ES1165735U - Ultraviolet radiation indicating device (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Device (1) ultraviolet radiation indicator comprising ultraviolet radiation sensor means (2) for detecting a level of ultraviolet radiation, comprising means for visual representation (3) of the level of ultraviolet radiation detected, characterized in that it also comprises wireless communication means (4) to transmit the level of ultraviolet radiation detected. (Machine-translation by Google Translate, not legally binding)

Description

Ultraviolet radiation indicator device

5 Technical sector of the invention The ultraviolet radiation indicating device of the present invention is one of those that allows to know in detail the level of ultraviolet radiation of the local sun to be able to determine the sun exposure time and avoid burns in open spaces such as beaches or ski resorts

Background of the Invention We are all exposed to UV radiation from the sun and from numerous artificial sources used in industry, commerce and during leisure time. The sun emits light, heat and UV radiation. The UV region covers the wavelength range of 100 to 400 nm and is

15 divides into the following three bands: UVA (315-400 nm.), UVB (280-315 nm) and UVC (100-280 nm). When sunlight passes through the atmosphere, ozone, water vapor, oxygen and carbon dioxide absorb all UVC radiation and approximately 90% of UVB radiation. The atmosphere absorbs UVA radiation to a lesser extent. Consequently, the UV radiation that reaches the Earth's surface is mostly composed of rays

20 UVA, with a small part of UVB rays.

Small doses of UV radiation are beneficial for humans and essential for the production of vitamin D. In humans, prolonged exposure to solar UV radiation can produce acute and chronic effects on the health of the skin, eyes and skin. system

25 immune. Sunburn and tanning are the best known acute effects of excessive exposure to UV radiation; In the long term, premature aging of the skin occurs as a result of the degeneration of cells, fibrous tissue and blood vessels induced by UV radiation. UV radiation can also produce inflammatory eye reactions, such as actinic keratitis.

30 The UV index - also known as the global solar UV index or IUV - is a measure of the intensity of solar UV radiation on the earth's surface. The index is expressed as a value greater than zero, and the higher, the greater the likelihood of skin and eye lesions and the less time it takes to produce those lesions. The UV index is calculated from the

35 radiated power in the spectrum of the weighted ultraviolet band with a curve known as the erythemal action spectrum, corresponding to the effect that each length of

wave on the skin, the result being integrated into the entire spectrum. This weighted value obtained would typically be 250mW / m2 for the midday sun of an average summer day, so that value is divided by a value of 25 mW / m2, obtaining a scale value between 0 and 11+, known as the UV index, representative of the effect that ultraviolet solar radiation can have on a person's skin.

Ultraviolet radiation indicator devices are known that allow to display an indicator based on the detected UV index, such as the device described in document ES2294962 that allows instant and permanent measurement of ultraviolet radiation with visualization on a palette, sign or panel. However, since the UV index can vary, for example due to the effect of the passage of clouds or the position of the sun throughout the day that modify the level of ultraviolet radiation that reaches the earth's surface, these devices require that the user has We continually observe the UV index to control these variations and avoid burning. Even so, it is very difficult for the user to determine the maximum recommended exposure time to synthesize vitamin D without the risk of burns. Tables are known that allow to calculate approximately the maximum exposure time based on a UV index, however these tables do not consider the possible variations that the UV index may suffer, so it is difficult to calculate the ideal exposure time, being usually very conservative and greatly limiting the recommended exposure time.

It is therefore an objective of the present invention to disclose a device that allows to reliably know the level of ultraviolet radiation from the sun in a location without requiring the user to continually observe the level of instantaneous ultraviolet radiation.

It is also another objective of the present invention to facilitate the calculation of the maximum recommended exposure time taking into account changes in the level of ultraviolet radiation and the UV index during exposure.

Explanation of the invention The ultraviolet radiation indicating device of the present invention is one that includes ultraviolet radiation sensing means for detecting a level of ultraviolet radiation, from which the UV index can be calculated as an indicator of radiation intensity ultraviolet from the sun on the earth's surface.

The indicating device also includes means of visual representation of the level of ultraviolet radiation detected, which allow users close to the device to know the local UV index by simply observing the device, without requiring additional devices, thus being able to determine the risk of sun exposure . The device is specially designed to be installed in a location where you want to know the level of ultraviolet radiation from the sun, for example, a beach or a ski resort, to avoid burns from excessive exposure. This level of ultraviolet radiation detected can be both the intensity value, usually measured in W / m2, which is the radiated power in the spectrum of the ultraviolet band weighted with the erythemic action spectrum curve, integrated throughout the spectrum, as its corresponding UV index, also known as the global solar UV index or IUV.

