阅读说明：本技术 直发器 (Hair straightener ) 是由 彭骏宇 于 2019-01-29 设计创作，主要内容包括：一种直发器(HS),包括加热单元(HU),其用于加热头发并同时在所述头发上施加压力；温度传感器(TS),其用于测量被加热的所述头发的温度以获得测得温度；以及压力调节单元(PAU),其用于根据所述测得温度调节由所述加热单元(HU)施加在所述头发上的所述压力。所述加热单元(HU)可包括一对加热板(HP1、HP2),头发被夹在所述加热板之间,并且所述压力调节单元(PAU)可被布置成用于改变所述加热板(HP1、HP2)之间的距离。所述压力调节单元(PAU)可包括马达操作的推动工具(W、C),以用于在所述测得温度超过第一阈值温度时增加所述加热板(HP1、HP2)之间的所述距离。所述直发器(HS)可包括一对铰接臂(A1、A2),每个所述臂都设有所述加热板(HP1、HP2)中的一个相应的加热板。所述压力调节单元(PAU)可包括马达操作的拉动工具(W、S),以用于在所述测得温度降低到低于第二阈值温度时减小所述铰接臂(A1、A2)之间的距离,由此所述加热板(HP1、HP2)之间的所述距离被减小。(A Hair Straightener (HS) comprising a Heating Unit (HU) for heating hair while exerting pressure on the hair; a Temperature Sensor (TS) for measuring the temperature of the heated hair to obtain a measured temperature; and a Pressure Adjustment Unit (PAU) for adjusting the pressure exerted by the Heating Unit (HU) on the hair according to the measured temperature. The Heating Unit (HU) may comprise a pair of heating plates (HP1, HP2) between which hair is sandwiched, and the Pressure Adjusting Unit (PAU) may be arranged to change a distance between the heating plates (HP1, HP 2). The pressure regulating unit (PAU) may comprise a motor-operated pushing means (W, C) for increasing the distance between the heating plates (HP1, HP2) when the measured temperature exceeds a first threshold temperature. The iron (HS) may comprise a pair of articulated arms (A1, A2) each provided with a respective one of the heating plates (HP1, HP 2). The Pressure Adjustment Unit (PAU) may comprise a motor-operated pulling tool (W, S) for reducing the distance between the articulated arms (a1, a2) when the measured temperature falls below a second threshold temperature, whereby the distance between the heating plates (HP1, HP2) is reduced.)

1. A Hair Straightener (HS) comprising:

a Heating Unit (HU) for heating the hair and simultaneously exerting pressure on said hair;

a Temperature Sensor (TS) for measuring the temperature of the heated hair to obtain a measured temperature;

it is characterized in that the preparation method is characterized in that,

a Pressure Adjustment Unit (PAU) for adjusting the pressure exerted by the Heating Unit (HU) on the hair according to the measured temperature.

2. The Hair Straightener (HS) of claim 1, wherein the Heating Unit (HU) comprises a pair of heating plates (HP1, HP2) between which the hair is sandwiched, and the pressure regulating unit (PAU) is arranged for varying the distance between the heating plates (HP1, HP2) depending on the measured temperature.

3. The Hair Straightener (HS) of claim 2, wherein the pressure regulating unit (PAU) comprises a motor operated pushing means (W, C) for increasing the distance between the heating plates (HP1, HP2) when the measured temperature exceeds a first threshold temperature.

4. The iron (HS) according to claim 2,

the Hair Straightener (HS) comprises a pair of articulated arms (A1, A2) each provided with a respective one of the heating plates (HP1, HP2), and

the Pressure Adjustment Unit (PAU) comprises a motor-operated pulling tool (W, S) for reducing the distance between the articulated arms (A1, A2) when the measured temperature drops below a second threshold temperature, whereby the distance between the heating plates (HP1, HP2) is reduced.

