CN220321240U - Heat-insulating underground lamp structure - Google Patents

Abstract

The application discloses thermal-insulated buried lamp structure relates to the technical field of lighting apparatus, including lamps and lanterns body and thermal-insulated pipe, the lamps and lanterns body is located the thermal-insulated pipe, leave the space between lamps and lanterns body lateral wall and the thermal-insulated pipe wall. The application has the effect of improving the effect that the survival problem of peripheral vegetation is influenced by the high temperature generated by the underground lamp.

Description

Heat-insulating underground lamp structure

Technical Field

The application relates to the technical field of illumination appliances, in particular to a heat-insulating buried lamp structure.

Background

At present, the underground lamp is often used as outdoor illumination of squares, outdoor parks and the like, and night scene illumination of parks greening, lawns, fountain water bottoms, square lamp decoration and the like, so that the illumination is added for life. The LED underground lamp has the characteristics of small volume, low power consumption and long service life, and can be used for years after one-time construction.

The patent document in the publication number CN210800918U discloses a waterproof dampproof LED buried lamp which comprises a lamp body with fins on the outer wall, wherein the bottoms of the fins are fixed in a ring cylinder internally provided with desiccant particles, the desiccant is used for absorbing moisture, the lamp body and the ring cylinder are both sleeved and fixed in a box body, and a fan is further arranged at the bottom of the ring cylinder in the box body for radiating heat.

However, in the above proposal, the heat generated by the lamp body is blown out by the fan and is directly transferred to the soil at the periphery of the box body. If the lamp is arranged in a zone with vegetation such as a lawn, the vegetation with the periphery of 10-20 cm can survive for a long time with a height of Wen Mofa, and the overall appearance of greening engineering is affected.

Disclosure of Invention

In order to solve the problem that the survival of peripheral vegetation is affected by the high temperature generated by the underground lamp, so that the whole greening is not attractive, the application provides a heat-insulating underground lamp structure.

The application provides a thermal-insulated buried lamp structure, adopts following technical scheme:

the heat-insulating underground lamp structure comprises a lamp body and a heat-insulating pipe, wherein the lamp body is positioned in the heat-insulating pipe, and a space is reserved between the side wall of the lamp body and the wall of the heat-insulating pipe.

Through adopting above-mentioned technical scheme, during the use, bury the insulating tube in the soil horizon, install lamps and lanterns body to the insulating tube in, the insulating tube plays the effect of isolating heat, and the lamps and lanterns body is at the high temperature that the during operation produced by the isolated at the inside of insulating tube to reduce the circumstances that the heat that lamps and lanterns body produced directly transmitted soil around for, do benefit to the vegetation survival of planting soil around lamps and lanterns.

Optionally, a fixing seat is fixed at one end of the heat insulation pipe far away from the lamp body.

Through adopting above-mentioned technical scheme, during the use, the fixing base buries in the soil horizon, and the insulating tube inserts in the fixing base fixedly, and the fixing base can make the insulating tube fix in working position steadily, plays the effect of supporting lamps and lanterns.

Optionally, one end of the heat insulation pipe penetrates into and is fixed in the fixing seat, and a coarse sand layer is filled in the heat insulation pipe.

Through adopting above-mentioned technical scheme, the thick sand layer can absorb the heat that produces by lamps and lanterns body during operation in the heat insulating tube, simultaneously, and the heat insulating tube inserts thick sand layer, and thick sand layer can be to playing the further fixed effect of heat insulating tube.

Optionally, the one end mouth of pipe department that the thick sand layer was kept away from to the insulating tube is provided with the installation section of thick bamboo, installation section of thick bamboo one end wears to locate in the insulating tube, the mounting hole has been seted up to installation section of thick bamboo inside, the lamps and lanterns body sets up in the mounting hole.

Through adopting above-mentioned technical scheme, the lamps and lanterns body can be through installing in the installation section of thick bamboo to realize fixing in the heat insulating tube, simultaneously, the installation section of thick bamboo also can separate lamps and lanterns body and heat insulating tube, increases the heat dissipation space of lamps and lanterns.

Optionally, one end of the installation cylinder far away from the soil layer is provided with a waterproof cover, the waterproof cover is provided with a through hole, and the through hole is embedded with a reinforced glass layer.

By adopting the technical scheme, the waterproof cover can protect and seal the lamp body, so that the possibility that the lamp is damaged by foreign objects is reduced. Meanwhile, the light rays emitted by the lamp can be transmitted out from the reinforced glass layer embedded in the waterproof cover.

Optionally, the mounting hole internal fixation has first waterproof pad, first waterproof pad sets up between mounting hole and lamps and lanterns body and offsets tightly with lamps and lanterns body outer wall.

