EP3946577A1

EP3946577A1 - Parameterized operating environment for irradiation

Info

Publication number: EP3946577A1
Application number: EP20718810.3A
Authority: EP
Inventors: Jürgen GERSTENMEIER
Original assignee: JK Holding GmbH
Current assignee: JK Holding GmbH
Priority date: 2019-04-03
Filing date: 2020-04-02
Publication date: 2022-02-09
Also published as: JP2022527807A; CN113795302A; CA3135909A1; CH716064A1; US20220161048A1; KR20210149119A; WO2020202064A1; MX2021012111A

Abstract

The invention relates to an apparatus (30) for irradiating the human body or parts of the human body with optical radiation. The apparatus (30) comprises a first interface (20) for transmitting data, an analysis module (22) for creating a parameterized operating environment (23) on the basis of the transmitted data, a control unit (24) for adapting device settings on the basis of the parameterized operating environment created, and an irradiation unit (26) which receives a signal (25) from the control unit (24) according to the parameterized operating environment (23) created. The invention further relates to a system, a method and a computer program product for carrying out the method.

Description

Parameterized operating environment for irradiations

The present invention relates to a device for irradiating the human body or parts of the human body with optical radiation. It also relates to a method, a computer program product for executing this method and a system, all in accordance with the preambles of the independent claims.

Technological background

Devices for irradiating the human body or parts of the human body with optical radiation are known. These are used in the medical, cosmetic and / or therapeutic area. In the area of irradiation of the skin, emitting arrangements are used whose radiation produces, for example, a photobiological effect on an irradiated person. The radiation hits a person's skin, but can penetrate deeper regions of the body depending on the specific wavelength. The effect includes, for example, a tanning of the skin, but other physiological and psychological effects also result from the radiation. Radiation comprises the spectrum of ultraviolet (UV) radiation, visible (VIS) radiation and near infrared (nIR) radiation. The UV radiation here has wavelengths in the spectrum between 100 nm and approx. 380 nm, the VIS radiation here has wavelengths in the spectrum between approx. 380 nm and approx. 780 nm, the nIR radiation here has wavelengths in the spectrum between approx. 780 nm and approx. 1400 nm. The specified spectra merge into one another. Depending on the application, the irradiation can be concentrated on a sub-spectrum of the specified spectra. For this purpose, medical-cosmetic radiation-emitting arrangements can also be dedicated to individual wavelengths, e.g. the UV radiation that is generated by 5 radiant tubes.

Devices for acting on the skin of a user are known from practice, such as those used in tanning salons, in which a person to be irradiated can lie on a cover forming a lying surface or end surface for the purpose of tanning their skin by pigmentation, with the cover being below the cover an arrangement emitting UV radiation with usually one A plurality of radiant tubes, in particular fluorescent tubes, is arranged. Usually, such tanning devices also have a further structural unit with further radiant tubes and a second cover, which can be swiveled together on the person to be irradiated, so that the person can be tanned from two sides. The problem here is that the user can enter any operating parameters on the device, but these are not tailored to the user and can therefore lead to disadvantages.

It is an object of the invention to provide a device for irradiating the human body or parts of the human body with ultraviolet and / or optical radiation with which a user can set the device to his needs in advance or regardless of location and this can be optimized Provides irradiation result.

Presentation of the invention

According to the invention, this object is achieved by a device with the features of the independent claim.

According to one aspect of the invention, a device for irradiating the human body or parts of the human body with optical radiation is created, comprising a first interface for transmitting data, an analysis module for creating a parameterized operating environment as a function of the transmitted data, a control unit for adaptation of device settings as a function of the created parameterized operating environment, and an irradiation unit which receives a signal from the control unit in accordance with the created parameterized operating environment.

This advantageously creates the possibility of taking into account user-specific wishes and settings and of offering optimal irradiation. The user can, for example, make presettings for certain operating parameters in advance. It is particularly advantageous that the parameterized operating environment is determined and implemented fully automatically by the device. The parameterized operating environment includes an irradiation plan, also referred to as a tanning plan, which can be applied individually to a user can. A user therefore has more time for the application or irradiation, since the parameter settings on the device at the start of the application are not necessary. Device settings and, for example, an optimal tanning time can be determined on the basis of a stored history and imported through an application. Of course, the user has the option of making readjustments or other settings.

