EP1937037A2 - Method for measuring the temperature at the Tc point of a preswitching device and preswitching device - Google Patents

Abstract

The fixture device (3) comprises a fixture section (25) for mounting the fixture device on a carrier and a support section (5) for the channel. There is an additional extending holder section (19) in front of the support section for pre-fixing the fixture device on the channel. There may be two holder sections in counter-opposing directions, whilst the holder section may have holder bracket (25?) that extends perpendicularly above the channel. The holder section may be elastically deformable.

Description

Technical area

The invention relates to a method for determining the temperature at the T _c point of a ballast and a ballast.

State of the art

From practice ballasts are known, which are used for example in gas discharge lamps and fluorescent tubes for current limiting. The standard DIN EN 61347-1 (VDE 0712-30) specifies requirements for devices for lamps, including ballasts. According to this standard, it is stipulated that a temperature measuring point, the so-called T _c point, must be specified on ballasts. This T _C point is used for the heating evaluation of the ballast in the luminaire application.

Manufacturers of ballasts connect with the T _c point different device properties. In particular, a maximum allowable temperature is set, which should not be exceeded for safe operation of the lamp or the ballast.

Usually, the T _c point is provided with a thermocouple in the luminaire qualification. This thermocouple is used to determine a maximum allowable temperature (T _a ) of the respective lamp.

Presentation of the invention

The invention has for its object to provide an alternative and inexpensive method for determining the temperature at the T _c point of a ballast available. Furthermore, a ballast is to be made available, with which the temperature at the T _c point can be determined and which is inexpensive to produce. This object is achieved by a method having the features of claim 1 and by a ballast having the features of claim 8.

In accordance with the method according to the invention, a temperature T _{M is determined} by means of a temperature sensor arranged in the region of a T _c point. This temperature T _M is then processed and output by an electronic component, and based on the temperature T _M output from the electronic component, the temperature T _c at the T _c point is then determined. According to the invention, it is therefore no longer absolutely necessary to carry out a temperature measurement at the T _c point to determine the temperature T _c at the T _c point, but it is sufficient if the temperature T _M in the region of the T _c point is detected , On the basis of this temperature T _M , the temperature T _c at the T _c point is determined without further temperature measurement by the method according to the invention. This has the advantage that even existing in a ballast, not at the T _c point itself arranged temperature sensor for determining the temperature T _c at the T _c point can be used and the temperature T _{c is} thus determined without additional costs for another temperature sensor. The ballast temperature can therefore with this method be detected more easily, which significantly reduces the cost of a luminaire qualification.

Particularly advantageous embodiments can be found in the dependent claims.

In order to determine the temperature T _c at the T _c point, a correlation table is preferably used which comprises correlated temperatures T _c at the T _c point for determined temperatures T _M. Such a correlation table can be determined, for example, by tests already by a ballast manufacturer for each ballast type and for each lamp combination. Already performed tests have shown that the determination of the temperature T _c at the point T _c is determined by means of determined temperature T _M in the range of T _c point location with sufficient accuracy. The temperature sensor for determining the temperature T _M should be within the ballast. Particularly accurate correlation values result when the distance of the temperature sensor from the T _c point is less than 50 mm, in particular less than 20 mm.

Of course, instead of a correlation table, a calculation function or a different assignment of temperature values can also be used.

In a further preferred embodiment, a microcontroller is used as the electronic component. Microcontrollers are not only inexpensive, but are also suitable for performing additional functions in addition to processing the signals of the temperature sensor.

In particular, it is possible to deposit a correlation table in the microcontroller and also to use the microcontroller for the automatic determination of the temperature T _c at the T _c point. Then only very few hardware elements are required for carrying out the method according to the invention, so that the elements required for the method can also be integrated into very compact ballasts.

In a particularly simple embodiment variant of the method according to the invention, the correlation table comprises precisely one temperature T _M and one correlated temperature T _c , wherein the microcontroller causes a power reduction as soon as the temperature T _c at the T _c point is reached or exceeded. The temperature T _c contained in the correlation table of this _variant is a predetermined maximum temperature T _a , which should not be exceeded in order to prevent damage to individual components of the ballast. The temperature T _a is therefore designed in particular so that any electrolytic capacitors contained in the ballast do not disproportionately dry out and any semiconductor components contained therein do not suffer any damage due to overheating.

In a further preferred embodiment variant of the method according to the invention, the determined temperature T _M and / or the temperature T _c at the T _c point is detected by the electronic component, in particular by a microcontroller, and made available via a digital interface. This makes it possible to query the temperature T _c or T _M at any time. It can even be permanently monitored for temperature and due to these temperature monitoring Draw conclusions about the life of the ballast. Furthermore, it is possible to display the temperatures T _c and / or T _M, for example, by means of an internal or external display device. With such information analyzes can be carried out. For example, it can be determined by simple observation when an elevated temperature T _c is present. Possibly. even the cause of the increased temperature T _c can be detected and eliminated. This would be the case, for example, if the temperature T _c is increased because the ballast is in the immediate vicinity of an external heat source. The method also provides the display device with the ability to estimate the life of the ballast.

Further, a digital interface allows the expected device life to be determined based on a temperature analysis and also to display it.

