(a) TECHNICAL FIELD OF THE INVENTION
This invention relates to a relay protector device mitigating the impact of inrush current and particularly to a relay protector device available for electronic products or household electronic appliances, such as air conditioners, TV sets and the like, and method for the same.
(b) DESCRIPTION OF THE PRIOR ART
An electronic device is required to work with a protector circuit because each electronic device consumes its own power and operates with its own voltage and current. In the condition of unigauge power supply, to avoid the voltage or current of the power supply from damaging the electronic device, the protector circuit must be designed in to make the electronic device operate normally. The means of voltage-based protection comprises a regular voltage or variable voltage circuit design, while the means of current-based protection comprises a limited current or rectifier circuit design. Accordingly, the protector circuit prevents the voltage or current of the normal power supply from damaging the electronic device.
Generally, the electronic device is designed with a resistor-capacitor (RC) or resistor-inductor (RL) circuit. When the electronic device is suddenly powered, its RC or RL circuit is transiently short or open, which easily causes the irush current doing damage to the electronic device. Thus, a protection circuit for power switch must be designed in. A relay is widely used as a protector member for power switch. The relay is a device as a switch controlling the current, being characterized with input loop control and output loop control; that is, when the input coil of the relay is powered, the relay's output contact turns ON. Thus, the relay is widely used in an automatic control circuit. Besides, being featured with an automatic switch that uses its small current signal to drive a large-current electronic device, so the relay is generally used in a delay-action switch circuit design for mitigating the impact of inrush current caused to the electronic device that is suddenly powered.
Consequently, because of the technical defects of described above, the applicant keeps on carving unflaggingly through wholehearted experience and research to develop the present invention, which can effectively improve the defects described above.
SUMMARY OF THE INVENTION
A relay protector device according to this invention, particularly mitigating the impact of the inrush current to an electronic product, comprises a relay circuit; a driver circuit, connecting in parallel with the relay circuit; and a controller, connecting through a signal to the relay circuit and the driver circuit and being driven by a driving signal to trigger in sequence the relay circuit and the driver circuit to operate for the effect of protection.
The relay protector device according to this invention is provided to mitigating the impact of inrush current by using a driver circuit working with a relay circuit for circuit protection. If an electronic device works with a single relay circuit to mitigate the impact of inrush current, the effect of mitigation depends on the speed of response and launch of the relay circuit. When the instantaneous short of the RC circuit does not end, if the response of the relay circuit startup is very slow and the material for the relay cannot properly mitigate the impact of inrush current, the inrush current still probably damages the electronic device. The relay protector device according to this invention is provided with a driver circuit connected in parallel with a relay circuit. When the inrush current occurs, a controller that is arranged transmits a driving signal to enable in advance the driver circuit for protection and then transmits another driving signal to enable the relay circuit. The relay protector device according to this invention significantly may decrease the probability of the impact of inrush current to the electronic device and also may lower the extent of impairment of the relay.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a circuit diagram of a relay protector device according to this invention.
FIG. 2 is a circuit diagram of a relay protector device provided with a zero-crossing circuit.
FIG. 3 is a timing diagram of operation of a controller for enabling the relay protector device.
FIG. 4 is a timing diagram of operation of the controller for disabling the relay protector device.
FIG. 5 is a timing diagram of operation of a controller having a zero-crossing signal for enabling for enabling the relay protector device.
FIG. 6 is a timing diagram of operation of a controller having a zero-crossing signal for enabling for disabling the relay protector device.
FIG. 7 is a schematic view illustrating the circuit of relay protector device in a first embodiment of this invention.
FIG. 8 is a schematic view illustrating the circuit of relay protector device in a second embodiment of this invention.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS
Now, the present invention will be described more specifically with reference to the following embodiments. It is to be noted that the following descriptions of preferred embodiments of this invention are presented herein for purpose of illustration and description only; it is not intended to be exhaustive or to be limited to the precise form disclosed.
