1. Field of the Disclosure
The present disclosure is generally directed to hairstyling devices, and more particularly to curling irons and flat irons.
2. Description of Related Art
Traditional techniques for styling hair involve the application of heat. Attempts to style hair faster or create more robust holds have been based on increasing the amount of heat applied to the hair. The heat acts upon water molecules contained in the center of the hair. Restructuring the hydrogen bonds between the water molecules allows the hair to retain the desired styling.
Unfortunately, elevated amounts of applied heat tend to dry and damage hair, rendering the hair difficult to style, reducing shine, and ultimately resulting in unhealthy hair. Excessive heat can damage the outer layers of the hair, i.e., the cuticle, resulting in split ends. The hair becomes more limp and unable to hold desired styling, once the cuticle and inner shaft of the hair lose the water content that would otherwise provide strength.
In accordance with one aspect of the disclosure, a device for styling hair includes a wand defining a handle grip surface and a first styling surface spaced from the handle grip surface, a plate defining a second styling surface, the plate being pivotally coupled to the wand to clamp the hair between the first styling surface and the second styling surface, a heating element in thermal communication with the first styling surface or the second styling surface to transfer heat to the hair via the first styling surface or the second styling surface, respectively, and an ultrasonic transducer configured to generate ultrasonic vibrations. The ultrasonic transducer includes a horn in contact with the wand or the plate to transmit the ultrasonic vibrations to the hair via the first styling surface or the second styling surface, respectively.
In some cases, the wand is oriented along a longitudinal axis, and the ultrasonic transducer is oriented along the longitudinal axis such that the ultrasonic vibrations are generated in a direction parallel to the longitudinal axis. Alternatively or additionally, the ultrasonic transducer is disposed within the wand. The ultrasonic transducer may then include a horn with a rim in contact with an interior surface of the wand that defines an annular interface through which the ultrasonic vibrations travel.
The wand may include a barrel that terminates at an end cap. The plate may be curved to match a curvature of the barrel. The ultrasonic transducer may include a horn in contact with the end cap. Alternatively or additionally, the barrel may then have a length equal to a wavelength of the ultrasonic vibrations or a multiple of the wavelength.
In some cases, the device further includes an arm pivotally coupled to the wand. The plate may be mounted on the arm. Alternatively or additionally, the first and second styling surfaces may be flat.
The device may include a flat plate mounted on the wand. The flat plate may have a first side that defines the first styling surface and a second side in contact with the ultrasonic transducer. The ultrasonic transducer may then be oriented in alignment with the wand, and the ultrasonic transducer may include a horn adapter to direct the ultrasonic vibrations laterally toward the flat plate. The flat plate may have a length equal to a wavelength of the ultrasonic vibrations or a multiple of the wavelength.
In some cases, the wand may include a handle that defines the handle grip surface and also include a barrel extending from the handle and defining the first styling surface. The ultrasonic transducer may then be disposed in contact with, and external to, the barrel.
In accordance with another aspect of the disclosure, a device for styling hair includes a first arm defining a first handle grip surface, a second arm pivotally coupled to the first arm and defining a second handle grip surface, a first flat plate mounted on the first arm and defining a first styling surface spaced from the first handle grip surface, and a second flat plate mounted on the second arm and defining a second styling surface spaced from the second handle grip surface. The first and second flat plates are positioned to clamp the hair between the first and second styling surfaces. The device further includes a heating element in thermal communication with the first flat plate or the second flat plate to transfer heat to the hair via the first styling surface or the second styling surface, and an ultrasonic transducer secured to the first arm and configured to generate ultrasonic vibrations. The ultrasonic transducer includes a horn in contact with the first flat plate to transmit the ultrasonic vibrations to the hair via the first styling surface.
The first arm may be oriented along a longitudinal axis, and the ultrasonic transducer may be oriented along the longitudinal axis such that the ultrasonic vibrations are generated in a direction parallel to the longitudinal axis.
In some cases, the ultrasonic transducer is disposed within the first arm. Alternatively or additionally, the ultrasonic transducer is oriented in alignment with the first arm, and the ultrasonic transducer includes a horn adapter to direct the ultrasonic vibrations laterally toward the first flat plate.
