CN108343919B - Breathing lamp - Google Patents

Abstract

The invention relates to a breathing lamp which comprises an elastic layer, a frame structure and a plurality of LED lamps; the elastic layer seals the frame structure; and the LED lamps are respectively arranged on the elastic layer. When the LED lamp emits light, the elastic layer can be slowly changed by the generated heat, so that the light emitting direction of the LED lamp on the elastic layer is changed, and the effect similar to breathing change is generated; after the light is emitted for a certain time, the elastic layer swells and expands on the frame structure to form the irradiation effect of the luminous curved surface, the luminous curved surface can be changed variably because the elastic layer is not in a fixed shape, the change is often random until the change is constant, the last change process and the next change process are different and completely the same, and therefore the luminous curved surface has the amorphous irradiation effect, the direction change performance of the illumination is improved, and the luminous curved surface is particularly suitable for hanging or dynamic mounting.

Description

Breathing lamp

Technical Field

The invention relates to the field of LED display, in particular to a breathing lamp.

Background

The light emitting diode, abbreviated As LED, is made of a compound containing gallium (Ga), arsenic (As), phosphorus (P), nitrogen (N), and the like. When electrons and holes are recombined, visible light is radiated, so that the light-emitting diode can be manufactured. In circuits and instruments as indicator lights or to form text or numerical displays. Gallium arsenide diodes emit red light, gallium phosphide diodes emit green light, silicon carbide diodes emit yellow light, and gallium nitride diodes emit blue light. Organic light emitting diodes OLED and inorganic light emitting diodes LED are classified by their chemical properties.

The rapid development of LEDs, which is regarded as important, is not separated from the advantages of LEDs. These advantages are summarized as follows: high brightness, low working voltage, low power consumption, large size, long service life, impact resistance and stable performance. The development prospect of the LED is very wide, and the LED is developing towards the directions of higher brightness, higher weather resistance, higher luminous density, higher luminous uniformity, reliability and full colorization. The LED display screen is widely applied to advertising in different outdoor places such as stadiums, commercial applications, banks, securities, postal service, docks, markets, stations, postal service, telecommunication, offices, monitoring, schools, restaurants, hotels, entertainment and the like.

However, the shape of the conventional LED lamp is often fixed, and after the LED lamp is produced, the irradiation effect is already set, and is not changed.

Disclosure of Invention

Based on this, it is necessary to provide a breathing light fixture.

A breathing lamp comprises an elastic layer, a frame structure and a plurality of LED lamps; the elastic layer seals the frame structure; and the LED lamps are respectively arranged on the elastic layer.

When the LED lamp emits light, the elastic layer can be slowly changed by the generated heat, so that the light emitting direction of the LED lamp on the elastic layer is changed, and the effect similar to breathing change is generated; after the light is emitted for a certain time, the elastic layer swells and expands on the frame structure to form the irradiation effect of the luminous curved surface, the luminous curved surface can be changed variably because the elastic layer is not in a fixed shape, the change is often random until the change is constant, and the previous change process and the next change process are not identical, so that the luminous curved surface has an amorphous irradiation effect, the direction change performance of the illumination is improved, and the luminous curved surface is particularly suitable for hanging or dynamic mounting and is also suitable for fixed mounting.

Further, in one embodiment, a copper layer is further disposed on the elastic layer, and the copper layer is disposed adjacent to the LED lamp.

In one embodiment, the breathing lamp comprises a plurality of elastic layers, the elastic layers jointly seal the frame structure, and at least one LED lamp is arranged on each elastic layer.

In one embodiment, each of the elastomeric layers forms a seal with the frame structure.

In one embodiment, the frame structure and each elastic layer form a sealing structure.

Further, in one embodiment, the frame structure is prism-shaped or polyhedron-shaped.

In one embodiment, the frame structure includes a plurality of support rods.

In one embodiment, the frame structure further comprises a rotating column; one end of each supporting rod is connected with the elastic layer, and the other end of each supporting rod is connected with the rotating column.

In one embodiment, a driving motor connected with the rotating column is further arranged inside the frame structure.

In one embodiment, a connection circuit is further disposed on the elastic layer, and the connection circuit is respectively connected with each of the LED lamps.

In one embodiment, the LED lamp is a surface mount lamp.

In one embodiment, the breathing lamp further comprises an air pump and an air inflation pipeline, one end of the air inflation pipeline is communicated with the inside of the frame structure, and the other end of the air inflation pipeline is communicated with an output end of the air pump.

Drawings

FIG. 1 is a schematic diagram of one embodiment of the present invention.

Fig. 2 is a schematic expansion of the embodiment of fig. 1.

FIG. 3 is a schematic view of one light emitting face of the embodiment shown in FIG. 1.