With reference to FIG. 1 as a circuit diagram of a relay protector device according to this invention, the relay protector device comprises: a relay circuit R, a driver circuit D connected in parallel with the relay circuit R, and a controller. The driver circuit D is connected in parallel with the relay circuit R. The driver circuit D and the relay circuit R are provided respectively with a driving signal terminal C1 and a diving signal terminal C2 for the controller to signal to. The controller transmits a driving signal to enable in sequence the driver circuit D and the relay circuit R. In the relay protector device according to this invention, the driver circuit D further comprises a circuit in which a photo coupler device P and a TRIAC device T are arranged. The photo coupler device P is connected in parallel with the TRIAC device T to control the TRIAC device T. The relay circuit R is a relay unit provided with an electromagnetic relay and a diode.
With reference to FIG. 2 as a circuit diagram of a relay protector device according to this invention, the relay protector device comprises a driver circuit D connected in parallel with a relay circuit R. The driver circuit D and the relay circuit R are provided respectively with a driving signal terminal C1 and a diving signal terminal C2 for a controller to signal to. The controller transmits a driving signal to enable in sequence the driver circuit D and the relay circuit R. In the relay protector device according to this invention, the driver circuit D further comprises a circuit in which a photo coupler device P and a TRIAC device T are arranged. The photo coupler device P is connected in parallel with the TRIAC device T to control the TRIAC device T. Further, the photo coupler device P is designed with a zero-crossing circuit Z that is used to correct the zero-crossing signal of AC power.
Refer to FIG. 3 as a timing diagram of operation of the controller for enabling the relay protector device. It is characterized that the driver circuit D firstly operates and then the relay circuit R works. Refer to FIGS. 2 and 3 at the same time. At t1, the controller inputs a driving signal from a driving signal terminal C1 to enable the driver circuit D, and with the photo coupler device P that enables the TRIAC device T at t2, the impact of inrush current is mitigated. At t3, the controller inputs another driving signal from a driving signal terminal C2 to enable the relay circuit R. At t4, the relay works. Then, at t5, the controller stops signaling from the driving signal terminal C1. With the photo coupler device P that disables the TRIAC device T at t6, the impact of inrush current to the relay circuit R is mitigated.
Refer to FIG. 4 as a timing diagram of operation of the controller for disabling the relay protector device. It is characterized that the relay circuit R firstly stop operating and then the driver circuit D stop working. Refer to FIGS. 2 and 4 at the same time. At t1, the controller inputs another driving signal from a driving signal terminal C1 to enable the driver circuit D. With the photo coupler device P that enables the TRIAC device T at t2, the impact of inrush current is mitigated. At t3, the controller inputs another driving signal from the driving signal terminal C2. At t4, the relay works. At t5, the controller stops signaling from the driving signal terminal C1 and thus the driver circuit D is disabled. At t6, the TRIAC device T stop working and the inrush current is mitigated, the relay protector device thereby stopping working.
Refer to FIG. 2 as the circuit diagram of relay protector device according to this invention. The driver circuit D is designed with a zero-crossing circuit Z that is used to correct the zero-crossing signal of AC power. In case of arrangement of no zero-crossing circuit Z, the relay protector device needs to depend on the controller that corrects the zero-crossing signal of AC power.
Refer to FIG. 5 as a timing diagram of operation of a controller having a zero-crossing signal for enabling for enabling the relay protector device. At t1, calculating the timing of zero signal, the controller, inputs a driving signal from the driving signal terminal C1 to enable the driver circuit D. At t2, time of zero signal, the TRIAC device T is enabled. At t3, the controller inputs another driving signal from the driving signal terminal C2. At t4, time of zero signal, the relay circuit R stops working. At t5, the controller stops signaling from the driving signal terminal C1 and the TRIAC device T stop working. Accordingly, the impact of inrush current may be mitigated.