5. The Hair Straightener (HS) of claim 4, wherein the motor operated pulling tool (W, S) is coupled to the second arm (A2) and comprises:

a spring (S) for generating a first pulling force substantially parallel to said first arm (A1), an

A force translation means (T) coupled to the first arm (A1) for translating the first pulling force substantially parallel to the first arm (A1) into a second pulling force substantially perpendicular to the first arm (A1) thereby reducing the distance between the heating plates (HP1, HP2) when the measured temperature falls below a second threshold temperature.

Technical Field

The present invention relates to hair straighteners.

Background

WO2014001128 discloses a hair straightener with two legs having a gripping area and a heatable operating area. A detection device is provided which detects that the iron is being used and communicates this information to a corresponding control/regulating device which is designed to activate the heating device upon receipt of a corresponding signal in order to heat the operating area. The detection device may be a pressure switch to register the closing of the two legs.

US2012080047 discloses a comb-like hair straightening tool. The straightening tool has a row of teeth spaced apart from each other by a respective hair receiving portion. Each tooth is associated with at least one first moulded part, which is movably mounted. It is movably supported relative to another tooth surrounding the hair-receiving portion. The straightening tool also surrounds a second moulded part which is associated with the further tooth surrounding this hair-receiving portion. This serves to implement the hair styling gap between the molded portions of the hair-receiving portion. Only one of the two molded parts is considered sufficient when heated. The prior art devices on which this tool is based have shown a spring force acting on the respective first moulded part, which determines the force acting on the hair during straightening. The second moulded part now represents the support seat. EP1721539 shows that the spring force and thus the force acting on the hair during hair straightening can be adjusted by means of a set screw.

A typical hair straightener uses a temperature sensor to detect changes in the temperature of the heating plate and either compensate for any heat loss caused by heating the hair by increasing the temperature of the heater, or when the heating plate temperature is too high, it cuts off power to the heater until the temperature again falls within the target range. This type of control has some drawbacks. First is the fact that the heating plate temperature does not closely reflect the hair temperature. The hair temperature may be largely affected by the contact pressure and the swing speed. The second is the time delay between when the heater plate temperature changes and when the temperature sensor begins to respond to the change. A typical delay is at least 5 seconds. Third, the time delay between when the heater begins to react and when the heating plate temperature begins to change. For example, when the temperature sensor senses that the heating plate temperature is too low, it signals the heater to turn on. After the heater is turned up, it will take a few seconds before the temperature of the heating plate begins to rise. And it will be a few more seconds later that the heating plate will reach its target temperature. The straightening swing may end before the temperature of the heating plate begins to change, let alone affect the hair temperature in a desired manner.

Disclosure of Invention

The primary object of the present invention is to provide an improved hair straightener. The invention is defined by the independent claims. Advantageous embodiments are defined in the dependent claims.

One aspect of the present invention provides a hair straightener, comprising a heating unit for heating hair while applying pressure to the hair, a temperature sensor for measuring the temperature of the heated hair to obtain a measured temperature, and a pressure adjusting unit for adjusting the pressure applied by the heating unit to the hair based on the measured temperature. The heating unit may include a pair of heating plates between which the hair is sandwiched, and the pressure adjusting unit may include a tool for changing a distance between the heating plates. The pressure regulating unit may comprise a pushing means operated by a motor for increasing the distance between the heating plates when the measured temperature exceeds the first threshold temperature. The iron may comprise a pair of hinged arms, each arm being provided with a respective one of said heating plates. The pressure adjustment unit may comprise a motor operated pulling tool for reducing the distance between the articulated arms, thereby reducing the distance between the heating plates, when the measured temperature falls below the second threshold temperature. The motor operated pulling means may be coupled to the second arm and may comprise a spring for generating a first pulling force substantially parallel to the first arm, and force transformation means coupled to the first arm for transforming the first pulling force substantially parallel to the first arm into a second pulling force substantially perpendicular to the first arm, thereby reducing the distance between the heating plates when the measured temperature falls below a second threshold temperature.

