This application is based upon and claims the benefit of priority from Japanese Patent Applications No. 2010-133369 and No. 2010-133409, respectively filed Jun. 10, 2010, the entire contents of which are incorporated herein by reference.
Embodiments described herein relate generally to a lighting apparatus.
In place of a filament bulb and a fluorescent lamp, lighting devices such as an LED lamp and a lighting apparatus using a light emitting diode as a light source, i.e., a solid-state light emitting device, consuming a low electric power and having a long life are commercially available these days. Among these lighting apparatuses, long and narrow straight pipe-shaped lighting apparatuses and LED lamps are proposed. The pipe-shaped lighting apparatuses and LED lamps can be used in place of the straight pipe fluorescent lamps widely employed in a storage container such as a refrigerator and a showcase and in the indoor and outdoor lighting apparatuses
However, when the lighting apparatuses and LED lamps are used for illumination in a refrigerator in particular, the use environment is about −25° C. When they are installed outdoors, the temperature is 40° C. or more under burning sun in the summer. In this case, components constituting these lighting apparatuses, i.e., synthetic resin components and metal components, have different thermal expansion coefficients. For example, when the lighting apparatus is made by fixing a light source unit mainly having many metal components having small thermal expansion coefficients onto a transparent tubular cover member made with a synthetic resin having a high thermal expansion coefficient, the thermal expansion coefficient of the cover member is different from the thermal expansion coefficient of the light source unit. For example, when the lighting apparatus is used in an environmental temperature of −25° C., the cover member made of the synthetic resin shrinks more greatly than the light source unit. On the contrary, when the light source unit is placed under burning sun outdoors, the cover member expands more greatly than the light source unit.
Therefore, the light source unit is affected by stress caused by expansion and shrink of the cover member, and in particular, this is one of the causes of malfunction of the electronic component made by implementing a semiconductor device such as a light emitting diode. Further, when the cover member shrinks, a space is made between components, and this causes a problem in air tightness and waterproof property. Therefore, it is very important how to configure the components having different thermal expansion coefficients without any problem.
The accompanying drawings, which are incorporated in and configure a portion of the specification, illustrate embodiments of the invention, and together with the general description given above and the detailed description of the embodiments given below, serve to explain the principles of the invention.
A lighting apparatus according to an exemplary embodiment of the present invention will now be described with reference to the accompanying drawings wherein the same or like reference numerals designate the same or corresponding portions throughout the several views.
In one embodiment, a lighting apparatus includes: a light source unit having light sources arranged in a longitudinal direction; a transparent cover member formed in a substantially straight pipe shape and having openings at both ends for housing the light source unit along the longitudinal direction, the cover member having a higher thermal expansion coefficient than that of the light source unit; and end plate members fixed to both ends of the light source unit and closing the openings at the both ends of the cover member.
A lighting apparatus according to this embodiment constitutes a straight pipe-shaped waterproof lighting apparatus 10 for a showcase. As illustrated in
The light source unit 11 includes the rectangular substrates 11a, the light emitting unit 11c made of the solid-state light emitting devices 11b arranged along the longitudinal direction of the substrate, and the light-control device 11d for lighting the solid-state light emitting devices. The substrate 11a is made of a member having electrical insulating property. More particularly, in this embodiment, the substrate 11a is made of a thin tabular circuit substrate having a long and narrow rectangular shape made of glass epoxy resin. On the surface of the substrate 11a (the upper surface in
As illustrated in
The light emitting unit 11c is supported by a substrate attachment plate 11a1. The substrate attachment plate 11a1 is made of a metal having thermal conductivity. In this embodiment, the substrate attachment plate 11a1 is made of a thin tabular copper plate having a long and narrow shape. On the surface of the substrate attachment plate 11a1, a plurality of light emitting units is provided. In this embodiment, four light emitting units 11c are provided in one row in a longitudinal direction of the substrate attachment plate 11a1 so that the axial lines of the light emitting units 11c and the substrate attachment plate 11a1 align each other. As illustrated in
The light-control device 11d includes a lighting circuit for converting an alternating-current voltage of 100V into a direct-current voltage of 24V and providing a constant direct current to the LEDs 11b. The light-control device 11d includes an electronic component 11d1 constituting the lighting circuit and a circuit substrate 11d2 on which electronic components are mounted. Like the substrate 11a of the light emitting unit 11c, the circuit substrate 11d2 is made of a thin tabular rectangular glass epoxy resin having a long and narrow shape, and circuit patterns are formed on one side or both sides thereof. A plurality of small electronic components 11d1 is mounted on the mounting surface thereof.