Objects, features, and advantages of the present invention will become apparent upon reading the following description in conjunction with the drawing figures, in which like reference numerals identify like elements in the figures.
The disclosure is generally directed to an ultrasonic hair styling device that transmits ultrasonic vibrations to the hair to reduce the amount of heat applied for styling. The disclosed devices generally improve hairstyling by decreasing the time and temperature level of the applied heat, thereby improving the overall health of the hair, increasing shine, and improving styling hold. In this way, users of the disclosed devices can style hair faster and create longer-lasting holds without having to resort to the application of more heat. Instead of conventional styling heat levels of 400-450° F., use of the disclosed devices has effectively styled hair at temperature levels around about 250° F. to about 350° F.
The ultrasonic vibrations generally apply energy to the hair via the styling elements or surfaces in contact with the hair. The energy from the ultrasonic vibrations then adds to the energy applied by the heat such that the total energy reaches a level appropriate for styling. The energy from the ultrasonic vibrations also results in improved heat distribution in the styling elements or surfaces, which may also help reduce the time needed to achieve and set the desired styling. In hairstyling devices involving wet-to-dry operation, the ultrasonic vibrations lead to faster drying and, thus, lower amounts of applied heat. For these reasons, the likelihood or risk of damage to the hair decreases.
Although described below in connection with curling irons and flat irons, the ultrasonic vibrations may be useful in connection with a variety of hair styling tools or techniques. Thus, the disclosed hair styling devices are not limited to curling irons or flat irons. Nonetheless, in some cases, the ultrasonic vibrations may be transferred while the hair is clamped or otherwise fixed between styling tools or elements. In this way, contact between the vibrating elements of the disclosed devices in the hair is ensured.
Turning to the drawing figures,
The handle 24 and the barrel 26 may be integrally formed to any desired extent. The handle 24, for instance, may include a rubberized, plastic, or other grip (not shown) mounted upon an extension of the barrel 26. In other cases, one or both of the portions of the elongate housing 22 may be formed via interlocking or interconnected half- or other shells. For example, the handle 24 may include a molded, two-piece construction consisting of two matching, half-cylinder plastic covers secured to one another via one or more screw or other fasteners. These and other parts of the handle 24 may be constructed of a variety of materials other than plastics, including stainless steel. The barrel 26 may include one or more components constructed of stainless steel, iron, aluminum, or other thermally conductive materials. In some cases, the handle 24 and the barrel 26 are discrete structures connected to one another via one or more fasteners, one or more snap-fit connectors, or some other coupling mechanism. Alternatively, the handle 24 may be configured as a sleeve that fits over a tube or other housing that runs the length of the device to also form the barrel 26.
The handle 24 includes a number of user interface or control elements. To this end, the handle 24 may have a non-circular cross-sectional shape. The example shown, for instance, has a longitudinal ridge 31 that runs the entire length of the handle 24. The ridge 31 presents a panel or other section of the grip surface 28 for the user interface or control elements. The ridge 31 and other projections may also improve the grip surface 28. In other cases, the handle 24 may have an oval or other non-circular cross-sectional shape to configure the grip surface 28 in a desired manner. Similarly, the barrel 26 need not have a circular cross-sectional shape as shown in the event that, for instance, a different curl or other styling effect is desired.
Both the handle 24 and the barrel 26 are configured as hollow tubes to accommodate a number of functional elements, such as electrical components and circuitry. These components generally support the operation of the curling iron 20, which includes ultrasonic vibration as described below. In this example, the handle 24 houses a circuit board 32 shaped as an elongate strip oriented lengthwise and mounted within the handle 24 via one or more screw or other fasteners. The barrel 26, in turn, houses one or more heating elements 34 and an ultrasonic transducer 36. The heating elements 34 are generally disposed within the barrel 26 in thermal communication with the styling surface 30 to transfer heat to the hair wound around the barrel 26. In this example, each heating element 34 includes a thermally conductive strip 38 disposed and extending along an interior wall of the barrel 26. Each strip 38 may have any desired shape, including, for instance, a flat or curved plate. Both the heating elements 34 and the ultrasonic transducer 36 are generally oriented lengthwise within the barrel 26.
