Patent Description:
In order to solve the glare problem of the existing lamps, a line-shaped (linear) light source is used to replace the conventional point-like light source. The main procedure to implement such a configuration is as follows: an optical diffusion film is interspersed to the lampshade to form a line-shaped (linear) light source. The light of this kind of lamp passes through the lens, optical diffusion film and lampshade, resulting in a large loss of optical efficiency of the lamp. Optical efficiency may be only about <NUM>. Another problem is that the light passes through the lens and then passes through the lampshade with a micro-convex lens structure. Although the optical efficiency of this kind of configuration is higher than that of the previous form, only a certain improvement can be achieved, as the optical efficiency will only be of the order of about <NUM>. In this configuration, the light still passes through a two-layer structure, which cannot meet the actual demand for higher optical efficiency of lamps in display cabinets.

<CIT> discloses a lamp embodied as a line source lighting lamp according to the preamble of claim <NUM>. The line source lighting lamp adopts a strip-shaped convex lens array that diffuses light from the point light sources only in the length direction of the lamp holder to form a line source. On a plane perpendicular to the length direction of a LED light fixture, a reflection wall may be provided on both sides of the point light source for reflecting the lateral light from the point light source to the light incident plane of the strip-shaped convex lens array. A diffuse reflector plate is not disclosed.

<CIT> discloses a display cabinet comprising at least one lamp for use in a display cabinet.

It is an object of the present invention to provide a lamp for use in a display cabinet, which enables a higher optical efficiency to thereby overcome the afore-mentioned deficiencies of conventional lamps of low optical efficiency of the array-type for display cabinets.

This problem is solved by a lamp for use in a display cabinet as claimed in claim <NUM>, and by a display cabinet as claimed in claim <NUM>. Further advantageous embodiments are the subject-matter of the dependent claims.

A lamp for use in a display cabinet according to the present invention can meet the actual needs with an efficient and low-cost configuration, and enables in particular a high optical efficiency for display cabinets.

A lamp for use in a display cabinet comprises: a bracket, arranged on a bottom plate of the display cabinet; a circuit board, provided on the bracket; a plurality of point-like light sources arranged on the circuit board at intervals along the length direction of the circuit board, preferably at equidistant intervals. A lens structure extends (is arranged) along the length direction of the circuit board and is disposed in the light output direction of the plurality of point-like light sources and is connected with the bracket to cover the plurality of point-like light sources. The lens structure comprises an integrally formed light distribution lens and a lens array for extending respective two adjacent point-like light sources of the plurality of point-like light sources to form a line (linear-shaped) light source. The lamp further comprises a first reflector provided on a first side of the lens structure and a second reflector provided on a second side of the lens structure opposite to the first side, each of the first and second reflector extending in the longitudinal direction, wherein the first reflector, the second reflector and the lens structure enclose an accommodating space accommodating the plurality of the point-like light sources.

According to the present invention, the first reflector is a diffuse reflector plate and the second reflector is a non-transparent lens integrally formed with the lens structure.

According to a further embodiment, the light distribution lens and the lens array are both convex lenses.

According to a further embodiment, the bracket is provided with a support plate extending toward the circuit board, wherein the first reflector is attached to the support plate.

According to a further embodiment, the first reflector is formed integrally with the lens structure and the first reflector is provided with a connecting portion connected with the bracket and a reflection portion extending toward the plurality of point-like light sources.

According to a further embodiment, the bracket is provided with a plug-in board extending toward the lens structure, and one end of the first reflector is inserted with the plug-in board, and the other end abuts on the circuit board.

A display cabinet according to the present invention comprises at least one lamp as described above and hereinunder in more details.

The technical scheme of the present invention has the following advantages:.

In order to more clearly illustrate the specific embodiments of the present invention or the technical solutions as compared to the prior art, the following will briefly introduce the accompanying drawings that need to be used in the description of the specific embodiments or the prior art. Obviously, the following descriptions of the accompanying drawings are some embodiments of the present invention. For those of ordinary skill in the art, other drawings can also be obtained based on these drawings without creative efforts.

The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are a part of the embodiments of the present invention, and the present invention shall not be construed to be delimited to only these specific embodiments.

