FR2752480A1 - COLD CATHODE FLUORESCENT LAMP - Google Patents

Abstract

Cold cathode fluorescent lamp 1 comprising a heating device 4 in which the heating device 4 is disposed over the entire length of the tube 3 of the cold cathode fluorescent lamp and a calorific value of the latter being controlled as a function of the portion of the tube to obtain an almost uniform temperature distribution such that a temperature of the central portion of the tube does not become much higher than that of the two terminal portions 3c of the tube before the cold cathode fluorescent lamp is turned on. Since there is sufficient mercury vapor in the vicinity of the central portion 3b of the tube which is sufficiently cold at the time of preheating with the aid of the heater 4 before ignition, an ignition brightness of a practical level can be obtained immediately after starting the discharge by applying an ignition voltage.

Description

COLD CATHODE FLUORESCENT LAMP

  The invention relates to a cold cathode fluorescent lamp for use as a light source for automobile meters, as a rear light source for liquid crystal displays, as a source of light for image reading devices for facsimiles and the like. More specifically, it relates to a cold cathode fluorescent lamp comprising a heating element arranged around a bulb to improve the starting properties in cold weather. This type of fluorescent lamp comprising a heating device according to the prior art is described in the published Japanese patent application No. Hei 4-172221, for example. The published application describes a fluorescent lamp in which a heating wire is wound in a spiral around the tube of the fluorescent lamp with a predetermined pitch which is smaller than the diameter of the bulb. Figure 1 (C) of this published application shows an embodiment in which the wire is surrounded in a spiral around the tube more densely at the central portion thereof than at the terminal portions. In the case of the above conventional fluorescent lamp comprising a heating device, the starting time is improved without the excessive liquefaction of the mercury vapor in cold weather. On the other hand, it has been found that the presence of the

  heating causes the following problems.

  First, when the pitch is small in the central portion of the tube as shown in Figure 1 (C) of the above published application, the temperature distribution in the direction of the length L of the tube at the time of preheating the ignition is such that the temperature of the central part becomes higher than that of the two end parts of the tube as shown by the curve P in Figure 4. Second, since the mercury vapor inside the tube has the property of moving in the direction of the parts at low temperature and moving towards the two ends of this tube which have a low temperature compared to the central part of the latter, the central part of the tube is rid of mercury vapor immediately after an ignition voltage is applied. Thus, only about 50% of the brightness can be obtained at the time of normal lighting. Thus, sufficient shine cannot

  not be obtained at the time of ignition.

  In addition, the operating time of the fluorescent lamp having a heater is greatly shortened compared to an ordinary fluorescent lamp without a heater because the discharge is carried out while the mercury vapor

  runs out, as described above.

  As a means of solving the above problems of the prior art, the present invention provides a cold cathode fluorescent lamp having a heater around the tube itself to improve the ignition properties, in which the heater is placed around the tube over the entire length of the tube of the cold cathode fluorescent lamp and the calorific value is controlled as a function of the portion along the tube to obtain an almost uniform temperature distribution so that the temperature of a central portion of the cold cathode fluorescent lamp is not much higher than that of the two terminal portions thereof before the cold cathode fluorescent lamp turns on. Thus, the brightness at start-up is improved and a reduction in the lamp operating time

fluorescent is minimized.

  These aims and advantages of the present invention

  will become apparent from the following description

  with reference to the accompanying drawings in which: FIG. 1 is a side view with partial cutaway of a cold cathode fluorescent lamp according to an embodiment of the present invention; FIG. 2 is a graph showing the temperature distribution along the entire length of the tube of the cold cathode fluorescent lamp according to an embodiment of the present invention at the time of preheating before ignition; Figure 3 is an explanatory diagram of the essential parts of a cold cathode fluorescent lamp according to another embodiment of the present invention and Figure 4 is a graph showing the temperature distribution along the entire length of the tube a cold cathode fluorescent lamp

  conventional at the time of preheating before ignition.

  The present invention is described in detail with reference to the preferred embodiments shown in the accompanying drawings. Designated by 1 in Figure 1 a fluorescent lamp with cold cathode according to the present invention. The cold cathode fluorescent lamp comprises a cold cathode fluorescent lamp 2 having a tube 3 comprising a central portion 3b and two end portions 3c, 3c, electrodes 5 included inside the tube 3 and lead wires 6 which are in electrical contact with said electrodes respectively and which penetrate through the tube 3 to connect to the electrodes from the outside of the tube 3, and a heating device 4 on the outer peripheral surface 3a of the tube 3 of said fluorescent lamp 2 cold cathode in

  to reduce start-up time in cold weather.