Fig. 4 is a schematic diagram of another embodiment of the present invention.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the invention herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

One embodiment of the invention is a breathing lamp, which comprises an elastic layer, a frame structure and a plurality of LED lamps; the elastic layer seals the frame structure; and the LED lamps are respectively arranged on the elastic layer. When the LED lamp emits light, the elastic layer can be slowly changed by the generated heat, so that the light emitting direction of the LED lamp on the elastic layer is changed, and the effect similar to breathing change is generated; after the light is emitted for a certain time, the elastic layer swells and expands on the frame structure to form the irradiation effect of the luminous curved surface, the luminous curved surface can be changed variably because the elastic layer is not in a fixed shape, the change is often random until the change is constant, and the previous change process and the next change process are not identical, so that the luminous curved surface has an amorphous irradiation effect, the direction change performance of the illumination is improved, and the luminous curved surface is particularly suitable for hanging or dynamic mounting and is also suitable for fixed mounting.

For example, as shown in fig. 1, the frame structure having the support rod 100 is provided with the elastic layer 300, the elastic layer 300 seals the frame structure to form a sealed cavity 200, and the plurality of LED lamps 400 are disposed on the elastic layer, as shown in fig. 2, after a certain time of light emission, the elastic layer 300 swells and expands on the frame structure. For a breathing light fixture with multiple illumination surfaces, multiple sets of LED lamps may be designed such that each illumination surface has LED lamps arranged in a matrix. In one embodiment, the breathing lamp comprises a plurality of illuminating surfaces formed by the elastic layer and the frame structure and located on the elastic layer, each illuminating surface has a matrix arrangement of LED lamps, for example, as shown in fig. 3, the illuminating surfaces have a matrix arrangement of LED lamps.

In one embodiment, the breathing lamp comprises a plurality of elastic layers, the elastic layers jointly seal the frame structure, and at least one LED lamp is arranged on each elastic layer. In one embodiment, each of the elastomeric layers forms a seal with the frame structure. Alternatively, in one embodiment, the frame structure and each of the elastic layers form a sealing structure.

Further, in one embodiment, the frame structure is prism-shaped or polyhedron-shaped. As shown in fig. 1, the frame structure has a regular octagonal shape. As another example, the frame structure has a 16-sided body shape or a 12-sided body shape.

In one embodiment, the frame structure includes a plurality of support rods. As shown in fig. 1, the frame structure includes eight support rods. As shown in fig. 4, in one embodiment, the frame structure further comprises a rotating column 600; one end of each of the support rods 100 is connected to the elastic layer 300, and the other end of each of the support rods 100 is connected to the rotating column 600. In one embodiment, a driving motor connected with the rotating column is further arranged inside the frame structure. Therefore, the rotary column can be driven to rotate by the driving motor, so that the breathing lamp integrally rotates and has a more dynamic irradiation effect.

In one embodiment, a connection circuit is further disposed on the elastic layer, and the connection circuit is connected to each of the LED lamps, so that each of the LED lamps can be powered through the connection circuit. In one embodiment, the LED lamp is a surface mount lamp, which has the advantages of small size and light weight, and is particularly suitable for being disposed on the elastic layer. Furthermore, a solar thin film battery pack is further arranged on the elastic layer and connected with the connecting lines, and the solar thin film battery pack is used for supplying power to the LED lamps through the connecting lines.

Further, in one embodiment, a copper layer is further disposed on the elastic layer, and the copper layer is disposed adjacent to the LED lamp. As shown in fig. 3, a plurality of copper layers 500 are further disposed on the elastic layer 300, and each copper layer 500 is disposed adjacent to the LED lamp 400. Therefore, the safety problem of the elastic layer caused by excessive heat accumulation can be avoided when the working time is too long. For example, the thickness of the copper layer is 0.04-0.07 mm, and as for the design of the embodiment shown in fig. 3, for a low-power surface-mounted lamp, in an actual test, the temperature of the position where the elastic layer is in contact with the LED lamp can be controlled below 40 ℃, so that the safety and long-term use of the breathing lamp can be ensured.

In one embodiment, the breathing lamp further comprises an air pump and an air inflation pipeline, one end of the air inflation pipeline is communicated with the inside of the frame structure, and the other end of the air inflation pipeline is communicated with an output end of the air pump. Therefore, the air pump can be used for pumping air into the frame structure through the air inflation pipeline so as to enable the breathing lamp to expand rapidly, and the elastic layer can achieve the effect of expansion and deformation rapidly. Furthermore, the breathing lamp further comprises a hydrogen generating device, the hydrogen generating device is communicated with the input end of the air pump, and the hydrogen generating device is used for generating hydrogen and pumping the hydrogen into the frame structure through the air pump, so that the breathing lamp can float in the air. Further, the frame structure is a light hollow structure, such as a carbon fiber hollow structure or an aluminum alloy hollow structure, and only needs to play a supporting role. Further, the elastic layer is a plastic film layer. This facilitates the breathing light fixture to float more easily in the air.