Through adopting above-mentioned technical scheme, first waterproof pad makes lamps and lanterns body position more stable through frictional force, simultaneously, and first waterproof pad can also play sealed effect, reduces external moisture and gets into inside the lamps and lanterns and cause lamps and lanterns damage.

Optionally, a water leakage groove is formed in the waterproof cover, an extending edge is arranged on the outer wall, close to one end of the waterproof cover, of the mounting cylinder, and a water leakage hole communicated with the water leakage groove is formed in the extending edge.

Through adopting above-mentioned technical scheme, through the water leakage groove on the waterproof cover and the hole that leaks that is linked together with it, can introduce the external water in the thermal-insulated pipe, store in the thermal-insulated pipe bottom, utilize the heat-conducting property of water to absorb the heat in the thermal-insulated pipe.

Optionally, the installation section of thick bamboo is kept away from waterproof cover one end and is provided with the base, a plurality of louvres have been seted up to the base, and the base is kept away from lamps and lanterns body one side and is fixed with the heat conduction pole, the thick sand in heat insulating tube bottom is inserted to heat conduction pipe one end in situ.

By adopting the technical scheme, the base can isolate the lamp body, so that the condition that water introduced from the outside enters the lamp body is reduced; the radiating effect of the lamp can be enhanced through the radiating holes, and meanwhile, the heat generated by the lamp can be transferred to the coarse sand layer and water introduced from the outside through the heat conducting rod, so that the radiating effect is further enhanced.

Optionally, a water stop plate is fixed in the heat insulation pipe, the heat conduction rod penetrates through the water stop plate, a second waterproof pad is arranged at the joint of the water stop plate and the heat conduction rod, a water leakage pipe communicated with the water leakage hole is fixed on the mounting cylinder, and the water leakage pipe penetrates through the water stop plate and is connected with the water stop plate in a sealing mode.

By adopting the technical scheme, the water-stop plate further isolates the lamp body from water in the heat-insulating pipe, and the water leakage pipe guides water introduced from the outside into the heat-insulating pipe, so that the influence of water flow on the lamp body is reduced.

Optionally, water seepage holes are formed in the wall of the heat insulation pipe, and the water seepage holes are located on one side, away from the waterproof cover, of the waterproof plate.

By adopting the technical scheme, when the water in the heat insulation pipe is more and the water level reaches the water seepage hole, the water in the pipe can be discharged out of the heat insulation pipe through the water seepage hole, and the water in the surrounding soil is supplemented, so that the water level in the heat insulation pipe is kept below the water seepage hole; when more moisture exists in the soil, the moisture can enter the heat insulation pipe through the water seepage holes for storage.

In summary, the present application includes at least one of the following beneficial effects:

1. the heat insulation pipe is sleeved outside the lamp body, so that heat generated by the lamp body is isolated in the heat insulation pipe, the condition that the heat generated by the lamp is directly transferred to surrounding soil is reduced, and the growth of vegetation around the lamp is facilitated;

2. by introducing external moisture into the heat insulation pipe, the absorption of heat in the pipe can be enhanced, so that the temperature in the pipe is reduced;

3. through setting up the heat conduction pole in lamps and lanterns bottom, and heat conduction pole inserts pipe bottom aquifer and thick sand layer for absorb the heat that lamps and lanterns produced, further accelerate the decline of intraductal temperature.

Drawings

FIG. 1 is a schematic side sectional view of example 1 of the present application;

FIG. 2 is a schematic side cross-sectional view of example 2 of the present application;

FIG. 3 is a schematic view showing the structure of a water leakage groove of a waterproof cover according to example 2 of the present application;

fig. 4 is a schematic view showing a water leakage hole structure of a mounting cylinder according to example 2 of the present application.

Reference numerals illustrate: 1. a heat insulating pipe; 11. water seepage holes; 2. a lamp body; 3. a fixing seat; 4. coarse sand layer; 5. a mounting cylinder; 51. a mounting hole; 52. an extension edge; 53. a water leakage hole; 54. a heat radiation hole; 55. a base; 6. a first waterproof pad; 7. a waterproof cover; 71. a water leakage groove; 72. strengthening the glass layer; 8. a water leakage pipe; 9. a water-stop plate; 10. a heat conduction rod; 12. a second waterproof pad; 13. a soil layer; 14. an aquifer; 15. and a greening belt layer.

Detailed Description

The present application is described in further detail below in conjunction with figures 1-4.