In essence, the indicating device is characterized in that it also comprises wireless communication means for transmitting the level of detected ultraviolet radiation, so that the information corresponding to the level of detected ultraviolet radiation is available and thus, the user does not have to be constantly observing the device to know the possible local variations of the local UV index corresponding to the level of ultraviolet radiation detected. In this way, users close to the device can configure portable devices, such as their mobile phones, to monitor said value of the local UV index corresponding to the level of ultraviolet radiation detected and thus establish warnings and alarms to control the dose of ultraviolet radiation received to avoid burns, as well as being able to determine the most recommended protection factor, being able to additionally observe the level of ultraviolet radiation in the means of visual representation.

It is disclosed that the means of visual representation of the level of ultraviolet radiation comprise a rod that protrudes from the device depending on the level of ultraviolet radiation detected to indicate the level of ultraviolet radiation detected, allowing users to correctly visualize the index distance UV even if they are in a highly lit environment, such as a beach or a ski resort. It is envisaged that the device will have a single rod, which will stand out according to the UV index, although it also contemplates the existence of multiple rods with different colors, so that depending on the UV index one or the other is activated.

Preferably, the device has a single rod provided with a scale, so that as the rod protrudes from the device, in the visible section of the rod it is -410

display a higher value of the scale.

It is disclosed that the stem scale is a color scale corresponding to the colors of the UV indices published by the World Health Organization for the levels of ultraviolet radiation to be detected.

It is disclosed that the color scale has at least five colors, the five colors published by the World Health Organization on a simplified scale in which the green color corresponds to UV indexes 1 and 2, the yellow color corresponds to UV indexes 3 to 5, the orange color corresponds to UV indexes 6 to 7, the red color corresponds to indexes 8 to 10 and from index 11 the violet color would correspond.

For a more detailed visualization, it is expected that the color scale may have eleven colors, corresponding to those recommended by the World Health Organization, with the hexadecimal color # 4eb400 at the UV index 1, the hexadecimal color # a0ce00 at the UV index 2 , hexadecimal color # f7e400 at UV index 3, hexadecimal color # f8b600 at UV index 4, hexadecimal color # f88700 at UV index 5, hexadecimal color, hexadecimal color # f85900 at UV index 6, hexadecimal color # e82c0e at UV index 7, the hexadecimal color # d8001d at UV index 8, the hexadecimal color # ff0099 at UV index 9, the hexadecimal color # b54cff at UV index 10 and the hexadecimal color # 998cff at UV index 11 and following.

It is also known that the device comprises pushing means connected to the rod to exert a push on the rod proportional to the level of ultraviolet radiation detected, the push on the rod corresponding to the detected UV index, so that the higher the index UV detected, the greater the length of the stem protruding from the device. These thrust means can for example a pneumatic piston

or a rack and pinion set. Naturally, it is also envisioned that other mechanisms, such as handles and elastic means, may be used to drive the rod.

It is disclosed that the rod protrudes superiorly from the device, so that it is visible at a greater distance

It is disclosed that the sensing means are arranged at the end of the rod, making the sensing means located at a point where other components of the device do not shade it, since in this case the reading would be falsified and could be communicated. A wrong UV reading and index.

It is disclosed that the wireless communication means comprise an antenna integrated in the stem, advantageously achieving that the antenna is arranged in an area of the device with high visibility.

It is disclosed that the wireless communication means are adapted to transmit the level of ultraviolet radiation detected by diffusion to nearby devices, for example by means of a point-to-point connection such as establishing a network connection between the different nearby devices. The wireless media can be a bluetooth interface or a wireless local area network interface, also known as WLAN, so that users can connect via their mobile phone. Once the connection is established, it is envisaged that by means of an application installed in the mobile phone the level of ultraviolet radiation detected can be monitored, which can be both the value of the intensity measured in W / m2 and its corresponding UV index. Naturally, the device is also expected to host a web server, so that, after establishing a connection, a web page accessible by the mobile phone can be opened to monitor the level of detected ultraviolet radiation, thus spreading the level of detected ultraviolet radiation , presenting it to the user through the mobile phone without needing to download a new application. Advantageously, this service can also integrate advertising and allow users to access other subscription content such as music. It is also envisaged that the means of communication of the device may allow Internet access to the connected mobile phones or a part of their contents, acting as an access point.

It is also known that the wireless communication means are adapted to transmit the level of ultraviolet radiation detected to a remote server, so that a history of the level of local radiation detected in a server can be stored and in addition to other users of the level of instantaneous local radiation at the location of the device by said server.

It is known that the device comprises autonomous power supplies provided with a photovoltaic panel, so that the device can be installed in locations where there is no connection to the power grid.