Each heating element 34 may be conventionally constructed and configured. Suitable heating element materials include ceramics and metals. In this example, each heating element 34 includes an elongate, flat, ceramic plate disposed upon a flat or other mount inside the barrel 26. Each mount may be constructed of a heat conductive material to encourage the transfer of heat from the heating element 34 to the styling surface 30 of the barrel 26. The barrel 26 in this case has a pair of opposing heating elements positioned lengthwise within the barrel 26. Each heating element 34 may run the length of the barrel 26 or any desired segment thereof. In this example, each heating element 34 extends from an inner end of the barrel 26 to the electronic transducer 36, stopping short of the outer end of the barrel 26 as shown. Any number of heating elements 34 may be disposed within the barrel 26 at a variety of locations, including those that reach the outer end of the barrel 26 as with, for instance, the embodiment described below. One potential advantage of the disclosed hair styling devices, however, is that the number, size, or intensity of the heating elements 34 may be reduced as a result of the application of ultrasonic vibrations, as described below. Nonetheless, the disclosed hair styling devices may still include a conventional amount of heating capacity to provide the operator with various operational options, including a non-ultrasonic option. In these and other ways, the curling iron 20, for instance, may be configured to present a range of possible heating levels to the operator to accommodate different hairstyling requirements arising from, for instance, differing hair thickness.
The curling iron 20 also includes a clip assembly 40 pivotally secured to the elongate housing 22. The clip assembly 40 may include one or more springs or other elastic elements to bias the clip assembly 40 toward the barrel 26 to thereby clamp and hold the hair in position between the styling surface 30 of the barrel 26 and a plate 42 of the clip assembly 40. The plate 42 extends lengthwise along the barrel 26 and has a styling surface 44 on an inward facing side. The plate 42 is generally capable of moving the styling surface 44 into a position facing or opposite from the styling surface 30 of the barrel 26. The barrel 26 and the plate 42 may be configured so that the shapes of the styling surfaces 30 and 44 are matching or complementary. For instance, the plate 42 may be curved to an extent to match the curvature of the barrel 26.
In this example, the plate 42 is pivotally coupled to the elongate housing 22 via a pivot link 46 of the clip assembly 40. The pivot link 46 has one or more ends that terminate at a respective pivot joint or hinge 48 at which the clip assembly 40 is secured to the elongate housing 22. In this example, the clip assembly 40 has two diametrically opposed pivot joints 48 at an inner or proximate end 50 of the barrel 26. Each pivot joint 48 includes a pin, bolt, or other pivot element 52 that passes through the pivot link 46 and the barrel 26. The pivot link 46 generally extends laterally outward from the barrel 26 to form a lever 54, which may, in turn, include a grip surface 56 to facilitate operator engagement during operation. The manner in which the clip assembly 40 is pivotally coupled may vary considerably. For instance, in some cases, the clip assembly 40 is secured to the handle 24.
The shape, construction, and other characteristics of the handle 24, the barrel 26, and the clip assembly 40 may vary considerably from the example shown. A variety of different configurations and constructions are well suited for use with the ultrasonic features of the disclosed hairstyling devices.
The circuit board 32 includes a number of circuit elements 58 to control each heating element 34 and the ultrasonic transducer 36. The circuitry responsible for controlling the heating and ultrasonic vibrating functions may be integrated to any desired extent. In some cases, a separate circuit board may be disposed within the elongate housing 22 to handle one of the two functions alone. In any event, the circuit elements 58 may be disposed in a location within the elongate housing 22 (e.g., near a base end of the handle 24) to avoid the heat generated by the heating elements 34. Because one or more of the circuit elements 58 may also constitute sources of heat, the circuit elements 58 may be nonetheless configured for operation in an elevated temperature environment. Temperature levels within the housing 22 may exceed normal operating temperatures even though the circuit elements 58 are spaced from the heating elements 34. To help dissipate heat, one or more of the circuit elements 58 may include a heat sink 60. For example, one or more copper elements may be disposed upon a circuit board 32 or a respective one of the circuit elements 58. In some cases, the curling iron 20 may include a barrier, divider, wall, or other element within the housing 22 to block the transmission of heat from the barrel 26 to the components within the handle 24.
