KR20160093918A - Power transmission and blocking device - Google Patents

Abstract

The present invention relates to a power transmission and cutoff device including at least one conductive pin inserted into a socket where electricity is supplied and receiving the electricity from the socket; a housing having one end joined to the conductive pin while covering a part of the conductive pin and the other end with at least one hole where a plug of an electronic device is inserted at a position corresponding to the conductive pin; a switching unit positioned between the internal hole of the housing and the conductive pin and transmitting or cutting off the electricity supplied through the conductive pin to the plug; and a manipulation unit displacing the switching unit to transmit or cut off the electricity of the switching unit. Accordingly, the power transmission and cutoff device enables anyone to manipulate the manipulation unit of the power transmission and cutoff device to transmit or cut off the electricity supplied from the socket without forcibly inserting or separating the plug of the electronic device into/from the socket. In addition, the power transmission and cutoff device is used by being inserted into the socket, and the plug of the electronic device can be inserted into the hole of the housing, thus the power transmission and cutoff device can be used without a separate plug of the electronic device. Additionally, the power transmission and cutoff device is capable of securing safety by reducing danger caused by a defective connection of the plug inserted into the socket and preventing sparks which may be generated in the switch unit and a transmission part by forming an extinction unit connected to the transmission part inside the housing.

Description

[0001] POWER TRANSMISSION AND BLOCKING DEVICE [0002]

The present invention relates to a power transmission and blocking device.

In general, electrical energy has been used extensively in the 19th century, due to its ease of operation, ease of conversion to other energies, environmental preservation, and relative safety, resulting in rapid transformation of human culture .

Thus, the expansion of time, space, and ability of mankind by electricity gives effect to all sectors of society, and as a driving force to realize human desire in all fields today, the importance of electric energy as the driving force of economic development is increased have.

The electric energy is transmitted to the plug through the receptacle, and supplies electric energy to the electric apparatus equipped with the plug to drive the electric apparatus.

However, the plug often does not easily plug in or out from the outlet, and if not used, it is necessary to physically disconnect the plug inserted in the outlet to prevent power waste.

In order to solve such a problem, Korean Patent Laid-Open Publication No. 10-0030721 (Filing Date: 1998.07.29, published on Feb. 2, 2000, hereinafter referred to as "prior art") discloses a plug- A plug provided with a power switch for turning off the plug is disclosed.

The prior art has a technical construction for opening / closing the supply of power by opening / closing the contact state by attaching a switch to any one of the two electric wires connected to the plug.

However, in such a conventional technique, it is inconvenient to provide a switch in a plug of all the electric apparatuses, and there is a problem that it can not be applied to a plug of a general electric apparatus which has been used in the past.

The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide an electric apparatus which can use a plug of an electric apparatus that has been used previously without any additional switch, The present invention is to provide a technique for conveniently shutting off standby power due to neglect of a plug inserted into an outlet.

In order to attain the above object, the power transmission and blocking device of the present invention includes at least one energizing pin inserted into an outlet to which electric power is supplied and receiving electric power supplied from the outlet; A housing having at least one hole for inserting a plug of an electric device at a position corresponding to the energizing pin; A switching unit located between the hole in the housing and the energizing pin and transmitting or blocking the power supplied through the energizing pin to the plug; And an operating portion for displacing the switching portion for power transmission or interruption of the switching portion.

Here, the energizing pin includes: an insertion portion to be inserted into the socket; And a transmitting portion connected to the insertion portion and contacting the switching portion to transmit electric power to the switching portion.

Further, the switching portion may include: a conductor portion that electrically connects the transmission portion and the plug; And a non-conductive portion for electrically disconnecting the transmission portion and the plug, wherein the conductive portion and the non-conductive portion are sequentially disposed.

The power transmission and blocking device may further include a braking unit located inside the housing for preventing sparks generated in the transmission unit and the switching unit.

On the other hand, the operating section includes a first switch extended from one side of the switching section; And a second switch extended from the other side of the switching unit.

Here, when the first switch is drawn into the housing, the switch portion is moved in the second switch direction so that a part of the second switch protrudes from the housing, and the conductor portion contacts the transmission portion do.

In addition, when the second switch is drawn into the housing, the switch portion is moved in the first switch direction so that a part of the first switch protrudes from the housing, and the non- do.

The switching unit may further include a switching spring which is disposed between one side of the switching unit and one side of the housing and provides an elastic force to the switching unit, and an oblique surface is formed on the other side of the switching unit.