The first interface preferably enables a Bluetooth connection with a user device. This makes the device easy to connect to the user equipment, e.g. Connect a smartphone, tablet or user computer to transfer user data such as a profile or preferred settings. Depending on the location of the user, i.e. the user is in the immediate vicinity of the user device on a device, can start the device immediately and begin reading in user data and creating a parameterized operating environment. The device starts fully automatically, so to speak. The user does not have to make any further settings on the device. The first interface can also be connected to a user device in a wired manner, so that a clear assignment and immediate connection to the device can be established. The device is also referred to as an arrangement, tanning device, or tanning device for short, and preferably has a connection on the outside, i.e. Interface, for a user device. After connecting the user device, the user data are transmitted or read in and the user device can be supplied with energy at the same connection so that it is charged while the device is being used.

In a further embodiment it is provided that the first interface enables near field communication (NFC for short). This is a transmission standard based on RFID technology for the contactless exchange of data via electromagnetic induction using loosely coupled coils over short distances of a few centimeters. RFID (radio-frequency identification) describes a technology for transmitter-receiver systems for the automatic and contactless identification and localization of objects with the help of electromagnetic waves.

In a further advantageous embodiment it is provided that the device has a second interface, which is designed as a network interface. About these second interface, data can be transmitted or exchanged with a usage database. The usage database can be implemented as a relational or semi-structured database or as a database system.

The data in the usage database preferably include values such as time of use, frequency of use, skin type and device settings. These values can relate to a user and can be called up accordingly. The values can also relate to many users and values, e.g. Mean or reference values can be determined for other users or user groups. In turn, optimized operating environments can be determined and applied from historical data from other users. By analyzing the profile of a user, the skin type of the user can be determined, which flows into the parameterized operating environment and creates optimal values. If, for example, the user provides a facial image or a photo of an arm or a hand, the analysis module can determine the skin type directly and take it into account accordingly for an optimal operating environment.

It is particularly advantageous to store the transmitted data anonymously in the usage database. This guarantees privacy and data protection.

The analysis module creates the parameterized operating environment as a function of the transmitted data and / or the data provided. The analysis can be carried out on a stochastic basis, but comparative analyzes are also possible. The analysis results flow fully or partially into the parameterized operating environment.

If the analysis module receives data from the usage database, these data can be used as a basis for the parameterized operating environment and thus form a solid basis for an optimal operating environment. The analysis module can preferably determine the skin type of a user, which is relevant for the parameterized operating environment. A tanning prognosis can also be determined which can be given to the user. Corresponding readjustments are thus possible. In a further refinement, it is provided that the analysis module creates the parameterized operating environment as a function of the transmitted data relating to light therapy applications. The control unit then controls the appropriate application routines for relaxation or biostimulation. The positive effects of bio-stimulating phototherapy are very much appreciated by users. Such a device for biostimulating phototherapy, in particular for supplementary biostimulating phototherapy in connection with a therapy device, and embodiments are in the Swiss patent application by the same applicant entitled “Device for biostimulating phototherapy” with the date of deposit April 3, 2019, reference P100429CH and application number. described.

According to a further preferred embodiment, the analysis module is arranged outside the device. This means that computationally intensive tasks can be outsourced and carried out at any location. Due to the networking, the results can be used and fed in by any device.

The parameterized operating environment preferably includes an irradiation plan. This enables the individualized irradiation of a user, e.g. with defined body regions, different intensities and wavelengths as well as times. There are often multiple devices or tanners in tanning salons. The parameterized operating environment can also expediently be used to assign corresponding devices to the respective users. In this way, even use and utilization of the devices can be achieved. The energy load can also be better distributed as a result.

According to a particularly preferred embodiment, it is provided that the control unit can adapt the parameterized operating environment in

Dependency on a user's data. This allows the individual needs of a user to be addressed. The user can specify his desired irradiation, but this is then precisely tailored to the user on the device so that undesirable side effects cannot occur.

According to a further preferred embodiment, it is provided that the control unit can adapt the parameterized operating environment in Dependency on data from a usage database. The usage database not only stores the values of individual users, but also reference values that are advantageous for certain skin types or user groups. When a user goes to different studios for treatment or tanning, the values from the usage database are particularly useful and can accordingly be read into the respective device at a wide variety of locations. If a user does not have his user device with him, for example, the user can also be identified by a voice command, for example an individual code that is linked to data in the usage database, via a microphone on the device. The device is equipped with a voice recognition device and voice control. Such voice control and embodiments are described in the Swiss patent application by the same applicant with the title “Device for acting on at least parts of a body” with the filing date April 3, 2019, reference P100446CH and application number. described.

