RU2231166C2 - Electrodeless lighting fixture with cap - Google Patents

Abstract

FIELD: lighting equipment.

SUBSTANCE: electrodeless lighting fixture includes waveguide to send microwave generated in magnetron, gauze screen connected to output part of waveguide to block microwave and let pass light, lamp located in gauze screen for light emission by creation of plasma under action of microwave and cap mounted on external part of gauze screen so that light generated by amp can be emitted in all directions. Cap has aggregate of small protrusions made in external or internal surfaces.

EFFECT: simplified design and enhanced efficiency of light emission in all directions.

16 cl, 11 dwg

Description

FIELD OF THE INVENTION

The present invention relates to an electrodeless lighting device and, in particular, relates to an electrodeless lighting device with a cap, characterized by a simple design and capable of expanding the illuminated area.

BACKGROUND

Typically, an electrodeless lighting device is a device that emits visible rays or ultraviolet rays by emitting a microwave onto an electrodeless lamp. In addition, an electrodeless lighting device has a longer service life than a device based on an incandescent lamp or a fluorescent lamp and higher light output.

Figure 1 shows a longitudinal section of an electrodeless lighting device according to the prior art.

As shown in the figure, a known electrodeless lighting device includes: a housing 10; a high voltage generator 20 mounted in the housing 10 for generating a high voltage; a magnetron 30 mounted in the housing 10 at a distance from the high-voltage generator 20, for generating a microwave using a high-voltage voltage generated by the high-voltage generator 20; a waveguide 40 for guiding the microwave generated in the magnetron 30; an electrodeless lamp 60 protruding forward from the waveguide 40 to emit light when the material filling the lamp 60 transitions to a plasma state under the influence of microwave energy; and a mesh screen 50 covering the lamp 60 in front, for blocking the microwave and transmitting light emitted from the lamp 60.

In addition, the lighting device includes: a mirror 70 mounted on the outlet of the waveguide 40, for forward reflection of the light generated in the lamp 60; and a reflector 80 mounted on the outside of the housing 10 to reflect the light generated in the lamp 60.

On the other hand, the housing 10 includes a lamp motor 90 for rotating the lamp 60 and a lamp axis 91 for connecting the lamp motor 90 to the lamp 60. In addition, a cooling fan 100 is mounted in the housing 10 to remove heat generated in the high-voltage generator 20 and in the magnetron 30 and a fan motor 101 for driving a cooling fan 100. In addition, in the housing 10 there is an air duct 110 for supplying a stream of air generated by the cooling fan 100 to the high-voltage generator 20 and the magnetron 30.

The following describes the operation of an electrodeless lighting device according to the prior art constructed in the above manner.

When the high-voltage generator 20 is connected to a power source, the magnetron 30 generates a microwave by the high voltage generated by the high-voltage generator 20. The microwave generated in the magnetron 30 is transmitted to the mesh screen 50 through the waveguide 40 to create a discharge in the substance filling the lamp 60, as a result what creates a plasma.

The light emitted from the plasma in the lamp 60 is reflected from the mirror 70 and the reflector 80 and is emitted forward.

At the same time, the lamp motor 90 rotates the lamp 60, whereby the lamp 60 is cooled. In addition, the lamp motor 90 rotates the cooling fan 100, whereby the outside air is forced through the duct 110, cooling the high voltage generator 20 and the magnetron 30.

On the other hand, as shown in FIG. 2, the reflector 80 reflecting the light that is generated in the lamp 60 has a parabolic surface portion 81 comprising an open hole 83 formed on the front surface and a connecting portion 82 protruding backward from the portion 81 with a parabolic surface and associated with the housing 10.

The reflector 80 is made using a metal material, and the inner surface of the parabolic surface part 81 is covered with a reflective film.

The connecting part 82 of the reflector 80 is rigidly connected to the housing 10, and the lamp 60 and the mesh screen 50 are located inside the reflector 80.

In addition, the fiber waveguide 120 is of an elongated cylindrical shape with a diameter corresponding to the diameter of the open hole 83 of the reflector, for external and internal lighting by the light generated in the lamp 60, is connected so that it is connected to the open hole 83 of the reflector 80.

In the described design of the lighting device, the light generated in the lamp 60 is reflected by the mirror 70 and the reflector 80, and then enters the light guide 120. External or internal lighting occurs when the light reflected from the mirror 70 and the reflector 80 passes through the light guide 120.