As illustrated in
As illustrated in
In the box of the support case 11e having the above configuration, the light source unit 11 is arranged so that the longitudinal direction of the light source unit 11 is in the longitudinal direction of the box. At this occasion, the light emitting unit 11c, i.e., each LED 11b, faces outside, and the circuit substrates 11d2 constituting the light-control devices 11d are arranged to be housed in the support case 11e. The circuit substrate 11d2 constituting the light-control device 11d is made of a member having electric insulating property. In this embodiment, the circuit substrate 11d2 is covered with an insulating cover 11d4 made of silicone resin, so that the circuit substrate 11d2 is housed in such a manner that the circuit substrate 11d2 is electrically insulated from the metal support case 11e.
Further, the substrate attachment plate 11a1 of the light source unit 11 is formed so that the width of the substrate attachment plate 11a1 of the light source unit 11 is substantially the same as the distance between the flange portions 11e2 at both sides of the support case 11e. On the other hand, the substrate attachment plate 11a1 is formed so that the length of the substrate attachment plate 11a1 is substantially the same as the length of the support case 11e, and that the opening portion 11e1 of the upper surface of the support case 11e is closed with the substrate attachment plates 11a1. The substrate attachment plate 11a1 may be fixed onto the upper surface of the flange portions 11e2 at both sides of the support case 11e using means such as screws and adhesive agents.
As described above, the light emitting units 11c face the outside, and the light source unit 11 is inserted and housed in the tubular cover member 12 in such a manner that the light-control device 11d is housed in the support case 11e. As illustrated in
Along the longitudinal direction of the cover member 12, the light source unit 11 is inserted from one of the openings 12a into the cover member 12 of the tubular member having the above configuration, and is housed therein. In other words, the substrate attachment plate 11a1 of the light source unit 11 overlaps the flange portion 11e2 of the support case 11e, whereby the upper surfaces of the protruding pieces 11f protruding at both sides are brought into contact with the lower surfaces of the inner surface sides of the steps 12 at both sides of the cover member 12. Further, the lower surface of the support case 11e is brought into contact with the support protruding line portion 12e. Subsequently, one end portion of the long light source unit 11 is inserted from one of the openings 12a of the cover member 12 while the light source unit 11 is positioned using the inner surface sides of the steps 12c at both sides and the upper surface of the support protruding line portion 12e as guides. In other words, the light source unit 11 is housed in the cover member 12 serving as a tubular member so as to be movable in the axial direction of the cover member 12, and in addition, the light source unit 11 is positionally restricted in a direction perpendicular to the axial direction. Therefore, this facilitates the assembly work, and the light source unit 11 is reliably housed in the cover member 12.