The circuit board 32 is coupled to a power source via a power cord 62. In other examples, the circuit board 32 is coupled to a battery or other portable power source, which may be rechargeable via, for instance, the power cord 62. The circuit board 32 is also coupled to one or more control or input elements 64. One or more of the control elements 64 may be directed to activating and deactivating the curling iron 20 or one or more operational features thereof, including ultrasonic vibration. Other control elements 64 may be directed to selecting or determining operational parameters, such as heat level and ultrasonic vibration. For instance, an operator may be given an opportunity to adjust the heat level to a lower temperature when the ultrasonic vibration feature is activated. In other cases, the heat level is automatically reduced upon activation of the ultrasonic vibration feature. More generally, an operator may adjust the temperature level to customize the curling iron 20 for personal use requirements or preferences.
The positioning, structural configuration, and other physical characteristics of the electrical and circuit-related components of the curling iron 20 may also vary considerably from the example shown. For example, circuit elements may be disposed on more than one circuit board or otherwise spaced apart to improve heat dissipation. Details regarding the electrical characteristics of the circuit-related components are provided below.
As described below, the ultrasonic transducer 36 is generally configured to generate ultrasonic vibrations to improve and facilitate hairstyling through lower levels of applied heat. In this example, the ultrasonic transducer 36 includes an assembly of components disposed within the barrel 26. In that way, the vibrations generated by the transducer 36 are transmitted through the barrel 26 to the styling surface 30, at which point the vibrations are, in turn, transmitted to the hair in contact therewith. To that end, the ultrasonic transducer 36 is generally disposed in a position that allows the vibrations to be transmitted to the styling surface 30 and, ultimately, to the hair being styled. In this example, the transducer 36 is mounted or oriented lengthwise along a longitudinal axis of the barrel 26. The longitudinal axes of the barrel 26 and the transducer 36 are aligned such that the ultrasonic vibrations are generated in a direction parallel to the longitudinal axis. This transducer orientation allows the size and length of the transducer 36 to be maximized in the limited space available within the barrel 26. However, as shown with the examples described below, the location and orientation of the transducer 36 may vary, including, for instance, non-axial orientation involving a radial mount.
With reference now to a
The ultrasonic transducer 36 may be disposed at other locations within the elongate housing 22. For example, the transducer 36 may be disposed at the inner end 50 of the barrel 26. In that case, the front face 68 of the transducer 36 may again be adjacent another end cap or other face (not shown) to maximize the surface area of the interface between the transducer 36 and the barrel 26. In such cases, the transducer 36 may not extend the entire width of the barrel 26 so as to allow electrical connections and other elements to pass by the transducer 36 to reach the heating elements 34 (
The ultrasonic transducer 36 may be secured within the elongate housing 22 via an adhesive layer or film 72 between the rim 70 and the inner surface of the barrel 26 (also shown in
The piezoelectric section 82 is disposed between the front- and back-end stages of the transducer 36. The piezoelectric section 82 includes a set of piezoelectric discs 88 arranged in a stack. Each disc 88 may be made of Lead zirconate titanate (PZT) or other piezoelectric ceramic(s) or other material(s) with the piezoelectric property of changing shape upon the application of an electric field. PZT and other ceramic materials are useful in the curling iron context due to heat compatibility, as the heating elements 34 are conventionally raised to temperature levels of approximately 400-450° F. for hairstyling (or 250-350° F. with the benefit of ultrasonic vibration as described herein). The piezoelectric discs 88 as well as the transducer 36 are commercially available from Sunnytec Electronics Co. Ltd. (Taiwan). The disc stack is generally configured so that the vibrations generated by the discs 88 are in phase for constructive amplification. In this case, the stack includes four discs 88 oriented axially, or longitudinally, within the housing 22 (
Positive and negative pairs of the electrodes 90 are reached via U-shaped contacts 92, which generally run along the stack lengthwise before bending radially inward toward the electrodes 90. Each contact 92, in turn, is connected to wiring (not shown) that leads to the circuit board 32 (
The three stages of the transducer 36 are secured to one another by a bolt or other fastener 94 that extends axially forward from the reflector 84 through the discs 88 of the piezoelectric stage 82 to reach the horn 80. To that end, each disc 88 and each electrode 90 may have a hole (not shown) formed in the center thereof to allow the bolt 94 to pass through. The bolt 94 may have a threaded end 96 configured to engage a matching threaded opening (not shown) in the horn 80. The bolt 94 may be welded or otherwise fixed to the reflector 84 at its other end. In some cases, the bolt 94 may be integrally formed with the reflector 84. During assembly of the transducer 36, the reflector 84 is rotated relative to the horn 80 for compression of the stages of the transducer 36. The horn 80 and the reflector 84 include opposed pairs of flattened sections 98, 100, respectively, to allow a wrench or other tool to help tighten the assembly to reach a suitable level of compression.