In a further embodiment of the voice control it is provided, due to the networking, to enter voice commands and, for example, to receive emails or messages, weather forecasts or the like during the application. Have information read out online or even make phone calls. The device also has one or more loudspeakers. A user can use the microphone, i. use the voice control, also before or after an application. It is also possible for an operator to use the voice control for communication, maintenance work, instructions, information queries or the like. to use.

One aspect of the present invention relates to a method for operating a device for irradiating the human body or parts of the human body with optical radiation.

Another aspect of the present invention relates to a computer program product for executing a method according to the invention on a computer or computer for controlling a device for irradiating the human body or parts of the human body with optical radiation.

Yet another aspect of the present invention relates to a system or components for creating a parameterized operating environment for irradiating the human body or parts of the human body optical radiation. The system comprises an interface for transmitting first data of a user, a usage database that receives, stores or provides second data, an analysis module for creating a parameterized operating environment as a function of the transmitted first data and provided second data, a control unit for adapting device settings as a function the created parameterized operating environment, and an irradiation unit which receives a signal according to the created parameterized operating environment from the control unit.

The usage database can be provided locally in a tanning salon, or studio for short. The usage database is preferably designed as a cloud service. This enables easy storage, maintenance and backup of data and allows time-independent access by users.

According to a particularly preferred embodiment, it is provided to connect or couple several devices to the usage database via a connection. This allows data from a wide variety of devices and users to be merged, which, through evaluation and analysis, lead to optimized operating environments.

The analysis module expediently outputs user-specific suggestions for the parameterized operating environment with an irradiation plan. These suggestions can be stored in the usage database and accessed by a user. Alternatively, the suggestions are transferred to a user device, can be edited there and saved in the profile or the usage database.

A user device preferably accesses the usage database via an Internet connection. For data security reasons, an encrypted connection, e.g. via https, to be preferred. If the usage database is local, e.g. is located in a studio, a user device can also access them locally.

According to one embodiment, the user device receives usage database data from the usage database, which can be correspondingly individualized by the user. This data can then be used to create a parameterized operating environment. The user can also use the user device Provide feedback that will be taken into account in the future or incorporated into further analyzes.

Once a user has created and saved a profile, e.g. with the desired duration, intensity, temperature, music, etc., the stored profile can be transferred to a device in order to make the optimal operating environment and device settings. A saved history can also be used for an optimal tanning time. In a preferred embodiment, the desired data as well as the operating environment and device settings are stored in the usage database. Determining an optimal operating environment enables intelligent tanning, also known as smart tanning.

The profile of a user can preferably be used in an application, e.g. in an app on a user's smartphone. Sensitive user data is then not stored in the device or in the studio, which requires complex security measures, but on the user's device.

The recording of the course and / or measurement of an exposure duration and display of a maximum increases user safety. The values can be stored in the usage database and / or user device and made available for future applications. The display can take place on the device or via the application mentioned.

For a person skilled in the art, it goes without saying that all of the described embodiments can be implemented in an embodiment of the present invention according to the invention, provided they are not explicitly mutually exclusive.

The present invention will now be explained in more detail below on the basis of specific exemplary embodiments and figures, but without being restricted to these.

By studying these particular embodiments and figures, further advantageous embodiments of the present invention can result for a person skilled in the art. Character description

Exemplary embodiments of the invention are described with the aid of the following figures, the same reference symbols denoting the same or similar parts.

1: shows schematically an arrangement with a plurality of devices, a usage database and a user device.

2: shows schematically an arrangement of a device according to the invention, coupled with a usage database and a user device.

3: shows schematically an arrangement of a device according to the invention, coupled with a usage database and a connection from a user device to the usage database.

4: shows a schematic sequence of steps.