However, according to the known electrodeless lighting device for outdoor or indoor lighting, it is necessary to have a reflector 80 and a light guide 120, in connection with which the initial cost of the product increases. In addition, the reflector 80 and the light guide 120 are very long, and therefore a large installation area is required, and it is limited.

Also, the shape of the reflector 80 must have a parabolic cross section for direct light reflection, as a result of which the reflector 80 is heated by heat coming from the lamp 60, which is located inside the reflector 80. In addition, the life of the device is reduced due to the heat from the reflector 80.

SUMMARY OF THE INVENTION

Thus, the present invention is based on the task of creating a simple-in-construction electrodeless lighting device with a cap that is capable of emitting light in all directions.

The problem is solved in that the electrodeless lighting device includes a waveguide for transmitting microwave energy generated in the magnetron, a mesh screen connected to the outlet of the waveguide to block microwave energy and transmit light, a lamp located in the mesh screen and containing ionizing material for emitting light by creating a plasma under the influence of microwave energy, and a cap mounted on the outer area of the mesh screen with the possibility of emitting light generated in the lamp, in all directions, and the cap contains many small protrusions formed on at least one of the surfaces, internal or external.

The creation of an electrodeless lighting device with a cap makes it possible to minimize the sparkling effect and remove the heat created in it by installing an unevenly reflecting cap around the lamp, and the proposed electrodeless lighting device with a cap is able to protect the cap from deformation or to prevent its life from being reduced due to the heating created by the lamp .

It is desirable that the cap be made in the form of a sphere. It is desirable that the cap be made in the form of a polyhedron. It is desirable that the cap be made using an unevenly reflective material. It is desirable that the light permeability of the cap is 50-95%.

It is desirable that the cap be made using a material that can withstand heating to a temperature of 100 ° C or higher. It is desirable to choose the location of the lamp and the shape of the cap so that the angle of illumination is at least 270 ° around the lamp as a center. It is desirable that the waveguide be fixed on the inside of the case, and the cap is fixed on the outside of the case. It is desirable that the cap includes a passage of a spherical or multifaceted shape through which light passes, and an installation part protruding from the passage in the form of a cylinder and mounted on the housing. It is desirable that the small protrusions are made in the form of a pentahedron.

It is desirable that the small protrusions are made in the form of a hemisphere. It is desirable that the heat blocking element is mounted between the lamp and the cap, next to the lamp, with the possibility of blocking the heat transmitted from the lamp. It is desirable that the heat blocking element includes a plurality of ring-shaped louvres located between the mesh screen and the hood, and a plurality of louvres are connected to each other by a connecting part. It is desirable that the louvre portion expand in the forward direction.

The problem is solved due to the fact that an electrodeless lighting device is proposed, including a waveguide for transmitting microwave energy generated in a magnetron, a mesh screen connected to the outlet of the waveguide to block microwave energy leakage and light transmission, a lamp located in the mesh screen for light radiation by creating a plasma under the influence of microwave energy, a cap mounted on the outer area of the mesh screen, with the possibility of emitting light generated in the lamp, Cex directions, the element blocking the heat is located between the lamp and the cover, next to the lamp, for blocking heat transferred from the lamp.

According to the above-described electrodeless lighting device of the present invention, the design of the lighting device can be simple, and the effect of lighting in all directions can be achieved by mounting the cap around the lamp instead of using a reflector and a light guide.

The above and other features, aspects and advantages of the present invention will become more apparent from the following detailed description of the present invention, taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The accompanying drawings, which are presented here to provide a better understanding of the invention and are an integral part of this description, illustrate embodiments of the invention and together with the description are intended to disclose the principles of the invention. In the drawings:

Figure 1 is a longitudinal section of an electrodeless lighting device according to the prior art;

Figure 2 is a cross section showing the state when the light guide is connected to a known lighting device;

Figure 3 is a longitudinal section of an electrodeless lighting device according to a first embodiment of the present invention;

4 is a cross section showing the operating state of the main parts of an electrodeless lighting device according to a first embodiment of the present invention;

5 is a cross section showing the main parts of an electrodeless lighting device according to a second embodiment of the present invention;

6 is a longitudinal section of an electrodeless lighting device according to a third embodiment of the present invention;

Figures 7 and 8 are views showing various modified versions of an electrodeless lighting device according to a third embodiment of the present invention;

Fig. 9 is a cross-sectional view of an electrodeless lighting device according to a fourth embodiment of the present invention;

10 is a cross-sectional view of an electrodeless lighting device according to a fifth embodiment of the present invention; and

11 is a cross section showing an operational state of an electrodeless lighting device according to a fifth embodiment of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

For details, we now turn to the preferred variants of the present invention, examples of which are shown in the accompanying drawings.