Example 1:

the embodiment 1 of the application discloses a thermal-insulated buried lamp structure, refer to fig. 1, a thermal-insulated buried lamp structure includes lamps and lanterns body 2, thermal-insulated pipe 1 and fixing base 3, thermal-insulated pipe 1 is the PVC pipe, the fixing base 3 internal fixation is inserted to thermal-insulated pipe 1 one end, and thermal-insulated pipe 1 inserts the one end of fixing base 3 and buries soil horizon 13 together with fixing base 3 in, and wears to establish in fixing base 3, fixing base 3 is for pouring at thermal-insulated pipe 1 outlying concrete layer, can strengthen the stability of thermal-insulated pipe 1. The rough sand layer 4 is paved inside one side of the heat insulation pipe 1 close to the fixed seat 3, and can absorb heat generated by the lamp body 2 in the heat insulation pipe 1. The other end pipe orifice of the heat insulation pipe 1 is vertically upwards and extends out of the soil layer 13 and is positioned in the greening belt layer 15, and the lamp body 2 is fixed in the pipe orifice. The heat insulation pipe 1 isolates a space between the lamp body 2 and the soil layer 13, so that heat generated by the lamp body 2 is reduced to be directly transferred to the soil layer 13.

The pipe orifice that the thermal-insulated pipe 1 stretches out soil layer 13 one end department is fixed and is provided with installation section of thick bamboo 5, and an organic whole is connected with on the outer wall of installation section of thick bamboo 5 one end and extends along 52, and installation section of thick bamboo 5 main part wears to locate thermal-insulated pipe 1 pipe orifice department, and extends along 52 and thermal-insulated pipe 1 joint fixedly, and installation section of thick bamboo 5 is kept away from fixing base 3 one end and is provided with waterproof cover 7, waterproof cover 7 and extends along 52 and pass through the screw thread and dismantle the connection. The installation hole 51 is formed in the installation barrel 5 of the waterproof cover 7, the lamp body 2 is fixedly installed in the installation hole 51, the waterproof cover 7 can play a role in protecting the lamp, and the damage caused by external impact to the lamp is reduced. Meanwhile, a through hole is formed in the waterproof cover 7, a reinforced glass layer 72 is embedded in the through hole, and light rays emitted by the lamp body 2 can be emitted through the reinforced glass layer 72.

Be provided with first waterproof pad 6 between lamps and lanterns body 2 and mounting hole 51 inner wall, first waterproof pad 6 is the rubber waterproof pad, and first waterproof pad 6 supports tightly mounting hole 51 inner wall and lamps and lanterns body 2 respectively, can fix lamps and lanterns body 2's position through the frictional force of first waterproof pad 6 to reduce the inside condition of external moisture entering lamps and lanterns body 2, thereby extension lamps and lanterns life.

The implementation principle of the heat-insulating underground lamp structure in the embodiment 1 of the application is as follows: the soil layer 13 is buried into to thermal-insulated pipe 1 one end, and fix in concrete layer, the coarse sand layer 4 of laying in the thermal-insulated pipe 1 of burying soil layer 13 one end is used for absorbing heat, and thermal-insulated pipe 1 other end mouth of pipe is higher than soil layer 13, and lamp body 2 cover is established in mounting hole 51 of mounting tube 5, and then fixes in thermal-insulated pipe 1, and the inner space of thermal-insulated pipe 1 keeps apart lamp body 2 and surrounding soil to reduce the condition that the heat that lamp body 2 produced directly transmits for surrounding soil.

Example 2:

example 2 and example 1 of the present application differ in that: referring to fig. 2 and 3, the waterproof cover 7 is provided with an arc-shaped water leakage groove 71, and the water leakage groove 71 penetrates the waterproof cover 7.

Referring to fig. 2 and 4, a water leakage hole 53 communicating with the water leakage groove 71 is formed in the extension edge 52, and a water leakage pipe 8 is also connected to the extension edge 52 at a side close to the bottom of the water leakage hole 53 in a sealing manner. Outside rainwater passes through the water leakage groove 71 to the water leakage hole 53 and then is introduced into the heat insulation pipe 1 through the water leakage pipe 8, and the outside rainwater can be stored in the heat insulation pipe 1 to form the water storage layer 14 so as to enhance the heat absorption capacity in the heat insulation pipe 1.

