RU2737278C1 - Gas-discharge reflecting lamp - Google Patents

Abstract

FIELD: electrical equipment.

SUBSTANCE: invention relates to electrotechnical industry, in particular, it improves design of high-pressure gas-discharge mirror lamps for general and special lighting purposes. In a gas-discharge mirror lamp comprising a burner mounted in the current leads a bulb, burner axis is located on bulb symmetry longitudinal plane and shifted from its axis to mirror coating applied to bulb inner surface part so that plane passing through its longitudinal edges is parallel to burner lengthwise axis. Bulb is made with cylindrical diameter D lying within 9.2÷10.2 of burner diameter, and in the mirror surface area of the bulb there is a recess of the V-shaped transverse profile with bulged outward edges 9, 10 emanating from rib 8, located on the longitudinal plane of symmetry of the lamp at a depth, which is equal to H in range of 0.04÷0.07 of bulb diameter D, wherein recess edges are located on tangential planes K, K1 to burner and passing through bulb axis, and convex outer faces are made with radii R, R1 lying within 0.30÷0.34 of diameter of bulb D. Application of invention in production of gas-discharge mirror sodium lamps will allow to increase light output of lamps due to prevention of falling part of radiation back to burner and to increase service life. When using these lamps in greenhouse illumination, it is possible to increase illumination from mirror lamps by average of 8 % and to increase plant productivity by more than 8 %.

EFFECT: technical result is increase in light output and service life of gas-discharge reflector lamps.

1 cl, 3 dwg

Description

The proposed invention relates to the electrical industry, in particular, improves the design of gas-discharge mirror lamps for general and special lighting purposes.

A gas-discharge mirror lamp is known containing a burner mounted on current leads to a flask, at least half of the inner surface of which is covered with a mirror layer so that the plane passing through its longitudinal edges is parallel to the longitudinal axis of the burner (AS USSR, No. 1636896 A1, 23.03 .91).

This technical solution makes it possible to obtain lamps with high luminous efficiency, with different curves of luminous intensity in the longitudinal and transverse planes, which is important when using lamps for lighting roads, greenhouses, etc.

The disadvantage of the known technical solution is the loss of part of the luminous flux of the lamp, because it is not taken into account that the rays from the burner leave the surface of the burner and absorb light also by the surface of the burner of a certain diameter.

The disadvantage is also the high cost of manufacturing a lamp due to the complexity of manufacturing non-axisymmetric ellipsoidal flasks, uneven wall thickness of the flasks due to the impossibility of rotation of the blowing molds during the production of flasks and a high probability of violation of the integrity of the vacuum lamp flask due to residual internal stresses in the recesses of the glass working to break.

The closest, in technical essence, is a gas-discharge mirror lamp containing a burner mounted on current leads in a flask, the burner axis is located on the longitudinal plane of symmetry of the flask and is displaced from its axis to the mirror coating applied to a part of the inner surface of the flask so that the plane passing through its longitudinal the edge is parallel to the longitudinal axis of the burner (Japan Pat. No. 59230252 dated 12.24.84).

There are practically no internal stresses in the glass of the lamp.

The disadvantage of the technical solution taken as a prototype is the relatively low luminous efficiency of the lamps due to the ingress of part of the reflected rays onto the burner and attenuation in it, overheating of the burner by reflected rays, which reduces the lamp life.

The disadvantage of the technical solution taken as a prototype, when performed on the mirror layer of the transparent section, is the relatively low illumination from the lamp due to the loss of part of the radiation passing through the transparent section, which does not fall on the illuminated surface.

The objective of the invention is to increase the light output of gas-discharge mirror lamps and the service life.

The task is achieved by the fact that in a gas-discharge mirror lamp containing a burner mounted on current leads in a flask, the burner axis is located on the longitudinal plane of symmetry of the flask and is displaced from its axis to the mirror coating applied to a part of the inner surface of the flask so that the plane passing through its longitudinal edges parallel to the longitudinal axis of the burner, the flask is made with a cylindrical diameter D lying within 9.2 ÷ 10.2 of the diameter of the burner d, and in the area of the mirror surface of the flask there is a depression of the V-shaped transverse profile with outward convex edges 9, 10 emanating from the rib 8 , located on the longitudinal plane of symmetry of the lamp at a depth equal to the value of H within 0.04 ÷ 0.07 of the bulb diameter D, and the edges of the recess are on the tangent planes K, K1 to the burner and passing through the axis of the bulb, and the convex outer edges are made with radii R, R1, lying within 0.30 ÷ 0.34 of the diameter of the flask D.

FIG. 1 shows a general view of a gas-discharge mirror lamp in the longitudinal plane of symmetry. Burner 1 is mounted on current leads 4, 5 in a cylindrical flask 2. A mirror layer is applied to the flask, indicated by hatching 3, the border of which is indicated by a dashed line 6. The burner axis is offset from the flask axis towards the mirror layer.

FIG. 2 shows a cross section of the AA lamp. Burner 1 is mounted on a current lead 5, a cylindrical flask 2 with a diameter D equal to 9.2 ÷ 10.2 of a burner diameter d. The mirror layer 3 is applied to the flask so that the plane passing through its longitudinal edges 6, 7 is parallel to the longitudinal axis of the burner. The axis of the burner is located on the longitudinal plane of symmetry of the flask and is offset from the axis of the flask to the mirror layer. On the flask in the zone of the mirror surface, a recess of the V-shaped transverse profile is made in the form of outwardly convex faces 9 and 10 with radii R and R1 lying within 0.30 ÷ 0.34 of the diameter of the flask D. The edges of the recess come from rib 8 located on the longitudinal the plane of symmetry of the lamp, at a depth constituting the value of H within 0.04 ÷ 0.07 of the diameter D of the bulb. The edges of the recess are located on the tangent planes K, K1 to the burner passing through the axis of the bulb.