For components matching the same components in the prior art, the same reference numbers are used.

Figure 3 shows a longitudinal section of an electrodeless lighting device according to a first embodiment of the present invention.

As shown in the figure, an electrodeless lighting device according to a first embodiment of the present invention includes: a high voltage generator 20 for generating a high voltage mounted on an inner front surface of the housing 10; and a magnetron 30 located at a predetermined distance from the high-voltage generator 20, for generating a microwave as a result of the high voltage generated in the high-voltage generator 20.

In addition, a waveguide 40 is mounted between the magnetron 30 and the high-voltage generator 20 for transmitting the microwave generated in the magnetron 30, and a mesh screen 50 is mounted on the output portion 41 of the waveguide 40 to form the resonant zone of the microwave transmitted from the waveguide 40.

Here, the mesh screen 50 is made in the form of a cylinder having a mesh structure so as to block the microwave and transmit light.

In addition, a lamp 60 is located inside the mesh screen 50, which is filled with emitting substances, the filling substance may contain a metal that emits light when creating a plasma under the influence of a microwave.

In the housing 10 there is a lamp motor 90 for rotating the lamp 60 and the axis of the lamp 91, which serves to connect the lamp motor 90 to the lamp 60. In addition, a cooling fan 100 and a fan motor 101 are mounted on the housing 10, which drives the fan 100 to remove heat entering from the high voltage generator 20 and the magnetron 30, and the duct 110 for directing the air flow generated by the cooling fan 100, in the direction of the high voltage generator 20 and the magnetron 30.

It is especially important that the cap 130, made in the form of a sphere, is mounted on the front surface of the housing 10 so that it covers the mesh screen 50. Thus, the mesh screen 50 is located inside the cap 130, and the lamp 60 is located in the mesh screen 50.

The spherical cap 130 comprises a passage portion 131 through which light passes outward, and a mounting part 132 protruding from the passage part 131 and connected to the housing 10. Here, the mounting part 132 includes a neck 132a that is worn over the outlet part 41 of the waveguide 40, and at the end of the neck 132a, a flange 132b is formed which extends radially for connection with the housing 10 using a bolt 135 and is fixed to the housing.

It is desirable that the cap 130 be made using an unevenly reflective material, for example a polymer. In addition, it is desirable that the permeability of the material is ~ 50-95% and that the cap can withstand heating to a temperature of 100 ° C or higher.

On the other hand, a mirror 70 is mounted on the rear side of the lamp 60 in the outlet portion of the waveguide 40 to reflect forward the light generated in the lamp 60. The microwave can pass through the mirror 70.

In addition, it is desirable that the location of the lamp 60 and the shape of the cap 130 be selected so that the angle of illumination is 270 °.

The following describes the operation and action of an electrodeless lighting device according to a first embodiment of the present invention.

When the high-voltage generator 20 is connected to an electric power source, the magnetron 30 generates a microwave wave under the influence of the high voltage generated in the high-voltage generator 20. The microwave generated in the magnetron 30 is transmitted to the mesh screen 50 through the waveguide 40, and then a strong microwave electric field is generated in the mesh screen 50, which creates a plasma upon excitation of the substance filling the lamp 60.

The light emitted by the plasma created in the lamp 60 passes through the cap 130, made in the form of a sphere, and then emitted in all directions in the illuminated area. In addition, the light emitted from the lamp back is reflected forward by the mirror 70, and then radiated outward, passing through the cap 130.

Here, the cap 130 is made of uneven reflective material, and therefore, light passing through the cap is unevenly reflected in all directions. Thus, it becomes possible to minimize the effect of sparkling, which can be felt to use, located in the illuminated area.

On the other hand, when a power source is connected, the lamp engine 90 rotates the lamp 60, cooling it. The fan motor 101 also operates by rotating the cooling fan 100, as a result of which external air is pumped into the housing 10 through the duct 100, cooling the high-voltage generator 20 and the magnetron 30.

In an electrodeless lighting device according to the present invention, the light emitted when the substance filling the lamp 60 is converted to a plasma by the action of a microwave has the same characteristics as natural rays, such as visible or ultraviolet rays. As described above, the light generated in the lamp 60 passes through a cap 130 of a spherical shape, as a result of which internal or external illumination is provided in all directions.