In case of arrangement of no zero-crossing circuit Z in the photo coupler device of the relay protector device, the relay protector device needs to depend on the controller that corrects the zero-crossing signal of AC power. Alternatively, a zero-crossing circuit that may detect the zero-crossing signal is further added to the AC power terminal in another manner to transmit the detected zero-crossing signal to the controller for enabling or disabling the photo coupler TO control the TRIAC. Refer to FIG. 6 as a timing diagram of operation of a controller having a zero-crossing signal for enabling for disabling the relay protector device. At t1, calculating the timing of zero signal, the controller, inputs a driving signal from the driving signal terminal C1 to enable the driver circuit D. At t2, time of zero signal, the TRIAC device T is enabled. At t3, the controller inputs another driving signal from the driving signal terminal C2. At t4, time of zero signal, the relay circuit R stops working. At t5, the controller stops signaling from the driving signal terminal C1 and the TRIAC device T stop working. Accordingly, the impact of inrush current may be mitigated. Thus, from FIGS. 5 and 6 that illustrate the timing diagram, it is known that the design of zero-crossing circuit Z helps the relay protection device to operate.
From the description made above, the relay protection device not only may protect the relay circuit R but may protect the contacts R1a and R1b of switch R1 of the relay to mitigate the impact of inrush current formed in the circuit.
Refer to FIG. 7 as a schematic view illustrating the circuit of relay protector device in a first embodiment of this invention. The relay circuit is further designed in a sensor device 1, in which the sensor device 1 a wall-hanging sensor device or a ceiling sensor device. The sensor device 1 comprises a sensor unit 2, an amplifier circuit 3, and a controller 4. When the sensor unit 2 in the sensor device 1 detects a person or vehicle moving in a sensitive range, the sensor unit 2 transmits a signal to the controller 4. Here, the controller 4 thereby transmits a driving signal to the driving signal terminal C1 for making the TRIAC device turn ON for a period of time, and then transmits a driving signal to the driving signal terminal C2. Here, the relay turns ON. After the relay turns ON for a period of time, the controller 4 transmits a driving signal to the driving signal terminal C1, making the TRIAC device stop working.
When the sensor unit 2 in the sensor device 1 detects neither person nor vehicle moving in the sensitive range, the sensor unit 2 transmits a signal to the controller 4. Here, the controller 4 thereby transmits a driving signal to the driving signal terminal C1 for making the TRIAC device turn ON for a period of time, and then transmits a driving signal to the driving signal terminal C2. Here, the relay is made to turn OFF. After the relay turns OFF for a period of time, the controller 4 transmits a driving signal to the driving signal terminal C1, making the TRIAC device stop working.
Refer to FIG. 8 as a schematic view illustrating the circuit of relay protector device in a second embodiment of this invention. The relay circuit is further designed in the sensor device 1 and the zero-crossing circuit Z is further designed in, in which the sensor device 1 a wall-hanging sensor device or a ceiling sensor device. The sensor device 1 comprises a sensor unit 2, an amplifier circuit 3, and a controller 4. When the sensor unit 2 in the sensor device 1 detects a person or vehicle moving in a sensitive range, the sensor unit 2 transmits a signal to the controller 4. Here, the controller 4 thereby transmits a driving signal to the driving signal terminal C1 for making the TRIAC device turn ON for a period of time, and then transmits a driving signal to the driving signal terminal C2. Here, the relay turns ON. After the relay turns ON for a period of time, the controller 4 transmits a driving signal to the driving signal terminal C1, making the TRIAC device stop working.
When the sensor unit 2 in the sensor device 1 detects neither person nor vehicle moving in a sensitive range, the sensor unit 2 transmits a signal to the controller 4. Here, the controller 4 thereby transmits a driving signal to the driving signal terminal C1 for making the TRIAC device turn ON for a period of time, and then transmits a driving signal to the driving signal terminal C2. Here, the relay is made to turn OFF. After the relay turns OFF for a period of time, the controller 4 transmits a driving signal to the driving signal terminal C1, making the TRIAC device stop working.
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.