METHOD USING BISMUTH BASED ALLOY AS SWITCH OR SOCKET POWER-OFF ELEMENT

Abstract

A method for using a bismuth based alloy as switch or socket power-off element which is applied to a switch or a socket, and the switch or the socket includes two conductive elements for conducting currents and one power-off element. A bismuth based alloy is used as the power-off element and a melting point of the bismuth based alloy is between 100 C. to 380 C. When the power-off element is in an environment below the melting point, the two conductive elements are mutually contacted and capable of conducting currents, whereas the power-off element is only receptive of the currents but does not serve as a medium for conducting the currents; when a working temperature of the switch or the socket is close to or exceeds the melting point, the power-off element loses rigidity and enables the two conductive elements to be separated from each other, thereby forming an electrically disconnected state.

Claims

1. A method for using a bismuth based alloy as switch or socket power-off element, the method being applied to a switch or a socket, wherein the switch or the socket includes two conductive elements for conducting currents and one power-off element, a bismuth based alloy is used as the power-off element and a melting point of the bismuth based alloy is between 100 C. to 380 C.; when the power-off element is in an environment below the melting point, the two conductive elements are mutually contacted and capable of conducting currents, whereas the power-off element is only receptive of the currents but does not serve as a medium for conducting the currents; when a working temperature of the switch or the socket is close to or exceeds the melting point, the power-off element loses a rigidity thereof and enables the two conductive elements to be separated from each other, thereby forming an electrically disconnected state.

2. The method using a bismuth based alloy as switch or socket power-off element in accordance with claim 1, wherein after the two conductive elements are mutually separated and an electrically disconnected state is formed, the power-off element is limited and is not contacted with the two conductive elements at the same time.

3. The method for using a bismuth based alloy as switch or socket power-off element in accordance with claim 1, wherein after the two conductive elements are mutually separated and an electrically disconnected state is formed, the power-off element remains as an integrated body without disintegrating.

4. The method for using a bismuth based alloy as switch or socket power-off element in accordance with claim 1, wherein the bismuth based alloy comprises bismuth and any of the following metals: cadmium, indium, silver, tin, lead, antimony, and copper.

5. The method for using a bismuth based alloy as switch or socket power-off element in accordance with claim 1, wherein the bismuth based alloy comprises 50% to 70% of bismuth and 30% to 50% of tin.

6. The method using a bismuth based alloy as switch or socket power-off element in accordance with claim 5, wherein the bismuth based alloy further comprises a metal addition, and the metal addition is selected from one of the following or any combinations thereof: arsenic, calcium, tellurium, and mercury.

7. The method for using a bismuth based alloy as switch or socket power-off element in accordance with claim 6, wherein a proportion of the metal addition in the bismuth based alloy is between 0.01% to 20%.

8. The method for using a bismuth based alloy as switch or socket power-off element in accordance with claim 1, wherein at least one of the two conductive elements has or is receptive of a force, and the force enables the two conductive elements to be away from each other relatively, however, the force is incapable of destroying the rigidity of the power-off element below the melting point.

9. The method for using a bismuth based alloy as switch or socket power-off element in accordance with claim 1, wherein the power-off element utilizes an external force to limit the two conductive elements below the melting point, so as to enable the two conductive elements to be selectively contacted.

10. The method for using a bismuth based alloy as switch or socket power-off element in accordance with claim 9, wherein the external force is an elastic force of a spring.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0017] FIG. 1 illustrates a schematic view of a power-off element applied to a switch in accordance with a first embodiment of the present invention, wherein the switch is in a non-conducting state.

[0018] FIG. 2 illustrates a schematic view of a power-off element applied to a switch in accordance with the first embodiment of the present invention, wherein the switch is in a conducting state.

[0019] FIG. 3 illustrates a schematic view of a power-off element applied to a switch in accordance with the first embodiment of the present invention, wherein the power-off element is destroyed due to overheating and thus forming a non-conducting state.

[0020] FIG. 4 illustrates a schematic view of a power-off element applied to an extension cord in accordance with a second embodiment of the present invention.

[0021] FIG. 5 illustrates a schematic view showing that in FIG. 4, live wire terminals and a live wire are contacted in a limited manner via a J-shaped power-off element, and a stopper is provided at an outer peripheral of the J-shaped power-off element.

[0022] FIG. 6 illustrates a schematic view of a power-off element applied to an extension cord in accordance with the second embodiment of the present invention, wherein the power-off element is destroyed due to overheating and a destroyed part thereof is blocked by the stopper.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0023] In summary of the technical features described above, the main effects of the method using a bismuth based alloy as switch or socket power-off element of the present invention can be clearly illustrated by the following embodiments.