Further, the operating portion may include a button portion protruding from one side of the housing; A beveled portion positioned inside the housing and extending from a lower portion of the button portion to move the switchable portion and having a beveled surface formed on one surface thereof; A fixing groove formed on one surface of the oblique surface portion and fixing the oblique surface of the switching portion moved in the direction of the switching spring; And an operating spring which is positioned between a lower portion of the oblique face portion and an inner side surface of the housing, and which provides an elastic force to the operating portion.

Here, when the button portion is lowered, the switching portion is moved in the direction of the switching spring by the oblique surface portion, the operating portion is raised by the operating spring, and the oblique surface of the switching portion is fixed by the fixing groove, A conductor portion is in contact with the transmission portion.

The present invention has the following effects.

First, even if the plug of the electric appliance is not inserted or separated by a physical force, it is possible to easily transmit or block the electric power supplied from the outlet to the plug of the electric appliance through the operation portion of the electric power transmission and blocking device.

Second, since the electric power transmission and blocking device can be inserted into a socket and used to insert a plug of an electric device into a hole of a housing, it can be used without being provided with a plug of an electric device.

Fifth, safety can be secured by reducing the risk of contact failure of the plug inserted into the socket-outlet.

Fourthly, it is possible to prevent the spark that may occur in the transmission portion and the switching portion by providing the inside of the housing.

1 is a cross-sectional view illustrating a power transmission and blocking device according to a first embodiment of the present invention.
FIG. 2 illustrates an operation of the power transmission and blocking device according to the first embodiment of the present invention.
3 is a cross-sectional view illustrating a power transmission and blocking device according to a second embodiment of the present invention.
FIG. 4 illustrates an operation of a power transmission and blocking device according to a second embodiment of the present invention.

The preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings, in which the technical parts already known will be omitted or compressed for the sake of brevity.

One. In the first embodiment  A description of the components and mode of operation of the power delivery and blocking device

Referring to FIG. 1, components of the power transmission and blocking device 100 according to the first embodiment of the present invention will be described. The power transmission and blocking device 100 includes: a power supply pin 110; A housing 120; A switching unit 130; An operation unit 140; Rejection (150).

The energizing pin 110 is inserted into an outlet (not shown) to which electric power is supplied, and receives power supplied from an outlet (not shown).

Here, the energizing pins 110 are provided in at least one or more than two, and are electrically connected to the inserting portion 111 and the inserting portion 111 inserted into the receptacle (not shown) To the switching unit 130, which will be described in greater detail below.

Specifically, the power supplied from the socket (not shown) is transmitted to the insertion portion 111, and the power of the insertion portion 111 is transmitted to the switching portion 130 through the transmission portion 112.

The insertion portion 111 and the transmission portion 112 may be integrally formed.

1, a hole H is provided at a position corresponding to the energizing pin 110 on one side of the housing 120 for inserting the plug P, and the other side of the housing 120 is energized And is wrapped around a part of the pin 110.

The number of the holes H on one side of the housing 120 may be the same as the number of the plugs P so that the plug P can be inserted into the housing 120.

The switching unit 130 is disposed between the transmitting part 112 in the housing 120 and the hole H of the housing 120 and transmits the power supplied through the energizing pin 110 to the plug P It is responsible for blocking.

The switching unit 130 electrically separates the conductive part 131 and the transmitting part 112 from the plug P by electrically connecting the transmitting part 112 and the plug P to each other, And a non-conductive portion 132 capable of blocking the non-conductive portion 132.

The conductor portion 131 is made of a material capable of transmitting a large amount of free electrons, while the non-conductor portion 132 is preferably made of a material that can not transmit electric power because there is no free electrons.

In addition, the switching unit 130 is preferably arranged such that the non-conductive portion 132 and the conductive portion 131 are alternately arranged in order, as shown in FIG. 1, to transmit or cut off power.

The operating unit 140 controls the switching unit 130 to displace the switching unit 130 so that the switching unit 130 can transmit or block the power of the transmitting unit 112 to or from the plug P.

1, the operation unit 140 includes a first switch 141 extended from one side of the switching unit 130, a second switch 141 extending from the other side of the switching unit 130, (142).

The scavenging 150 is located inside the housing 120 and prevents sparks that may occur in the transfer part 112 and the switching part 130.

Particularly, the portion where the transmission portion 112 and the switching portion 130 are in contact with each other due to the spark can be consumed, deformed, and fused, and the oxidation contact resistance on the surface may increase and the service life may be shortened due to contact failure. Likewise, the rejection 150 serves to prevent the occurrence of sparks.