Also, the cap 130 is made using an unevenly reflecting material, therefore, the light emitted from the lamp 60 is reflected unevenly passing through the cap 130. As a result, it is possible to minimize the sparkling effect that the user can feel.

Also, according to the present invention, the light generated in the lamp 60 is radiated outwardly using the cap 130, and therefore, illumination in all directions can be provided, and the overall design of the lighting device can be simplified. That is, according to the prior art, the light guide 120 must be located in the lighting device shown in FIG. 1, however, according to the present invention, only a cap 130 is required. Therefore, the overall construction of the lighting device can be simplified.

Figure 5 shows a cross section of the main parts of an electrodeless lighting device according to a second embodiment of the present invention.

The lighting device according to the second embodiment of the present invention has the same construction as the lighting device according to the first embodiment, except for the shape of the cap 140.

That is, the cap 130 in the first embodiment is made in the form of a clean sphere, and the cap 140 in the second embodiment is made in the form of a polyhedron with many planes, as shown in Fig. 5.

The multifaceted cap 140 is also made using an uneven reflective material, as in the first embodiment, and it is desirable that the material has a light permeability of ~ 50-95% and can withstand heating to a temperature of 100 ° C.

Here, the shape of the polyhedral cap 140 is not limited to the shape shown in FIG. 5, but may also have a different shape, for example a hexagon or an octahedron, except for the tetrahedron.

In the electrodeless lighting device according to the second embodiment of the present invention, the light emitted from the lamp 60 is reflected in all directions through the polyhedral cap 140, made in the form of a polyhedron, and irradiates the illuminated area.

Figure 6 shows a longitudinal section of an electrodeless lighting device according to a third embodiment of the present invention.

An electrodeless lighting device according to a third embodiment of the present invention includes: a high voltage generator 20 for generating a high voltage in the housing 10; a magnetron 30 for generating a microwave under the action of a high voltage coming from a high voltage generator 20; and a waveguide 40 for guiding the microwave generated in the magnetron 30.

Also in the housing 10 is a lamp motor 90 and a lamp axis 91 for rotating the lamp 60, a cooling fan 100 and a fan motor 101 for cooling the internal components, as well as an air duct 110.

In addition, a mesh screen 50 with a mesh structure is mounted on the front side of the housing 10, blocking the microwave and transmitting light, which is provided on the outlet portion of the waveguide 40, as well as a lamp 60 in the mesh screen for generating light under the influence of the microwave.

It is especially important that the cap 150 according to the third embodiment of the present invention, unlike the first and second embodiments described above, includes a plurality of small protrusions (E) formed on the outer surface of the cap 150.

The spherical hood 150 has a passage 151 through which the light generated in the lamp 60 passes out as a result of the formation of small protrusions E on the outer surface of the hood 150, and a mounting portion 152 protruding from the passage 151 and connected to the housing 10. Here, the mounting part 152 has the same construction as the mounting part in the first embodiment.

In addition, the small protrusions (E) made on the passage 151 protrude outward in the form of pentagons at the intersections of the vertical (L) and horizontal (N) folds, as shown in FIG. 7.

Here, the vertical folds (L) are made with a predetermined interval between the folds, forming a reference vertical axis that connects the point a on the side where the lamp 60 is located, with the point a ’opposite the point a. In addition, horizontal folds (N) are formed with a predetermined spacing between the folds, forming a horizontal axis at an angle of 90 ° to the reference vertical axis.

It is desirable that the angle at the apex (α) of the small protrusion of the pentagonal shape be ~ 70-130 °, and the distance between the bases should be no more than 5 mm.

A modified example of small protrusions (E) of a pentagonal shape is a small protrusion, which may be in the form of a hemisphere at the intersection of vertical folds (L) and horizontal folds (N), as shown in Fig. 8.

It is desirable that the cap made using an irregularly reflective material, for example a polymer, has a light permeability of 50-95% and can withstand heating to a temperature of 100 ° C or higher.

Figure 9 shows a cross section of the main parts of an electrodeless lighting device according to a fourth embodiment of the present invention.

The design of the electrodeless lighting device according to the fourth embodiment of the present invention is similar to the third embodiment, however, small protrusions (E ’) formed on the cap 160 are formed in a row along the entire inner surface of the cap 160.

The small protrusion (E ’) is made in the form of a pentagon with a vertex or in the form of a hemisphere, as in the third embodiment.

