NL2021710B1 - Lighting system for applying electromagnetic radiation in a stable for diurnal animals, stable provided with it and method therefor - Google Patents

Abstract

The invention relates to a lighting system for applying electromagnetic radiation in a barn for diurnal animals, barn provided thereof and method thereof. The lighting system comprises: - at least one light source provided with LED chips arranged for applying electromagnetic radiation; - a controller operatively connected to the light source, arranged for controlling the at least one light source, the controller being arranged for applying a day pattern of electromagnetic radiation, the day pattern being composed of wavelengths located in the ranges of UV and visible light , and wherein the wavelength assembly in the daytime pattern varies in a time period of at least one day.

Description

Lighting system for applying electromagnetic radiation in a stable for diurnal animals, stable provided with it and method thereof

The invention relates to a lighting system for applying electromagnetic radiation in a stable. In particular, the stable is adapted for diurnal animals, or so-called day-active animals, which are particularly active during the day, such as poultry, including in particular chickens, ducks, geese and turkeys, as well as other animals.

Stables are known from practice for, for example, chickens. Such chicken stables use a lighting system. In practice it is further known that light influences the livestock. For example, it is possible to stimulate the growth of the animals and to promote the laying of eggs with the help of (visible) light and light variation. Nowadays, an LED application is often used for this. In addition, it is known that by omitting certain wavelengths from the visible light, some bacteria develop less quickly.

US 2011/0101883 A1 describes a lighting system with LED chips with which it is possible to emit visible light with a specific wavelength and thereby adjust the intensity to the animal and possibly the stage of development, or the growth curve, of this animal.

A problem with conventional lighting systems for stables is the limited animal welfare, including the risk of stress occurring with possible loss of production, arguments between animals resulting in injuries, and even cannibalism between the animals. Although animals have often been displaced in the past to avoid the consequences of these problems, this approach is often not allowed.

The object of the present invention is to provide an illumination system for applying electromagnetic radiation in a stable for diurnal animals, which obviates or at least alleviates the above-mentioned problems.

This object is achieved with the lighting system according to the invention for applying electromagnetic radiation in a stable for diurnal animals, the lighting system comprising:

at least one light source provided with LED chips arranged for applying electromagnetic radiation;

a controller operatively connected to the light source, arranged to control the at least one light source, the controller being arranged for applying a day pattern of electromagnetic radiation, the day pattern being composed of wavelengths located in the ranges of UV and visible light, and wherein the assembly of wavelengths in the day pattern varies in a time period of at least one day.

By providing the lighting system with one or more light sources equipped with LED chips, it is possible to effectively use specific wavelengths or bandwidths of wavelengths and thereby provide lighting in the house. The specific wavelengths are tuned to the animal kept in the stable. In the case of chickens, a distinction can further be made between laying hens and broilers, as well as taking into account the age or development stage of the animal in question.

According to the invention, the lighting system is provided with a control that controls the one or more light sources such that a day pattern can be followed with regard to the electromagnetic radiation which is applied in the house. The day pattern hereby uses an assembly of different wavelengths, or bandwidths of wavelengths, and makes a variation during the day. This makes it possible to adapt the day pattern to the needs of the animal in question. In the case of chickens, for example, it can be connected to the tropical daylight spectrum during the day. The combination of wavelengths in the daytime pattern in the morning, for example, is different from the used combination of wavelengths in the daytime pattern in the evening.

It has been found that with the lighting system according to the invention the animal welfare of the animals is increased. This further results in fewer problems between the animals, such as quarrels, injuries and cannibalism. Furthermore, it contributes to the reduction of the stress of an individual animal and thereby increases production, such as growth and / or amount of eggs. It will be understood that this also applies to other similar animals such as chickens, including ducks, geese, and turkeys. This can concern meat animals, laying animals as well as breeding animals. Furthermore, it is possible to apply the lighting system according to the invention to other animal species, including insects and pigs.

By using electromagnetic radiation in a broader spectrum, that is to say also outside the light visible to humans in the wavelength range of 380-780 nm, the optimum pattern for the animal in question is approximated as closely as possible. In addition to wave springs in the human visible region, UV light is used in the wavelength range of 10-380 nm, more in particular UV-A in the range of 320-400 nm and / or UV-B in the range of 280-320 nm. UV wavelengths have been shown to improve the social behavior of the animals, in particular in the range of said UV-A spectrum. Furthermore, the UV-B spectrum seems to provide better vitamin D in various animals.