Referring to FIG. 2, the operation of the power transmission and blocking device 100 according to the first embodiment of the present invention will be described. The power transmission and blocking device 100 includes a plug P, FIG. 2 (a) shows the cutoff and FIG. 2 (b) shows that the power is transmitted.

2 (a), the switching unit 130 in the power transmission and blocking device 100 is configured such that the second switch 142 is drawn into the housing 120 and the non-conductive portion 132 is transmitted The power introduced through the transmitting portion 112 is transmitted to the plug P by the nonconductive portion 132 by being positioned between the portion 112 and the plug P inserted in the hole H of the housing 120, Lt; / RTI >

2 (b), the switching unit 130 moves in the direction of the second switch 142 to move the first switch 141 into the housing 120. As a result, 2 switch 142 is protruded to one side of the housing 120 and the conductor portion 131 and the transmission portion 112 are brought into contact with each other so that power introduced through the transmission portion 112 is transmitted to the conductor portion 131, To the plug (P).

2 (b), when the second switch 142 is pressed and drawn inward, the switching unit 130 moves in the direction of the first switch 141 to move the first switch 141, A part of the air is protruded to the other side of the housing 120 and the non-conducting portion 132 and the transmitting portion 112 come into contact with each other, The power is blocked from being transmitted to the plug P by the nonconductive portion 132.

2. In the second embodiment  A description of the components and mode of operation of the power delivery and blocking device

Referring to FIG. 3, components of the power transmission and blocking device 200 according to the second embodiment of the present invention will be described. The power transmission and blocking device 200 includes an energizing pin 210; A housing 220; A switching unit 230; An operation unit 240; (250).

The second embodiment of the present invention will be described mainly with respect to the differences from the first embodiment mentioned above, and a duplicate description will be simplified or omitted.

The structural features of the power supply pin 210, the housing 220 and the bare cell 250 of the power transmission and blocking device 200 according to the second embodiment of the present invention are the same as those of the first embodiment of the present invention The description of the constitutional features of the energizing pin 110, the housing 120, and the rejection 150 of the power transmission and blocking device 100 according to the present invention is the same as that described above, and thus a detailed description thereof will be omitted.

The energizing pin 210 includes an insertion portion 211 and a transmission portion 212.

3, one side of the housing 220 is provided with a hole H at a position corresponding to the energizing pin 210 for inserting the plug P, and the other side of the housing 220 is energized And is wrapped around a part of the pin 210.

The switching unit 230 is disposed between the transmitting part 212 inside the housing 220 and the hole H of the housing 220 and is connected to the plug P via the power supply pin 210. [ And includes a conductor portion 231, a non-conductive portion 232, and a switching spring 233. The conductive portion 231 is connected to the conductive portion 231,

3, the switching spring 233 is located between one side of the switching unit 230 and one side of the interior of the housing 220, and provides an elastic force for moving the switching unit 230.

3, an inclined surface is formed on the other side of the switching unit 230 so that the switching unit 230 can be moved.

The operation unit 240 controls and displaces the switching unit 230 so that the switching unit 230 can transmit or block the power of the transmitting unit 212 to the plug P, Includes a button portion 241, an oblique portion 242, a fixing groove 243, and an operating spring 244.

Here, the button portion 241 protrudes from one side of the housing 220, and controls the operation portion 240.

The button portion 241 may be provided in various forms on one side of the housing 220 so as to control the operation portion 240 regardless of which portion of the one side of the housing 220 is pressed.

The beveled portion 242 is located inside the housing 220 and extends from the lower portion of the button portion 241 to directly move the switch portion 230.

Specifically, as shown in FIG. 3, the oblique portion 242 has an oblique surface formed on one surface thereof, and pushes the oblique surface of the diverting portion 230 to move.

The fixing groove 243 is formed on one side of the oblique portion 242 and serves to fix the oblique face of the diverter 230 moved in the direction of the diverting spring 233.

The operating spring 244 is positioned between the lower portion of the beveled portion 242 and one side of the interior of the housing 220 and serves to provide an elastic force for lifting the operating portion 240.

The operating spring 244 is preferably made of a material having a higher elasticity than the switching spring 233 so that the operating portion 240 can be lifted.

4, the operation of the power transmission and blocking device 200 according to the second embodiment of the present invention will be described. When a plug P is inserted into the power transmission and blocking device 200, 4 (a) in which power is transmitted and FIG. 4 (b) in which power is transmitted.