As described above, the light source unit 11 inserted and housed in the cover member 12 is fixed such that both end portions of the light source unit 11 are fixed by the end plate members 13 closing the openings 12a at both ends of the cover member. As illustrated in
As illustrated in
As illustrated in
The end plate member 13, the packing 14, and the screw packing 15 configured as described above are provided in pairs so as to correspond to the openings 12a of both right and left ends of the cover member 12, and are fixed to both end portions of the light source unit 11 inserted and housed in the cover member 12. This fixing structure is the same both at the right and left ends. In the explanation below, the structure at the left will be explained as illustrated in
First, the inner peripheral portion of the packing 14 is fitted into the outer peripheral portion of the end plate member 13. At this occasion, as illustrated in
As described above, the packing 14 is engaged with the end plate member 13, and the integrated members are fitted into the openings 12a at both ends of the tubular cover member 12 for housing the light source unit 11 which is inserted in advance. This engagement is done as follows. The outer peripheral portion of the packing 14 fitted to the outer peripheral portion of the end plate member 13 is engaged with the opening 12a of the cover member 12 and is fitted therein. At this occasion, as illustrated in
Subsequently, the screw packing 15 is engaged with the packing support portion 13h of the end plate member 13. In this time, the two insertion holes 15h1 of the screw packing 15, the two insertion holes 13h1 of the end plate member 13, and the two insertion holes 14h1 of the packing 14 are in communication with each other. Further, the light source unit 11 is positioned using the inner surface sides of the steps 12c at both sides as guides. In other words, the light source unit 11 is positionally restricted in a direction perpendicular to the axial direction of the cover member 12. Therefore, many insertion holes and the two screw holes 11e4 are in a positioned state.
In this state, two screws, tapping screws S2 in this embodiment, are inserted into the two insertion holes 15h1 of the screw packing 15, then screwed and fixed in the screw holes 11e4 of the support end plate 11e3 of the light source unit 11 via the respective insertion holes 13h1, 14h1 of the end plate member 13 and the packing 14. The above screwing process is performed to the end plate member 13 engaged with the opening 12a at each of both right and left sides. When the screws are fixed as above, the end plate member 13 and the packing 14 at each of both right and left sides are pressed toward the support end plate 11e3 (arrow direction in
The cover member 12 is configured to have a non-circular cross sectional shape, and the shape of the inner peripheral surface is formed to have a smoothly continuous surface. Accordingly, the protruding line portions 14k on the outer peripheral surface of the packing 14 is deformed according to the shape of the inner peripheral surface of the cover member 12 due to its elasticity, so that the air tightness is more reliably maintained.
The tubular cover member 12 is made of a synthetic resin having a high thermal expansion coefficient, but component parts of the light source unit 11 such as the support case 11e are made of metal. Therefore, there is a difference between the thermal expansion coefficient of the cover member 12 and the thermal expansion coefficient of the light source unit 11. Depending on the temperature of use environment, the cover member 12 made of acrylic resin having a high thermal expansion coefficient expands or shrinks more greatly than the light source unit 11, and as a result, the length of the long and narrow straight pipe-shaped cover member 14 changes.
In this embodiment, however, the air tightness is maintained even when the length of the cover member changes. More specifically, when the cover member expands due to heat, the length of the cover member 12 slightly increases. However, the expansion is sufficiently absorbed by the expansion and shrinking of the packing 14 due to its elasticity, and higher degree of air tightness is attained. For example, even when the lighting apparatus is used as an illumination in a refrigerator and the like in which the temperature is about −25° C., and the cover member 12 shrinks and the length thereof decreases, the flange portion 14g of the packing 14 sufficiently keeps track of the cover member 12 due to the elasticity of the packing 14 and recovers with its elasticity, whereby a close contact state is maintained.
Further, as described above, in the light source unit 11, the upper surfaces of the protruding pieces 11f are in contact with the inner surface sides of the steps 12c of the cover member 12, and the lower surface of the support case 11e is brought into contact with the support protruding line portion 12e. The light source unit 11 is positioned and housed using them as guides. In other words, the light source unit 11 is supported and fixed only by the end plate member 13, and is not fixed to the cover member 12, i.e., tubular member. The cover member is supported by the end plate member so as to be movable with respect to the light source unit 11 in the longitudinal direction, and the light source unit 11 is positioned in a perpendicular direction with the longitudinal direction by the cover member 12.