Further, in one of them embodiment, frame construction still sets up the deformation gib block, the elastic layer orientation frame construction's one side with the deformation gib block is connected, for example the elastic layer orientation frame construction's one side with deformation gib block bonding or lock joint, the deformation gib block is used for restricting the deformation direction of elastic layer, so that breathe the lamps and lanterns and be in the elastic layer is heated and can have certain deformation restriction when taking place the inflation, thereby make breathe the lamps and lanterns and can outwards show preset shape when aerifing the inflation or being heated the inflation, for example stars, torch or Santa Claus etc.. For example, the deformation guide strip is a long strip-shaped bamboo strip or a hard plastic strip or a carbon fiber strip, so that the cost can be saved on one hand, and the breathing lamp is not too heavy on the other hand. Further, the frame structure is provided with a plurality of deformation guide strips, each deformation guide strip is at least connected with the other two deformation guide strips in a rotating mode, for example, the deformation guide strips are integrally formed into an umbrella frame structure or a structure similar to the umbrella frame structure, and the breathing lamp can be unfolded outwards when inflated or expanded by heat, so that a preset shape is formed, for example, the shape is similar to umbrella opening or peacock spreading.

Further, in one embodiment, the breathing lamp further comprises a support structure, one end of the support structure is connected with the frame structure, and the other end of the support structure is used for being fixed to the outside to integrally fix the breathing lamp. For example, the support structure has an installation position and a hollow pipe portion, the outer side surface of the pipe portion is connected with the frame structure, one end of the pipe portion is located inside the frame structure, the inflation pipeline is arranged inside the pipe portion, one end of the inflation pipeline is communicated with the inside of the frame structure through the pipe portion, the air pump is fixedly arranged at the installation position, and the output end of the air pump is communicated with the other end of the inflation pipeline. It will be appreciated that the resilient layer seals the connection location of the frame structure to the carrier structure, for example by banding, gluing or plugging. Further, the support structure is provided with a wire groove, and for example, a connection line of each LED lamp extends into the wire groove of the support structure through the surface of the elastic layer. Furthermore, the support structure is further provided with an installation cavity communicated with the wire slot, and the control module of each LED lamp is arranged in the installation cavity and communicated with each connection circuit respectively so as to control each LED lamp.

Further, in one embodiment, the supporting structure is provided with a plurality of extending branches in an extending manner, and each extending branch is provided with at least one festive lantern. The festive lantern comprises a body and at least three petal structures arranged at the edge of the body; the body is provided with a plurality of first sub LED lamps, and each petal structure is provided with at least one third sub LED lamp; the first sub LED lamps are respectively arranged in N rows and N columns, wherein part of the first sub LED lamps are arranged into N rows of first sub LED lamp groups, and part of the first sub LED lamps are arranged into N columns of first sub LED lamp groups; the N rows of first sub-LED lamp groups and 50% of the N columns of first sub-LED lamp groups are arranged in a superposition mode. For example, the geometric centers of the three petal designs are connected to form an equilateral triangle. It can be understood that the sub LED lamps, including the first sub LED lamp, the second sub LED lamp, the third sub LED lamp, the fourth sub LED lamp, the fifth sub LED lamp and/or the sixth sub LED lamp, are names that are different from the LED lamps on the elastic layer, and the nature of the sub LED lamps is a light source that uses the LED chip to emit light; the sub-LED lamps comprise chips, structures, shapes, sizes, powers and the like of a first sub-LED lamp, a second sub-LED lamp, a third sub-LED lamp, a fourth sub-LED lamp, a fifth sub-LED lamp and/or a sixth sub-LED lamp and the like, and the chips, the structures, the shapes, the sizes, the powers and the like can be the same or different. The N rows of first sub-LED lamp groups and the N columns of first sub-LED lamp groups are provided with 50% of the first sub-LED lamps in the first sub-LED lamp groups in a superposition manner, that is, the total number of the first sub-LED lamps in each row of the first sub-LED lamp groups is equal to the total number of the first sub-LED lamps in each column of the first sub-LED lamp groups, and half of the first sub-LED lamps in each row of the first sub-LED lamp groups are provided in a superposition manner with half of the first sub-LED lamps in each column of the first sub-LED lamp groups. Like this, through the luminous design of arranging to body and its sub-LED lamp, can provide the festive lantern illumination when realizing breathing lamps and lanterns illuminating effect, be particularly suitable for landscape lighting design.