Brief description of the drawings To complement the description that is being made and in order to facilitate the understanding of the features of the invention, the present specification is attached

descriptive a set of drawings in which, for illustrative and non-limiting purposes, represented the following:

Fig. 1a shows the device of the present invention indicating a radiation level low ultraviolet; Fig. 1b shows the device of Fig. 1a indicating a level of ultraviolet radiation intermediate; Fig. 1c shows the device of Fig. 1a indicating a high level of ultraviolet radiation; Fig. 2 shows a sectional view of the device of Fig. 1b; Y Fig. 3 shows an installation with a plurality of devices.

Detailed description of the drawings Figs. 1a to 1c present the device 1 ultraviolet radiation indicator of the present invention in which different levels of ultraviolet radiation are detected.

The device with a very low or zero ultraviolet radiation level is presented in Fig. 1a. As can be seen, the device 1 comprises radiation sensing means 2 ultraviolet to detect a level of ultraviolet radiation, and a means of representation visual 3 of the level of ultraviolet radiation detected, in the form of stem 5 protruding from the device 1 depending on the level of ultraviolet radiation detected to indicate the level of ultraviolet radiation detected.

Specifically, the sensor means 2 detect the power received by the sun by means of a ultraviolet spectrum radiation sensor and from this power calculate the UV index in a known way by using a curve of erythemic action in the spectrum ultraviolet, obtaining a scale value usually between 0 and 11. It is expected that the scale may reach higher values, however, this situation is very unlikely.

From the value of the calculated UV index, connected thrust means 7 are activated to the rod 5 to exert a thrust on the rod 5 proportional to the level of radiation ultraviolet detected, so that the stem 5 which is provided with a scale 6 of colors corresponding to the colors indicative of the UV index, it protrudes until the section is shown corresponding to the scale value corresponding to the value of the calculated UV index. It is expected that the scale 6 of the stem 5 begins at level 1 of the UV indica, thus corresponding the level 0 of the UV index to the hidden rod 5, as illustrated in Fig. 1a, level 1 being corresponding to the most extreme stem section, level 2 the next and so on

up to level 11. For higher levels, the rod is expected to keep showing up to level 11. Naturally, the rod 5 can protrude continuously, based on the calculated ultraviolet radiation level, in W / m2, as a discreetly, depending on the whole number of the calculated UV index. Therefore, it is envisaged that the color scale 6 of the stem 5 of the device 1 has at least the five colors recommended by the World Health Organization in its simplified scale, although these colors can be increased to the eleven recommended by the World Health Organization. Health in its detailed scale. It is further provided that the device 1 has a body 12 from which the rod 5 protrudes superiorly depending on the level of ultraviolet radiation detected, corresponding Fig. 1a to a situation in which the level of ultraviolet radiation detected is very low or zero , for example, at night, in which the rod 5 is completely inserted in the body 12, Fig. 1b, a situation in which the level of ultraviolet radiation detected is medium, for example in the morning or on a very cloudy day , in which the stem 5 is partially inserted in the body 12, the visible color scale 6 corresponding to the corresponding UV level. Fig. 1c corresponds to a situation in which the level of ultraviolet radiation detected is high. The rod 5 is actuated by pushing means 7 controlled by control means 15 that receive the reading of the sensor means 2 and actuate the pushing means 7 as a function of the level indicated by the sensor means 2. Said pushing means 7 they can be for example a pinion and rack set or a pneumatic piston 16. These components are arranged inside the body 12 of the device 1 which serves to contain and protect both the pushing means 7 of the rod and other components of the device 1 of the outside, for example, of inclement weather. As can be seen, the sensor means 2 are advantageously arranged at the end of the rod 5 so that they are always exposed to sunlight.

The device 1 further comprises autonomous power supply means 10 provided with one or more photovoltaic panels 11 which allow the device 1 to be autonomous and can be installed in locations where there are no electrical outlets. Optionally, the supply means 10 can have a battery 18 in which to store the excess energy produced. However, since it is expected that the device 1 is only operative in sunny hours it is possible to dispense with the battery, so that the device 1 is only powered when there is sunshine. In this case, it is envisaged that the pushing means 7 are adapted to return the rod 5 to its initial resting position when it stops feeding, for example by effect of the weight of the rod 5.

As can be seen, the body 12 will preferably have a cylindrical shape, to be able to be installed in an outer space as a pole, from which the rod 5 protrudes superiorly to indicate the level of ultraviolet radiation, said body 12 resting on a foot 13 It will be fixed to the ground. In said body 12 it is envisioned that an informative poster 14 of the operation of the device 1 can be displayed, explaining both the color scale and the recommended sun protection recommendations.

