EP1926574A1

EP1926574A1 - Electric hair-removal appliance

Info

Publication number: EP1926574A1
Application number: EP06776742A
Authority: EP
Inventors: Bernhard Kraus
Original assignee: Braun GmbH
Current assignee: Braun GmbH
Priority date: 2005-09-24
Filing date: 2006-08-10
Publication date: 2008-06-04
Anticipated expiration: 2026-08-10
Also published as: DE102005045713A1; US20080196258A1; JP5020958B2; WO2007033729A1; JP2009508606A; DE502006005993D1; US8667692B2; EP1926574B1; ATE455628T1

Abstract

An electric hair removal apparatus for removing hair from the human skin. The hair removal apparatus includes a housing adapted to be held in the hand, a mechanically working hair removal device and a motor for driving the hair removal device. Provision is made for a sensor device for generating a signal that depends on the speed at which the hair removal device is moved over the skin during the hair removal.

Description

Electric hair removal device

The invention relates to an electric hair removal device. Furthermore, the invention relates to a method for removing hair from the human skin.

Electric hair removal devices are often operated by means of built-in batteries, especially rechargeable batteries. This can be avoided that the handling of the hair removal devices is hindered by cables. Since the storage capacity of the batteries is limited, the most efficient use of stored electrical energy is desirable. Much of the electrical energy used to operate the hair removal devices is not immediately used to remove the hair but is lost, for example, by friction in the driveline of the hair removal devices. This means that the operation of hair removal equipment even then results in a significant consumption of electrical energy, if no or only a few hairs are removed.

In order to limit energy consumption and achieve adequate hair removal, hair removal devices are often designed for the average expected operating conditions. However, this leads to the hair removal devices idle, d. H. if no hair is removed, cause vibration and noise, and at full load, d. H. if a lot of hair is removed, show an insufficient function. This undesirable behavior can be counteracted by controlling the speed of the drive motor of the hair removal devices.

Thus, from DE 42 01 027 A1 and US-PS 5,367,599 an electric shaver is known, which includes depending on the load current of the motor to a high or low density. The motor is then controlled on the basis of the determined density of the beard. At a low density of the bark, the engine is operated at a low speed and at a high density of barbs at a high speed.

EP 0 719 202 B1 discloses a razor with an electric motor whose speed varies from a feedforward control unit as a function of at least one physical quantity. The physical quantity is measurable by means of a pick-up which detects a sound signal for determining the hair cut per unit time, the shaving time which has hitherto elapsed or a skin contact force. The invention has for its object to achieve a thorough hair removal with a hair removal device with low energy consumption.

This object is achieved by a hair removal device with the feature combination of claim 1 and by a method according to claim 18.

The electric hair removal apparatus of the present invention for removing hair from the human skin has a hand-durable case, a mechanical hair removal device, and a motor for driving the hair removal device. The peculiarity of the hair removal device according to the invention is that a sensor device is provided for generating a signal which depends on the speed with which the hair removal device is moved over the skin during hair removal.

An advantage of the hair removal device according to the invention is that by using the signal of the sensor device, a low energy consumption can be achieved and yet a thorough and skin-friendly hair removal is possible. In the case of battery operation results over known hair removal devices a longer battery life or it can be used batteries with reduced dimensions. In addition, even with rapid movements of the hair removal device relative to the skin, there is no painful pulling on the hair. Another advantage is that the noise level and the vibrations during operation of the hair removal device can be kept relatively low overall.

The sensor device may have at least one rotatably mounted rotary body. The rotary body is preferably arranged to be rotated as the hair removal device is moved across the skin. Furthermore, the sensor device may have a measuring transducer for direct or indirect detection of the rotation of the rotary body. In this way, the speed of the hair removal device relative to the skin can be detected by simple means.

Likewise, it is also possible that the sensor device has a light source and a light sensor. The light source is preferably arranged to irradiate the skin as the hair removal device is moved across the skin. This embodiment of the sensor device has no moving parts and therefore has a long Lifespan. In addition, a sensor device designed in this way works very reliably and precisely.

In a preferred embodiment, the hair removal device according to the invention has a control device for controlling the motor depending on the signal of the sensor device. It can be provided that the control device controls or controls a movement amount of a component of the hair removal device to a first predefinable value, which depends on the signal of the sensor device. This means that the movement of this component depends on how quickly the hair removal device is moved across the skin. The amount of movement may, in particular, be a speed or a vibration amplitude of the component of the hair removal device.

Likewise, it is also possible for the control device to regulate or control a movement variable of the motor to a second predefinable value, which depends on the signal of the sensor device. It is advantageous if a motor sensor is provided for providing a signal for the control device, which depends on the amount of movement of the motor. The amount of movement can be a speed, a speed or a vibration amplitude of the motor. It is particularly advantageous if the control device determines the second predefinable value on the basis of the first predefinable value.