In a presently preferred embodiment, the day pattern is further composed with one or more wavelengths in the infrared (IR) wavelength range of 780 nm-1 mm. The use of IR wavelengths shows an improved eating behavior of the animals in experiments. This allows the behavior and welfare of the animals to be influenced by using the different wavelengths to different degrees in a day pattern. Wavelengths in the visible area can also be specifically included in the day pattern. For example, wavelengths visible in the 650 nm range are possible to reduce animal aggression. A combination of light in the so-called blue visible light spectrum in combination with IR light also has a calming effect that can be applied in the evening, for example. It will be understood that various wavelengths, bandwidths of wavelengths, any combinations thereof, can be used to achieve the desired effects.

The control generates the desired control signals for the lighting system according to the invention for the different light sources such that the wavelengths and the day pattern vary for at least a time period of a day. By providing a day pattern such that certain wavelengths are applied to a certain intensity during part of the day, the desired behavior of the animals in the house can be influenced. As indicated earlier, with a certain wavelength the health as well as the behavior of the animals can be improved.

In addition to a day pattern, according to the invention it is also possible to use various day patterns in a season or year. With this, for example, a "tropics" pattern can be better approached, whereby animal welfare can be further improved, as well as, for example, stimulate vitamin D production, whereby, for example, a better construction of bones and feathers is achieved.

The control in the lighting system according to the invention realizes the desired day pattern and for this purpose preferably controls several light sources with regard to the wavelength (s) and preferably also the intensity thereof. The control is preferably possible per individual light source. This even makes it possible to realize a variation in the space of the barn in addition to variation in the day pattern in driving.

In a presently preferred embodiment, the control of the lighting system according to the invention is provided with a user interface for, among other things, adjusting settings, making corrections as well as setting a manual pattern by a user. Preferably, the controller is further provided with an interface for exchanging information with other users, so that this information can be used manually and / or automatically, for example to achieve a learning effect. Furthermore, the control is preferably arranged in such a way that the realized radiation does not flicker or fluctuate undesirably, so as to further reduce the stress in the animals.

In an advantageous embodiment of the invention, the controller is arranged to provide a day pattern with wavelengths in the range of both UV-A and UV-B.

By using wavelengths from both the UV-A and the UV-B wavelength range, a combined effect is achieved. For example, tests have shown that UV-A, for example, promotes social behavior of the animals, while UV-B, for example, further promotes health.

In an advantageous embodiment according to the invention, the control of the lighting system according to the invention is further provided with a weather sensor, such as a temperature sensor and / or humidity sensor, and a weather module adapted for adapting on the basis of measured weather conditions, such as temperature and / or humidity. of the day pattern.

By measuring outside conditions, such as temperature, humidity and / or sunlight, a complete or partial weather image can be formed. Based on this, a weather correction can be carried out with a weather module of the control system, in order to better simulate the natural variation occurring in daylight in the barn. By also expressing this natural variation in the stable, it has been found that the natural behavior of the stable animals is further improved. In addition or as an alternative to the current weather conditions, it is also possible to use historical weather images and / or future weather forecasts. The weather corrections can result in adjustment of the wavelengths and / or intensities used in the day pattern. Weather correction lean can also be applied, if desired, to conventional lighting systems to improve such systems.

A further advantageous embodiment according to the invention, the control of the lighting system further comprises a camera system arranged for detecting the behavior of the animals in the stable.

When using a day pattern, animal behavior can be influenced and steered in the desired direction. By using a camera system in a presently preferred embodiment, with which animals can be observed, it is possible to correct the day pattern when, for example, quarrels between animals, stress or other undesirable things occur. In addition to a steering or influencing mechanism of the lighting system with the established day pattern, this offers the opportunity to achieve a corrective effect. This is achieved by using the camera manually or automatically with image recognition to detect unwanted things such as unwanted behavior and then apply a correction to the lighting system. This may include switching on or off certain wavelengths or ranges of wavelengths, as well as adjusting the intensity of the lighting or any wavelengths therein. It has been found that this can effectively intervene in the actual behavior of the livestock.