Further, in one embodiment, the festive lantern further comprises sub LED lamp control modules, a cavity is further formed in the body, the sub LED lamp control modules are accommodated in the cavity and respectively connected with the first sub LED lamps, and the sub LED lamp control modules are used for simultaneously or respectively controlling the first sub LED lamps; further, when other sub LED lamps exist, the sub LED lamp control module is further connected to each of the sub LED lamps, and the sub LED lamp control module is configured to control each of the sub LED lamps simultaneously or separately. For example, the sub LED lamps include a first sub LED lamp, a second sub LED lamp, a third sub LED lamp, a fourth sub LED lamp, a fifth sub LED lamp and/or a sixth sub LED lamp, the sub LED lamp control module is respectively connected to each of the sub LED lamps, the sub LED lamp control module is configured to control each of the sub LED lamps simultaneously or respectively, that is, the sub LED lamp control module is respectively connected to each of the first sub LED lamps, each of the second sub LED lamps, each of the third sub LED lamps, each of the fourth sub LED lamps, each of the fifth sub LED lamps and/or each of the sixth sub LED lamps, and the sub LED lamp control module is configured to control each of the first sub LED lamps, each of the second sub LED lamps, each of the third sub LED lamps, each of the fourth sub LED lamps, each of the fifth sub LED lamps and/or each of the sixth sub LED lamps simultaneously or respectively. Therefore, various control effects can be realized by controlling each sub LED lamp through the sub LED lamp control module, so that the festive lantern can achieve diversified irradiation or lighting effects.

In one embodiment, N is an even number. For example, N is 2, 4, 6, or 8, etc. In one embodiment, N is 2; namely, the first sub-LED lamps are respectively arranged in two rows and two columns; for example, 12 first sub LED lamps are arranged on the body, and each of the first sub LED lamps is arranged in two rows and two columns, wherein 8 first sub LED lamps are arranged in 2 rows of first sub LED lamp groups, 8 first sub LED lamps are arranged in 2 columns of first sub LED lamp groups, and 50% of the 2 rows of first sub LED lamp groups and the 2 columns of first sub LED lamp groups are overlapped. Namely, the 2 rows of first sub-LED lamp groups and 4 first sub-LED lamps in the 2 columns of first sub-LED lamp groups are overlapped.

In one embodiment, the festive lantern further comprises a plurality of second sub-LED lamps arranged between the first sub-LED lamps, and each second sub-LED lamp is located at the geometric center of four first sub-LED lamps. In one embodiment, the volume of the second sub LED lamp is smaller than the volume of the first sub LED lamp. Furthermore, the festive lantern also comprises a plurality of fifth sub-LED lamps, and each fifth sub-LED lamp is arranged between two adjacent first sub-LED lamps. Further, in one embodiment, the volume of the fifth sub LED lamp is smaller than the volume of the first sub LED lamp. Further, the light emitting surface of the fifth sub-LED lamp is different from the light emitting surface of the second sub-LED lamp. Therefore, the sub-LED lamps with different specifications can be flexibly designed, and comprise a first sub-LED lamp, a second sub-LED lamp and a fifth sub-LED lamp, and different irradiation effects can be realized by matching different control modes, for example, the light-emitting wavelengths of the first sub-LED lamp, the second sub-LED lamp and the fifth sub-LED lamp are the same or different, and/or the turn-on time and/or the working power of the first sub-LED lamp, the second sub-LED lamp and the fifth sub-LED lamp are the same or different.

Further, in one embodiment, a plurality of sixth sub LED lamps are further disposed at the edge of the body; or a plurality of sixth sub-LED lamps are also arranged at the edge of part of the luminous layer of the body; in this way, an edge light extraction effect can be achieved. Further, the light emitting surface of the sixth sub-LED lamp is arranged differently from the light emitting surface of the fifth sub-LED lamp and/or the light emitting surface of the second sub-LED lamp. Further, the sixth sub LED lamps are dispersedly disposed.

Further, in one embodiment, the body has a plurality of light emitting layers, each of the first sub-LED lamps is disposed on the outermost light emitting layer, and each of the light emitting layers is at least partially stacked. Furthermore, except the outermost light-emitting layer, a plurality of fourth sub-LED lamps are respectively arranged on the rest light-emitting layers. Further, each of the fourth sub LED lamps of the inner light emitting layer is partially shielded. Furthermore, the light emitting direction of each fourth sub-LED lamp is obliquely arranged, that is, the light emitting direction of each fourth sub-LED lamp is obliquely downward, so as to obtain a better irradiation effect. Further, in one embodiment, each light emitting layer of the body has a regular polygon structure and/or a rounded regular polygon structure; further, in one embodiment, the light emitting layers of the body are arranged in the same shape or different shapes, for example, one light emitting layer has a circular structure, the other light emitting layer has a regular polygonal structure, and so on. For another example, the light emitting layers of the body are identical in shape and different in size, that is, the light emitting layers of the body have similar structures, so that on one hand, the mold is favorable for overall manufacturing, on the other hand, the production and assembly process is favorable for realizing, and the production efficiency is improved while the cost is controlled.