The heating elements 34 in this example are disposed along the inner surface 102 of the barrel 26. However, the heating elements 34 need not be curved to match the curvature of the barrel 26 and, thus, need not be disposed in contact with the inner surface 102 across their entire width or length. Instead, the heating elements 34 are more generally disposed along the barrel 26 at a radial position outward of the transducer 36 and either directly or indirectly coupled to the inner surface 102. An indirect coupling may include heat-conductive mounting hardware (not shown) that establishes the transmission of heat from the elements 34 to the inner surface 102 and, from there, through the barrel 26 to the styling surface 30 opposite the inner surface 102.
The transducer 36 has an overall axial length LT and a horn length LH, as defined in
Notwithstanding the foregoing, the diameter of the barrel 26 may present challenges for the design and mounting of the transducer 36 and thereby cause a deviation from the ideal λ/4 configuration. In some cases, the diameter of the rim 70 of the horn 80 may be limited by the diameter of the barrel 26. As a result, the length of the horn 80 may be shorter than the optimal length in order to achieve resonant operation with the other stages of the transducer 36. In one example with a 1.5″ diameter barrel, the horn 80 is shorter than the optimal length to ensure that the horn 80 resonates at the same frequency as the piezoelectric stage. The shorter horn length also helps to maintain a proper mass differential between the reflector and horn stages in the interest of ensuring that the vibrations are directed toward the horn.
With the horn-shaped (or frustoconical) transducer configuration shown in
During operation, the vibrations generated by the piezoelectric discs 88 travel axially forward to the horn 80. Once at the horn 80, the vibrations travel further forward to transmit energy to the end cap 66 via the front face 68. The vibrations of the horn 80 also spread radially to transfer energy to the barrel 26 via the annular interface between the rim 70 and the inner surface 102 of the barrel. Through these transmission paths, the ultrasonic energy eventually reaches the hair clamped between the styling surface 30 and the styling surface 44 (
The transmission of ultrasonic energy improves the styling of the hair by facilitating heat transfer within the barrel 26 and by accelerating the restructuring of hydrogen bonds with the hair. On the one hand, the ultrasonic vibrations result in more efficient transfer of heat from the heating elements 34 to the hair through excitation of the molecules within the barrel 26. The excitation of the barrel molecules lowers the heat transfer resistance of the barrel 26. More effective transmission of heat through the barrel 26 lowers the possibility of undesirable hot spots along the barrel, which could otherwise damage hair. More effective heat transmission also lowers the overall heating required to raise the temperature of areas along the barrel 26 other than the hot spots. The general result is more uniform distribution of heat along the barrel 26. Turning to the effects on the hair itself, the vibrations apply energy to the hydrogen bonds between the water molecules in the medulla of the hair. To style hair, these weak electrochemical bonds are broken so that the molecular bonds can be reformed with the molecules in different positions. The ultrasonic energy supplies part of the total amount of energy required to break the bonds. As a consequence, less energy is required from the heat, which ultimately helps to prevent damage to the hair follicle resulting from the heat. For all of these reasons, the hair can be styled faster, which, in turn, lowers the total amount of heat applied to the hair, thereby reducing the possibility for damage.