Therefore, even when the cover member 12 made of resin expands or shrinks due to heat, stress caused by expansion and shrinking is less likely to be transmitted to the light source unit 11, and the light source unit 11 is less likely to be affected. At the same time, vibration and shock transmitted from the cover member 12 is absorbed by the packing 14 also which serves as a vibration/shock absorbing member, and accordingly, the vibration and shock is less likely to be transmitted to the light source unit 11. Therefore, the vibration/shock resistant lighting apparatus can be made.
As described above, the flange portion 14g of the packing 14 and the flange portion 13g of the end plate member 13 are brought into close contact with each other by the packing in an air tight manner, and at the same time, the electric wire insertion holes 13j of the end plate member 13 are pressed against the electric wire packing 14j of the packing 14, whereby the electric wire insertion portion is in close contact in an air tight manner. Further, the heads of the two tapping screws S2 are pressed against the surface of the screw packing 15, whereby the screw insertion portion is in close contact in an air tight manner.
Therefore, as illustrated in
The lighting apparatus 10 having the above configuration is installed in a showcase as follows. As illustrated in
As described above, the lighting apparatus 10 is fixed to the attachment metal parts 16 fixed to the pillar 32. First, as illustrated in
With this inserting operation, the fixing piece 16b1 of each of the support pieces 16b moves along the both side portions 12d of the cover member 12 while the fixing piece 16b1 is bent, and the fixing piece 16b1 is dropped into the upper surface of the step 12c of the cover member due to the spring property of the support pieces 16b. As a result, the fixing piece 16b1 is engaged on the outer surface of the step 12c of the cover member due to the elastic force of the spring property, and the lighting apparatus 10 is fixed in the vertical direction, i.e., the longitudinal direction of the pillar 32. When the lighting apparatus 10 is detached, the steps opposite to the above are taken. The support pieces 16b are pressed and opened with fingers and the like, whereby the fixing piece 16b1 is disengaged from the step 12c, and the lighting apparatus 10 can be pulled from the support pieces 16b1.
The power source lines are connected to the light source units 11 of the lighting apparatus 10 before the lighting apparatus is installed. More specifically, the electric wire drawn from the pillar 32, i.e., a Cabtyre cable C1 having a circular cross section in this embodiment, are connected in advance. The Cabtyre cable C1 includes totally three electric wires including two power source lines and one earth line. These wires are inserted into the electric wire sealing holes 14j1 formed in the packing 14 of the lighting apparatus 10, and are connected to the input terminal of the light source unit 11.
At this occasion, as illustrated in
As described above, when the lighting apparatus 10 installed at the back surface side of the door 31 is turned on, each LED 11b of the light emitting units 11c in the light source unit 11 is turned on so that each LED 11b emits light. The light emitted from the LEDs passes through the light transmitting portion 12b having a semicircular cross section in the cover member 12, and the light is emitted substantially in a distribution direction of LEDs. Accordingly, the light expands in the horizontal direction from each LED 11b arranged in the vertical direction, and beverages and the like displayed on the shelves installed in the vertical direction can be illuminated substantially uniformly in a vertical direction. When dew and spilled water generated in the showcase drop on the lighting apparatus 10, no water enters into the lighting apparatus 10 according to this embodiment because the packings 14, 15 maintain air tight closing between the end plate member 13 and the cover member 12, the screw insertion portions, and the electric wire insertion portions. Moreover, neither trash nor dust enters into the lighting apparatus 10.
The heat generated by each LED 11b is radiated to the cover member 12 from the substrate attachment plate 11a1 made of a steel sheet, and this prevents the increase in the temperature of the LEDs. The heat generated by the electronic components 11d1 of the light-control device 11d is also radiated from the support case 11e made of a steel plate to the cover member 12, and this prevents the increase in the temperature of the electronic components. In the above case, the lighting apparatus 10 is made as a lighting apparatus newly installed in a showcase. Alternatively, the lighting apparatus 10 according to this embodiment may be substituted for fluorescent lamp lighting apparatuses already installed in showcases, so that further power saving and longer life can be attained.