The hair removal device according to the invention can be developed so that the control device, the motor depending on a user setting for skin sensitivity and / or a power consumption of the engine and / or a current hair removal mode and / or from a parameter determined in the past and / or a Advances the hair removal and / or of a minimum and / or maximum value for the amount of movement of the engine or the component of the hair removal device. As a result, the hair removal device can be further optimized and adapted to the particular user.

Preferably, the hair removal device according to the invention is designed as a shaver. But there is also the possibility of training as an epilation device.

In the method of removing hair from human skin according to the present invention, an electric hair removal device incorporating a motor-driven hair removal device is disclosed. Removal device has passed over the skin. The inventive method is characterized in that the motor is driven depending on the speed with which the hair removal device is moved over the skin.

In the context of the method according to the invention, a movement amount of a component of the hair removal device can be regulated or controlled to a first predefinable value, which depends on the speed with which the hair removal device is moved over the skin. Furthermore, a movement amount of the motor can be controlled or controlled to a second predetermined value, which depends on the speed with which the hair removal device is moved over the skin.

The invention is explained below with reference to the embodiments illustrated in the drawings.

Show it:

1 shows an embodiment of an inventive electric shaver in side view,

2 is an enlarged detail of the razor in a sectional view for illustrating an embodiment of the sensor device,

Fig. 3 shows a further embodiment of the sensor device in a Fig. 2 corresponding representation and

Fig. 4 is a block diagram of a possible variant of an inventive control of the motor of the razor.

Fig. 1 shows an embodiment of an inventive electric shaver 1 in side view. The razor 1 has a housing 2 durable in the hand and a shaving head 3 attached thereto. On the housing 2, a switch 4 for switching on and off of the shaver 1 is arranged.

The shaving head 3 has a shearing system 5 with a lower blade 6 and a shearing foil 7. The shearing foil 7 is arranged in a holding frame 8. Furthermore, the shaving head 3 has a sensor device 9 for detecting the speed at which the shaving head 3 while the shave is moving over the skin. Structure and operation of the sensor device 9 will be explained in more detail with reference to FIGS. 2 and 3.

Within the housing 2 further components are arranged, some of which are shown schematically in Fig. 1. One of these components is a motor 10 that drives the lower blade 6. The motor 10 may be formed as a rotary motor and be coupled via a non-figured eccentric with the lower blade 6. Likewise, it is also possible to form the motor 10 as a linear motor. As further components, a rechargeable battery 11 and a microcontroller 12 are shown symbolically. The battery 11 provides the supply voltage for operation of the razor 1, wherein the motor 10 is the largest energy consumer. The microcontroller 12 is required in particular for the evaluation of the signals of the sensor device 9 and activation of the motor 10, which will be described in more detail below.

During operation of the razor 1, the lower blade 6 is displaced relative to the shear foil 7 in a linear oscillating movement. This movement causes hair, which penetrate through the shear foil 7 to the lower blade 6, detected by the lower blade 6 and severed in cooperation with the shear foil 7.

2 shows an enlarged detail of the razor 1 in a sectional illustration to illustrate an embodiment of the sensor device 9. In the illustrated embodiment, the sensor device 9 has a transmitter wheel 13 with an axis 14 which is rotatably mounted in a sleeve 15. The sender wheel 13 has a plurality of markings 16, which are arranged in the circumferential direction of the sender wheel 13 at regular intervals next to each other. In the region of the radius in which the markings 16 are arranged on the encoder wheel 13, a measuring transducer 17 is mounted next to the encoder wheel 13. The transducer 17 is responsive to the markings 16 and generates at a rotation of the encoder wheel 13 in the clock in which the markers 16 are moved past the transducer 17, a signal.

The detection of the markers 16 can be done in different ways, such as optically, by induction, etc. Also, the mechanical structure of the sensor device 9 can be modified in many ways. Thus, the encoder wheel 13 can be driven by another, non-figured wheel or by a ball. In addition, several differently oriented donor wheels 13 with associated measuring sensors 17 may be provided for detecting different directions of movement of the shaving head 3.

In Fig. 2, a skin surface 18 is further shown, over which the shaving head 3 of the shaver 1 is moved, d. H. Fig. 2 shows a snapshot during the implementation of a shave with the shaver 1. During shaving the shaving head 3 is pressed with light pressure against the skin surface 18 and thereby relative to the skin surface

18 moved laterally. In addition to the shaving foil 7, the transmitter wheel 13 also touches the skin surface 18 and converts the translational movement of the shaving head 3 into a rotational movement which is detected by the measuring transducer 17 and a corresponding signal is converted to it. In a rapid translational movement of the shaving head 3 relative to the skin surface 18, the encoder wheel 13 is set in a rapid rotational movement, so that the transducer 17 generates a signal at a relatively high frequency and provides at its output. With a slow translational movement of the shaving head 3, however, a slow rotation of the encoder wheel 13 is generated, so that the output signal from the transducer 17 has a relatively low frequency. The frequency of the signal generated by the transducer 17 thus represents a measure of the speed with which the shaving head 3 of the shaver 1 is moved over the skin surface 18. This speed can also be determined with the embodiment of the sensor device 9 shown in FIG.

