JP4192619B2 - Light emitting diode lamp device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an LED lamp device that efficiently dissipates heat energy generated by a light emitting diode (hereinafter simply referred to as “LED”), and in particular, is used as an LED lamp that improves heat dissipation characteristics and allows a large current to flow. The present invention relates to an LED lamp device having a heat dissipation structure.
[0002]
[Prior art]
[Patent Document 1]
JP 2001-345485 A
In general, it is possible to increase the brightness of an LED by increasing the current, but the temperature of the light-emitting element itself increases due to the increase in current, causing wire breakage or a decrease in luminous efficiency due to the residual stress of the sealing resin. . For this reason, the amount of energization current is not increased excessively, or a heat dissipation mechanism is provided to take measures against temperature rise of the light emitting element. As an example of the heat dissipation mechanism, in the case of LED lamps, the heat resistance was lowered by mounting it on an aluminum substrate with good heat dissipation so as not to accumulate heat through a lead frame, and the temperature rise due to the increase in current was suppressed. .
[0003]
Moreover, in the technique of the said patent document 1, what is called a printed circuit board which consists of a pair of metal layer each formed in the surface and back surface of an insulating base material, and several LED arranged on the said metal layer of the said surface And a metal connection portion that connects the pair of metal layers at a position where any one of the plurality of LEDs is disposed, and heat generated from the plurality of LEDs is formed on the surface of the insulating base material. Heat is radiated from the metal layer to the atmosphere, and at the same time, the heat is transmitted to the metal layer formed on the back surface of the insulating substrate through the metal connection portion and radiated from there to the atmosphere. Further, the heat dissipation area is increased and the heat dissipation efficiency is improved.
[0004]
Since the LED is disposed at the tip of the anode side lead frame, most of the heat generation amount of the LED is transmitted from the anode side lead frame to the aluminum substrate. Therefore, unless the heat dissipation on the anode side is increased, the temperature of the LED will increase. Therefore, the area of the aluminum substrate connected to the anode side needs to be increased for heat dissipation. On the other hand, since the heat generation of the LED at the anode is transmitted through the gold wire or the sealing resin of the LED on the cathode side, the total amount of heat is small. Therefore, since the amount of heat transferred from the cathode side lead frame to the aluminum substrate is small, it is not necessary to increase the area of the cathode side aluminum substrate.
[0005]
[Problems to be solved by the invention]
However, in order to sufficiently dissipate the heat generated from the LED with the aluminum substrate on the anode side, it is necessary to increase the area of the aluminum substrate on the anode side according to the amount of heat generated by the LED. This was an obstacle to miniaturization when the lamp was constructed. Further, since the heat dissipation efficiency decreases as the distance from the LED increases, a larger aluminum substrate is required. Furthermore, since the balance of the aluminum substrate area of the anode and the cathode becomes extremely bad, there are many design restrictions and the arrangement of the LED lamps is hindered. In the technique described in Patent Document 1, the plurality of LEDs arranged on the metal layer on the surface are heated in the atmosphere from the metal layer printed on the surface of the insulating substrate by generating heat from the plurality of LEDs. Heat is transferred to the metal layer formed on the back surface of the insulating base material through the metal connection portion, and the heat dissipation depends on the metal layer printed on the surface of the insulating base material. It is necessary to simply enlarge the area of the metal layer printed on the surface of the insulating substrate according to the heat generation amount of the plurality of LEDs, and this constitutes a high output LED lamp using the plurality of LEDs. The case was an obstacle to miniaturization.
[0006]
Therefore, an object of the present invention is to provide an LED lamp device that can dissipate heat without relying only on a metal layer, and can be downsized even if the output of the LED lamp is increased.
[0007]
[Means for Solving the Problems]
The LED lamp device according to claim 1 is a light emitting diode lamp having an anode side lead frame and a cathode side lead frame, an anode side metal electrode connected to the anode side lead frame of the light emitting diode lamp, and the light emitting diode lamp. A housing made of an insulating synthetic resin having a thermal conductivity of 0.4 W / m · K or more, in which a cathode-side metal electrode connected to the cathode-side lead frame is insert-molded, and the anode insert-molded in the housing The area of the side metal electrode is wide, the area of the cathode side metal electrode is also narrowed, and at least one of both surfaces of the metal electrode is connected so that the anode side lead frame and the cathode side lead frame of the light emitting diode lamp can be connected. Without being covered by the synthetic resin It is exposed on the back 2 surface side, in which is arranged close over the synthetic resin.