With reference now to
The exemplary drive circuit 110 is configured as a full H-bridge driver circuit. Other control circuits may instead include other self-oscillating, switched power supplies, such as a half bridge driver circuit. Still other alternatives may be based on a driven circuit configuration in which, for instance, a crystal is used to set an operating frequency. In this case, the power supply voltage Vcc is provided to a timer 126 configured and set in a stable mode for use as an oscillator. To that end, the timer 126 is coupled to a resistor R12 to set the frequency and duty cycle parameters. A commercially available timer suitable for use as the timer 126 may be obtained from National Semiconductor Corporation associated with product number LM555. The oscillating output of the timer 126 may be provided to a divider 128 configured to, for instance, reduce the duty cycle by 50%. A full-bridge driver 130 receives the oscillating signal to develop switch control signals for two full-bridge switch circuit pairs 132. In operation, the switch circuit pairs 132 are selectively activated in accordance with the switch control signals to generate an AC output drive signal based on the high DC voltage input V_hv and apply the signal to the ultrasonic transducer (
One or more of the above-identified integrated circuit chips or circuit components may be coupled to a heat sink. The heat sink(s) help maintain the operating temperatures of the chips and components to levels within a desired operating temperature range. The heat generated by the heating elements 34 (
In some cases, one or more circuit elements may be incorporated into the drive circuit 110 to address spurious vibration modes or other undesired vibrations. For example, a potentiometer may be added to prevent undesirable harmonic frequencies of the drive signal frequency from reaching the transducer. Otherwise, the harmonic frequencies may be audible to the operator of the curling iron or the operator's pets. The potentiometer may be configured to modify the duty cycle of the oscillator output.
The drive signal generated by the circuit 110 may have a peak-to-peak amplitude of about 160 Volts. With the full H-bridge driver is used, the amplitude may be increased to as high as 320 Volts, in which case the number of piezoelectric discs may be increased accordingly to accommodate the higher amplitude. Thus, the amplitude may fall within the range of about 160 Volts to about 320 Volts for some embodiments. With these amplitudes, the drive signal may, for instance, provide 10-100 Watts of power to the ultrasonic transducer. The amplitudes may exceed that range in some cases (e.g., transformer-based circuits) to deliver more energy to the hair and the barrel, although at the cost of increased component size and weight.
The drive circuit 110 does not include a transformer to generate the high AC drive voltage, despite the prevalence of transformers in ultrasonic drive circuits. A transformer would add significant and undesirable amounts of size and weight to the hairstyling device. While the non-transformer drive circuit described above may be limited to lower drive voltage amplitudes, that factor can be offset by the selection of the drive frequency and optimal tuning of the transducer horn. For example, the transducer geometry may be adjusted and analyzed to operate at a natural resonant frequency of the transducer. An FEA package was used to analyze and determine the natural resonant frequencies. Geometric adjustments then led to an operational frequency close to the natural resonant frequency of the transducer and the drive frequency of the piezoelectric discs. The mounting of the transducer may also lead to improved transfer of the axial horn vibrations to the barrel. Notwithstanding the foregoing, all component values shown in
Turning to
The flat iron 140 includes an elongate housing 142 that has several components in common with the housing 22 described above. The housing 142 similarly defines a handle grip surface 144 and a styling surface 146 spaced from the handle grip surface 144. A plate 148 is also pivotally coupled to the housing 142 to clamp the hair between a styling surface 149 of the plate 148 and the styling surface 146. In this case, however, the plate 148 is carried by another elongate housing 150 (rather than a clip), and the styling surface 146 is an exterior face of another plate 152 carried by the housing 142. The housing 150 is configured as a pivoting arm (or wand) with a proximal, linked end 154 upon which a pivot joint 156 is mounted for coupling with a proximal, linked end 158 of the pivoting arm (or wand) of the housing 142. The two wands or arms extend outward from the linked ends to define a longitudinal axis of each housing 142, 150. The plates 148 and 152 are disposed at distal, free ends 160 and 162 of the housing arms, respectively, at locations disposing the styling surfaces 146, 149 opposite one another. The housing 150 also has a handle grip surface 164 so that an operator can grasp the two wand-shaped housings 142, 150 to bring the styling surfaces 146, 149 toward one another. In this manner, the plates 148, 152 can act as pressure plates to apply pressure to the hair to be styled therebetween. The pivot joint 156 is spring-loaded to bias the flat iron 140 open when no inward force is applied to the handle grip surfaces 144, 164.