As shown in <FIG> and <FIG>, a specific embodiment of the lamp for use in a display cabinet includes a bracket <NUM> configured to be arranged horizontally on the bottom plate of a display cabinet (not shown). In particular, the bracket <NUM> may include a more or less flat, planar surface for mounting on such a bottom plate of a display cabinet. The lamp further comprises a circuit board <NUM> and a lens structure arranged on the bracket <NUM>, and a plurality of point-like light sources <NUM> arranged on the circuit board <NUM> at intervals, preferably at equidistant intervals, along the length direction of the circuit board <NUM>.

The bracket <NUM> is integrally processed and preferably made of aluminum. The bracket <NUM> includes a base <NUM> for fixing with the bottom plate of the display cabinet, a support portion <NUM> for installing the circuit board <NUM>, and a first installation portion <NUM> and a second installation portion <NUM> for connecting with the two ends of the lens structure respectively. The base <NUM> preferably has a flat, planar surface, and is configured to match the bottom plate of the display cabinet. The support portion <NUM> may be formed as an integrally formed boss or protrusion, and preferably includes a groove for accommodating an end surface of the circuit board <NUM> for mounting. The circuit board <NUM> may be tightly accommodated in such a groove. Moreover, the first installation portion <NUM> and the second installation portion <NUM> are preferably grooves integrally formed with the bracket. More specifically, the first and second installation portion <NUM>, <NUM> may be configured to accommodate a respective end surface of the lens structure in a form-fitting manner, in particular by snap-fitting.

The circuit board <NUM> is a printed circuit board mounted on the support portion <NUM> of the bracket <NUM> Each point-like light source <NUM> may be an LED chip.

The lens structure extends along the length direction of the circuit board <NUM> and is disposed in the light output direction of the point-like light sources <NUM> and connected with the bracket <NUM> to cover a plurality of the point-like light sources <NUM>, thereby reducing the lampshade setup and volume. The lens structure includes an integrally formed light distribution lens <NUM> of an appropriate shape for light distribution and a lens array <NUM> for extending two adjacent point-like light sources <NUM> to form a line-shaped light source. Specifically, the light distribution lens <NUM> and the lens array <NUM> are both convex lenses, which are processed and formed by an extrusion process, particularly a plastic extrusion process. One end of the light distribution lens <NUM> connected with the bracket <NUM> may be provided with a protruding portion <NUM>, and the protruding portion <NUM> may be inserted in a form-fitting manner into the first installation portion <NUM> of the bracket <NUM> to be fixed at least in a direction in parallel with the light output direction. The lens array <NUM> is arranged on the light exit surface of the light distribution lens <NUM>. As an alternative, the lens array <NUM> may also be arranged on the light entrance surface of light distribution lens <NUM>.

In order to improve the optical light efficiency of the lamp, reflection structures are arranged on each of the opposite sides of the lens structure along the length direction of the circuit board <NUM>, namely the first reflector <NUM> and the second reflector <NUM>. As shown in <FIG>, the first reflector <NUM> and second reflector <NUM> are each linear structure extending along the length direction of the bracket <NUM>. As shown in <FIG>, the first reflector <NUM>, the second reflector <NUM> and the lens structure enclose an accommodating space for the plurality of the point-like light sources <NUM>, which is more or less of triangular shape, if viewed in a cross-sectional view and extends along the length direction of the bracket <NUM>.

More specifically, the first reflector <NUM> is a diffuse reflector plate and the second reflector <NUM> is a non-transparent lens integrally formed with the lens structure, which may be accomplished e.g. by means of a two-color extrusion process. Preferably, the lens structure is a transparent part and the second reflector <NUM> is a white part. Most of the light emitted by the point-like light sources <NUM> is guided to the far end of the illuminated surface through the light distribution lens <NUM>. The first reflector <NUM> and the second reflector <NUM> reflect a small portion of the light not received by the light distribution lens <NUM> and then emit or guide this light portion towards and through the light distribution lens <NUM> so that it is guided towards the near end of the illuminated surface.