[0008]
Since the metal electrode is insert-molded, the heat energy from the LED lamp is transferred to the anode-side metal electrode and the cathode-side metal electrode connected to each other via the anode-side lead frame and the cathode-side lead frame of the LED lamp. Furthermore, efficient heat transfer is performed to a housing made of a synthetic resin in which the metal electrode is insert-molded. In particular, by using a synthetic resin with high thermal conductivity, heat generated in the LED on the anode side lead frame can be efficiently transferred from the anode side metal electrode to the cathode side metal electrode via the synthetic resin. it can.
[0009]
Further, the anode side metal electrode insert-molded in the housing is widened, the cathode-side metal electrode insert-molded in the housing is also narrowed, and the anode-side metal electrode and the cathode-side metal electrode Is insert-molded in close proximity through the synthetic resin, so that the heat of the anode-side metal electrode can be efficiently transferred to the cathode-side metal electrode.
[0010]
Therefore, since heat can be radiated not only by the anode side metal electrode but also by the cathode side metal electrode, heat can be radiated by the metal electrode near the LED, and the anode side metal electrode can be reduced in size.
[0011]
The anode-side metal electrode and the cathode-side metal electrode, which are insert-molded in the housing, are at least part of both surfaces of the metal electrode so that the anode-side lead frame and the cathode-side lead frame of the light-emitting diode lamp can be connected. Is exposed without being covered with the synthetic resin, it is possible to join the lead frame of the LED and the electrode, such as welding or caulking, even with a metal electrode which is insert-molded in the housing.
[0012]
Here, it is desirable that the anode side lead frame and the cathode side lead frame of the LED lamp have good heat conduction. Usually, a round copper wire or a square copper wire has a relatively large cross-sectional area and has a heat transfer resistance. Used in a small state.
[0013]
Further, the metal electrode insert-molded in the housing made of synthetic resin is preferably as thick as possible. However, the metal electrode may have a thickness that allows the anode-side lead frame and the cathode-side lead frame of the LED lamp to be mechanically and electrically joined. .
[0014]
in addition, Since the closest distance in the proximity arrangement of the anode side metal electrode and the cathode side metal electrode is 0.3 mm to 1.0 mm, it has an insulating function to prevent a short circuit between the anode side metal electrode and the cathode side metal electrode. In addition, the heat of the anode side metal electrode can be efficiently transferred to the cathode side metal electrode.
[0015]
Also, Each of the metal electrodes connecting the anode side lead frame and the cathode side lead frame of the LED lamp has a connection terminal for electrically and mechanically connecting each lead wire, so that Since electrical connection is easy and mechanical connection can be used as necessary, it can be used as a socket for an LED lamp.
[0016]
And The metal electrode connecting the anode side lead frame and the cathode side lead frame of the LED lamp of the housing has an area ratio of 7: 3 to 9: 1 between the anode side and the cathode side, and the anode side metal electrode Heat is actively transferred to the cathode-side metal electrode via a highly heat-conductive synthetic resin and radiated by both electrodes, so the size of the anode-side metal electrode can be reduced, and the LED The lamp device can be miniaturized.
[0017]
Furthermore, Since the heat dissipating fins are formed around the housing, the cooling capacity can be increased. In particular, by providing the radiation fins, heat is quickly released from the housing, and heat transfer is promoted.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that, in the above-described embodiment in the figure, the same reference numerals or the same symbols indicate the same or corresponding components, and thus a duplicate description is omitted.
[0019]
Embodiment 1
FIG. 1 is an explanatory diagram of a general LED lamp. FIG. 2 is a development view of the entire components of the LED lamp device according to Embodiment 1 of the present invention. 3A is a plan view of FIG. 2, FIG. 3B is a front view of FIG. 2, and FIG. 3C is a right side view of FIG. FIG. 4 is a cross-sectional view taken along line AA in FIG. FIG. 5 is an overall assembly diagram of the LED lamp device according to Embodiment 1 of the present invention. 6A is a perspective view of only the metal electrode inserted into the LED lamp device of Embodiment 1 of the present invention, and FIG. 6B is a cross-sectional view taken along line XX along the line XX.