The following describes the operation and action of an electrodeless lighting device according to the third and fourth embodiments of the present invention.

When the microwave generated in the magnetron 30 is transmitted to the mesh screen 50 through the waveguide 40, a light emitting plasma is created in the lamp 60.

The light emitted from the lamp 60 passes through a mesh screen 50 having a mesh structure, and then radiates outward through a cap 150 or 160.

At the same time, small protrusions (E or E ') are formed on the cap 150 or 160, which provide uneven reflection by forming different permeability angles when light passes through the cap 150 or 160. Thus, it becomes possible to reduce the sparkling effect that the user who is in the illuminated area.

In addition, the small protrusions (E or E ’) on the cap 150 or 160 form a significant total surface area, and therefore, the heat dissipation area is large. Thus, the heat generated in the cap 150 or 160 when using the lighting device can be evenly removed, and therefore it is possible to prevent the heating of the lamp 60 and the cap 150 or 160.

FIG. 10 is a cross-sectional view of an electrodeless lighting device according to a fifth embodiment of the present invention, and FIG. 11 is a cross-sectional view showing an operational state of an electrodeless lighting device according to a fifth embodiment of the present invention.

An electrodeless lighting device according to a fifth embodiment of the present invention includes a high voltage generator 20, a magnetron 30, a waveguide 40, a lamp motor 90 and a lamp axis 91, a cooling fan 100 and a fan motor 101, as well as an air duct 110 mounted in a housing having the same structure as in the previously described options.

Also, on the front of the housing 10, a mesh screen 50 and a lamp 60 are mounted, the same as in the previous embodiments.

However, according to a fifth embodiment of the present invention, a heat blocking unit 180 is disposed between the screen 50 and the hood 170 to prevent the hood from being heated by the heat generated in the lamp.

Here, the cap 170 includes a spherical passage 171 and a mounting part 172 protruding from the passage part 171 for fitting onto the outer part 41 of the waveguide 40 and connected to the housing 10.

The mounting portion 172 includes a cylindrical neck 172a and a flange 172b protruding radially from the neck 172a, as shown in FIG. 11. In this case, the neck 172a is made with such an inner diameter that it can be located at some distance from the outlet part 41 of the waveguide 40 so that the louver assembly 180 blocking heat can be mounted.

Turning now to FIG. 11, the heat blocking louvre assembly 180 includes a first ring-shaped louver portion 181 rigidly connected to the housing 10 to block heat by creating a barrier between the mesh screen 50 and the hood 170; a second annular louvre part 183 for blocking heat by creating a barrier between the screen 50 and the hood 170 at some distance from the first louvre part 181; and a connecting part 182 for connecting the first louvered part 181 with the second louvered part 183.

The first louvered part 181 is located between the inner part of the neck 172a in the hood 170 and the outer part of the mesh screen 50, and the second louvered part 183 is located on a straight line that connects the lamp 60 and the neck 172a of the hood 170.

In addition, the connecting parts 182 are formed in the form of a strip, the ends of which are connected to the first louvered part 181 and the second louvered part 183, providing a connection of the first louvered part 181 and the second louvered part 183 with a predetermined distance between them.

Here, the first louvre part 181 and the second louvre part 183 have horizontal parts 181a and 183a formed in the vertical direction along the length of the mesh screen 50, vertical parts 181b and 183b curved with respect to the horizontal parts 181a and 183a and protruding along the length of the mesh screen 50, and inclined parts 181c and 183c extending from the vertical parts 181b and 183b with an inclination towards the expansion side.

In addition, both ends of the connecting part 182 are connected to the horizontal part 181a of the first louvered part 181 and the horizontal part 183a of the second louvered part 183.

The heat blocking louvre assembly 180 has two louvre portions described above, however, one, two or more louvre portions may be formed in accordance with specific conditions.

The following describes the operation and action of an electrodeless lighting device according to a fifth embodiment of the present invention.

During operation of the lighting device during the process of emitting light, the lamp 60 creates heat characterized by high temperature.

The heat generated in the lamp 60, as described above, is blocked by the heat-blocking louver 180, as a result of which intense heating of the cap 170 adjacent to the lamp 60 can be prevented.

That is, the lamp 60 is located directly above the necks 172a of the cap for structural and functional reasons. Therefore, the heat generated by light emitting from the lamp 60 is concentrated on the necks 172a of the cap 170 near the lamp 60 and in the passage 171 connected to the neck 172a.