[0024] FIG. 1 illustrates a first embodiment of the present invention, wherein the embodiment uses a rocker switch as an example, comprising: a base (1), a first conductive element (2), a second conductive element (3), a movable conductive element, and a power-off element (5), wherein the first conductive element (2) and the second conductive element (3) are both penetrated into and provided in the base (1). The movable conductive element is a rocker conductive element (4), wherein the rocker conductive element (4) is provided above the first conductive element (2) and electrically connected to the first conductive element (2). In this embodiment, the two conductive elements defined in the present invention are the second conductive element (3) and the rocker conductive element (4). A material of the power-off element (5) is a bismuth based alloy, and a melting point of the bismuth based alloy is between 100 C. to 380 C.; for instance, the bismuth based alloy may be a bismuth-tin binary alloy which comprises 50% to 70% of bismuth and 30% to 50% of tin, wherein a melting point of the bismuth-tin binary alloy is approximately 138 C., but the rigidity thereof starts to be lost as a temperature thereof approaches the melting point, thus making the alloy very suitable for detection of overheating in an electrically conducting circuit. Alternatively, the bismuth based alloy comprises bismuth and any one of the following metals: cadmium, indium, silver, lead, antimony and copper; as long as a bismuth based alloy consisted of bismuth and the aforesaid metals has a melting point between 100 C. to 380 C., the alloy can serve as a applicable embodiment of the present invention. The aforesaid bismuth based alloy may further comprise an added metal, and the metal addition is selected from one of the following or any combinations thereof: arsenic, calcium, tellurium, and mercury; a proportion of the metal addition in the bismuth based alloy is between 0.01% to 20%. Therefore, different metal addition may be selected for the bismuth based alloy according to different usage environments.

[0025] When a working temperature is increased abnormally, a disconnection is preferably generated in the live wire; therefore, the first conductive element (2) is used as a first end of the live wire, and the second conductive element (3) is used as a second end of the live wire, such that the first conductive element (2) and the second conductive element (3) are connected and conducted via the rocker conductive element (4) to form a live wire circuit.

[0026] The rocker switch of the embodiment further comprises an operating component (6) for operating the rocker conductive element (4) to connect and conduct the first conductive element (2) and the second conductive element (3) to form a live wire circuit, or to disconnect the connection between the first conductive element (2) and the second conductive element (3) so as to form an open circuit on the live wire. The operating component (6) is assembled on the base (1) and comprises an operating element (61) and a first elastic element (62), wherein the operating element (61) is pivotally connected to the base (1) to enable the operating element (61) to be rotated reciprocally in a limited manner, and the operating element (61) comprises a thermal conductive shell (611) which is contacted with the rocker conductive element (4); the power-off element (5) is provided in the thermal conductive shell (611), and the first elastic element (62) has one end thereof pressed against the operating element (61) and another end thereof pressed against the power-off element (5); the power-off element (5) has a rigidity to enable the first elastic element (62) to be compressed and thus having a first elastic force; the first elastic force serves as an external force for controlling the rocker conductive element (4) to contact with the second conductive element (3) to form a connected circuit, or controlling the rocker conductive element (4) not to contact with the second conductive element (3) to form a disconnected circuit.

[0027] The rocker switch further has a second elastic element (7), and the second elastic element (7) is a spring in the embodiment. The second elastic element (7) has a second elastic force, and the second elastic force is a force acting on the operating element (61); when the aforesaid first elastic force is reduced, the second conductive element (3) becomes receptive of the force so as to enable the rocker conductive element (4) to be relatively separated and away from the second conductive element (3). The aforesaid second conductive element (3) is receptive of the force, which is equivalent to at least one conductive element is receptive of a force defined in the present invention.

[0028] Referring to FIG. 2, a user enables the thermal conductive shell (611) to slidably move on the rocker conductive element (4) by operating the operating element (61), so as to drive the rocker conductive element (4) to be selectively contacted with or separated from the second conductive element (3) in a manner of rocking motions. When the thermal conductive shell (611) slidably moves on the rocker conductive element (4) towards a silver contact point (41) on the rocker conductive element (4), the aforesaid external force forces the silver contact point (41) to be contacted with the second conductive element (3) to form an electrically connected state.