Advantageously, the use of the pressure regulating mechanism can immediately affect the heat transfer from the heating unit to the hair without waiting for the heating unit to slowly change its temperature.

These and other aspects of the invention are apparent from and will be elucidated with reference to the embodiments described hereinafter.

Drawings

Figure 1 shows an embodiment of a hair straightener according to the invention; and

fig. 2 shows another embodiment of a hair straightener according to the invention.

Detailed Description

Hair straighteners rely on physical contact between their heated plates and the hair to transfer energy to the hair to achieve a straightening effect. Generally, the higher the pressure between the heating plate and the hair, the better the straightening effect. However, when the pressure is too high, the friction between the heating plate and the hair will increase, the speed of the straightening swing will decrease, and the heat transfer from the heating plate to the hair will increase significantly due to the higher pressure and longer contact time.

An infrared sensor may be used to detect the hair temperature after the hair has been pressed by the heated plate and determine whether the temperature is above expectations (which may cause permanent hair damage) or below expectations (which may affect the straightening results). In each temperature setting selected by the user, there should be a desired hair temperature result. By comparing the data collected from the infrared temperature sensors with the expected values for each temperature setting, the internal processor will know whether the heat transfer is normal, too high, or too low. The use of an infrared sensor to directly measure the hair temperature greatly reduces the approximation between the heater plate temperature and the hair temperature and is a much faster sensor than the typical NTC temperature sensor used in hair straighteners.

One of the most direct ways to vary the heat transfer between the heating plate and the hair is by varying the contact pressure. The contact pressure is usually fully controlled by the user. However, a mechanism may be added to either increase or decrease the pressure during the straightening swing. When the actual hair temperature is measured to be too high, the mechanism should reduce the contact pressure currently applied by the user to reduce the heat input to the hair to prevent heat damage. Similarly, when the actual hair temperature is measured to be too low, the mechanism should increase the contact pressure currently applied by the user to add heat input to the hair to improve the straightening result.

The pressure regulating mechanism can work stepwise, which means that the pressure regulation can be smaller if the hair temperature is only slightly out of range. In contrast, if the hair temperature is far from the desired temperature range, the pressure adjustment mechanism may turn on all of the energy to increase or decrease the contact pressure to a maximum or minimum.

Embodiments of the present invention provide a hair straightener with at least one infrared sensor that senses the actual hair temperature coming out of the straightener. During the straightening swing, the hair is pressed between the heating plates by a certain pressure applied by the user. When the temperature of the hair at the outlet exceeds a certain value, the built-in pressure regulating mechanism will reduce the applied pressure, thereby reducing the heat transfer from the heating plate to the hair, thus preventing or reducing thermal damage. Similarly, when the hair temperature is less than a certain value, the pressure adjustment mechanism will increase the applied pressure; thereby increasing the heat transfer from the heating plate to the hair and thus improving the straightening effect.

One embodiment of the present invention provides a hair straightener with two arms, at least one infrared temperature sensor, two heating plates for applying pressure to the hair, a hinge, and a mechanism for applying additional contact pressure to the hair or reducing contact pressure from the hair. The infrared sensor may be installed on the side of the hair straightener facing in the direction in which the hair exits from between the upper and lower heating plates. The contact pressure adjustment mechanism may be mounted at a spring-loaded hinge as a geared design driven by a stepper motor with an angular position encoder. During normal use, the motor is not energized, so the two arms are free to open and close, without interference from the mechanism, even when the gears are always engaged. In a waving, when the user exerts a constant pressure on both arms and when the outlet hair temperature is too cold compared to the desired value, the motor will rotate clockwise by a certain angle as shown in the drawing, which will force the upper arm to press down from its current position, increasing the constant pressure being exerted by the user and thus the total contact pressure between the heating plate and the hair. This mechanism works in the opposite way when the hair contact pressure needs to be reduced, the motor being rotatable through an angle counterclockwise to achieve this result. This pressure regulating mechanism may be completely accommodated within the housing of the iron body.