Further, in one embodiment, the breathing lamp further includes a base structure, a lamp panel, a mounting seat, and an air supply assembly, the other end of the support structure, that is, the end of the support structure away from the frame structure, is connected to the base structure, and the other end of the support structure is used for being fixed to the outside through the base structure to integrally fix the breathing lamp, that is, the base structure is used for being fixed to the outside to integrally fix the breathing lamp. For example, the base structure comprises a fixed tube, a control switch, a base body and an airbag assembly; for example, the airbag module is arranged on the seat body; for example, the seat body has flexibility, and an accommodating cavity is formed in the seat body; for example, a cavity communicated with the accommodating cavity is formed in the air bag module; for example, the control switch is arranged on the seat body; for example, the fixed tube includes a tube body, a bent portion extending outward from the tube body, and a connecting portion extending outward from the bent portion; for example, the end of the pipe body far away from the bent part is connected with the seat body; for example, the lamp panel comprises a panel body structure and a plurality of auxiliary LED lamps; for example, the plate structure is connected to the side wall of the pipe body; for example, a plurality of the auxiliary LED lamps are disposed on the plate body structure; for example, each of the auxiliary LED lamps is electrically connected to the control switch; for example, the mounting seat is connected to an end of the connecting part far away from the bending part; for example, the air supply assembly is disposed on the mounting base and electrically connected to the control switch for generating an air flow.

For example, the base structure includes a seat body and an airbag assembly. The air bag assembly is arranged on the seat body. The seat body is flexible, and an accommodating cavity is formed in the seat body; for example, the seat body is provided with a support part and a flexible part connected with the support part, the flexible part has flexibility, and the accommodating cavity is formed in the flexible part; for example, the flexible member is a TPE, soft PVC or silicone member. And a cavity communicated with the accommodating cavity is formed in the air bag assembly. In one embodiment, the cross section of the accommodating cavity is V-shaped. In other embodiments, the cross section of the accommodating cavity is U-shaped or trapezoidal.

In one embodiment, the air bag assembly comprises a bag body and an air pipe which are connected, the cavity is formed in the bag body, the cavity is communicated with the accommodating cavity through the air pipe, and the end part of the air pipe, far away from the bag body, is connected to the seat body; when the bag body is extruded, the air in the cavity of the bag body enters the accommodating cavity through the air pipe, and a user can easily move the seat body; when the capsule body is loosened, the volume of the cavity is increased, and partial air in the accommodating cavity enters the cavity through the air pipe until the shape of the capsule body is restored, so that the breathing lamp is good in use convenience. For example, the balloon body and the air pipe are integrally formed, so that the structure of the air bag component is compact. In other embodiments, the balloon and the trachea may be formed separately and joined together by gluing. For example, the end of the air pipe far away from the bag body is glued on the seat body, so that the air pipe is connected with the seat body. It will be appreciated that in other embodiments, the air tube, the bladder and the seat body may be integrally formed, so as to make the structure of the seat structure more compact. In one embodiment, the bladder is spherical. For example, the balloon may be spherical or ellipsoidal. Of course, in other embodiments, the bladder may be circular truncated cone or cylindrical.

For example, the control switch is disposed on the base. The fixing tube comprises a tube body, a bending part and a connecting part, wherein the bending part extends outwards from the tube body, the connecting part extends outwards from the bending part, and the end part, far away from the bending part, of the tube body is connected with the seat body. In one embodiment, the tube body, the bending portion and the connecting portion are integrally formed, so that the structure of the fixing tube is compact. In other embodiments, the tube, the bent portion and the connecting portion may be formed separately and connected together by welding or gluing. For example, the bent portion has a U-shape.

For example, the lamp panel includes a plate body structure and a plurality of auxiliary LED lamps. The plate body structure is connected to the side wall of the pipe body. The auxiliary LED lamps are arranged on the plate body structure, so that heat generated by the auxiliary LED lamps is conducted to the plate body structure, and the plate body structure and surrounding air are subjected to heat exchange to realize heat dissipation of the auxiliary LED lamps. Each auxiliary LED lamp is electrically connected with the control switch. The mounting seat is connected to the end part, far away from the bending part, of the connecting part. The air supply assembly is arranged on the mounting seat, electrically connected with the control switch and used for generating air flow. In order to firmly connect the mounting seat with the connecting part, in one embodiment, the mounting seat is welded or glued on the connecting part, so that the mounting seat is firmly connected with the connecting part. For example, the air supply assembly comprises a motor and a blade, the motor is arranged on the mounting seat, the blade is arranged on the power output end of the motor, and the motor drives the blade to rotate relative to the mounting seat, so that the air supply assembly generates air flow. For another example, the motor is welded or glued to the mounting base, so that the motor is fixed to the mounting base.

