The present invention relates to a power strip, and more particularly to a power strip having surge protective devices.
Generally, conventional power strips are susceptible to transient surge voltages resulting from lightning strike. For preventing the transient surge voltages from damaging the electrical appliances which are electrically connected to the power strip, the conventional power strip usually has a surge protective device for preventing damage of electrical appliances.
For example, if a surge is inputted into the power strip 10 through the Line terminal 1011, the surge will be successively transmitted through the thermal fuse F1 and the metal oxide varistor MOV1 and outputted from the Neutral terminal 1012. When the surge is received by the metal oxide varistor MOV1, the inherent high impedance of the metal oxide varistor MOV1 will become low impedance. Since a low impedance path R1 is defined, the surge will be transmitted to the Neutral terminal 1012 through the low impedance path R1.
Recently, as the requirements for electrical safety of electrical appliances become more stringent, stringent safety regulations associated with surge protective device are provided. Underwriters Laboratories Standard for Safety for Transient Voltage (UL 1449) is the primary safety standard for testing surge protective device. The second edition of UL 1449 proposes a lightning strike simulation test. In accordance with the lightning strike simulation test, when a voltage of 6,000 volts and a current of 500 amperes are inputted into an electrical appliance having a surge protective device, the surge protective device should exhibit a clamping voltage less than 330 volts.
On Sep. 29, 2006, UL 1449 has recently been revised, and will be introduced as a third edition. In accordance with the lightning strike simulation test proposed in the third edition of UL 1449, the surge protective device should also exhibit a clamping voltage less than 330 volts even if the test condition become more stringent (i.e. 6,000 volts, 3,000 amperes). Experiments demonstrate that most surge protective devices meeting the requirements of the second edition of UL 1449 exhibit a clamping voltage larger than 400 volts. In other words, the surge protective devices of the conventional power strips fail to meet the requirements of the third edition of UL 1449.
Therefore, there is a need of providing a power strip having a surge protective device to meet the requirements of the third edition of UL 1449 while having the advantages of simplified configuration, cost-effectiveness and industrial utility.
It is an object of the present invention to provide a power strip having a surge protective device, in which the surge is suppressed in multiple stages so as to protect the electrical appliances which are electrically connected to the power strip.
Another object of the present invention provides a power strip having a surge protective device, in which the power strip has the advantages of simplified configuration and cost-effectiveness.
In accordance with an aspect of the present invention, there is provided a power strip having surge protective devices for suppressing a surge and protecting an electrical appliance which is connected to the power strip. The power strip includes a plug device, a buffer conductive device and a power strip main body. The plug device includes a plurality of pins to be inserted into a power socket and a first surge protective device for initially suppressing the surge. The buffer conductive device has an end connected to the first surge protective device for providing a buffer conductive path for delaying the duration of transferring the surge. The power strip main body includes a second surge protective device and a plurality of electrical sockets. The electrical sockets are connected to the electrical appliance. The second surge protective device is connected to the other end of the buffer conductive device for receiving and further suppressing the surge.
In an embodiment, the buffer conductive device is a conducting wire covered with insulating material.
In an embodiment, the plug device comprises a plug part and the first surge protective device, wherein the plug part is connected to the first surge protective device, and the plug part contains the plurality of pins.
In an embodiment, the plug device includes a first plug part and a second plug part, wherein the first plug part is connected to the second plug part, and the second plug part contains the plurality of pins and the first surge protective device.
In an embodiment, the first surge protective device is a metal oxide varistor (MOV), a gas discharge tube (GDT) or a transient voltage suppressor (TVS).
In an embodiment, the second surge protective device is a metal oxide varistor (MOV), a gas discharge tube (GDT) or a transient voltage suppressor (TVS).