In a presently preferred embodiment, the camera system is connected to an analysis module of the control, which preferably detects on the basis of image recognition whether a behavior correction is desired. It is possible to implement such a behavior correction automatically in the day pattern, or to show this as a recommendation to a user, after which he can (have someone) make the correction. It will be clear that the aforementioned camera system can also be applied to a conventional lighting system. This also allows a correction to the actual behavior in conventional systems.

In a further preferred embodiment according to the invention, the lighting system comprises a usage indicator for the light source arranged for determining the useful life and / or the expected remaining useful life.

By providing an usage indicator for the different light sources, it is possible to obtain an indication of the status of such a light source. This concerns in particular the expected service life, so that a light source can be replaced or repaired as a preventive measure. This allows maintenance to be carried out in a planned manner so that maintenance costs can be reduced. Furthermore, this avoids that a lighting system does not function optimally for some time, as a result of which the stable animals can be negatively influenced.

Preferably, the light source is provided with at least six LED chips, preferably at least eight LED chips and most preferably at least ten LED chips. By providing multiple chips, the best possible spectrum of wavelengths can be realized. In this way an optimal day pattern can be realized in an effective manner, wherein in the presently preferred embodiment it is possible to carry out weather conditions and / or behavioral corrections.

The invention further relates to a stable provided with a lighting system as described above.

Such a stable provides similar advantages and effects as described for the lighting system. In a presently preferred embodiment, the shed relates to a chicken house intended for laying hens, broilers or breeding chickens.

The invention furthermore also relates to a lighting application comprising LED chips, the application being particularly suitable for a lighting system as described above, and comprising:

a housing for the lighting application;

at least one light source disposed in the housing adapted to apply electromagnetic radiation in the wavelength range of visible light and UV; and cooling elements arranged in or on the housing, the cooling elements comprising a number of cooling ribs.

Such a lighting application provides similar effects and advantages as described for the lighting system and the stable provided therewith. Preferably, the lighting application is also suitable for applying electromagnetic radiation in the IR wavelength range.

By providing a lighting application suitable for realizing electromagnetic radiation in the various wavelength ranges mentioned, an optimal living environment for the animals in the stable is provided. This benefits animal welfare as well as production. By providing the cooling elements in the form of a number of cooling ribs, the lighting application is further conditioned in such a way that it is more robust and reliable. The cooling elements, in particular the cooling ribs, preferably extend in a direction coinciding with or parallel to the longitudinal direction of the light source. Effective cooling is hereby achieved.

The invention also further relates to a method for applying an electromagnetic radiation pattern in a stable for animals, the method comprising:

determining a day pattern of electromagnetic radiation, wherein the day pattern contains wavelengths in the wavelength range of UV and visible light, and wherein the day pattern varies the spectrum of wavelengths used in a time period of at least one day;

applying the day pattern of the electromagnetic radiation by a control with at least one light source; and following the day pattern for a time period of at least one day.

Such a method provides similar advantages and effects as described above for the lighting system, stable provided thereof and / or lighting application therefor. In particular, the method provides the best possible animal welfare as well as improved production. In the presently preferred embodiment, the radiation pattern is applied as much as possible to natural tropical daylight when used on chickens.

In a presently preferred embodiment of the method according to the invention, it comprises the additional step of determining a weather correction on the day pattern based on current weather conditions, for instance measured with a weather sensor. Additionally or alternatively, it is also possible to determine such a weather correction on the day pattern on the basis of weather conditions realized in the past and / or expected weather conditions. This allows the natural variation in weather conditions and the accompanying light conditions to be simulated in the house. This benefits the overall well-being of the animals.

In a presently preferred embodiment, according to the day pattern, the control activates at least one wavelength in the UV range during at least part of the evening hours. It has been found that this can have a calming effect on the livestock. It has been found that chickens in particular can be positively influenced by this and are stimulated to a calmer behavior.

Preferably, the day pattern also includes one or more wavelengths in the IR wavelength range. In a possible embodiment, this additionally or alternatively according to the day pattern is activated by the control at least a wavelength in the IR range for at least part of the period between 12 and 3 hours. This can, for example, influence the eating behavior in the desired way. This has been found to work positively for chickens in particular.