FIG. 3 is a cross-sectional view of a mirror-coated flask on the part of the inner surface of the flask indicated by dotted lines. The burner in the lamp is displaced from the bulb axis towards the mirror surface. Thin lines indicate rays incident from the center of the burner and reflected rays from the mirror layer of the bulb. For clarity, a thin line shows the reflected surface of the burner from one of the zones of the mirror layer, which does not cross the surface of the burner emitting rays. Below is the curve of luminous intensity of a high pressure sodium lamp type DNaZ 600 in relative units.

The cylindrical shape of the flask makes it possible to manufacture a mold for blowing with a low cost price. the indentation can be defined in two-dimensional space. The cylindrical flask after blowing has a small difference in wall thickness across the glass, although the blowing mold does not rotate during the manufacture of the flasks. The relatively small size of the rib recess allows it to be molded onto a cylindrical flask after the flasks are blown out.

In order to minimize the shading of natural light, the mirror lamp has a compact design with the smallest possible overall dimensions, which is especially important when using lamps in greenhouse lighting.

When the bulb with a diameter D is less than 9.2 of the diameter of the burner d, the operating temperature of the burner increases significantly and the life of the lamp decreases.

When a flask with a diameter D of more than 10.2 of the diameter of the burner d is made, the dimensions of the outer flask significantly increase in relation to the burner, insufficient insulation of the latter is observed, which worsens the lighting characteristics of the lamp, and the time for the lamp to enter the operating mode also increases.

The recess on the flask is made in order to exclude the return of a part of the radiation from the mirror surface back to the burner surface and to form the spatial structure of the light field with the most complete, lossless, uniform light supply to the illuminated surface.

When performing a deepening, the edges of which go beyond the tangent plane K, K1, the area of the recess increases and the residual internal stresses in the glass increase, at which the integrity of the flask is possible.

When making a recess, the edges of which are inside the tangent planes K, K1, part of the reflected rays from the mirror surface of the recess fall on the burner, overheat it, reducing the luminous flux of the lamp.

When making edges 9, 10 with a radius R of more than 0.34 of the diameter of the bulb D, part of the reflected rays from the mirror surface of the recess fall on the burner, overheat it, reducing the luminous flux of the lamp, and in the place of the deepening of the rib, internal stresses in the glass are observed.

When the ribs with a depth H less than 0.04 of the diameter of the bulb D are made, part of the reflected rays from the mirror surface of the recess fall on the burner, overheat it, reducing the luminous flux of the lamp.

When the rib with a depth H of more than 0.07 of the bulb diameter D is made, part of the reflected rays from the mirror surface of the recess fall back onto the mirror surface, reducing the luminous flux of the lamp, and in the place of the deepening of the rib, the occurrence of internal stresses in the glass is observed.

Assembly of lamps is as follows. Previously, a mirror layer is applied to the flask in vacuum on a part of the inner surface of the flask. The legs are connected to the current leads and the burner is connected. The leg is welded into the flask, placing the burner in a strictly defined place relative to the mirror layer. Then a base is attached to the lamp.

The lamp works as follows. Light rays exiting from the burner surface towards the bulb surface without a mirror layer exit the lamp without reflection.

Light rays coming out of the burner surface in the direction of the mirror layer located on the inside of the bulb are reflected from it, pass by the burner surface and are not attenuated in it.

The proposed mirror lamp with a high-pressure sodium burner with a power of 600 W is made in a cylindrical flask with a diameter of 86 mm. The axis of the burner with a diameter of 9.2 mm is displaced from the axis of the lamp towards the mirror layer on the longitudinal plane of symmetry by 12 mm. In the area of the mirror surface of the flask, a recess of the V-shaped transverse profile is made, the edges of which are located on the tangent planes K, K1 to the burner passing through the axis of the flask. The edges of the recess originate from a rib located on the longitudinal plane of symmetry of the lamp, at a depth of 4.2 mm inside the bulb. The convex edges of the recess are made with radii R, R1 equal to 27 mm.

The curves of the light intensity of the gas-discharge mirror sodium lamp in the longitudinal and transverse directions are similar to the serially produced irradiator ZhSP 30-600-015 with a semi-wide light distribution.

The use of the proposed invention in the production of gas-discharge mirror sodium lamps will increase the light output of the lamps by preventing a part of the radiation from falling back onto the burner and increasing the service life.

When using the proposed lamps in greenhouse lighting, it will increase the illumination from mirror lamps by an average of 8% and increase the productivity of plants by more than 8%.

Claims (1)

Gas-discharge mirror lamp containing a burner mounted on current leads in a flask, the burner axis is located on the longitudinal plane of symmetry of the flask and is shifted from its axis to a mirror coating applied to a part of the inner surface of the flask so that the plane passing through its longitudinal edges is parallel to the longitudinal axis of the burner , the flask is made with a cylindrical diameter D, lying within 9.2 ÷ 10.2 of the diameter of the burner d, and in the zone of the mirror surface of the flask there is a deepening of the V-shaped transverse profile with outward convex faces (9), (10) emanating from the rib ( 8), located on the longitudinal plane of symmetry of the lamp at a depth of H in the range of 0.04 ÷ 0.07 of the bulb diameter D, and the edges of the depression are on the tangent planes K, K1 to the burner and passing through the axis of the bulb, and the convex outer edges made with radii R, R1 lying within 0.30 ÷ 0.34 of the diameter of the bulb D.

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