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Basic principles of induction heating date back to Michael Faraday's work in 1831. Induction heating is the process of heating an electrically conductive object by electromagnetic induction, where eddy currents are generated within the metal and resistance leads to Joule heating of the metal. This technology is widely used in industrial welding, brazing, bending, and sealing processes. Also, induction heating has grown very popular in culinary applications, providing a more efficient and accelerated heating of liquids and/or foods on stovetops or in ovens. Advantages of using an induction heating system are an increase in efficiency using less energy and also applying direct heat to a specific target.
Applying heated shaving cream or cleansing gel to the skin opens pores translating in a more comfortable shave or a more effective skin cleansing. Currently the process of heating shaving cream to the desired temperature is difficult. It requires meticulous attention and practice. Overheating can ruin the product and under-heating does not generate the desired effect. The technology available to heat shaving cream often requires shaving cream to be in an aerosol dispensed can. An aerosol based shaving cream is often times of poor quality. These shaving cans are often destroyed by repeated process of heating, and also unevenly heat the product. Resistance heating of the can is also extremely inefficient and causes the shaving can to remain hot for long periods after use.
One attempt of using an induction heating system is disclosed by Brown, et al. in US 20080257880 A1. Brown, et al. disclose an induction heating dispenser having a refill unit 8 heated by primary and secondary induction coils 2 and 13. As disclosed in paragraph [0020], the dispenser can be used for many different applications such as air fresheners, depilatory waxes, insecticides, stain removal products, cleaning materials, creams and oils for applications to the skin or hair, shaving products, shoe polish, furniture polish, etc. The refill unit 8 comprises a multiplicity of replaceable containers 9 for holding the respective products. The containers are sealed under a porous membrane 11. As disclosed in paragraph [0011], the porous membrane is usually removed for meltable solid substances. For volatile liquid substances, the porous membrane is not removed. As disclosed in paragraph [0023], the porous membrane 11 has a porosity that allows vapor to pass through but not liquid to prevent spillage. Also, in paragraph [0020], for heated products that are applied to a surface, the container may have an associated applicator such as a brush, pad or sponge.
Another heated dispenser system is disclosed by Bylsma, et al. in US 20110200381 A1. Bylsma, et al. disclose a dispenser wherein the heating unit could be either in the base unit 10 as illustrated in
Although the prior art systems have proven to be quite useful for their purposes, none have been designed to be energy efficient or to heat and/or melt only the amount of composition necessary for the immediate application as accomplished by the present invention.
The present invention relates generally to a dispenser for products such as soaps, creams, lotions, gel compositions or other solutions (hereinafter “products”) for shaving purposes or cosmetic purposes such as skin cleansing. The products are stored in a container wherein only the upper surface or region of the products is heated and/or melted by an induction heating device.
The present invention is an induction heating device capable of warming and/or melting, and warming and/or liquefying an upper surface region of the products. The device provides a non-contact heating system for the products. The device includes an induction receptacle which accepts a cup filled with a product wherein only the upper surface region of the product is heated. Inside the cup, a floating conductive porous screen is disposed across the upper surface of the product and is excited by electromagnetic induction and transfers heat to the top surface of the product. As the top surface of the product is heated and/or melted, an applicator such as a shaving brush or skin pad can be used to collect the heated and/or melted product from the upper surface of the floating screen which can be applied to the face or any other desired location of the body. The present invention is a more effective means of heating the product, especially for an amount necessary for the immediate application since only the upper surface or region is heated and/or melted. The cups of product are easily accessible and interchangeable from the receptacle. The present invention has no open flame, operates silently, and stays cool after the cup is removed. Furthermore, the product will return to its original form (e.g., solid, cream or gel) more quickly than if the entire product was melted.