[0029] Referring to FIG. 3, when an external conducting apparatus connected to the first conductive element (2) or the second conductive element (3) is in an abnormal state and generates a heat energy, the heat energy is transmitted to the rocker conductive element (4) via the first conductive element (2) or the second conductive element (3), and then further transmitted to the power-off element (5) via the thermal conductive shell (611); the power-off element (5) absorbs the heat energy and gradually loses the rigidity thereof; for example, a material of the power-off element (5) is a bismuth-tin alloy, and even though a melting point thereof is 138 C., the bismuth-tin alloy starts losing rigidity before reaching the approximate melting point; therefore, under the effect of the external force, the power-off element (5) is compressed and deformed by the first elastic element (62), and the first elastic element (62) is extended into the softened power-off element (5); the first elastic element (62) is elongated, thus reducing or eliminating the external force, such that the force of the second elastic element (7) becomes greater than the aforesaid external force and subsequently driving the thermal conductive shell (611) to slidably move on the rocker conductive element (4), thus forcing the silver contact point (41) of the rocker conductive element (4) to be separated from the second conductive element (3) and forming an electrically disconnected state, thereby achieving protection against overheating. In the embodiment, the power-off element (5) which lost the rigidity thereof due to receiving an abnormal heat energy will still be limited in the thermal conductive shell (611) after being deformed, and will not be contacted with the second conductive element (3) and the rocker conductive element (4) at the same time. It should be particularly noted that the power-off element (5) utilizes a different means for melting from that of a fuse, in which the power-off element (5) of the present invention is not responsible for transmitting currents; therefore, even if the conductivity of the power-off element (5) is poorer than that of copper, the electricity consumption performance of the circuit would not be directly affected. In addition, as indicated in FIG. 3, the power-off element (5) of the embodiment is a non-insulative body; when the power-off element (5) is destroyed and deformed or after the same is deformed, the power-off element (5) is limited inside the thermal conductive shell (611) without overflowing or spreading outwardly to be reconnected to the rocker conductive element (4) and the second conductive element (3), thus avoiding accidentally conducting a power source when the rocker switch is in a switch-off state. In a process of power-off protection, an increase in the working temperature leads to the power-off element (5) being destroyed, and then the power source is interrupted; once the power source is interrupted, the working temperature is consequently decreased to enable the power-off element (5) to be cooled off and maintained in a deformed state.

[0030] FIGS. 4 and 5 illustrate a second embodiment of the present invention, wherein the embodiment uses an extension cord as an example, comprising:

[0031] an insulative body (1C) having a live wire jack (11C) and a neutral line jack (12C); a live wire terminal (2C) mounted in the insulative body (1C) and in correspondence with the live wire jack (11C), wherein the live wire terminal (2C) has a terminal extension portion (21C); a neutral line terminal (3C) mounted in the insulative body (1C) and in correspondence with the neutral line jack (12C); a live wire (4C) and a neutral line (5C) respectively corresponding to the live wire terminal (2C) and the neutral line terminal (3C), wherein the live wire (4C) has a live wire elastic member (41C), the live wire elastic member (41C) has an elastic force and the force enables the live wire elastic member (41C) to be inclined away from the terminal extension portion (21C); a power-off element (6C) presented in a J-shape; the power-off element (6C) of the embodiment utilizes a bismuth-tin binary alloy, in which the power-off element (6C) has a terminal portion thereof clamping the terminal extension portion (21C) of the live wire terminal (2C) and the live wire elastic member (41C) of the live wire (4C); the rigidity limitation of the power-off element (6C) enables the live wire terminal (2C) and the live wire (4C) to be mutually contacted to form a connected circuit, whereas the neutral line terminal (3C) and the neutral line (5C) can be connected and fixed to form a connected circuit by soldering or other fixing manners; a stopper (7C) located on an outer peripheral of the power-off element (6C). In the embodiment, two conductive elements defined in the present invention are equivalent to the live wire elastic member (41C) and the terminal extension portion (21C), wherein the live wire elastic member (41C) has an elastic force which is equivalent to at least one conductive element has a force defined in the present invention.

[0032] Referring to FIG. 6, when a circuit is overheated, the power-off element (6C) gradually loses the rigidity thereof, thus the force of the live wire elastic member (41C) forcing the power-off element (6C) to be deformed into a shape similar to an L-shape, thereby removing the limitation on the live wire elastic member (41C) to enable the terminal extension portion (21C) of the live wire terminal (2C) to be pushed away from the live wire elastic member (41C) of the live wire (4C) by the force to form a disconnected circuit, hence achieving protection from overheating. After the power-off element (6C) is destroyed, the stopper (7C) can restrain the power-off element (6C) to prevent the power-off element (6C) from randomly bounced off due to the force. Similarly, the power-off element (6C) is not responsible for transmitting currents in the embodiment, and so even if the conductivity of the power-off element (6C) is poorer than that of copper, the electricity consumption performance of the connected circuit would not be directly affected. In addition, FIG. 6 shows that the power-off element (6C) of the embodiment is a non-insulative body, in which when the power-off element (6C) is destroyed and deformed or after the same is deformed, the power-off element (6C) still remains as an integrated body without disintegrating, the power-off element (6C) and the terminal extension portion (21C) is limited together in an original position by the stopper (7C) without spreading outwards and reconnecting the terminal extension portion (21C) and the live wire elastic member (41C), thus preventing the extension cord from accidentally conducting a power source in a power-off state. In a process of power-off protection, an increase in the working temperature leads to the power-off element (6C) being destroyed, thereby the power source is interrupted; once the power source is interrupted, the working temperature is consequently decreased to enable the power-off element (6C) to be cooled off and maintained in a deformed state.

[0033] In summary of the description of the aforesaid embodiments, it is of course to be understood that the embodiments described herein is merely illustrative of the principles of the invention and that a wide variety of modifications thereto may be effected by persons skilled in the art without departing from the spirit and scope of the invention as set forth in the following claims.