As described above, in this embodiment, the lighting apparatus 10 is installed vertically in the double-door showcase 30. Alternatively; the lighting apparatus 10 may be installed horizontally. Still alternatively, the lighting apparatus 10 can be applied to not only the showcase but also, for example, illumination for a parking fee collecting machine in a parking lot installed outdoors. In this case, even when the lighting apparatus 10 is installed outdoors and exposed to weather, the lighting apparatus prevents entry of water such as rain and entry of trash and dust in the same manner. This embodiment can be applied to not only the above listed exemplary uses but also various other kinds of lighting apparatuses used for business and in facilities such as homes, shops, and offices.
Further, in the above explanation, the lighting apparatus is made. Alternatively, a base-attached lamp may be made. As illustrated in
In this structure, the lighting apparatus according to this embodiment includes the light-control device 11d. Therefore, for example, a base-attached lamp 40 can be provided. The base-attached lamp 40 has the same structure as a socket of a generally-available fluorescent lamp, and it can be turned on by just inserting the base pin 42 according to this modification into a fitting terminal of a socket connected to a power source.
In this embodiment, the solid-state light emitting device is made of LED. Alternatively, other solid-state light emitting devices such as semiconductor laser and organic EL may be employed. In this embodiment, the solid-state light emitting device is linearly implemented on a long and narrow rectangular substrate. Alternatively, many solid-state light emitting devices may be arranged in matrix form, staggered form, radiating form, and the like, in such a manner that all of the solid-state light emitting devices are arranged and implemented on a surface with a certain order according to a rule.
In this embodiment, four light emitting units 11c are used to make the light source unit 11. Alternatively, light source units 11c may be made by making the light emitting unit 11c and the light-control device 11d into a module having a length of, e.g., about 600 mm and appropriately selecting the number of modules, so that various kinds of lighting apparatuses having lengths suitable for purposes can be obtained.
In this embodiment, the substrate attachment plate 11a1 on which the light emitting units 11c are arranged is made of a flat plate, and the support case 11e housing the light-control device 11d has a box shape. On the contrary, as illustrated in
The cover member 12 may be semitransparent such as milky-white color so as to diffuse light. Alternatively; the cover member 12 may be made of transparent or semitransparent glass. Further, the cover members may be dyed in blue, red, or the like.
The substrate 11a and the circuit substrate 11d2 of the light-control device 11d are made of glass epoxy resin. Alternatively, they may be made of ceramics and metal such as aluminum having a high thermal conductivity. The substrate attachment plate 11a1 and the support case 11e are made of steel plates. Alternatively, the substrate attachment plate 11a1 and the support case 11e may be made by aluminum die casting having a high thermal conductivity, so as to achieve more effective radiation effect.
The attachment metal part 16 may be configured to have a function of connecting a plurality of lighting apparatuses, in other words, as illustrated in
The attachment metal part 16 having the above configuration can be used to connect and install a plurality of lighting apparatuses as follows. First, an end portion of one of connected lighting apparatuses 10A is supported using a wider supporting piece 16b of the attachment metal part 16. Then, both corner portions at a lower side of the flange portions 13g of the end plate member 13 of the lighting apparatus 10A are engaged with the groves 16e, so that it is positioned in the horizontal direction, i.e., the longitudinal direction. Subsequently, likewise, the other of the lighting apparatuses 10B is supported using the other support piece 16b of the attachment metal part 16. Then, both corner portions at a lower side of the flange portions 13g of the end plate member 13 of the lighting apparatus 10B are engaged with the gloves 16e, so that it is positioned in the longitudinal direction.