Referring to fig. 2, a base 55 is disposed at the bottom of the mounting hole 51 of the mounting cylinder 5, and a plurality of heat dissipation holes 54 are formed in the base 55, so that heat generated by the lamp body 2 can be partially discharged into the heat insulation tube 1 through the heat dissipation holes 54. The heat insulation pipe 1 is internally provided with a water-stop plate 9 and a heat conduction rod 10 at the lower part of the installation cylinder 5, the water-stop plate 9 is clamped in the heat insulation pipe 1, one end of the heat conduction rod 10 is detachably connected with the base 55 through threads, the other end of the heat conduction rod penetrates through the water-stop plate 9 and is inserted into the water storage layer 14 and the coarse sand layer 4 at the bottom of the heat insulation pipe 1, and a second waterproof pad 12 is fixed at the joint of the heat conduction rod 10 and the water-stop plate 9 and is also a rubber waterproof pad. The heat conducting rod 10 can absorb heat generated by the lamp body 2 during working and transfer the absorbed heat into the water storage layer 14 and the coarse sand layer 4 at the bottom of the heat insulating tube 1, so that the temperature in the heat insulating tube 1 is effectively reduced. The water leakage pipe 8 penetrates through the water isolation plate 9 and is in sealing connection with the water isolation plate 9, the water isolation plate 9 separates the lamp body 2 from the water storage layer 14 at the bottom of the heat isolation pipe 1, and the influence of moisture on the lamp body 2 is reduced.

The heat insulation pipe 1 is provided with a plurality of water seepage holes 11 on the pipe wall of the lower part of the water insulation plate 9, water in the heat insulation pipe 1 can seep out through the water seepage holes 11 and is supplemented into soil around the heat insulation pipe 1, peripheral vegetation can supplement water, external water can enter the heat insulation pipe 1 through the water seepage holes 11 for storage, and in order to reduce the water entering the heat insulation pipe 1, in other embodiments of the application, a layer of geotechnical cloth can be sleeved outside the heat insulation pipe 1.

The foregoing are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in any way, therefore: all equivalent changes in structure, shape and principle of this application should be covered in the protection scope of this application.

Claims (7)

1. The utility model provides a thermal-insulated buried lamp structure which characterized in that: the lamp comprises a heat insulation pipe (1) and a lamp body (2), wherein the lamp body (2) is positioned in the heat insulation pipe (1), and a space is reserved between the side wall of the lamp body (2) and the wall of the heat insulation pipe (1);

one end of the heat insulation pipe (1) far away from the lamp body (2) is fixed with a fixed seat (3), one end of the heat insulation pipe (1) penetrates into and is fixed in the fixed seat (3), and a coarse sand layer (4) is filled in the part of the heat insulation pipe (1) fixed in the fixed seat (3);

the heat insulation pipe is characterized in that an installation cylinder (5) is arranged at a pipe orifice at one end of the heat insulation pipe (1) far away from the coarse sand layer (4), one end of the installation cylinder (5) is arranged in the heat insulation pipe (1) in a penetrating mode, an installation hole (51) is formed in the installation cylinder (5), and the lamp body (2) is arranged in the installation hole (51).

2. The insulated underground lamp structure of claim 1, wherein: one end of the mounting cylinder (5) far away from the soil layer (13) is provided with a waterproof cover (7), the waterproof cover (7) is provided with a through hole, and a reinforced glass layer (72) is embedded in the through hole.

3. The insulated underground lamp structure of claim 1, wherein: the mounting hole (51) is internally fixed with a first waterproof pad (6), and the first waterproof pad (6) is arranged between the inner wall of the mounting hole (51) and the lamp body (2) and is abutted against the outer wall of the lamp body (2).

4. The insulated underground lamp structure of claim 2, wherein: the waterproof cover (7) is provided with a water leakage groove (71), the outer wall of the installation cylinder (5) close to one end of the waterproof cover (7) is provided with an extension edge (52), and the extension edge (52) is provided with a water leakage hole (53) communicated with the water leakage groove (71).

5. The insulated underground lamp structure of claim 4, wherein: the waterproof lamp is characterized in that a base (55) is arranged at one end, far away from the waterproof cover (7), of the mounting cylinder (5), a plurality of radiating holes (54) are formed in the base (55), a heat conducting rod (10) is fixed on one side, far away from the lamp body (2), of the base (55), and one end of the heat conducting rod (10) is inserted into a coarse sand layer (4) at the bottom of the heat insulating pipe (1).

6. The insulated underground lamp structure of claim 5, wherein: the heat insulation pipe is characterized in that a water stop plate (9) is fixed in the heat insulation pipe (1), the heat conduction rod (10) penetrates through the water stop plate (9), a second waterproof pad (12) is arranged at the joint of the water stop plate (9) and the heat conduction rod (10), a water leakage pipe (8) communicated with a water leakage hole (53) is fixed on the mounting cylinder (5), and the water leakage pipe (8) penetrates through the water stop plate (9) and is connected with the water stop plate (9) in a sealing mode.

7. The insulated underground lamp structure of claim 6, wherein: the wall of the heat insulation pipe (1) is provided with water seepage holes (11), and the water seepage holes (11) are positioned on one side, far away from the waterproof cover (7), of the waterproof plate (9).