  In the case of the present invention, the heating device 4 is arranged around the tube over the entire length L of the tube 3 in order to obtain an almost uniform temperature distribution in the direction of the length L of the tube 3 so that the temperature of a central portion 3b does not become much higher than that of the two terminal portions 3c when the fluorescent lamp 1 with a cold cathode is in the preheating phase. As shown by the heating temperature curve H in Figure 2, there is not a large temperature difference between the central portion

  3b and the two terminal portions 3c.

  The two end portions 3c of the tube 3 have a high radiation efficiency towards the outside air compared to the central portion of the tube 3 due to the fact that they have more extensive contact with the outside air than the central portion 3b and the fact that it moreover includes electrodes 5 and lead wires 6. When the heating device 4 is formed by surrounding a heating wire of a predetermined diameter at a predetermined pitch around the tube 3, the heat generated by the heating wire is distributed with the same value along the length direction L of the tube 3 and the temperatures of the two terminal portions 3c become lower than the

  temperature of the central portion 3b.

  In the case of the present invention, the heating device 4 constituted by winding the heating wire with a small pitch compensates for the difference in the radiation function inside the tube 3, whereby the distribution of the temperature inside the tube

3 becomes almost uniform.

  In the case of the present invention, the heating device 4 does not need to be constituted by a winding of the above heating wire and can be constituted by arranging a transparent electrode such as in indium oxide and tin (ITO) over the entire peripheral surface 3a of the tube 3, unnecessary portions being removed by pickling so that the above uniform temperature distribution can be obtained.

  A description is given below of

  operation and effect of the cold cathode fluorescent lamp 1 according to the present invention and constituted as just described. First of all, when the preheating is carried out by the heating device 4 before the lighting of the fluorescent lamp 2 with a cold cathode in cold weather, the temperature distribution inside the tube 3 is such that the temperature of the central portion 3b is suitably lower than that of the two terminal portions 3c due to the above constitution according to the present invention. Secondly, since the mercury in the vapor state is maintained by the heater 4, it moves towards and is present in the vicinity of the central portion 3b which has a lower temperature than the two terminal portions 3c when an ignition voltage is applied between the electrodes 5 in this state, a rarefaction of the mercury vapor does not occur from the start of the discharge, thus making it possible to obtain sufficient brightness from the moment of ignition. According to the results of manufacturing and study tests by the inventors with a view to carrying out this invention, 90% of the brightness at the time of stable operation is obtained immediately after the cold cathode fluorescent lamp 1 is started and it is not a problem from the point of view of the practical applicability of the lamp when it is used as a light source for automobile meters and as a rear lighting light source for liquid crystal displays being given the constitution of the present invention. Thirdly, when the discharge starts, a sufficient quantity of mercury vapor is present in the vicinity of the central portion 3b, whereby the discharge between the electrodes 5 with a depletion of the mercury vapor is avoided. As a result, it is possible to avoid a reduction in the operating time of a cold cathode fluorescent lamp 1 which would be caused by the depletion of mercury vapor. In accordance with the results of the above manufacturing and study tests, the operating time of the fluorescent lamp can be extended from 3 to 5 times compared to that of a cold cathode fluorescent lamp

  conventional comprising a heating device.

  The mere fact of avoiding the liquefaction of mercury by the heater 4 is not sufficient to allow a cold cathode fluorescent lamp having a heater to operate effectively in cold weather. A satisfactory effect cannot be obtained unless the distribution of the mercury vapor inside the tube is controlled by an optimization of the temperature distribution as proposed by the

present invention.

  Figure 3 shows another embodiment of the present invention. In the effective use of the fluorescent lamp 2 with cold cathode, an external component 7 such as a socket is often fixed to the two end portions 3c of the fluorescent lamp 2 with cold cathode in order to install the fluorescent lamp 2 in a chassis or the like. In this case, there is the possibility that the temperature distribution inside the tube 3 is made different from the temperature distribution which had been explained in the case of the embodiment.

  previous due to the attachment of the external component 7.

