RU116604U1 - LED LAMP - Google Patents

Abstract

1. LED light including:! - at least one body, made in the form of a hollow profile, along the outer perimeter of which there are ribbing plates, and having upper and lower parts, hermetically separated by a heat transfer partition, while the upper part is made both closed and open, and the lower part - only open, while the profiles have grooves for the possibility of their rigid fastening to each other with the help of fasteners,! - installed inside the lower part of the housing on the heat transfer baffle, at least one LED module with LEDs interconnected on a printed circuit board,! - LED power supply installed in the interdisciplinary (near the profile) space of the luminaire body,! - a transparent sealing protective screen attached from below to the bottom of the profile! - and an outer casing attached to the upper part of at least one profile to form at least one hollow space above the upper part,! characterized in that the luminaire additionally has two end caps describing the cross section of at least one profile with an attached outer casing, while they seal the lower part of at least one profile, have ventilation slots or louvers for the upper part, along at least one profile and ventilation slots or louvers for a hollow space between the top of the at least one profile and the attached outer casing; and the outer casing is fastened with a gap to the upper part of at least one profile with the formation of longitudinal holes of the corresponding

Description

The proposed utility model relates to lighting engineering and can be used to build various lamps, both for outdoor use and for indoor use.

Currently, modern powerful LEDs are used in all areas of lighting technology due to their high efficiency, durability, high quality of light, and a positive effect on both humans and plants and animals grown in artificial lighting.

A significant difficulty in the design of LED lighting fixtures is the need to create and maintain hard temperature conditions of the LED (cooling).

Two of the most common methods of cooling LEDs and LED modules are known: forced, natural (convective) and mixed.

One of the most effective cooling methods is the natural or convective cooling method. So, with a correctly designed housing with passive cooling elements — radiator profiles and convection slots — openings, the lamp will work efficiently for its entire service life within the specified thermal limits. Such lamps are known.

Known LED lamp RU 102748 U1 from 03/10/2011, in which the housing is made in the form of a hollow profile, on the outer perimeter of which there are fins. The profile has upper and lower parts, separated by a hermetically heat-transmitting partition, while the upper part is closed and the lower part is only open. Inside the case, a LED module is installed on the heat transfer partition below - a printed circuit board with LEDs interconnected and the power supply. A transparent protective shield is attached to the bottom of the profile from below. The disadvantage of an LED luminaire is the following factor: so if solar radiation enters its surface, due to the absence of an external casing from above, it will be uncontrollably overheated and, as a result, electronic components can quickly fail. In addition, in this case, in the luminaire, the internal convection flows of hot air at the outlet can stagnate, which also leads to overheating of the luminaire.

The closest technical solution to the proposed lamp is a LED lamp RU 104281 U1 from 05/10/2011. This lamp includes:

- at least one body, made in the form of a hollow profile, on the outer perimeter of which there are fins, and having upper and lower parts separated by a hermetically heat-transmitting partition, the upper part being closed and the lower part only open;

- installed inside the lower part of the housing, from below on the heat transfer partition, at least one LED module - a printed circuit board with LEDs interconnected, and a power supply unit mounted on or in the upper part;

- a transparent protective shield attached from below to the bottom of the profile;

- and an outer casing, attached to the upper part of at least one profile, with the formation above the upper part of at least one profile of a hollow enclosed space.

Due to the lack of a system of ventilation ducts and slots in this lamp housing, internal convection flows of hot air are not distributed and stagnated (especially when the lamp is horizontal), which may cause overheating.

In addition, in the above analogs, the internal cavities in which the LEDs are installed are not sealed and, as a result, dust and moisture can collect on the transparent protective screen and on the surface of the LED lenses.

The proposed present technical solution is intended to eliminate the above disadvantages.

EFFECT: effective distribution of convection air flows inside the luminaire using a housing design containing a perimeter system of blinds or slots.