As shown in <FIG>, a first plug portion <NUM> may be provided at an end of the second reflector <NUM>, which is preferably formed of a plastic material and includes a resilient hook that extends into a groove provided at the second installation portion <NUM>. More specifically, the first plug portion or its resilient hook may be snap-fitted into the groove shown in <FIG>, and grips behind a corresponding protrusion formed in the second installation portion <NUM> of the bracket <NUM>, so as to install and fix the lens structure with the bracket <NUM>.

In order to prevent dust from entering the accommodating space, an end cover <NUM> may be provided at each end of the bracket <NUM>, and each end cover <NUM> may be detachably connected to the bracket <NUM>, e.g. by means of screws.

As shown in <FIG>, the bracket <NUM> is provided with a support plate <NUM> extending toward the circuit board <NUM>, and the support plate <NUM> is connected with the first installation portion <NUM> and is set at an angle without contacting the circuit board <NUM>. The first reflector <NUM> is attached to the support plate <NUM>, e.g. by means of an adhesive. The supporting plate <NUM> and the first reflecting plate <NUM> are inclined and extend towards the point-like light sources <NUM> to collect the light emitted by the point-like light sources <NUM> away from the irradiating surface as much as possible, and the reflected light is emitted through the light distribution lens <NUM> to minimize the energy loss and improve the light efficiency. According to a further embodiment, the first reflector <NUM> may also be replaced by diffuse paper.

In the second embodiment as shown in <FIG>, the first reflector <NUM> is integrally formed with the lens structure, and the first reflector <NUM> is provided with a connecting portion <NUM> connected with the bracket <NUM>. The front end of the connecting portion may be formed as a resilient hook, configured to be snap-fitted into a groove of the first installation portion. The reflection portion <NUM> extends toward the point-like light source <NUM>. The connecting portion <NUM> of the first reflector <NUM> is inserted into the first installation portion <NUM> of the bracket <NUM>, more particularly into a groove disposed therein, to be fixed. The connecting portion <NUM> may approximately horizontally arranged, and the reflection portion <NUM> is arranged obliquely.

As to the third embodiment as shown in <FIG>, the bracket <NUM> is provided with a plug-in board <NUM> extending toward the convex lens structure, and one end of the first reflector <NUM> is provided with a second plug-in portion <NUM> which is fixed with the plug-in board <NUM> in a form-fitting manner, and the other end abuts on the circuit board <NUM>. One end of the light distribution lens <NUM> connected with the bracket <NUM> is provided with a protruding portion <NUM>, which is inserted into the first installation portion <NUM> of the bracket <NUM> and fixed, more specifically into a groove provided therein.

The present invention also provides a display cabinet, which includes the lamp used for the display cabinet, and the display cabinet is a vertical freezer, a refrigerator, and the like.

Claim 1:
A lamp for use in a display cabinet, comprising:
a bracket (<NUM>) configured to be arranged on a bottom plate of the display cabinet;
a circuit board (<NUM>) provided on the bracket (<NUM>);
a plurality of point-like light sources (<NUM>) arranged on the circuit board (<NUM>) at intervals along the length direction of the circuit board (<NUM>);
a lens structure (<NUM>) extending along the length direction of the circuit board (<NUM>) and disposed in the light output direction of the plurality of point-like light sources (<NUM>), wherein
the lens structure (<NUM>) is connected with the bracket (<NUM>) to cover the plurality of the point-like light sources (<NUM>) and comprises an integrally formed light distribution lens (<NUM>) and a lens array (<NUM>) for extending respective two adjacent point-like light sources (<NUM>) of the plurality of point-like light sources (<NUM>) to form a line light source; wherein
a first reflector (<NUM>) is provided on a first side of the lens structure (<NUM>) and second reflector (<NUM>) is provided on a second side of the lens structure (<NUM>) opposite to the first side, said first reflector (<NUM>) and said second reflector (<NUM>) each extending along the longitudinal direction, and wherein
the first reflector (<NUM>), the second reflector (<NUM>) and the lens structure (<NUM>) enclose an accommodating space accommodating the plurality of the point-like light sources (<NUM>);
characterized in that the first reflector (<NUM>) is a diffuse reflector plate and the second reflector (<NUM>) is a non-transparent lens integrally formed with the lens structure (<NUM>).