Implementation of the invention

1 shows a system 1 with several components. A device 30 is designed for irradiating the human body or parts of the human body with optical radiation. The device 30 is equipped with an interface 20 via which a first connection 2 to a user device 10 can be established. The user device 10, which can be a smartphone, tablet or other application-executing device, is connected to the device 30 via the first connection 2 in a wired manner via the interface 20 and can use it to exchange data. The device 30 is connected to a usage database 40 via a second connection 4. The usage database 40 is connected to further devices 50, 60, 70, 80 via a third connection 6. Still other devices can be connected to the usage database 40. Each device 30, 50, 60, 70, 80 can be the same or a different irradiation or tanning device. The data transmission via the second connection 4 and the third connection 6 is preferably carried out via LAN or WLAN. FIG. 2 shows a device 30 which is connected to the user device 10 wirelessly, for example via Bluetooth®, WLAN (Wireless Local Area Network), or near field communication. The user device 10 has a display 12 for displaying information and an input unit 14. Display 12 and input unit 14 can be fused and combined into one unit. A user records his profile or desired settings on the display 12, which are then transmitted to the interface 20, also referred to below as the first interface 20.

The device 30 further comprises an analysis module 22 for creating a parameterized operating environment 23, a control unit 24, and an irradiation unit 26. The analysis module 22 comprises a computing unit for processing data. The device 30 is equipped with a second interface 28 which is connected to the analysis module 22. The second interface 28 is connected via a second connection 4 to the usage database 40 ', which in the example is designed as a cloud service. The analysis module 22 is connected to the control unit 24. The control unit 24 adapts the device settings accordingly as a function of the parameterized operating environment created. A signal 25 is sent from the control unit 24 to the irradiation unit 26 in accordance with the parameterized operating environment created. The parameterized operating environment is determined by the analysis module 22 as a function of the transmitted data from the user device 10 and / or the usage database 40 '. The control unit 24 then undertakes the adaptation or settings of the device settings. A wide variety of values are incorporated into the determination of the optimal operating environment. On the one hand, there are specifications from the user, e.g. are given by a profile, and on the other hand, values from the usage database 40 'are used to determine the optimal operating environment. In general, the parameterized operating environment contributes to the comfort of a user, since values such as preferred intensity, temperature, but also optimal exposure duration can be set. If there are several tanning devices, the utilization and use of individual devices can be better controlled through the parameterized operating environment.

The irradiation unit 26, which emits actinic radiation, for example, is controlled by the control unit 24 in accordance with the parameterized operating environment 23 created by a signal 25. This has the advantage that certain body regions with defined intensity and duration can be assigned to achieve an optimal result.

3 shows the system 1 in a further preferred embodiment. The device 30 is designed for irradiating the human body with medical cosmetic radiation. The first interface 20 is here connected to the user device 10 via the first connection 2 by WLAN (Wireless Local Area Network). The interface 20 particularly preferably comprises a module with a microchip with 2.4 GHz 802.1 1 b / g / n WLAN capacity. Other types of wireless connections, but also wired ones, are definitely possible. The user device 10 transmits data that is stored in the user device 10. The device 30 receives these data through the first interface 20 and forwards them to the analysis module 22 for further processing.

The device 30 is connected to a network 90, such as the Internet, via the second connection 4. The network 90 can be implemented as a LAN (local area network), WAN (wide-area network), WLAN (wireless local area network), or a proprietary network. The user device 10 is connected to the network 90 via a fourth connection 8. The usage database 40 is connected to the network 90 via the third connection 6. This allows data of a user from the user device 10 to be stored directly on the usage database 40. The user can also obtain information from the usage database 40. These can include evaluation, preferably free dates or periods, but also advertising. This is particularly effective when the usage database 40 functions as a clould service, as described in FIG. 2. The usage database 40 'is then not a pure database, but can be provided with modules for analyzing the data, which generate added value.

4 shows a schematic sequence of steps 100 for operating a device 30 for irradiating the human body or parts of the human body with optical radiation.

In step 102, data of a user are transmitted via the interface 20. The interface 20 can be designed for sending and receiving, that is, bidirectional. In a further embodiment, the interface 20 is only provided for receiving data. This unidirectional connection only enables one Reading data into the device 30. In combination with further data, for example from the described usage database 40, 40 ', an optimal operating environment can be created.

In step 104, a parameterized operating environment 23 is created as a function of the transmitted or received data. Since the transmitted or received data contain user-specific values and information, they can be analyzed, compared with the usage database 40, 40 'or correlated in order to provide an optimal operating environment 23 for the user. This is done by the analysis module 22, which is preferably located in the device 30.

In step 106, device settings are adapted as a function of the parameterized operating environment 23 that has been created. Thus, individual wishes and preferences of a user, but also system and device-relevant conditions, can be taken into account. The control unit 24 makes the adjustments.