The air bag assembly is arranged on the seat body, the end part of the tube body, far away from the bent part, is connected with the seat body, the bent part is formed by extending the tube body outwards, the connecting part is formed by extending the bent part outwards, the connecting part is connected onto the tube body through the bent part, the mounting seat is connected onto the end part of the connecting part, far away from the bent part, so that the mounting seat is connected onto the fixed tube, and the air supply assembly is arranged on the mounting seat; the board body structure is connected to the side wall of the pipe body, the plurality of auxiliary LED lamps are arranged on the board body structure, each auxiliary LED lamp is electrically connected with the control switch, and the control switch is also electrically connected with the air supply assembly, so that the control switches can respectively control the auxiliary LED lamps and the air supply assemblies to work, and can also simultaneously control the auxiliary LED lamps and the air supply assemblies to work, only one jack is needed on the row socket, and the problem that the jacks of the row socket are insufficient is effectively solved; the user can place the breathing lamp on the table top or fix the breathing lamp on the table top; when the breathing lamp is required to be fixed on the desktop, the seat body is extruded, and because the seat body has flexibility, the seat body can be temporarily deformed by being extruded, air in the accommodating cavity is extruded, so that the seat body is reliably attached to any position of the desktop without being limited to the edge of the desktop, and the use convenience of the breathing lamp is improved; when the breathing lamp is required to be moved relative to the desktop, the air bag assembly is extruded, air in the cavity of the air bag assembly is discharged into the accommodating cavity, and at the moment, a user can easily move the breathing lamp, so that the breathing lamp is convenient and fast to use.

It can be understood that the control switch can control the auxiliary LED lamp and the air supply component to work separately, and can also control the auxiliary LED lamp and the air supply component to work simultaneously, that is, the breathing lamp can only provide illumination or air supply, and can also provide illumination and air supply simultaneously. For example, in hot summer, the breathing light can provide both illumination and air supply, or only air supply; in cold winter, the breathing light fixture may only provide illumination.

In order to enable the breathing lamp to have a good lighting effect, in one embodiment, the plate body structure is cylindrical, and the plurality of auxiliary LED lamps are distributed along the periphery of the plate body structure, so that the breathing lamp has a good lighting effect. In one embodiment, a plurality of auxiliary LED lamps are distributed at intervals along the periphery of the plate body structure, so that the breathing lamp has a better lighting effect. For example, a plurality of auxiliary LED lights are spaced circumferentially along the side of the plate body structure.

In order to enable the breathing lamp to have a larger irradiation area, in one embodiment, the number of the lamp panels is a plurality, and the lamp panels are arranged along the circumferential direction of the tube body, so that the breathing lamp has a larger irradiation area. In one embodiment, the lamp panels are arranged along the circumferential direction of the tube body at intervals, so that the breathing lamp can emit light to the surrounding area of the breathing lamp. For example, the number of the lamp panels is three, and the three lamp panels are arranged at intervals along the circumferential direction of the tube body; for another example, the included angle between two adjacent lamp panels is 120 degrees, so that the breathing lamp can irradiate the surroundings without dead angles. In other embodiments, the number of the lamp panels may also be four or five or other numbers.

In order to prolong the service life of an auxiliary LED lamp of a breathing lamp and fully utilize the negative pressure effect generated by a fan, for example, the plate body structure is provided with a heat dissipation hole and a heat dissipation channel which are communicated, the tube body is provided with a first ventilation channel communicated with the heat dissipation channel, a second ventilation channel communicated with the first ventilation channel is formed in the bent part, a third ventilation channel communicated with the second ventilation channel is formed in the connecting part, the mounting seat is provided with an air outlet hole, and the air outlet hole is communicated with the third ventilation channel, so that the heat dissipation channel is communicated with the air outlet hole sequentially through the first ventilation channel, the second ventilation channel and the third ventilation channel; the mounting seat is also provided with an air collecting groove communicated with the air outlet hole, and the air supply assembly is positioned in the air collecting groove; when the air supply assembly works, negative pressure is generated on the inner wall of the air collecting groove adjacent to the connecting part of the air supply assembly, so that air flow sequentially passes through the heat dissipation channel, the first ventilation channel, the second ventilation channel, the third ventilation channel and the air outlet hole to enter the air collecting groove, the heat exchange rate of the heat of the plate body structure and the air flow is improved, and the heat dissipation efficiency of the lamp panel is improved; the negative pressure through utilizing the air feed subassembly to produce adjusts the circulation of air on the lamp plate, and the required air current of air feed subassembly air feed in-process flows and the required air current of lamp plate heat dissipation flows and associates promptly, improves giving off of the heat of lamp plate when realizing the effect of air feed subassembly air feed, need not to increase extra fan and comes to dispel the heat to the lamp plate, improves the life of breathing lamps and lanterns.

