' position to the 'A' position, and the contact terminal 41 is in an open state with the commercial power supply terminal 10, as shown in FIGS. 10 and 14. The contact terminal 42 is changed to a short circuit state with the emergency power supply terminal 20.

Claims (5)

It includes a movable terminal unit for making contact switching of the commercial power terminal or emergency power terminal with the load terminal connected to the load, and a rotation control unit for rotating the movable terminal to contact the commercial power stationary terminal or emergency power fixed terminal. In the automatic switching switch,
Rotating force with equal force to the terminal rotation shaft 50 which is rotatably installed on the inner wall of the main body 80 through the center of each movable terminal portion 40 and the respective movable terminal portions 40 connected to the terminal rotation shaft 50. The rotary link unit 60 for transmitting the rotational force to the center position of the terminal rotation shaft 50 and the rotational force provided from the rotation control unit 90 to the terminal rotation shaft 50 through the rotation link unit 60 so that it can act Transmitting to the control terminal for rotating the terminal axis of rotation (50) 70, characterized in that it comprises a control terminal switch structure for moving the power supply device characterized in that it comprises a. According to claim 1, The rotary link unit 60 is connected to the center position of the terminal rotation shaft 50, the drive piece 61 for transmitting a rotational force to the terminal rotation shaft 50, and the top and bottom of the drive piece 61 Each side is connected to the side position, the other side is connected to the control link unit 70, the link unit for rotating the terminal rotation shaft 50 by moving backward and upward according to the rotational force transmitted from the control link unit 70 And (62) a movable terminal rotation structure of a power supply automatic switching switch device. According to claim 2, wherein the drive piece 61 is made of a triangular shape having three corners, one edge is connected to the terminal rotation shaft 50, the other two corners are connected to the link portion up and down A rotating structure of a movable terminal of a power supply automatic switching switch device, characterized in that the terminal rotation shaft 50 is rotated by a force pushed on it. According to any one of claims 1 to 3, the control link unit 70 is coupled to the fixed shaft 71 in a rotatable structure in accordance with the operation of the rotation control unit 90 around the fixed shaft 71 A control link 72 including a control moving shaft 72a moving in a gentle arc shape along a predetermined angle;
It comprises a guide panel 73 formed with a guide slot 74 for guiding the movement of the control movement shaft (72a) so that the control movement shaft (72a) is rotatable,
The link portion 62 is coupled to the control movement shaft 72a coupled to the guide slot 74 of the guide panel 73 at the upper portion thereof, and is slot 64 so as to be movable along a path moving on the guide slot 74. Is formed so that the control movement shaft 72a moves along the guide slot 74, the connection link 63 and the rotation center shaft 65 having a structure that rotates about the rotation center shaft 65. Power source, characterized in that it comprises an upper link 66 and a lower link 67 having a rotatable coupling structure for rotating the terminal rotation shaft 50 by pushing the upper and lower sides of the drive piece 61 in accordance with the rotation to Rotating structure of the moving terminal of the automatic switching device. 5. The automatic power switch according to claim 4, further comprising a cover (75) for covering the guide panel (73) to prevent the flow of the link link (63) operated on the guide panel (73). Rotation structure of the movable terminal of the device.

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