The technical result is achieved by the fact that the LED lamp includes:

- at least one body made in the form of a hollow profile, on the outer perimeter of which there are fins, and having upper and lower parts separated by a hermetically heat-transmitting partition, the upper part being made both closed and open, and the lower part only open, while on the profiles there are grooves for the possibility of rigid fastening of the bodies to each other with the help of fasteners;

- installed inside the lower part of the housing on the heat transfer partition, at least one LED module is a printed circuit board with LEDs interconnected,

- LED power supply installed in the inter-profile (in the space between the profile and the outer casing) space of the lamp housing;

- a transparent protective shield attached to the bottom of the profile;

- and an outer casing, mounted in the upper part of at least one profile, with the formation above the upper part of at least one profile of an open domed hollow space;

In addition, the luminaire additionally has two end caps that describe the cross section of at least one profile with an outer casing attached to them in their upper part, while they seal the lower part of at least one profile, but have ventilation slots ( blinds) for the upper part of at least one profile and ventilation slots (blinds) for the hollow space between the upper part of at least one profile and the attached external casing, as well as between the profiles themselves and the external casing - in taking into account the use of more than one profile, and the outer casing is mounted in special fastening places in the end caps with observing the gap between the ribs of its lower part and the upper part of at least one profile with the formation of longitudinal ventilation ducts of the corresponding section along the entire length of the profile and the outer casing .

In addition, it is required that at least two lines of ventilation slots (a system of linear longitudinal blinds) exist along the perimeter of the outer plane of the outer casing, under the arch, or the casing is longitudinally perforated with holes.

The heat transfer partition must be made either integrally with the profile, or hermetically inserted into the grooves made for it between the upper and lower parts of the profile.

Preferably, the gap between the lower ribs of the outer casing and the upper part of the at least one profile is 10-20 mm, and the inner space between the outer casing of the upper part of the at least one profile is large for good air exchange and sufficient for installation in this cavity, if necessary, a power source.

Also, in one of the two end caps there is an opening for the output of the luminaire mounting unit to the lighting support or bracket and the supply of electrical wires inside the housing to the power supply, and in the upper part of the profile and heat transfer partition there are corresponding subsequently sealed openings for supplying electrical wires from LED module with LEDs to the power supply.

In essence, the cross section of the upper and lower parts of the profile, together with the heat transfer partition of the radiator type, are cavities truncated from either side by planes and equipped with fins.

When using two or more profiles between them from below, in the longitudinal horizontal plane for aesthetics, a flat plate with optimal perforation is fixed.

The profile of the LED luminaire is mainly made of aluminum or from other effective heat-conducting materials, for example, copper, heat-scattering plastics, etc.

The proposed design is illustrated by drawings.

Figure 1 - the design of the LED lamp with two buildings made in the form of a hollow profile,

Figure 2 - end cap, LED lamp,

Figure 3 - distribution of convection flows in the LED lamp with two buildings made of a hollow profile,

The LED lamp disclosed in FIG. 1 consists of the following elements:

Radiator technological part (1) - housing of hollow profile (s) (radiator) - radiator (s) made of any effective heat-conducting material and consisting of two vertical parts - lower and upper, separated by a sealed heat transfer partition (2) which in an amount of more than one are interconnected by means of fasteners, for example, fastening brackets (3) in a single block design. To further enhance the heat transfer of the partition from the lower section to the upper, it is possible to use an additional radiator on it (partition) from above (not shown in the figures).

The lower part (5) is a light chamber open on the outer plane and from the ends, used to install blocks of lighting elements (not shown in the figures), which are sources of increased heat generation, followed by its sealing with a protective transparent screen along the lower open plane and along the ends end cap (8).

The upper section (4) is a closed hollow space with open ends, which can be closed, and possibly sealed with the same plug (8) as the lower section. According to the configuration of the section, the upper section can be either closed or with an open roof — horizontally along its upper part — to enhance convection and remove heat from the heat transfer partition upward.