[0020]
In FIG. 1, an LED lamp 1 has an anode of an LED chip 1a joined to a cup 2a at an upper end of an anode side lead frame 2 with silver paste or the like, and an upper end of a cathode side lead frame 3 is connected to a cathode of the LED chip 1a. They are connected by a gold wire 3a. The ends of the anode side lead frame 2 and the cathode side lead frame 3 are sealed with a package 4 made of a transparent epoxy resin. The anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1 embodying the present invention are preferably made of materials having good heat conduction, and are usually round copper wires or square copper wires and have a relatively large cross-sectional area and are conductive. It is configured with a low thermal resistance.
[0021]
As shown in FIGS. 1 to 6, the housing base 10 made of synthetic resin has a metal electrode 12 that connects the anode-side lead frame 2 of the LED lamp 1 and a metal electrode 13 that connects the cathode-side lead frame 3 of the LED lamp 1. Are formed such that the area of the anode-side metal electrode 12 corresponding to the cup 2a at the upper end of the anode-side lead frame 2 of the LED lamp 1 is wide and the area of the cathode-side metal electrode 13 connecting the cathode-side lead frame 3 is narrow. . The synthetic resin of the housing base 10 is an insulator and is made of a material having a high thermal conductivity of 0.4 W / m · K or higher.
[0022]
The housing base 10 and the housing cover 20 constitute the housing of the present embodiment, and the anode side metal electrode 12 and the cathode side metal electrode 13 are integrated by insert molding.
[0023]
As shown in FIG. 6, the metal electrode 12 connecting the anode side lead frame 2 is generally U-shaped as a whole, and sandwiches a lead wire provided with a substantially V-shaped slit 12 b at one end, A connection terminal 12a for electrical and mechanical connection is formed. The other end portion is formed with a notch 12c that prevents contact with the cathode-side lead frame 3 at a substantially central portion of the upper surface.
[0024]
The metal electrode 13 connecting the cathode side lead frame 3 is substantially U-shaped as a whole, and sandwiches a lead wire provided with a substantially V-shaped slit 13b at one end to electrically and mechanically A connection terminal 13a to be connected to is formed.
[0025]
The inner surface of the metal electrode 12 and the outer surface of the metal electrode 13 are doubled so as to form an opposing surface so that the distance between them is about 0.3 to 1 mm. The larger the facing surface, the better the heat conduction, and the heat transfer is uniformly conducted to the synthetic resin of the housing base 10, and even if a temperature difference occurs between the metal electrode 12 and the metal electrode 13, the temperature difference is It works to eliminate. Specifically, the housing base 10 is made of a synthetic resin made of a material having a thermal conductivity of 0.4 W / m · K or more, so that if there is a temperature gradient between them, the housing base 10 is made uniform by thermal conduction. . The gap between the end portions of the insert-molded metal electrode 12 and the metal electrode 13 is about 0.3 to 1 mm because, for example, the end portions of the metal electrode 12 and the metal electrode 13 overlap each other with a predetermined distance. Although the electrostatic capacitance between the metal electrode 12 and the metal electrode 13 is increased, the heat transfer characteristics can be improved.
[0026]
The large capacitance between the metal electrode 12 and the metal electrode 13 means that the capacitance between the anode and the cathode of the LED lamp 1 is large. When used for a display, the response is delayed. An afterimage is generated in moving image output. Further, the lighting display circuit resonates at a relatively low frequency due to the reactor component of the constant current circuit, and an unpredictable voltage may be applied to the LED lamp 1 in accordance with the switching operation. Therefore, it is desirable that the capacitance between the metal electrode 12 and the metal electrode 13 is small.
[0027]
Here, changes in the structures of the metal electrode 12 and the metal electrode 13 will be described with reference to FIGS. 7 and 8.
[0028]
7A is a perspective view of only the metal electrode inserted into the LED lamp device of Embodiment 2 of the present invention, FIG. 7B is a YY sectional view taken along the cutting line YY, and FIG. These are the perspective views of only the metal electrode inserted in the LED lamp device of Embodiment 3 of this invention, (b) is YY sectional drawing by the cutting line YY. FIG. 9 is a cross-sectional view corresponding to the cross-sectional view taken along the line AA in FIG. 3A of the LED lamp device according to Embodiment 3 of the present invention.