Each plate 148, 152 may be fixedly or otherwise mounted within a recess, notch, or other hole in its respective housing. The plates may be made from stainless steel, aluminum, copper, or any other suitably thermal conductive material. Each housing 142, 150 may be made from stainless steel, aluminum, plastic, or any other desired material.
The flat iron 140 also includes a power cord 166 for delivery of power to one or more control circuits (not shown) disposed within one or both of the housings 142, 150. In this case, a control circuit may be disposed within the housing 142 in proximity to a control panel 168 that includes user interface elements 170, 172 for operator control of the flat iron 140. The control panel 168 may be used to activate and deactivate an ultrasonic vibration feature of the flat iron 140 provided by an ultrasonic transducer 174. The control panel 168 may also be used to select a temperature level or other operational parameters. Heat is applied to the hair clamped between the styling surfaces 146, 149 via one or more heating elements 176 in thermal communication with a respective one of the surfaces 146, 149. Each heating element 176 may be configured as a flat plate secured to an interior side of one of the plates 148, 152. In this case, the housing 142 is shown with one of the heating elements 176, although, in other cases, the other housing 150 may contain the sole (or an additional) heating element secured to the plate 148.
The ultrasonic transducer 174 is again configured as an assembly of sections or stages disposed within a hollow interior space of a wand or arm of the hairstyling device. The transducer 174 is generally configured to generate ultrasonic vibrations to facilitate energy transmission with one or both of the pressure plates 148, 152 and to transfer vibration energy to the hair clamped therebetween. However, in this case, the interior space provided by each housing 142, 150 of the flat iron 140 may not be sufficiently large or appropriately shaped to mount the Langevin transducer described above in a manner that disposes the front face of the horn in contact with a matching surface within the housing. However, it may remain beneficial to orient the transducer 174 axially within the housing, with the longitudinal axes of the transducer 174 and the housing aligned. Consequently, the transducer 174 in the depicted example is configured with a horn 178 having an adapter that translates the longitudinal, axial vibration into vibration in a lateral direction toward one of the plate 152. To that end, the horn 178 includes an L- or elbow-shaped head 180 that projects forward from a cylindrical section of the horn 178 adjacent a piezoelectric stage 182. After extending forward, the L-shaped head 180 projects laterally downward to place an outer end 183 in contact with an interior surface 184 of the plate 152. The remainder of the transducer 174 may rest upon, and be secured to the heating element 176 or other surface or component within the housing 142. A similarly mounted transducer may be housed within the housing 150 for transmission of ultrasonic vibrations through the plate 148. In operation, the vibration mode causes the head 180 to move laterally (as opposed to axially) toward and away from the plate 152. The transducer 174 thus vibrates along a hammer-like motion path.
Despite the directional translation of the vibration propagation achieved by the head 180, the profile of the flat iron wands or arms may, in some cases, be too thin to mount the transducer 174 within the housing. The thickness of the heating element 176 may also be a factor. Part of the problem may also arise from a transducer selected or configured for a desired resonant frequency, power capacity, or other operational parameter that ends up being too large for the housing.
With reference now to
As shown in
The overall length LT and horn length LH dimensions of the transducer 200 may be selected in accordance with the above-described considerations. The horn length includes the combined length of the cylindrical section 210 and the adapter 202. The length of the reflector stage 204 is noted as LR and may be a direct multiple of the wavelength in the interest of constructive interference (as is the case with the above-described example).
As described above, the transducer 200 may be configured with dimensions offset from the desired lengths in order to ensure that the horn resonates at substantially the same frequency as the ceramic discs of the piezoelectric stage. As a result, the piezoelectric discs are driven with a frequency corresponding with the resonant frequency of the transducer. Thus, the horn length is shorter than λ/4. One exemplary transducer has a main body length of 56 mm, a horn length of 28 mm, a disc diameter of 15.04 mm, a cylindrical horn section diameter of 16.25 mm, an adapter (hammer) width of 12 mm, and an adapter (hammer) lateral extension width (or height) of 15 mm.