In step 108, the device settings are used for irradiation. In one embodiment, the irradiation unit 26 receives a signal 25 from the control unit 24 in accordance with the parameterized operating environment 23 created. This enables optimal irradiation in accordance with the parameterized operating environment 23 created.

The present invention provides a device, a system, a method and a computer program product for operating the method, which eliminates at least one disadvantage of the known.

Claims

A device (30) for irradiating the human body or parts of the human body with optical radiation, comprising: a. a first interface (20) for transferring data; b. an analysis module (22) for creating a parameterized operating environment (23) as a function of the transmitted data; c. a control unit (24) for adapting device settings as a function of the parameterized operating environment (23) created; and d. an irradiation unit (26) which receives a signal (25) from the control unit (24) according to the parameterized operating environment (23) created.

2. Device according to claim 1, wherein the first interface (20) enables a Bluetooth connection with a user device (10).

3. The device according to claim 1, wherein the first interface (20) is connected to a user device (10) by cable.

4. Device according to one of the preceding claims, further comprising a second interface (28), in particular a network interface, for transmitting data with a usage database (40, 40 ').

5. The device according to claim 4, wherein the analysis module (22) data of the

Usage database (40, 40 ') and this of the parameterized

Operating environment (23).

6. Device according to one of the preceding claims, wherein the analysis module (22) is arranged outside the device (30).

7. Device according to one of the preceding claims, wherein the parameterized operating environment (23) comprises an irradiation plan.

8. Device according to one of the preceding claims, wherein the

Control unit (24) adjusts the parameterized operating environment (23) as a function of data from a user.

9. Device according to one of the preceding claims, wherein the

Control unit (24) adjusts the parameterized operating environment (23) depending on data from a usage database (40, 40 ').

10. A method for operating a device for irradiating the human body or parts of the human body with optical radiation, in particular for operating a device according to one of claims 1 to 9, comprising the steps: a. Transmitting data of a user via an interface (20); b. Creation of a parameterized operating environment (23) depending on the transmitted data; c. Adaptation of device settings as a function of the parameterized operating environment created (23); and d. Use of the device settings for irradiation according to the parameterized operating environment created (23).

1 1. Method according to claim 10, wherein the transmitted data comprises one or more of the following information: default settings, a profile, a partial profile, a history of previous irradiations.

12. The method according to any one of claims 10 and 1 1, further comprising transmitting data from a usage database (40, 40 '), wherein the data

preferably include one or more of the following values:

Time of use, frequency of use, skin type, and device settings.

13. The method of claim 12, wherein the transferring of data from the

Usage database (40, 40 ') includes historical data of other users.

14. The method according to any one of claims 10 to 13, wherein the creation of the parameterized operating environment (23) comprises an analysis of the profile of the user and thereby the skin type of the user is determined.

15. Computer program product for executing a method according to one of claims 10 to 14.

16. System (1) for creating a parameterized operating environment (23) for irradiating the human body or parts of the human body with optical radiation, comprising: a. an interface (20) for transmitting first data of a user; b. a usage database (40, 40 ') that provides second data; c. an analysis module (22) for creating a parameterized operating environment (23) as a function of the transmitted first data and provided second data; d. a control unit (24) for adapting device settings as a function of the parameterized operating environment (23) created; and e. an irradiation unit (26) which receives a signal (25) from the control unit (24) according to the parameterized operating environment (23) created.

17. System (1) according to claim 16, wherein the usage database (40, 40 ') contains second data with one or more of the following values: duration of use, frequency of use, skin type and device settings.

18. System (1) according to one of claims 16 and 17, wherein the transmitted first data is stored anonymously in the usage database (40, 40 ').

19. System (1) according to one of claims 16 to 18, wherein the usage database (40) is designed as a cloud service (40 ').

20. System (1) according to one of claims 16 to 19, wherein several devices (30, 50, 60, 70, 80) are connected to the usage database (40, 40 ') via a connection (4, 6).

21st System (1) according to one of Claims 16 to 20, the analysis module (22) issuing user-specific suggestions for the parameterized operating environment (23) with an irradiation plan.

22. System (1) according to one of claims 16 to 21, wherein a user device (10) accesses the usage database (40, 40 ') via a network connection (8).

23. System (1) according to claim 22, wherein the user device (10) receives usage database data from the usage database (40, 40 '), which after individualization to create the parameterised operating environment (23) in one or more devices (30, 50, 60 , 70, 80) leads.