When the button portion 241 shown in Fig. 4 (a) is lowered, the switching portion 230 is moved in the direction of the switching spring 233 by the beveled portion 242, and the operating portion 240 is operated The conductive portion 231 is brought into contact with the transmitting portion 212 by being raised by the spring 244 and the beveled surface of the switch portion 230 is fixed by the fixing groove 243. [

That is, as shown in FIG. 4 (b), the power introduced through the transmission portion 212 is transmitted to the plug P by the conductor portion 231.

When the lowered button portion 241 shown in FIG. 4 (b) is pressed and raised, the operation portion 240 is lowered so that the oblique face of the switch portion 230 is fixed in the fixing groove 243 The operating portion 240 is lifted by the operating spring 244 and the switching portion 230 is moved in the direction of the oblique portion 242 by the switching spring 233 so that the nonconductive portion 232 contacts the transmitting portion 212 .

That is, as shown in FIG. 4 (a), the power introduced through the transmission portion 212 is blocked from being transmitted to the plug P by the non-conductive portion 232.

The embodiments disclosed in the present invention are not intended to limit the scope of the present invention but to limit the scope of the technical idea of the present invention. The scope of protection is to be construed in accordance with the following claims, and all technical ideas within the scope of equivalents thereof should be construed as being included in the scope of the present invention.

100: Power transmission and blocking device according to the first embodiment
110: energizing pin
111: insert part 112: transfer part
120: Housing
H: hole
130:
131: conductor portion 132: non-conductive portion
140:
141: first switch 142: second switch
150: refuse
200: electric power transmission and blocking device according to the second embodiment
210: energizing pin
211: insert part 212: transfer part
220: Housing
H: hole
230:
231: conductor portion 232: non-conductive portion
233: switching spring
240:
241: button portion 242: oblique portion
243: Fixing groove 244: Operation spring
250: Reject the petition
P: Plug

Claims (10)

At least one energizing pin inserted into an outlet to which electric power is supplied and receiving power supplied from the outlet;
A housing having at least one hole for inserting a plug of an electric device at a position corresponding to the energizing pin;
A switching unit positioned between the hole in the housing and the energizing pin and transmitting or blocking the electric power transmitted through the energizing pin to the plug; And
And an operating portion for displacing the switching portion for power transmission or interruption of the switching portion
Power transmission and blocking devices.
The method according to claim 1,
The power-
An insertion portion to be inserted into the socket; And
And a transmitting portion that is electrically connected to the insertion portion and contacts the switching portion to transmit electric power to the switching portion.
Power transmission and blocking devices.
3. The method of claim 2,
Wherein,
A conductor portion for electrically connecting the transmission portion and the plug; And
And a nonconductive portion for electrically disconnecting the transmission portion and the plug,
And the conductor portion and the non-conductor portion are sequentially arranged.
Power transmission and blocking devices.
The method of claim 3,
The power transmission and blocking device includes:
Further comprising a baffle disposed inside the housing for preventing sparks that may occur in the transmission portion and the switching portion
Power transmission and blocking devices.
5. The method of claim 4,
Wherein,
A first switch extended from one side of the switching unit; And
And a second switch extended from the other side of the switching unit
Power transmission and blocking devices.
6. The method of claim 5,
When the first switch is pulled into the housing, the switch portion is moved in the second switch direction so that a part of the second switch protrudes from the housing, and the conductor portion contacts the transmission portion Featured
Power transmission and blocking devices.
The method according to claim 6,
When the second switch is drawn into the housing, the switching portion is moved in the first switch direction so that a part of the first switch protrudes from the housing, and the non-conducting portion contacts the transmitting portion Featured
Power transmission and blocking devices.
5. The method of claim 4,
Wherein,
And a switching spring which is located between one side of the switching part and one side of the inside of the housing and provides an elastic force to the switching part,
And an oblique surface is formed on the other side of the switching portion
Power transmission and blocking devices.
9. The method of claim 8,
Wherein,
A button portion protruding from one side of the housing;
A beveled portion positioned inside the housing and extending from a lower portion of the button portion to move the switchable portion and having a beveled surface formed on one surface thereof;
A fixing groove formed on one surface of the oblique surface portion and fixing the oblique surface of the switching portion moved in the direction of the switching spring; And
And an operating spring which is positioned between a lower portion of the oblique face portion and one side of the inside of the housing and provides an elastic force to the operating portion
Power transmission and blocking devices.
10. The method of claim 9,
When the button portion is lowered, the switch portion is moved in the direction of the switch spring by the oblique portion, and the operation portion is raised by the operation spring to fix the oblique face of the switch portion by the fixing groove, Is in contact with the transmission portion
Power transmission and blocking devices.

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