The present invention relates generally to a toilet seat cover, and more particularly to a wireless power supply and electric control system for a toilet seat cover.
With the advancement of technology, modern people pay much attention to the quality of life and health. For example, office workers have to maintain a sedentary posture over a long period so that many of them are suffering from hemorrhoids. Therefore, bidet toilets are more and more common in domestic toilets to facilitate users to washing their anuses after defecation.
Additionally, bidet toilets also facilitate female users to clean their intimate part to reduce the chance of urinary tract infections.
Besides, in higher latitude countries or regions, due to the cold climate, residents usually add extra cushions on the toilet seat to keep them warm. However, when flushing, the water could be splashed out of the toilet, causing the cushion to be dirty so it would be difficult to maintain hygiene. In view of this, electric heated toilet seats have been developed. With an electric heating device combined with the toilet seat, a user can sit directly on the warm toilet seat, and it's convenient for cleaning and maintaining hygiene.
Both the bidet toilet seat and the electric heated toilet seat have an exposed plug put in the socket to supply power to the toilet seat. Nevertheless, if water leaks while the toilet is being cleaned, the exposed plug or external wire may cause electric leakage which could let users get an electric shock unexpectedly and even be life-threatening.
From the above, the present toilet seats with exposed plugs or external wires still need to be improved.
In view of the above, the primary objective of the present invention is to provide a wireless power supply and electric control system for a toilet seat cover, which supplies power to electric devices in the toilet seat cover with a direct current power supply device rather than an exposed plug or external wire, which prevents users from getting an electric shock.
The present invention provides a wireless power supply and electric control system for a toilet seat cover, including a seat cover assembly, an electric device, and a direct current power supply device; the seat cover assembly includes a seat and a cover which is controllable to move pivotally relative to the seat so that the cover is in a closed state or a lifted state relative to the seat, wherein when the cover is in the closed state relative to the seat, the cover covers the seat, while when the cover is in the lifted state relative to the seat, the cover doesn't cover the seat so that the seat is exposed. The electric device is provided in the seat cover assembly, and includes an electric control unit and at least an electric assembly, wherein the electric control unit transmits an electrical control signal to the at least an electric assembly to actuate the at least an electric assembly. The direct current power supply device is provided in the seat cover assembly and is electrically connected to the electric device; the direct current power supply device includes at least a rechargeable battery which supplies power to the electric device for operation.
The wireless power supply and electric control system supplies power to the electric device in the toilet seat cover with the direct current power supply device rather than an exposed plug or external wire, which prevents users from getting an electric shock. Besides, using the rechargeable battery as the resource of direct current for the direct current power supply device makes the toilet seat cover beautiful and clean, which improves the quality and brings the toilet seat cover a sense of design.
The present invention will be best understood by referring to the following detailed description of some illustrative embodiments in conjunction with the accompanying drawings, in which
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The electric device 10 is provided in the seat cover assembly 5, and includes an electric control unit 12 and at least an electric assembly 14. The electric control unit 12 transmits electrical control signal to the electric assembly 14 to actuate the electric assembly 14.
The direct current power supply device 20 is provided in the seat cover assembly 5, and is electrically connected to the electric device 10. The direct current power supply device 20 includes at least a rechargeable battery 22 which supplies power to the electric device 10 for operation. In this embodiment, the rechargeable battery 22 can be fixed in the seat cover assembly 5. In this embodiment, the rechargeable battery 22 is detachably provided in the seat cover assembly 5.
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In this embodiment, the cover main body 56 has a battery compartment 562 for accommodating the rechargeable battery 22, so that the rechargeable battery 22 can be detachably installed in the battery compartment 562. In this embodiment, the rechargeable battery 22 has a drawing groove 224 on the top surface thereof, which facilitates users to pull out the rechargeable battery 22 from the battery compartment 562 and replace the rechargeable battery 22. In this embodiment, the battery compartment 562 has a drainage groove 564 provided around the top edge of the battery compartment 562 to prevent water from entering the battery compartment 562, which causes electric leakage. In this embodiment, the rechargeable battery 22 includes a waterproof ring 222 provided around the outer surface thereof. When the rechargeable battery 22 is installed in the battery compartment 562, the waterproof ring 222 is sandwiched between the outer surface of the rechargeable battery 22 and the inner wall of the battery compartment 562.