As a result, the two lighting apparatuses 10A, 10B are connected by the attachment metal part 16 with a minimum clearance at the connection portion, and the two lighting apparatuses 10A, 10B are connected in such a manner that they appear to be one continuous long lighting apparatus. When three lighting apparatuses are connected, one more attachment metal part having the above configuration may be prepared, and the lighting apparatus can be connected in the same manner. As described above, when the necessary number of attachment metal parts having the above configuration are prepared, the necessary number of lighting apparatuses can be easily connected. It should be noted that the attachment metal part 16 is connected while it is already fixed to an installation location in advance as described-above. In
According to the above configuration, the attachment metal part 16 can easily connect a plurality of lighting apparatuses, and at the same time, the plurality of lighting apparatuses can be easily installed to the installation portion. Moreover, since the lighting apparatuses can be positioned and connected using the grooves 16e, an installation interval (pitch) a1 of the LEDs 11b of the lighting apparatuses adjacent to each other at the connection portion can be configured to be the same as a pitch a2 of each apparatus as illustrated in the figure (a1≈a2). Accordingly, the installation interval between the light emitting units of the plurality of connected lighting apparatuses becomes substantially the same, and the clearance at the above connection portion is reduced to the minimum. For these reasons, one continuous lighting apparatus is formed to emit uniform light in the longitudinal direction.
As described above, according to this embodiment, the cover member 12, i.e., tubular member, houses the light source unit 11 in such a manner that the light source unit 11 can move in the axial direction and the light source unit 11 is positionally restricted in the direction perpendicular to the axis. Moreover, the light source unit 11 is supported by the end plate members 13. As a result, it becomes possible to supply the lighting apparatus such as a base-attached lamp and a lighting apparatus that can be assembled without any problem even when materials having different thermal expansion coefficients are used.
Further, the tubular cover member 12 is made of synthetic resin having a high thermal expansion coefficient, and main components of the light source unit 11 such as the substrate attachment plate 11a1 are made of metal. Therefore, the cover member 12 made of acrylic resin having a high thermal expansion coefficient expands or shrinks more greatly than the light source unit 11, which changes the length of the cover member 12. In this embodiment, however, the light source unit 11 is fixed to only the end plate member 13 but is not fixed to the cover member 12. In other words, the cover member 12 houses the light source unit 11 in such a manner that the light source unit 11 can move in the axial direction of the cover member 12 and that the light source unit 11 is positionally restricted in the direction perpendicular to the axis. Since the light source unit 11 is supported by the end plate member 13, even when the resin cover member 12 expands or shrinks due to heat, stress of expansion and shrinking is not applied to the light source unit 11, and the light source unit is less likely to be affected. Further, the lighting apparatus is less likely to cause malfunction due to temperature even under harsh use environment. Still further, since the packing 14 absorbs vibration and shock transmitted from the cover member 12, the vibration and shock are less likely to be transmitted to the light source unit 11. Therefore, the vibration/shock resistant lighting apparatus can be made. Even when the length of the cover member, i.e., tubular member, changes, the change is sufficiently absorbed by the elastic force of the packing 14 having shock absorbing function. The lighting apparatus can be provided that can sufficiently ensure the air tightness and waterproof property.
The cover member 12 has a semicircular cross section, and the shape of the inner peripheral surface is formed to have a smoothly continuous surface. Accordingly, the packing 14 is deformed according to the shape of the inner peripheral surface of the cover member due to its elasticity, so that the air tightness is more maintained. Therefore, more reliable waterproof property can be ensured. Since the cover member 12 has a semicircular cross section, the bottom surface of the attachment portion 12f can be flat, and the flat attachment portion 12f can be brought into close contact with the flat base portion 16a of the attachment metal part 16, so that the cover member can be reliably attached to the attachment metal part 16. At the same time, the orientation of the apparatus can be easily determined.
The inner surface of step 12c of the cover member 12 is configured to be used to position the light source unit 11, and the outer surface of step 12c is configured to be supported by the attachment metal part 16. Therefore, one end portion of the long light source unit 11 can be inserted from one of the openings 12a of the cover member 12. In addition, this facilitates the assembly work, and the light source unit 11 can be reliably attached to the cover member 12.
While certain embodiments have been described, these embodiments have been used by way of example only and are not intended to limit the scope of the inventions. Indeed, the novel embodiments described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modifications as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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P2010-133369 | Jun 2010 | JP | national |
P2010-133409 | Jun 2010 | JP | national |