RU8523U1 - COMPACT LUMINESCENT LAMP - Google Patents

Description

COMPACT LUMINESCENT LAMP

The utility model relates to lighting engineering, namely to the design of compact luminescent light sources, the diameter of the discharge tube of which does not exceed 16 mm and designed to replace incandescent lamps in lighting devices (OS) used in industrial, public or residential premises.

One of the important operational characteristics of light sources intended for general or local illumination is the magnitude of the luminous flux generated by it, per elementary solid angle in the selected direction. Another important design feature of CFLs is the distance between the ends of the discharge tube, since it is this value in the maximum degree affects the overall mounting dimensions of the housing containing the ballast (PRA).

Known CFL designs containing a discharge tube in the form of a sealed glass container made in the form of straight pipe segments interconnected by tubular hollow jumpers. For example, US patent No. 4853591, MKI H01 7 61/32, publ. 08/01/89. The magnitude of the luminous flux generated by such lamps is not the same in different directions of the race, the maximum in the direction perpendicular to the axis of the lamp and the minimum in its axial direction, and the mutual shielding of parallel segments reinforces this drawback. This distribution of the light flux is very different from the distribution of the light flux generated the usual incandescent lamp (LN) and for use requires the creation of OA designs that take into account this drawback of the well-known CFL design.

HOI J

A solution is known in which a compact fluorescent lamp contains a sealed glass tube / made in the form of a cylindrical bifilar spiral, the ends of which are directed in one direction. Moreover, the distance between the axes of the ends of the spiral is approximately equal to the diameter of the coil nearest to them (application for invention of the Russian Federation 1 94018301/25 , Н05В 33/10, publ. 27. 01.96).

In this solution, the implementation of the discharge glass tube in the form of a bifilar spiral provides a more uniform distribution of the light flux to the solid angle. However, even with this design of the discharge glass tube, the light flux generated by each of its turns is lost in the axial direction due to their mutual screening. In addition, the approximate equality of the distance between the axes of the ends of the tube and the diameter of the coil nearest to them leads to the need to increase the connecting dimensions of the lamp housing, increases its geometric dimensions and gives undesirable massiveness of the entire structure as a whole.

One of the possible constructive options for reducing the mutual screening of the turns of a bifilar discharge tube is its implementation in the form of a cone, in which the diameter of each of the turns increases as it approaches the ends of the discharge tube.

A compact fluorescent lamp is known, containing a discharge tube / made in the form of a conical bifilar spiral, the diameter of each of which turns, as it approaches the ends of the tube, increases (PCT application WO No. 94/29895 / MKi5 H01761 / 30, publ. 22.12.94) .

However, the known solution has the same drawback as the previous of the described analogues: the approximate equality of the distance between the axes of the ends of the tube and the diameter of the coil nearest to them. In combination with the conical shape of the glass cylinder this gives the lamp extraordinary massiveness, undesirable geometric dimensions.

The last of the described analogues on the PCT application WO No. 94/29895 adopted as a prototype, because it coincides with the stated decision on most of the essential features.

The technical result of the utility model is to reduce the geometric dimensions of the lamp, without affecting its light characteristics.

The essence of the utility model can be expressed by the following set of essential features: a compact fluorescent lamp containing a sealed glass spiral tube, for example, in the form of a bifilar spiral, the ends of which are parallel, directed to one side and placed at a distance -v from each other, the value of which is selected from expressions:

ot t / z ed

where C- is the distance between the axes of the ends of the tube, mm,

the detectable diameter of the glass tube, mm

- the maximum overall dimension of the lamp in the direction perpendicular to the axis of the lamp, mm,

current leads, tightly fixed in a glass tube / ballast, located in the housing with the possibility of electrical or electromechanical connection of ballasts with current leads and a power supply network.

The given set of features is sufficient to achieve a technical result / provided by a useful model.

At the prior art, no solutions have been identified that have a combination of features that are identical to the set of features of the claimed solution. No solutions are also identified that contain distinctive features / indicated in the utility model formula.

The utility model is illustrated by graphic materials, in which Fig. 1 shows a general plan view of a CFL with a discharge tube in the form of a bifilar spiral; in Fig. 2, a bifilar discharge tube of the CFL shown in Fig. 1.

The compact fluorescent lamp contains a discharge tube 1 in the form of a bifilar spiral with turns 1 and 1, the radius of curvature of which increases to a certain extent as it approaches the ends 2 and 3 of tube 1, while the envelope of their surface is mainly a conical surface that extends to the ends 2 and 3 of the tube 1, mounted in the housing 4, inside of which is placed a ballast (not shown), a base 5, mounted on the housing 4 and designed to connect the CFL to the power supply network.

CFL works as follows. After a heating current is supplied to the electrodes (not shown), a gas discharge is generated that generates radiation that excites the luminophore deposited on the inner surface of the tube walls 1. The luminous flux radiated axially from the surface of the unshielded part of the turns 1 and 1, is summed up, increasing the luminous efficiency of the CFL, and the ends 2 and 3 of the tube 1, made in the process of spiral formation shifted to the CFL axis, do not shield radiation from the surface of the lower turn and provide enshenie dimensions of the housing 4.

Claims (6)

1. A compact fluorescent lamp, containing a sealed glass spiral tube, the ends of which are parallel and directed to one side, current leads fixed at each end of the tube, a ballasts placed in the housing, means for electrically or electromechanically connecting the ballasts with current leads, characterized in that the distance between the ends of the sealed glass tube is selected from the expression
d <l <b - d,
where l is the distance between the axes of the ends of the tube, mm;
d is the outer diameter of the glass tube, mm;
b - the maximum overall dimension of the lamp in the direction perpendicular to the axis of the lamp, mm.  2. The lamp according to claim 1, characterized in that the surface enveloping the spiral tube is approximately conical.  3. The lamp according to claim 1, characterized in that the surface enveloping the spiral tube is approximately cylindrical.  4. The lamp according to paragraphs. 1 and 2, characterized in that the radius of curvature of the coils of the spiral of the glass sealed tube is made to increase as it approaches its ends.  5. The lamp according to claim 1, characterized in that the radius of curvature of the turns of the spiral of the glass sealed tube is made essentially the same along its entire length. 6. The lamp according to claim 1, characterized in that the radii of curvature of the turns of the spiral-shaped glass sealed tube are made increasing by ΔK, tending to zero as it approaches the ends of the tube.