Hinged structural elements attached to the housing structure using threaded, adhesive or other joints and methods that create reliable attachment of these elements to the housing or its structural elements:

but). protective transparent sealing screen (7) - any transparent material of the required thickness and strength is used for light transmission and sealing of the lower section, planar or curvilinear-volume form factor, is installed in the lower section of the radiator profile along the entire open longitudinal plane of the lower section and in its dimensions after installation in the section of lighting elements, and the adjacency of the screen to specially protruding ribs or planes of the lower section along the longitudinal plane is sealed with either adhesive and mastics (gluing), or by any clamping elements through an elastic gasket (clamps, brackets, clamping rails or frames on a threaded connection), after which, leaving the lower section open only from the ends.

b) end caps (8), describe the configuration of sections of radiator profiles, are made of any durable material (metal, plastic, etc.) designed for the required static and dynamic load, with the lower pad provided for them to fully fit through the elastic gasket in the ends of the lower (their) section (s) of the radiator profiles for complete sealing of the lower sections from the ends and the upper platform adjacent to the ends of the upper section of the radiator profiles (without sealing them), as well as with the system th slots (louvres) (9), allowing to enhance the heat removal from the heat transfer partition of the light chamber to provide constant natural longitudinal ventilation of both the internal hollow space of the upper (s) section (s) and the inter-profile space (outside) of the group of radiator profiles (in case of application radiator profiles more than one):

- due to the occurrence of the convection effect, the rise of warm air inside the housing and its intense "blowing" through the exhaust louvre system when connected to the electric network and the heat is generated by the working lighting elements - LEDs in the lower section,

- due to the movement and penetration into the body of the air masses of cooler ambient air through a system of supply blinds,

- natural atmospheric pressure, taking into account the installation of lamps at heights of 6 m or more from the illuminated surfaces.

Also, the system of slots or shutters prevents the free penetration of ventilated internal cavities of radiator profiles and the interprofile space of precipitation, dust, foliage, thereby not interfering with heat transfer.

at). external sun-protection casing (10) - is made of any durable material (metal, plastic, etc.) that is designed for the required dynamic load and is a casing in the form of a “vault” (planar or more voluminous) along the entire length of the lamp housing and in its dimensions. The main task is to protect against excessive heating of the radiator elements of the housing profiles in direct sunlight during the daytime, to create and optimize the distribution and movement of convection flows inside the lamp housing. It is mounted on the housing by fixing its lateral end edges in the seats in the end caps mounted on the profiles, with the possibility of additional fixation of this connection by any convenient type of fastening (threaded, adhesive, etc.) and creates a dome-shaped, elongated along the profiles, inner space inside the lamp housing (in the case of profiles - radiators more than one). The longitudinal lower edges of the sun shroud do not touch the radiator part of the profiles, observing the required clearance (11) between it and the shroud for additional “edge” air exchange of the interprofile (underwater) space of the lamp housing. The surface of the sun shroud is perforated by a system of slots or blinds (9) in accordance with the required calculated values of air exchange for more intensive ventilation of the “underwater” space.

d). plate-gate - is made of any technologically suitable material and is a plate with perforation in the form of slots or blinds. It is rigidly (in contact) installed in the lower or middle part of the lamp housing in the interprofile space by fixing in the longitudinal horizontal plane between any radiator fins of adjacent profiles in any available way (only if more than one radiator profiles are used). The main task is to decoratively close the bottom of the interprofile space of the lamp housing, in which the power supply and electrical wiring are located, without obstructing from below the suction of colder air into the housing and, thereby, without deteriorating its thermal properties, the function of an additional mini-radiator is in the case of metal , an obstacle to free penetration into the interprofile space of the body from below dirt and dust. It is possible not to install.

Advantages of the design of the lamp housing.