FIG. 3 shows a further exemplary embodiment of the sensor device 9 in a representation corresponding to FIG. 2. In this exemplary embodiment, the sensor device 9 has a light source 19 and a light sensor 20. The light source 19 may be, for example, a light emitting diode. As a light sensor 20 is particularly suitable a photodiode. The light source 19 is mounted in the shaving head 3 so that it emits light toward the skin surface 18 when the shaving head 3 is moved over the skin surface 18 during a shave. The light is reflected in part on the skin surface 18, again detecting a portion of the reflected light from the light sensor 20. The light sensor 20 generates an electrical signal corresponding to the detected light, which is a measure of the speed with which the shaving head 3 is moved over the skin surface 18. The evaluation of the output from the light sensor 20 signal can be carried out in a similar manner as in an optical computer mouse.

The further processing of the signals generated by the exemplary embodiments according to FIGS. 2 and 3 will be explained in more detail with reference to FIG. 4. 4 shows a block diagram for a possible variant of a control according to the invention of the motor 10 of the razor 1. The illustration relates to an embodiment of the razor 1, in which the motor 10 is designed as a rotary motor. The illustrated blocks represent the sensor device 9, the microcontroller 12, the motor 10 and a speed sensor 21 which detects the current engine speed.

The signal output by the sensor device 9 is supplied to the microcontroller 12. Based on this signal, the microcontroller 12 determines a default value for the speed of the lower blade 6 relative to the shaving foil 7. The default value can be calculated, for example, using an algorithm implemented in the microcontroller 12 or read out from a table stored in the microcontroller 12. In this case, the default value is selected in each case so that for the determined by the sensor device 9 speeds of the shaving head 3 relative to the skin surface 18 favorable cutting conditions for the severing of the hair. During the cutting process, the hairs are each clamped briefly between the lower blade 6 and the shaving foil 7 immediately before cutting. By the movement of the shaving head 3 relative to the skin surface 18, the pinched hairs are slightly pulled out of the skin before they are severed by an interaction of the lower blade and the shaving foil. This effect is desirable and causes the hair to be cut closer to its root in the subsequent second cut, thereby allowing a very thorough shave.

However, the hair must not be pulled too far out of the skin, as this is otherwise painful for the user of the shaver 1. The pain threshold is typically around 0.4 mm, ie if the hair is pulled out of the skin by more than 0.4 mm, this is usually felt as pain. Conversely, shaving will not be particularly thorough if the hair is pulled out of the skin too little. This means that the hair should be severed relatively quickly after pinching, when the shaving head 3 is passed over the skin surface 18 at high speed. On the other hand, if the shaving head 3 is guided slowly over the skin surface 18, then a greater period of time should elapse between the pinching and severing of the hair. This can be achieved in the context of the invention in that the default value for the speed of the lower blade 6 is chosen to be greater, the faster the shaving head 3 is moved over the skin surface 18. From the default value for the speed of the lower blade 6, the Mikrocont- roller 12 determines a target value for the speed of the motor 10. The setpoint is chosen so that the speed of the lower blade 6 coincides with the default value when the engine 10 with the setpoint for the speed is rotating. Analogous to the default value for the speed of the lower blade 6 and the target value for the engine speed can be calculated by means of an algorithm or taken from a table. The thus determined setpoint of the engine speed is compared with the actual value detected by the speed sensor 21. Based on this target-actual comparison of the microcontroller 12 controls the motor 10 so that the actual value approaches the target value. In this case, the inertia of the motor 10 can be taken into account and the motor 10 can be controlled accordingly to a slightly higher speed than corresponds to the desired value.

When determining the default value for the speed of the lower blade 6, one or more parameters can be taken into account in addition to the signal of the sensor device 9. For example, it may be provided that the user on the shaver 1 can make an adjustment with respect to its skin sensitivity. This setting is then evaluated as part of the determination of the default value. It is also possible to consider the strength of the user's beard growth. The strength of the beard growth can be estimated from the current consumption of the motor 10. In addition, the particular shaving mode can be considered in which the shaver 1 is operated. For example, with a folded long-hair trimmer, a constant default value can be provided. In addition, a memory function can be provided, with the aid of which the microcontroller 12 can determine the user behavior and can adapt the default value to it. For example, a comparatively high standard value can be selected if the user usually shaves quickly or if the shaver 1 has not been used for such a long time that a strong expression of the barts is to be expected. Shaving progress during a shave can also be taken into account when determining the default value. Thus, at the beginning of the shave another default value can be selected as towards the end of the shave. In addition, when determining the default value, a minimum value and a maximum value for the speed of the lower blade 6 can be observed, which must not be exceeded or exceeded.