In a further advantageous embodiment, the method comprises the steps of determining a behavior correction on the day pattern based on camera detection of animal behavior in the stable. This achieves a controlling and steering effect.

Furthermore, in the presently preferred embodiment of the invention, a seasonal pattern is determined, which is incorporated into one or more day patterns that are applied over time. This further increases the overall animal welfare.

Further advantages, features and details of the invention are illustrated by preferred embodiments thereof, reference being made to the accompanying drawings, which show:

Fig. 1 is a view of a stable provided with a lighting system according to the invention;

Fig. 2 shows a number of schematically represented wavelengths handled in a day pattern and applied to the stable of FIG. 1;

Fig. 3 is a view of a lighting application applicable in the lighting system of FIG. 1; and

Fig. 4 is a schematic representation of the different steps in keeping animals in a house of FIG. 1.

Stable 2 (fig. 1) is provided with lighting system 4 and adapted for keeping animals, in particular chickens 6. Lighting system 4 is provided with a number of light sources 8, each of which is composed of a number of LED chips 10. Light sources 8 controlled by operating system 12 using control signals 14. User 16 is provided with information by means of user interface 18, with which it is possible to exchange data 20. With this, among other things, the current status of lighting system 4 can be shown to user 16, as well as user 16 can change settings via interface 18. Interface 18 communicates signals 22 with control 12. Based on this, control 12 can send adjusted control signals 14.

In the embodiment shown, lighting system 4 is provided with weather system 24, comprising one or more of a temperature sensor, relative humidity sensor, light detector and / or other detectors, in order to send current weather conditions 26 to weather analysis module 28. Weather analysis module 28 can send corrections 30 to control 12, which thereby then adjust the day pattern and send adjusted control signals 14 to light source 8. Optionally, weather system 24 includes a module for historical data and / or predictions of future weather conditions.

In the embodiment shown, stable 2 (fig. 1) is further provided with camera system 32.

Camera images 34 are used in behavior analysis module 36, optionally resulting in behavioral corrections 38 to the day pattern. Behavioral corrections 38 can thereby lead to an adapted control 14 to light source 8. It will be clear that the user interface 18, weather analysis module 28 and behavior analysis module 36 can also be provided integrally with control 12. This also applies to communication module 40, which can communicate information 42 with third parties, including, for example, other houses fitted with lighting systems 4. Relevant information 42 can be passed on to control 12 in order to make any further corrections.

A day pattern includes electromagnetic radiation of different wavelengths that are activated in different ways during a day, possibly with different intensity.

Figure 2A shows an example of part of a day pattern that is applicable, for example, in a time period between 10 and 12 hours in a day. The total spectrum in this part of the day pattern is shown with the top line in Figure 2A. In this part of the day pattern, two peaks in the UV range at about 365-375 nm and 380-400 nm are present, as well as peaks in the human visible range at wavelengths of about 440, 470, 530, 600 and 630 nm. Tests have shown that during this time of day this array of wavelengths in the day pattern works effectively, especially for chickens.

Figure 2B shows an example of a part of a day pattern that is applicable, for example, in a time period at, for example, the end of a day. A number of wavelength peaks are visible here, at about 365-375 nm, 380-400 nm, around 470 nm, around 530 nm and around 600 nm, respectively. Therefore, there is a variation in time peaks in the day pattern. It is further noted that the height of the peaks further deviates from the part of the day pattern as shown in figure 2A.

Figure 2C shows an example of a part of a day pattern that is applicable, for example, if in stable 2 there is an argument between animals 6 and / or cannibalism, for example detected with camera system 32. Three wavelength peaks are visible, respectively at such times. n 365-375 nm, 380-400 nm, and 620-640 nm.

Figure 2D shows a further example of part of a day pattern. The total spectrum in this part of the day pattern is shown with the top line in Figure 2A. In this part of the day pattern, six peaks in the UV range are included, as well as peaks around 445, 475, 525, 600 and 630 nm.

It will be clear that parts of a day pattern or day patterns shown can be adapted to the relevant circumstances, including, for example, data from stable 2, animals 6, behavior determined with the aid of camera system 32 and / or data from weather module 24.