In a particularly preferred embodiment variant, the digital interface controls a radio transmitter and thus makes it possible to transmit information about determined temperatures T _M or T _C wirelessly over longer distances to display or processing devices with radio reception. As a result, in particular where very many lamps equipped with ballasts are operated, for example in film studios, they can be monitored from a central location.

The advantages described above with reference to the method according to the invention are also evident in a ballast according to the invention. These advantages are hereby referred to.

Further advantageous embodiments and modifications of the invention will become apparent from the dependent claims and from the description in conjunction with the drawings.

Short description of the drawing (s)

Fig. 1

eine Leuchte mit einem erfindungsgemäßen Vorschaltgerät in einer schematischen Darstellung.

In the following, the invention will be explained in more detail with reference to an embodiment. It shows:

Fig. 1

a lamp with a ballast according to the invention in a schematic representation.

Preferred embodiment of the invention

Fig. 1 shows a lamp 8, comprising a ballast 10 according to the invention and a lamp 12. Since it is at Fig. 1 is a schematic representation, only those elements of the lamp 8 are shown, which have special significance for explaining the invention.

As in Fig. 1 shown, the ballast 10 according to the invention on a T _c point 24, at which takes place in the luminaire admission temperature measurement.

The ballast 10 according to the invention also has a temperature sensor 20, which is about 20 mm away from the T _c point and thus arranged in the region of the T _c point 24. The temperature sensor 20 is connected to a microcontroller 16 in which a correlation table (not shown) is stored in the present case. The microcontroller is designed to convert the analog signals detected by the temperature sensor 20 into digital signals and also with the help of the integrated correlation table on the basis of the determined Temperature T _M at the temperature sensor 20 to determine the temperature T _c at the T _c point. If a temperature T _{c is} determined which could lead to damage to the luminaire 8 or one of its elements, the microcontroller 16 reduces the power. The microcontroller 16 shown can continuously reduce the power and thus regulate the power such that a predetermined maximum temperature T _{a is} not exceeded. However, it is also possible to use cheaper and simpler microcontroller, which can reduce the power only gradually or reduce the power to zero at an allowable temperature T _a , until the predetermined maximum temperature T _{a is} fallen below again.

The microcontroller 16 is also connected to an interface 14, which in the present case is a digital interface. The interface comprises a connection for a data processing device (not shown) as well as for a radio transmitter (not shown). Via the interface 14 it is possible to display, export and further process temperatures T _M and T _c .

In the in Fig. 1 shown embodiment of the inventive ballast, it is not intended that the interface itself has a display device, since the ballast is installed in the lamp. In other embodiments of luminaires with external ballasts, however, it may be advantageous to provide the interface itself with a display device which permanently displays the determined values of the temperature T _M and / or the temperature T _c , because then the user of the lamp can directly on ballast read off the current temperature T _M and / or the temperature T _c .

Claims (15)

Method for determining the temperature T _c at the so-called T _c point (24) of a ballast (10), characterized by the following steps: a) a temperature T _{M is} determined by means of a temperature sensor (20) arranged in the region of the T _c point, b) the temperature T _M determined with the temperature sensor is processed and output by an electronic component (16), c) on the basis of the output from the electronic component (16) temperature T _M , the temperature T _c at the T _c point (24) is determined. Method according to claim 1,
characterized in that
the determination of the temperature T _c at the T _c point (24) by means of a correlation table which comprises temperatures T _c correlated to determined temperatures T _M at the T _c point (24) and / or is carried out with the aid of a calculation function. Method according to claim 1 or 2,
characterized in that
as electronic component (16) a microcontroller (16) is used. Method according to claim 3,
characterized in that
the correlation table is stored in the microcontroller (16) and the temperature T _c at the T _c point of Microcontroller (16) is determined automatically on the basis of the stored correlation table. Method according to one of claims 2 to 4,
characterized in that
the correlation table comprises exactly one temperature T _M and a correlated temperature T _c and that the microcontroller causes a power reduction as soon as the temperature T _{c is} reached or exceeded. Method according to one of claims 1 to 5,
characterized in that
the determined temperature T _M and / or the temperature T _c at the T _c point (24) is transmitted from the electronic component (16) to a digital interface (14). Method according to claim 6,
characterized in that
the digital interface (14) controls a radio transmitter. Ballast for a lamp (12) having a temperature sensor (20) arranged in the region of a T _c point (24) for determining a temperature T _{M of} an electronic component (16) in communication with said temperature sensor (20) the temperature sensor (16) determined temperature T _M ,
characterized in that
the electronic component (16) comprises means for determining the temperature T _c at a T _c point (24). Ballast according to claim 8,
characterized in that
the electronic component (16) for determining the temperature T _c at the T _c point has access to a correlation table. Ballast according to claim 9,
characterized in that
the correlation table is integrated in the electronic component (16). Ballast according to one of claims 8 to 10,
characterized in that
the electronic component (16) is a microcontroller (16). Ballast according to claim 11,
characterized in that
the microcontroller (16) comprises a module for controlling and regulating the operation of the lamp. Ballast according to claim 11 or 12,
characterized in that
the microcontroller (16) has a connection to a digital interface (14). Ballast according to one of claims 11 to 13,
characterized in that
the digital interface (14) comprises a radio transmitter. Luminaire, characterized by a ballast according to one of claims 8 to 14.

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