For example, the auxiliary LED lamp is partially positioned in the heat dissipation channel, so that heat exchange is carried out between the heat generated by the auxiliary LED lamp and the air in the heat dissipation channel, and the heat is partially conducted to the plate body structure, thereby improving the heat dissipation efficiency of the auxiliary LED lamp and ensuring the better heat dissipation effect of the auxiliary LED lamp. In order to further improve the radiating effect of lamp plate, for example, it has the heat-conducting layer to coat on the inner wall of heat dissipation channel, makes the heat of plate body structure conduct fast and carries out the heat exchange with the air in the heat dissipation channel on to the heat-conducting layer. In order to further improve the heat dissipation effect of the lamp panel, for example, the number of the heat dissipation holes is multiple, and the heat dissipation holes are all communicated with the heat dissipation channel; for another example, the heat dissipation holes are distributed on the plate body structure at intervals; for another example, the plurality of heat dissipation holes are arranged in a circular array manner, so that air around the plate body structure can quickly enter the heat dissipation channel, and the heat dissipation efficiency of the plate body structure is improved. When the air flow of the heat dissipation channel sequentially passes through the first ventilation channel, the second ventilation channel and the third ventilation channel, the heat of the air flow is partially transmitted to the fixed pipe, the heat on the fixed pipe exchanges heat with the air around the fixed pipe, and in order to improve the heat dissipation efficiency of the fixed pipe, for example, a plurality of first heat dissipation fins are arranged on the outer wall of the pipe body, a plurality of second heat dissipation fins are arranged on the outer wall of the bent part, and a plurality of third heat dissipation fins are arranged on the outer wall of the connecting part, so that the heat on the pipe body exchanges heat with the external air through the plurality of first heat dissipation fins; the heat on the bending part exchanges heat with the external air through the second radiating fins, and the heat on the connecting part exchanges heat with the external air through the third radiating fins, so that the radiating efficiency of the fixing tube is higher. For another example, the plurality of first heat dissipation fins are distributed at intervals along the extending direction of the tube body, so that the heat dissipation effect of the plurality of first heat dissipation fins is better; the plurality of second radiating fins are distributed at intervals along the extending direction of the bending part, so that the radiating effect of the plurality of second radiating fins is better; the plurality of third radiating fins are distributed at intervals along the extending direction of the connecting part, so that the radiating effect of the plurality of third radiating fins is better. For another example, an included angle between each first heat dissipation fin and the extending direction of the tube body is 30 to 45 degrees, so that the heat dissipation effect of the tube body is better. And/or the included angle between each second radiating fin and the extending direction of the bent part is 30-45 degrees, so that the radiating effect of the bent part is better. And/or the included angle between each third radiating fin and the extending direction of the connecting part is 30-45 degrees, so that the radiating effect of the connecting part is better. For example, the plurality of first heat dissipation fins are spirally distributed on the side wall of the tube body, so that the heat dissipation effect of the tube body is better. For example, the plurality of second heat dissipation fins are spirally distributed on the side wall of the bending part, so that the heat dissipation effect of the bending part is better. For example, the plurality of third heat dissipation fins are spirally distributed on the side wall of the connecting portion, so that the heat dissipation effect of the connecting portion is better. For example, the air outlet hole is positioned at the bottom of the air collecting groove. In order to make the air current of third ventilation flue get into the collection wind inslot fast, for example, still be formed with the annular groove on the mount pad, the figure of exhaust vent is a plurality of, and is a plurality of the exhaust vent all with the annular groove intercommunication, third ventilation flue still with the annular groove intercommunication makes the air current in the annular groove pass through a plurality of exhaust vents and gets into collection wind groove fast, has improved the velocity of flow of the air current of third ventilation flue greatly to the circulation efficiency of the air current of radiating passage has been improved. If the air outlet holes are distributed on the inner wall of the air collecting groove at intervals, the air flow in the air collecting groove is uniform, and the air supply effect of the air supply system is better. In order to further improve the flow rate of the air flow in the third air passage, for example, the mounting seat is further provided with a plurality of peripheral holes, and the peripheral holes are distributed at the end edge of the mounting seat, so that part of the air flow in the annular groove flows out through the peripheral holes, and the flow of the air flow in the annular groove is accelerated. For another example, the plurality of peripheral holes are distributed at intervals along the end edge of the mounting seat, so that the flowing effect of the airflow in the annular groove is better.