In the shown embodiment, light source 8 (fig. 3) is provided with a frame or frame 50 on which a control 52 is mounted. A number of applications / chips 10 are also provided for this. It will be clear that the number of applications / chips 10 can be expanded. In the embodiment shown, light source 8 is further provided with cooling element 54 comprising a number of cooling ribs extending in a length L parallel or coincident with this length L of lighting application 10. It will be clear that a different configuration for light source 8 can also be applied in lighting system 4 when used in stable 2.

The keeping 102 of animals (Fig. 4) requires the collection (104) of relevant data about, for example, stable 2 and animals 6. On the basis of this, a day pattern determination 106 is performed. When using the day pattern in a stable 2 with lighting system 4, it is possible to make corrections 108 if desired. These corrections can come from weather analysis module 28 and are used to determine weather corrections 30 during weather correction determination 110. With camera system 32 it is possible to analyze animal behavior 6 during behavior correction determination 112 with the aid of behavior analysis modules 36. After making corrections 108 subsequently lighting system 4 controlled during operation 114, wherein animals 6 subsequently grow, lay eggs or are otherwise to a greater or lesser extent active in realization step 116. In the embodiment shown, this realization is monitored with the aid of camera system 32, possibly resulting in a behavior correction. It will be understood that other process steps can be added or modified or removed if desired. For example, it is possible for the user to make corrections manually and / or to make such corrections by third parties, for example stable owners from other areas.

The present invention is by no means limited to the above described preferred embodiments thereof. The requested rights are defined by the following claims, within the scope of which many modifications are conceivable.

Claims (17)

Lighting system for applying electromagnetic radiation in a stable for diurnal animals, the lighting system comprising: at least one light source provided with LED chips arranged for applying electromagnetic radiation; a controller operatively connected to the light source adapted to control the at least one light source, the controller being arranged to apply a day pattern of electromagnetic radiation, the day pattern being composed of wavelengths located in the ranges of UV and visible light, and wherein the assembly of wavelengths in the day pattern varies in a time period of at least one day. The lighting system of claim 1, wherein the day pattern further includes wavelengths in the range of IR. The lighting system of claim 1 or 2, wherein the day pattern further includes wavelengths in the range of both UV-A and UV-B. The lighting system according to claim 1, 2 or 3, wherein the control further comprises a weather sensor and a weather module adapted to adjust the day pattern on the basis of measured weather conditions. Lighting system according to any of the preceding claims, wherein the control further comprises a camera system adapted to detect the behavior of the animals. The lighting system according to any of the preceding claims, further comprising a usage indicator for the light source adapted to determine the useful life and / or the expected remaining useful life. Lighting system according to any of the preceding claims, wherein the at least one light source is provided with at least 6 LED chips, preferably at least 8 LED chips, and most preferably at least 10 LED chips. Stable provided with a lighting system according to one of the preceding claims. Lighting application provided with a light source with LED chips, comprising: a housing for the lighting application; at least one light source disposed in the housing arranged for applying electromagnetic radiation in the wavelength range of UV and visible light; and cooling elements arranged in or on the housing, the cooling elements comprising a number of cooling ribs. The lighting application of claim 9, wherein the cooling elements extend a distance substantially coincident with or parallel to the light source. A method for applying an electromagnetic radiation pattern in an animal stable, the method comprising: determining a day pattern of electromagnetic radiation, wherein the day pattern contains wavelengths in the wavelength range of UV and visible light, the day pattern varying the spectrum of wavelengths used in a time period of at least one day; applying the day pattern of the electromagnetic radiation by a control with at least one light source; and following the day pattern for a time period of at least one day. The method of claim 11, further comprising the step of determining a weather correction to the day pattern based on current weather conditions. The method of claim 11 or 12, further comprising the step of determining a weather correction to the day pattern based on realized weather conditions and / or expected weather conditions. A method according to claim 11, 12 or 13, wherein according to the day pattern the control activates at least one wavelength in the UV range during at least part of the evening hours. A method according to any one of claims 11-14, further comprising the step of providing at least one wavelength in the IR range in the day pattern, wherein at least one wavelength in the IR field is preferably controlled by the control according to the day pattern. range is activated for at least part of the period between 12am and 3pm. The method of any of claims 11-15, further comprising the step of determining a behavioral correction to the day pattern based on camera detection. The method of any one of claims 11-16, further comprising the step of 5 determining a seasonal pattern.