The present invention as illustrated in
Referring to
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During the heat cycle and during non-heating idle time the microprocessor (19) monitors the current sensor (21) and temperature sensors (20) to ensure safe operation of the device. The coil is not visible to the outside of housing (1) and surrounds receptacle (4) and nested product cup (6) with target screen (7) resting on the top surface product within cup (6). Thus, the target screen (7) is closely coupled to the coil (27) which creates an electromagnetic field that passes electromagnetic energy into the external cup workpiece (28) which is the conductive target screen (7) shown in
Referring to
Operation of the electromechanical system of the present invention is a follows. First power is received by connecting (13), mains line AC power into the device with a plug. Voltage received is then electromagnetically reduced by transformer (15) and converted into direct current (DC) waveform by rectifier (16). Transformer (15) and rectifier (16) may be packaged together externally in an AC to DC power supply commonly used by computers or electronic devices. Inside the device the rectified DC power is passed through DC regulator (17), a monolithic integrated circuit regulator that step down the voltage to TTL, CMOS, ECL levels etc. The induction heater coil (3) is controlled by the microprocessor (19), which controls the timing and frequency of the HF inverter (25), sensors (20), (21), operator interface (18), led lights (34), timers, antenna (22), and speaker (23). It may be used to interact with many other device peripherals if needed. The microprocessor is programmed to control and vary the oscillation frequency in order to reach electromagnetic resonance between the workpiece, i.e., the screen, and the resonant tank. The microprocessor has flash memory read-while-write capabilities and EEPROM storage used in order to store user settings, timers, and safeties. Users are able to interact with the device by visually watching or pressing the operator interface (18) or user pushbuttons (29). Display of operator interface (18) is constructed of a piezoresistive, capacitive, surface acoustic, infrared grid or similar technologies. It allows the user to press and start a heating cycle while displaying helpful information based on the temperature or duration of the cycle. Safety information can be depicted on this display or any other helpful visual aids. In addition to operator interface (18), a speaker (23) is used to provide audible feedback and alerts to the user based on the state of the heat cycle. The pushbuttons (29) are used as a secondary source of user input. Nearby LEDs (34) are used to provide a secondary visual indication of the state of the device. Pushbuttons, LEDs, and the Operator Interface may be reprogrammed by the manufacturer in order to adjust the functionality and usability throughout different device revisions. Once a heat cycle is initiated, the microprocessor (19) inputs a low voltage pulse width modulated (PWM) signal received by the high frequency (HF) inverter module (25). The inverter module switches the rectified DC power from rectifier (16) to HF alternating current power at the oscillation frequency set by the microprocessor (19). High frequency AC power is then passed into a series or parallel resonant RLC tank. The tanks capacitance, inductance, and resistance are optimized to reach the resonant frequency of the PWM signal. This resonance also matches the oscillation frequency of the screen (7 or 9). Throughout the heat cycle, current transferred into screen (7 or 9) is measured by sensor (21). At this time, microprocessor (19) adjusts the oscillation frequency in order to transfer maximum power into screen (7 or 9). If the current exceeds a safety limit measured by sensor (21), the device shuts off the heat cycle. Likewise, the temperature of the internal components is measured by sensor (20). This prevents the device from being left on throughout the day or operating in harsh environments. Sensor (20) also measures the internal coil (3) temperature to prevent overheating on its internal windings. During the heat cycle high frequency currents are passed through the resonant tank (26) and into the coil (3) wrapped around a receptacle (4 or 11) that receives the cup (6 or 12). The high frequency currents are then transferred to screen (7 or 9) through means of electromagnetic induction. Eddy currents are generated inside screen (7 or 9) and cause a Joule heating effect as well as a heating through magnetic hysteresis. Heat generated through screen (7 or 9) then permeates through to the top layer of the product inside the cup. Due to the geometry of the screen (7 or 9), energy is transferred more directly to the top layer of the product inside cup (6 or 12).
The foregoing merely illustrates the principles of the invention. Various modifications and alterations to the described embodiments will be apparent to those skilled in the art in view of the teachings herein. It will thus be appreciated that those skilled in the art will be able to devise numerous systems, arrangements and methods which, although not explicitly shown or described herein, embody the principles of the invention and are thus within the spirit and scope of the present invention. In addition, all publications and patent documents referenced herein are incorporated herein by reference in their entireties.