In order to further improve the flow rate of the air flow of the third air passage, for example, a side wall hole is further formed in the mounting seat, the side wall hole is located on the side wall of the air collecting groove, and the side wall hole is communicated with the annular groove, so that the air flow of the third air passage can also enter the air collecting groove through the side wall hole, and the flow rate of the air flow of the third air passage is further improved. In order to improve the safety in utilization of breathing lamps and lanterns lamp plate part, for example, breathing lamps and lanterns still include the cover body, cover body cover is located the terminal edge department of mount pad, a plurality of wind holes that disperse have been seted up on the cover body, make between air feed system and the external world by the cover body separate, avoid the unexpected touching of user to lead to injured problem to air feed subassembly department, improved the security of breathing lamps and lanterns's use. In order to make the air outlet of the cover body more uniform, for example, a plurality of air dispersing holes are uniformly distributed. The angle that the air current passes through the cover body in order to realize the air feed subassembly can alternate, for example, the cover body rotate connect in on the mount pad, and be equipped with the spoke of a plurality of slopes on the cover body, when the air feed subassembly during operation, the air current is acted on to the spoke, makes the cover body automatic rotate for the mount pad, realizes the angle transform of air current through the cover body. In the breathing lamp, the air bag assembly is arranged on the seat body, the end part of the tube body, far away from the bent part, is connected with the seat body, the bent part is formed by outwards extending the tube body, the connecting part is formed by outwards extending the bent part, the connecting part is connected on the tube body through the bent part, the mounting seat is connected on the end part of the connecting part, far away from the bent part, so that the mounting seat is connected on the fixed tube, and the air supply assembly is arranged on the mounting seat; the board body structure is connected to the side wall of the pipe body, the plurality of auxiliary LED lamps are arranged on the board body structure, each auxiliary LED lamp is electrically connected with the control switch, and the control switch is also electrically connected with the air supply assembly, so that the control switches can respectively control the auxiliary LED lamps and the air supply assemblies to work, and can also simultaneously control the auxiliary LED lamps and the air supply assemblies to work, only one jack is needed on the row socket, and the problem that the jacks of the row socket are insufficient is effectively solved; when the breathing lamp is placed on a table top, or the breathing lamp is fixed on the table top; when the breathing lamp is required to be fixed on the desktop, the seat body is extruded, and because the seat body has flexibility, the seat body can be temporarily deformed by being extruded, air in the accommodating cavity is extruded, so that the seat body is reliably attached to any position of the desktop without being limited to the edge of the desktop, and the use convenience of the breathing lamp is improved; when the breathing lamp is required to be moved relative to the desktop, the air bag assembly is extruded, air in the cavity of the air bag assembly is discharged into the accommodating cavity, and at the moment, a user can easily move the breathing lamp, so that the breathing lamp is convenient and fast to use.

In addition, another embodiment of the present invention further includes a breathing lamp which can be implemented by combining the technical features of the above embodiments, and may also be referred to as an expansion lamp or a deformation lamp.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (10)

1. A breathing lamp is characterized by comprising an elastic layer, a frame structure and a plurality of LED lamps;

the elastic layer seals the frame structure; the frame structure is further provided with a deformation guide strip, one surface of the elastic layer, facing the frame structure, is connected with the deformation guide strip, and the deformation guide strip is used for limiting the deformation direction of the elastic layer, so that the breathing lamp has certain deformation limitation when the elastic layer is heated to expand;

the LED lamps are respectively arranged on the outer surface of the elastic layer, a copper layer is further arranged on the elastic layer, and the copper layer is arranged adjacent to the LED lamps;

the breathing lamp comprises a plurality of irradiation surfaces which are formed by the elastic layer and the frame structure together and are positioned on the elastic layer, and each irradiation surface is provided with LED lamps arranged in a matrix;

the LED lamp is a surface-mounted lamp.

2. The respiratory light fixture of claim 1 wherein the respiratory light fixture includes a plurality of the elastomeric layers, the elastomeric layers collectively sealing the frame structure and each having at least one of the LED lamps disposed thereon.

3. The respiratory light fixture of claim 2 wherein each of the elastomeric layers and the frame structure together form a sealed structure.

4. The respiratory light fixture of claim 2 wherein the frame structure forms a sealing structure with each of the elastic layers.

5. The respiratory light fixture of claim 1 wherein the frame structure comprises a plurality of support rods.

6. The breathing light fixture of claim 5 wherein the frame structure further comprises a rotating post; one end of each supporting rod is connected with the elastic layer, and the other end of each supporting rod is connected with the rotating column.

7. The breathing lamp set forth in claim 6 wherein the frame structure further includes a drive motor coupled to the rotating post.

8. The breathing lamp as claimed in claim 1, wherein a connection circuit is further disposed on the flexible layer, and the connection circuit is connected to each of the LED lamps.

9. The breathing lamp set as claimed in claim 8, wherein a solar thin film battery is further disposed on the elastic layer, the solar thin film battery is connected to the connection circuit, and the solar thin film battery is used for supplying power to each of the LED lamps through the connection circuit.

10. The breathing lamp set according to any one of claims 1 to 9, further comprising an air pump and an air inflation duct, wherein one end of the air inflation duct is communicated with the inside of the frame structure, and the other end of the air inflation duct is communicated with an output end of the air pump; the breathing lamp further comprises a support structure, one end of the support structure is connected with the frame structure, and the other end of the support structure is used for being fixed to the outside to integrally fix the breathing lamp; the supporting structure has installation position and hollow pipe portion, the lateral surface of pipe portion with frame construction connects, just the one end of pipe portion is located inside the frame construction, gas filled duct set up in the inside of pipe portion, gas filled duct's one end is passed through pipe portion intercommunication inside the frame construction, the air pump is fixed set up in the installation position, just the output intercommunication of air pump gas filled duct's the other end.

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