- This basic design made in a single block of profiles-radiators, with the indicated hinged structural elements, can significantly improve, as well as manage the parameters of the guaranteed removal of excess heat generated by the lighting elements from the profiles-radiators, with the possibility of reducing the material consumption of the main and most expensive element of the lamp housing - profiles-radiators.

- There is a great variability in the manufacture of luminaire designs due to the large depth of supply for heat dissipation of buildings due to the maximum use of natural and the possibility of additional creation of additional forced ventilation (convection) in almost all elements of the lamp housing, as well as the optimal amount of heat removal in a particular lamp can be set or adjusted selective change (increase-decrease) of the passage section of the upper section of the profiles is glad itators and interprofile space by changing the number and cross-sectional area of the blinds used in end caps, a sun-shirt, a sliding plate and a roof of the upper section. T.O. the design of the lamp absolutely meets the requirements of unification and standardization for mass production.

- The design of the luminaire body allows unhindered penetration of air flows into its internal cavity from almost any side, i.e. fully ventilated and less stressful from the standpoint of aerodynamic loads, which increases its strength and satisfies the use of a less powerful bracket for attaching the lamp to the support at a height.

Claims (11)

1. LED lamp, including: - at least one body, made in the form of a hollow profile, on the outer perimeter of which there are fins, and having upper and lower parts hermetically separated by a heat transfer partition, the upper part being made both closed and open, and the lower part only open, while on the profiles there are grooves for the possibility of their rigid fastening together with the help of fasteners, - installed inside the lower part of the housing on the heat transfer partition, at least one LED module with LEDs interconnected on a printed circuit board, - an LED power supply unit installed in the inter-profile (near the profile) space of the lamp housing, - transparent sealing protective shield attached from below to the bottom of the profile - and an outer casing attached to the upper part of at least one profile with the formation above the upper part of at least one profile of the hollow space, characterized in that the luminaire additionally has two end caps that describe the cross section of at least one profile with an external casing attached, while they seal the lower part of at least one profile, have ventilation slots or shutters for the upper part, at least one profile and ventilation slots or louvers for the hollow space between the upper part of the at least one profile and the attached outer casing; and the outer casing is fixed with a gap to the upper part of at least one profile with the formation of longitudinal holes of the corresponding section along the entire length of the profile. 2. The LED lamp according to claim 1, characterized in that on the surface around the perimeter of the outer casing there are at least two rows of ventilation slots or blinds. 3. The LED lamp according to claim 1, characterized in that the heat transfer partition is made integral with the profile. 4. The LED lamp according to claim 1, characterized in that the heat transfer partition is hermetically inserted between the upper and lower parts of the profile. 5. The LED lamp according to claim 1, characterized in that a radiator is additionally installed on top of the heat transfer partition. 6. The LED lamp according to claim 1, characterized in that the inner space between the outer casing and the upper part of at least one profile must correspond to the volume for the necessary air exchange or at least enough to install a power supply in it, while the outer casing is fixed at end caps and does not come in contact with profile elements, forming between it and its lower ribs a ventilation duct into the internal cavity, the height of which is 2-20 mm. 7. The LED lamp according to claim 1, characterized in that in one (of the two) end caps there is an opening for the outlet of the mounting unit to the support and the supply of electrical wires to the power supply, and in the upper part of the profile and heat transfer partition there are correspondingly sealed further openings for the supply of electrical wires from the LED module with LEDs to the power supply. 8. The LED lamp according to claim 1, characterized in that the cross section of the upper part of the profile, together with the heat transfer partition, is a hollow truncated segment. 9. The LED lamp according to claim 1, characterized in that when using two or more profiles from below, in the longitudinal horizontal plane, a flat plate is fixed perforated with slots. 10. The LED lamp according to claim 1, characterized in that the transparent sealing protective shield is made in the form of a planar or curvilinear volumetric form factor. 11. LED lamp according to any one of claims 1 to 10, characterized in that the profile is made of aluminum.