Operation of the transducer configuration shown in
With reference now to
One advantage of this exterior mounting of the embodiment of
Generally speaking, the material(s) from which the transducer horns described above are made are selected to ensure effective transmission of the ultrasonic vibrations through the interface between the horn and the barrel, plate, or other component. Effective transmission generally avoids reflection at the interface, which may occur in situations where the impedance of the materials on either side of the interface do not sufficiently match. Suitable materials for the transmission of ultrasonic vibrations in the context of hairstyling devices include aluminum and duraluminum because the acoustic impedance of these materials is approximately halfway between (i.e., an average of) the acoustic impedances of the ceramic (PZT) discs (45 MRay) and the water in the hair being styled (1.5 MRay), i.e., the final medium. Aluminum and duraluminum, for instance, have acoustic impedances of 17.3 MRay and 17.6 MRay, respectively. Duraluminum may be preferable over aluminum because it is harder. Other materials may be used, including those that have crystalline or polycrystalline material structures.
Notwithstanding the advantages of the foregoing examples, the transducer may be mounted in a variety of locations on the hairstyling devices. For instance, the transducer may be mounted on the clip or clamp of a curling iron. The transducers also need not be oriented axially, i.e., along the longitudinal axis of barrel. Even when the transducer is oriented axially, the horn may be configured to transmit vibrations in a direction transverse to the longitudinal axis of the barrel. Thus, the vibrations may be transmitted through the barrel, plate, or other housing structure radially, longitudinally, laterally, or any combination thereof. A variety of other translation sections other than the elbow-shaped adapter described above may be used to change the direction of the vibrations. Each housing or styling surface may contain or have more than one transducer associated therewith.
The transducers may be mounted on a flat surface extruded onto the inner surface of the above-described barrels or wands. The flat surface may be similar to those formed for supporting heating elements. The transducers may alternatively or additionally mounted to an end of the plates described above for transmission of the vibration longitudinally.
The plate with which the transducer is contact in some of the above-described embodiments may be floating relative to the wand or arm housing via one or more springs. The plate is indirectly coupled to the wand housing via the spring(s), in contrast to the plates described above which are rigidly fixed to the wand housing. The separation or indirect coupling of the plate and the wand housing may reduce the amount of vibration energy absorbed by, or dissipated via, the housing.
The above-described barrels, plates and other objects with which the transducers are in contact may be sized to maximize wave transmission within the plate or object. For instance, the plate or barrel may have a length or other dimension equal to the wavelength or a direct multiple thereof.
Other ultrasonic generators may be used. As described above, the device responsible for generating the ultrasonic vibrations may be located at various positions, including those within the barrel, handle, arm, wand, or other hollow structure or housing, as well as those exterior to, but in contact with, such structures, as well as those in contact with some other element in contact with the hair, such as a clip or clamp. Thus, in some cases, the ultrasonic generator is not in direct contact with the barrel or other iron structure.
The construction and configuration of the wands, arms, and elongate housings of the devices described above may vary widely from the examples shown. They need not be of uniform construction, circumference, diameter, or two-piece construction
The disclosed hairstyling devices are not limited to curling irons with clips or spring-loaded clamps. The ultrasonic vibrations may be applied to the hair via clipless wands in which the hair is wrapped around a rod or styled using an iron with a Marcel handle.
A variety of horn shapes may be used with the disclosed hairstyling devices. The transducer horns are not limited to cylindrical or frustoconical shapes. In this way, the disclosed hairstyling devices may accommodate a wide range of barrel diameters and shapes. The disclosed hairstyling devices are also not limited to Langevin transducers or bolt-clamped transducer stacks. A variety of different piezoelectric arrangements may be used, such that the configuration and construction of the sections, stages, or components may vary from the examples shown above.
Although certain curling irons and flat irons have been described herein in accordance with the teachings of the present disclosure, the scope of coverage of this disclosure is not limited thereto. On the contrary, all embodiments of the teachings of the disclosure that fairly fall within the scope of permissible equivalents are disclosed by implication herein.
This application claims the benefit of U.S. provisional application entitled “Ultrasonic Curling Iron,” filed Oct. 6, 2009, and assigned Ser. No. 61/249,074, and U.S. provisional application entitled “Ultrasonic Flat Iron,” filed Oct. 28, 2009, and assigned Ser. No. 61/255,657, the entire disclosures of which are hereby expressly incorporated by reference.
Number | Date | Country | |
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61249074 | Oct 2009 | US | |
61255657 | Oct 2009 | US |