Fig. 1 shows an embodiment of a hair straightener HS according to the invention. The hair straightener HS comprises two arms a1, a2, which are coupled by a hinge H. Each arm a1, a2 is provided with a respective heating plate HP1, HP2, which together form a heating unit HU. The temperature sensor TS measures the temperature of the heated hair to obtain a measured temperature. A pressure regulating unit PAU is provided to regulate the pressure of the heating plates HP1, HP2 against the hair between the heating plates HP1, HP2, depending on the measured temperature.

In the embodiment of fig. 1, the pressure regulating unit PAU comprises a wheel W mounted on and operated by a servomotor (not shown) mounted on the second arm a 2. The wheel W is provided with cams C, together forming a pushing means for increasing the distance between the heating plates (HP1, HP2) when the measured temperature exceeds a first threshold temperature. A spring S is mounted between the first arm a1 and a cam C on the wheel W, which together form a pulling means to reduce the distance between the heating plates when the measured temperature falls below a second threshold temperature.

If the measured hair temperature is too low, the temperature sensor TS controls the servomotor to rotate the wheel W clockwise. This will cause the first arm a1 to be pulled downward by the spring S. This will increase the pressure exerted by heating plates H1, H2 on the hair between heating plates H1, H2.

If the measured hair temperature is too high, the temperature sensor TS controls the servomotor to rotate the wheel W counterclockwise. This will cause the first arm a1 to be pushed upwards by the cam C mounted on the wheel W. This will reduce the pressure exerted by heating plates H1, H2 on the hair between heating plates H1, H2.

Fig. 2 shows another embodiment of a hair straightener HS according to the invention. Fig. 2 differs from fig. 1 in that the pressure regulating unit PAU now comprises a force transformation means T formed by a pair of triangles, one triangle (the left triangle in fig. 2) being connected to the spring S and the other triangle (the right triangle in fig. 2) being connected to the first arm a 1. If the measured hair temperature is too low and the wheel W is rotated clockwise, the spring S will pull the left triangle to the right and the left triangle will pull the first arm A1 downward because the hypotenuse of these triangles will translate the horizontal force of the left triangle being pulled against the right triangle into a vertical force. Instead of a pair of triangles, the force conversion tool T may comprise a pair of other shapes having matching hypotenuses to convert a force in a first direction to a force in a second direction substantially perpendicular to the first direction.

It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be able to design many alternative embodiments without departing from the scope of the appended claims. The heating unit may heat the hair by means of a heated heating plate, or heat the hair by means of applying light or ultrasonic waves to the hair. The pressure regulating unit may alternatively use a piston located between heating plates, to which air is applied if it is necessary to increase the distance between the heating plates, and from which air is withdrawn if it is necessary to decrease the distance between the heating plates. The pressure regulating unit may alternatively change the angle between the two arms in that they pivot at one point. The pressure regulating unit can alternatively change the pressure or force between the heating plates and the hair without changing the distance between the heating plates, since there is a high heat transfer when the heating plates are pressed tightly together. And when the plates are lightly touching there is low heat transfer, but in both cases the distance is zero. The iron may have two heating plates that are pressed together by the user, or may be a comb-like device as described in US 20120080047. In the claims, any reference signs placed between parentheses shall not be construed as limiting the claim. The word "comprising" does not exclude the presence of elements or steps other than those listed in a claim. The word "a" or "an" preceding an element does not exclude the presence of a plurality of such elements. The invention may be implemented by means of hardware comprising several distinct elements, and/or by means of a suitably programmed processor. In the device claim enumerating several means, several of these means may be embodied by one and the same item of hardware. The mere fact that certain measures are recited in mutually different dependent claims, which are not dependent on each other, does not indicate that a combination of these measures cannot be used to advantage.