At the same time, heat entering the neck 172a of the cap 170 and the passage 171 near the neck 172a is reflected by the first louver portion 181 forming the louvre assembly 180, which blocks heat, and then the heat enters the passage part 171 of the cap, which is far from the lamp 60. In this way, deformation or destruction of the cap 170 adjacent to the lamp 60 as a result of intense heating can be prevented.

In addition, the second louvre portion 183 forming the heat blocking louvre assembly 180 reflects forward light energy and heat energy passing through the mesh screen and directs heat blocked by the first louvre portion 181 forward.

Therefore, the heat blocking unit 180 blocks the high temperature heat generated by the llama 60 and thereby prevents deformation or destruction of the hood.

As described above, according to the electrodeless lighting device of the present invention, the cap is mounted around the lamp instead of the reflector and the light guide, as a result of which the design of the lighting device can be simplified and illumination is realized in all directions.

Also, according to the electrodeless lighting device of the present invention, uneven reflection occurs when the light emitted by the lamp passes through the cap, thereby preventing the sparkling effect and comfortable lighting of the environment can be realized.

Also, according to the electrodeless lighting device of the present invention, small protrusions are formed on the inner or outer surface of the hood to increase the surface area of the hood, as a result of which the light may be reflected non-uniformly, and heat dissipation is improved. Therefore, the service life of the product and the reliability of the device can be increased.

Also, according to the electrodeless lighting device of the present invention, a heat blocking louvre assembly is mounted between the cap and the lamp, as a result of which the deformation or collapse of the cap necks can be prevented by the heat generated by the lamp. Thus, the reliability of the device can be improved.

Since the present invention can be embodied in several forms, not going beyond its essence or essential characteristics, it should be borne in mind that the above options are not limited to any of the specific details described above, unless otherwise specified; rather, the invention should rather be interpreted broadly within the spirit and scope defined in the attached claims; therefore, it is intended here that all changes and modifications that do not go beyond the boundaries and limitations of the claims or the equivalents of such boundaries and limitations are encompassed by the appended claims.

Claims (16)

1. An electrodeless lighting device, including a waveguide for transmitting microwave energy generated in a magnetron, a mesh screen connected to the outlet of the waveguide to block microwave energy and transmit light, a lamp located in the mesh screen and containing ionizing material for emitting light by creating a plasma under the influence of microwave energy, and a cap mounted on the outer area of the mesh screen with the possibility of emitting light generated in the lamp in all directions, and the cap It comprises a plurality of small projections formed on at least one of the surfaces, internal or external. 2. The device according to claim 1, in which the cap is made in the form of a sphere. 3. The device according to claim 1, in which the cap is made in the form of a polyhedron. 4. The device according to claim 1, in which the cap is made using an unevenly reflective material. 5. The device according to claim 1, in which the light permeability of the cap is 50 ~ 95%. 6. The device according to claim 1, in which the cap is made using a material that can withstand heating to a temperature of 100 ° C or higher. 7. The device according to claim 1, in which the location of the lamp and the shape of the cap are selected so that the angle of illumination is at least 270 ° around the lamp as a center. 8. The device according to claim 1, in which the waveguide is fixed on the inner side of the housing, and the cap is fixed on the outer side of the housing. 9. The device of claim 8, in which the cap includes a passage of a spherical or multifaceted shape through which light passes, and a mounting portion protruding from the passage in the form of a cylinder and mounted on the housing. 10. The device according to claim 1, in which the small protrusions are made in the form of a pentahedron. 11. The device according to claim 1, in which the small protrusions are made in the form of a hemisphere. 12. The device according to claim 1, in which the element blocking heat is mounted between the lamp and the cap next to the lamp with the possibility of blocking the heat transmitted from the lamp. 13. The device according to item 12, in which the heat blocking element includes a plurality of louvered parts of an annular shape located between the mesh screen and the hood, and a plurality of louvered parts are connected to each other by a connecting part. 14. The device according to item 13, in which the louvered part expands in the forward direction. 15. An electrodeless lighting device, including a waveguide for transmitting microwave energy generated in a magnetron, a mesh screen connected to the outlet of the waveguide to block microwave energy leakage and light transmission, a lamp located in the mesh screen to emit light by creating plasma under the influence of energy microwaves, cap mounted on the outer area of the mesh screen, with the possibility of emitting light generated in the lamp in all directions, the heat blocking element being located bent between the lamp and the cap next to the lamp to block the heat transferred from the lamp. Priority on points: 11/23/2001 according to claims 1-15.

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