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In this embodiment, the transmitting coil 256 is provided in the wall W, while the receiving coil 262 is provided in the cover 54 of the seat cover assembly 5. When the cover 54 is in the lifted state relative to the seat 52, the receiving coil 262 and the transmitting coil 256 are close to each other, which makes the receiving coil 262 generate induced current to charge the rechargeable battery 22 as shown in
In the second embodiment, the transmitting coil 256 is provided in a portable wireless charging device P, while the receiving coil 262 is provided in the cover 54 of the seat cover assembly 5. When the cover 54 is in the closed state relative to the seat 52, the portable wireless charging device P can be put on the cover 54, making the receiving coil 262 and the transmitting coil 256 close to each other to generate induced current, which charges the rechargeable battery 22 as shown in
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If the transmission voltage value 251 is greater than the reference voltage value 250, the rechargeable battery 22 is being charged. On the other hand, if the transmission voltage value 251 is less than or equal to the reference voltage value 250, the rechargeable battery 22 has been charged, or, there is no electromagnetic induction between the receiving coil 262 and the transmitting coil 256. In this embodiment, if the transmission voltage value 251 is less than or equal to the reference voltage value 250, the power transmission module 25 automatically cuts off the current.
In this embodiment, the power transmission module 25 includes a pilot light (not shown). If the transmission voltage value 251 is greater than the reference voltage value 250, the pilot light shows a first light signal. By contrast, if the transmission voltage value 251 is less than or equal to the reference voltage value 250, the pilot light shows a second light signal which is different from the first light signal. For example, the first light signal can be flashing red light representing the rechargeable battery 22 is being charged, while the second light signal can be constant green light representing the rechargeable battery 22 has been charged. Practically, the pilot light is able to show a third light signal. For example, if there is no electromagnetic induction between the receiving coil 262 and the transmitting coil 256, that is, if the rechargeable battery 22 has not been charged, the third light signal can be constant yellow light.
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In this embodiment, the pressure regulator assembly 161 includes a connector, an electromagnetic valve, and a pressure regulator. The connector is provided to connect a water inlet pipe and the pressure regulator; the electromagnetic valve is provided to control the water flow in the washing device; the pressure regulator is provided to keep the water output pressure in the washing device stable.
In this embodiment, the flowmeter 162 is provided to monitor the water flow in the washing device 16, and transmit the monitoring results to the electric control unit 12. According to the monitoring results, the electric control unit 12 controls the instant thermal assembly 163 to heat the water in the washing device 16.
In this embodiment, the instant thermal assembly 163 includes a heater, a temperature control switch, a temperature sensor, and a water level switch. The heater heats the water in the washing device 16 to make the water reach a preset temperature, while the temperature control switch controls the temperature of the water in the washing device 16. The temperature sensor monitors the temperature of the water in the washing device 16, and sends it to the electric control unit 12; the electric control unit 12 controls the temperature control switch and the heater to turn on or turn off. If the water temperature is higher than the preset temperature, the temperature control switch blocks the power to the heater, and the water level switch is provided to avoid the heater from dry heating. In this embodiment, the heater is a positive temperature coefficient (PTC) thermistor heater.
In this embodiment, the instant thermal assembly 163 includes an instant thermal control board 160 which is provided to control the heating time and power of the heater to the water in the washing device 16, as well as to control the temperature of the water in the washing device 16. Specifically, the temperature sensor collects water temperature data in the washing device 16 and sends control signal to the instant thermal control board 160, and then the instant thermal control board 160 controls a heating pipe to make the water in the washing device 16 reach the preset temperature.
In this embodiment, the wash assembly 165 includes a motor, a gear train, and a nozzle group. The motor drives the gear train which meshes with racks in the nozzle group to make the nozzle group controllably move back and forth. The water in the washing device 16 is sprayed out by the nozzle group for providing users a wash function. The motor is electrically connected to the direct current power supply device 20 and the electric control unit 12 which controls the operation of the motor.
By the abovementioned design, the wireless power supply and electric control system for a toilet seat cover uses the direct current power supply device to supply power to the electric device of the toilet seat cover directly rather than using an exposed plug or external wire, which could let users get an electric shock. Besides, using the rechargeable battery as the resource of direct current for the direct current power supply device makes the toilet seat cover beautiful and clean, which improves the quality and brings the toilet seat cover a sense of design.
The embodiments described above are only preferred embodiments of the present invention. All equivalent structures which employ the concepts disclosed in this specification and the appended claims should fall within the scope of the present invention.