  This embodiment aims to correspond to a use of this type and the object of the present invention is achieved by controlling the calorific value of the heating device 4 which depends on the portion of the fluorescent lamp 2 with cold cathode in agreement with a modification. radiation efficiency of the two terminal parts 3c caused by the fixation of the external component 7

  to achieve the heating curve H in Figure 2.

  The calorific value of the heating device 4 is controlled by taking into consideration the heat conductivity of a member forming the external component 7. For example, when the external component 7 is made of a metal having excellent heat conductivity, the calorific value of the heating device 4 is increased at the portion of the tube which corresponds to the external component 7 by reducing the pitch of the winding of the heating wire or the like. In another example, when the external component 7 is made of a resin having excellent insulating properties against heat, the calorific value of the heating device 4 at the portion of the tube corresponding to the external component 7 is reduced by increasing the pitch of winding the heating wire or the like. As described above in accordance with the invention, a cold cathode fluorescent lamp comprising a heating device is arranged such that a heating device is provided over the entire length of the tube of the cold cathode fluorescent lamp and the calorific value of the heating device is controlled according to the portion of the tube to obtain an almost uniform temperature distribution so that a central portion of the cold cathode fluorescent lamp does not become much hotter than the two end portions of this tube before the cold cathode fluorescent lamp is on. Since mercury vapor is present in the vicinity of the central portion of the tube which suitably has a low temperature at the time of preheating with the pre-ignition heater, an ignition brightness of practical level can be obtained immediately after starting

  discharge by application of an ignition voltage.

  Thus, the present invention provides an extremely excellent effect, namely, that the performance of this type of cold cathode fluorescent lamp with heater

is improved.

  Since the discharge is carried out while a sufficient quantity of mercury is inside the tube of the cold cathode fluorescent lamp comprising a heating device, the discharges with rarefaction of mercury vapor which were encountered in the prior art are avoided. Thus, the present invention has this other excellent effect that the reduction of the operating time of this type of cold cathode fluorescent lamp comprising a heating device is avoided even when the lamp is used at

low temperature.

  In addition, the above described way of controlling the temperature distribution on the cold cathode fluorescent lamp is also effective when an external component is additionally attached to the cold cathode fluorescent lamp since this component can compensate for a change in the temperature distribution due to the fixing of a socket, or the like, making it possible to obtain a substantially uniform temperature distribution inside the tube of the fluorescent lamp with cold cathode. It will be clear to a person skilled in the art that numerous modifications and variations can be made to cold cathode fluorescent lamps comprising a heating device in accordance with the present invention without departing from the spirit or the scope of the invention. . The object is that the present invention covers the modifications and variations of this invention provided that they fall within

  the scope and spirit of the attached claims and

their equivalents.

Claims (4)

  1. A cold cathode fluorescent lamp 1 comprising: an electrode 5 and a lead wire 6 in electrical contact with said electrode 5; a tube 3 enclosing this electrode 5 and comprising a central portion 3b and two end portions 3c; this lead wire penetrating through the tube 3 to connect the electrode 5 from the outside of the tube; and a heater 4 provided around the tube 3 over the entire length of the latter to improve the starting properties, characterized in that the heater 4 is arranged so that its calorific value is controlled according to the portion of the tube for an almost uniform temperature distribution along the tube, so that a temperature of the central portion of the tube is not higher than that of the two end parts of the tube before the fluorescent lamp at cold cathode does is on.   2. fluorescent lamp with cold cathode 1 according to claim 1, characterized in that the heating device 4 is formed by winding a heating wire in a spiral around the tube 3 and in that the calorific value is controlled by the winding step heating wire.   3. Fluorescent lamp with cold cathode 1 according to claim 1, characterized in that the heating device 4 is arranged by the arrangement of a transparent electrode on the entire outer peripheral surface of the tube and by removing the portions not necessary of the transparent electrode in order to satisfy the conditions of temperature distribution, the calorific value being controlled by the surface of the transparent electrode. 4. Fluorescent lamp with cold cathode 1 according to claim 1 further comprising an external component 7 for supporting the fluorescent lamp 2 with cold cathode, characterized in that the calorific value of the heating device 4 is controlled as a function of the portion of the tube through which the effect of an external component 7 is compensated in order to maintain the distribution of   temperature on the cold cathode fluorescent lamp.