Furthermore, it is also possible to take into account in the control of the motor 10 that too fast control is perceived by the user as unpleasant and accordingly to limit the control speed. In an embodiment of the razor 1 in which the motor 10 is designed as a linear motor, the motor speed or the vibration amplitude of the motor 10 can be controlled in a corresponding manner, as described above for the rotational speed of a rotary motor.

Furthermore, the razor 1 can also be designed in each case so that directly a movement amount of the lower blade 6, for example, the speed or amplitude of vibration, is detected and regulated. In addition, a modification of the razor 1 is possible in each case, in which instead of a control, a pure control is performed without actual value detection.

The invention is not limited to an application in razors 1, but can also be used in other electric hair removal devices having a mechanically working hair removal device. In addition to razors 1, these can be, in particular, epilation apparatuses which detect hairs with the aid of rotating tweezers and pluck them out of the human skin. In epilators, for example, the rotational speed of the forceps or the opening and / or closing speed of the forceps can be varied depending on the speed with which the epilation device is moved across the skin.

Claims

claims:

An electric hair removal device for removing hair from the human skin, comprising a hand-held housing (2), a mechanical hair removal device (3) and a motor (10) for driving the hair removal device (3), characterized in that Sensor means (9) is provided for generating a signal which depends on the speed with which the hair removal device (3) is moved over the skin during hair removal.

2. Hair removal apparatus according to claim 1, characterized in that the sensor device (9) has at least one rotatably mounted rotary body (13).

3. A hair removal apparatus according to claim 2, characterized in that the rotary body (13) is arranged so that it is set in rotation when the hair removal device (3) is moved over the skin.

4. Hair removal device according to one of claims 2 or 3, characterized in that the sensor device (9) has a measuring transducer (17) for direct or indirect detection of the rotation of the rotary body (13).

5. hair removal apparatus according to claim 1, characterized in that the sensor device (9) has a light source (19) and a light sensor (20).

6. A hair removal apparatus according to claim 5, characterized in that the light source (19) is arranged so that it irradiates the skin when the hair removal device (3) is moved over the skin.

7. Hair removal device according to one of the preceding claims, characterized in that a control device (12) for controlling the motor (10) is provided depending on the signal of the sensor device (9).

8. A hair removal device according to claim 7, characterized in that the control device (12) has a movement amount of a component (6) of the hair removal. direction (3) to a first predetermined value, which depends on the signal of the sensor device (9) controls or controls.

9. hair removal apparatus according to claim 8, characterized in that it is the movement amount to a speed or a vibration amplitude of the component (6) of the hair removal device (3).

10. Hair removal device according to one of claims 7 to 9, characterized in that the control device (12) controls a movement amount of the motor (10) to a second predetermined value, which depends on the signal of the sensor device (9) or controls.

11. A hair removal apparatus according to claim 10, characterized in that a motor sensor (21) for providing a signal for the control device (12) is provided, which depends on the amount of movement of the motor (10).

12. Hair removal device according to one of claims 10 or 11, characterized in that it is the movement amount to a speed, a speed or a vibration amplitude of the motor (10).

13. Hair removal device according to one of claims 10 to 12, characterized in that the control device (12) determines the second predetermined value based on the first predetermined value.

14. A hair removal device according to any one of claims 7 to 13, characterized in that the control device (12) the motor (10) depending on a user setting for the skin sensitivity and / or current consumption of the motor (10) and / or a current Haarentfernungsmodus and / or from a parameter determined in the past and / or from an advance of the hair removal and / or from a minimum and / or maximum value for the amount of movement of the motor (10) or the component (6) of the hair removal device (3).

15. Hair removal device according to one of the preceding claims, characterized in that it comprises a battery (11).

16. Hair removal device according to one of the preceding claims, characterized in that it is designed as a shaver.

17. Hair removal device according to one of claims 1 to 15, characterized in that it is designed as an epilation device.

18. A method for removing hair from the human skin, wherein an electric hair removal device (1) having a hair removal device (3) driven by a motor (10) is guided over the skin, characterized in that the motor (10) depending on the speed with which the hair removal device (1) is moved across the skin is controlled.

19. The method according to claim 18, characterized in that a movement amount of a component (6) of the hair removal device (3) is controlled or controlled to a first predetermined value, which depends on the speed with which the hair removal device (1) moves over the skin becomes.

20. The method according to any one of claims 18 or 19, characterized in that a movement amount of the motor (10) is controlled or controlled to a second predetermined value, which depends on the speed with which the hair removal device (1) is moved over the skin ,