Advantageously, in addition to the visual representation means 3, the device 1 also comprises wireless communication means 4 that allow the level of ultraviolet radiation detected to be transmitted, this being the value in W / m2 as the calculated UV index, the means being of communication 4 adapted to transmit the level of ultraviolet radiation detected by diffusion to nearby devices. To achieve maximum range, as can be seen in Fig. 2, the communication means 4 comprise an antenna 8 integrated in the rod 5, which allows it to be placed in a high location, thus maximizing the range of the antenna 8. It is envisaged that said communication means 4 can be for example a bluetooth or wifi interface. In Fig. 2 it is also observed that the rod 5 is driven by a pneumatic piston 16 provided with a piston 17 connected to the rod 5 and controlled by the control means 15 connected to both the sensor means 2 and the feeding means 10 To simplify the scheme in Fig. 2 the connections between elements have not been detailed, which will be evident to an expert.

By means of the communication means 4, an apparatus, such as a mobile telephone, after connecting to the device 1 will periodically receive data corresponding to the level of ultraviolet radiation, for example its value in W / m2 or its corresponding UV index, with which You can calculate the user's solar exposure, automatically considering variations in the level of ultraviolet radiation and thus continuously adjusting the sun exposure time so that it is optimal. In this way, the mobile phone can notify the user after exceeding the recommended sun exposure time. This calculation can be done by an application previously installed on the mobile phone or the device 1 can offer the possibility of downloading it. The device 1 can also have a web interface to prevent the device 9 from having to download additional applications. It is envisaged that the data corresponding to the level of ultraviolet radiation will be received in the devices 9 by means of broadcast packets (for example in TCP or UDP packets) or can be sent independently to each device 9 corresponding to TCP requests. It is also provided that the devices 9 are the ones that make the request to update the data corresponding to the level of ultraviolet radiation, for example by means of a REST API to a web server.

As presented in Fig. 3, it is envisioned that different devices 1 can be installed to cover a surface, taking into account the maximum range R of the communication means 4, so that, even if a user moves from the area covered by a device 1 to an area covered by another device 1 can continue to monitor the level of local ultraviolet radiation, obtaining the data corresponding to the level of ultraviolet radiation of the nearest device 1, for example, the one with the highest signal strength. This can happen for example in a ski resort, where the user travels a great distance skiing and can cross areas covered by different devices 1.

10 It is also provided that the wireless communication means 4 are adapted to transmit the level of detected ultraviolet radiation to a remote server, so that the exact level of ultraviolet radiation at the location of the device 1 can be communicated to a remote server. In this way, a historical and detailed evolution of ultraviolet radiation levels in the locations of each location is achieved in the remote server

15 device 1.

Claims (9)

1. Ultraviolet radiation indicator device (1) comprising ultraviolet radiation sensor means (2) for detecting a level of ultraviolet radiation, 5 comprising visual representation means (3) of the level of detected ultraviolet radiation characterized in that it further comprises wireless communication means (4) for transmitting the level of detected ultraviolet radiation.

Device (1) according to the preceding claim, characterized in that the means of visual representation (3) of the level of ultraviolet radiation comprise a rod (5) protruding from the device as a function of the level of ultraviolet radiation detected to indicate the level of ultraviolet radiation detected.

Device (1) according to the preceding claim, characterized in that it comprises pushing means (7) connected to the rod (5) for exerting a push on the rod proportional to the level of ultraviolet radiation detected.

Device (1) according to any one of claims 2 to 3, characterized in that the rod (5) is provided with a scale (6). 5. Device (1) according to any one of claims 3 to 4, characterized in that the scale (6) is a color scale. Device according to the preceding claim, characterized in that the scale (6) of colors has at least five colors. 7. Device (1) according to the preceding claim, characterized in that the scale (6) of Colors has eleven colors. 30 Device (1) according to any one of claims 2 to 7, characterized in that the rod (5) protrudes superiorly from the device. 9. Device (1) according to any one of claims 2 to 8, characterized in that the sensor means (2) are arranged at the end of the rod (5). Device (1) according to any one of claims 2 to 9, characterized in that the wireless communication means (4) comprise an antenna (8) and the antenna is integrated in the rod (5). Device (1) according to any one of the preceding claims, characterized in that the wireless communication means (4) are adapted to transmit the level of ultraviolet radiation detected by diffusion to nearby devices (9). 12. Device (1) according to any one of the preceding claims, characterized in that the wireless communication means (4) are adapted to transmit the level of ultraviolet radiation detected to a remote server. A device (1) according to any one of the preceding claims, characterized in that it comprises autonomous feeding means (10) provided with a photovoltaic plate (11). DRAWINGS 2 2 3 6 33 11 10 14 141 1 1 12 13 13  Fig. 1a Fig. 1b Fig. 1c   2  Fig. 2