The above objects and advantages of the present invention will become more readily apparent to those ordinarily skilled in the art after reviewing the following detailed description and accompanying drawings, in which:
Please refer to
When a surge occurs, the surge is inputted into the first surge protective device 2012 of the plug device 201 through the pins 2011. By the first surge protective device 2012, the surge is subject to a first stage suppression. Next, the surge flows through the buffer conductive device 202 such that the buffer conductive device 202 provides a buffer conductive path for delaying the duration of transferring the surge. After the surge is transmitted to the second surge protective device 2031, the second surge protective device 2031 is enabled to perform a second stage suppression on the surge.
Since the surge is sufficiently suppressed by the two-stage suppressions when the surge reaches the electrical sockets 2032, the power strip 20 can meet the requirements of the third edition of UL 1449. That is, the power strip 20 exhibits a clamping voltage less than 330 volts according to the test proposed by the third edition of UL 1449. As a consequence, the surge protective device can prevent the electrical appliances connected to the power strip 20 from being damaged by the surge. It is noted that, however, those skilled in the art will readily observe that numerous modifications and alterations may be made while retaining the teachings of the invention. For example, the concept of using two surge protective devices to suppress the surge in two-stage suppressions can be expanded to three-stage or multi-stage suppressions. Accordingly, the above disclosure should be limited only by the bounds of the following claims.
Moreover, any surge protective devices known in the art can be used as the first surge protective device 2012 and the second surge protective device 2031 of the present invention. In views of cost, the surge protective device 1031 of
When a surge occurs, the surge is inputted into the first surge protective device 3012 through the pins 3011 of the plug part 3013. By the first surge protective device 3012, the surge is subject to a first stage suppression. Next, the surge flows through the buffer conductive device 302 such that the buffer conductive device 302 provides a buffer conductive path for delaying the duration of transferring the surge. After the surge is transmitted to the second surge protective device 3031, the second surge protective device 3031 is enabled to perform a second stage suppression on the surge. Since the surge is sufficiently suppressed by the two-stage suppressions when the surge reaches the electrical sockets 3032, the power strip 30 can meet the requirements of the third edition of UL 1449 exhibiting a clamping voltage less than 330 volts. As a consequence, the electrical appliances connected to the power strip 30 are prevented from being damaged by the surge.
When a surge occurs, the surge is inputted into the first surge protective device 4012 through the pins 4011 of the second plug part 4014. By the first surge protective device 4012, the surge is subject to a first stage suppression. Next, the surge flows through the first plug part 4013 and the buffer conductive device 402 such that the buffer conductive device 402 provides a buffer conductive path for delaying the duration of transferring the surge. After the surge is transmitted to the second surge protective device 4031, the second surge protective device 4031 is enabled to perform a second stage suppression on the surge. Since the surge is sufficiently suppressed by the two-stage suppressions when the surge reaches the electrical sockets 4032, the power strip 40 can meet the requirements of the third edition of UL 1449 exhibiting a clamping voltage less than 330 volts. As a consequence, the electrical appliances connected to the power strip 40 are prevented from being damaged by the surge.
As known, the power strips brought to the market should comply with the third edition of UL 1449 when the third edition of UL 1449 is effective. Before the effective date of the third edition of UL 1449, the manufacturers may keep a large reserve of power strips as shown in
From the above description, the power strip of the present invention can meet the requirements of the third edition of UL 1449 by two-stage suppressions. In addition, the power strip of the present invention has the advantages of simplified configuration and cost-effectiveness. Moreover, since the conventional surge protective device can be employed, the power strip of the present invention is cost-effective and has enhanced industrial utility.
While the invention has been described in terms of what is presently considered to be the most practical and preferred embodiments, it is to be understood that the invention needs not be limited to the disclosed embodiment. On the contrary, it is intended to cover various modifications and similar arrangements included within the spirit and scope of the appended claims which are to be accorded with the broadest interpretation so as to encompass all such modifications and similar structures.
Number | Date | Country | Kind |
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2008 1 0005641 | Feb 2008 | CN | national |
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Number | Date | Country | |
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20090207541 A1 | Aug 2009 | US |