[0029]
In FIG. 7, the metal electrode 12 that connects the anode side lead frame 2 is generally U-shaped as a whole, and a lead wire provided with a substantially V-shaped slit 12b at one end is sandwiched between A connection terminal 12a for mechanical connection is formed. The other end is a notch 12c that prevents contact with the cathode-side lead frame 3 at the substantially central portion of the upper surface, and the end excluding the notch 12c is a bent piece that is about ½ of the length of the connection terminal 12a. 12d (12d1 and 12d2) is formed.
[0030]
The metal electrode 13 connecting the cathode side lead frame 3 is substantially U-shaped as a whole, and sandwiches a lead wire provided with a substantially V-shaped slit 13b at one end to electrically and mechanically A connection terminal 13a to be connected to is formed. A bent piece 13d is formed at the other end of the metal electrode 12 so as to correspond to a bent piece 12d (12d1 and 12d2) that is about ½ of the length of the connection terminal 12a.
[0031]
The opposing surfaces of the bent pieces 12d (12d1 and 12d2) of the metal electrode 12 and the bent pieces 13d of the metal electrode 13 are formed so that the distance between them is about 0.3 to 1 mm. The larger the facing surface, the better the heat conduction, and the heat transfer is uniformly conducted to the synthetic resin of the housing base 10, and even if a temperature difference occurs between the metal electrode 12 and the metal electrode 13, the temperature difference is It works to eliminate. The gap between the end portions of the insert-molded metal electrode 12 and the metal electrode 13 is about 0.3 to 1 mm because, for example, the end portions of the metal electrode 12 and the metal electrode 13 face each other with a predetermined distance therebetween. The capacitance between the metal electrode 12 and the metal electrode 13 increases, but heat transfer characteristics can be improved.
[0032]
Further, as shown in FIGS. 8 and 9, the metal electrode 12 connecting the anode side lead frame 2 is generally U-shaped as a whole, and a lead wire having a substantially V-shaped slit 12b at one end. A connection terminal 12a that is electrically and mechanically connected is formed. At the other end, only a notch 12c for preventing contact with the cathode-side lead frame 3 is formed at the substantially central portion of the upper surface.
[0033]
The metal electrode 13 connecting the cathode side lead frame 3 is substantially U-shaped as a whole, and sandwiches a lead wire provided with a substantially V-shaped slit 13b at one end to electrically and mechanically Only the connection terminal 13a to be connected to is formed.
[0034]
The gap between the end of the metal electrode 13 and the end of the metal electrode 12 is about 0.3 to 1 mm, and usually 0.3 mm or more in consideration of static electricity, resin fluidity, and the like. This gap is an interval that eliminates the temperature difference even if a temperature difference occurs between the metal electrode 12 and the metal electrode 13. Specifically, the housing base 10 has a thermal conductivity of 0. By using a synthetic resin made of a material of 4 W / m · K or more, if there is a temperature gradient between them, it is made uniform by heat conduction. The gap between the end portions of the insert-molded metal electrode 12 and the metal electrode 13 is about 0.3 to 1 mm, for example, even when the end portions of the metal electrode 12 and the metal electrode 13 overlap with a predetermined distance. In this case, heat transfer characteristics can be improved without increasing the capacitance. The small capacitance between the metal electrode 12 and the metal electrode 13 improves the responsiveness when used for a display, and an afterimage does not remain even when moving images are output. Even if it is used as a lighting display circuit, it does not resonate at a relatively low frequency due to the reactor component of the constant current circuit, or an unpredictable voltage is applied to the LED lamp 1 with the switching operation. Therefore, in the present embodiment, since the electrostatic capacitance between the metal electrode 12 and the metal electrode 13 is small, it can be used as a display in which an afterimage can be ignored, and heat dissipation can be improved.
[0035]
Of course, according to the first to third embodiments, in the first embodiment of FIG. 6, the opposing area of the metal electrode 12 and the metal electrode 13 can be maximized, and the second embodiment of FIG. This is the order of the third embodiment shown in FIG. However, if the gap between the end portions of the insert-molded metal electrode 12 and the metal electrode 13 is about 0.3 to 1 mm, the embodiment 3 of FIG. There is an effect that the electric capacity can be set small.
[0036]
In the first to third embodiments, the opposite side of the housing base 10 of the insert-molded metal electrode 12 and metal electrode 13 is at least a portion where the anode-side lead frame 2 and the cathode-side lead frame 3 are connected. Exposed holes 10a and 10b are formed to be exposed surfaces. That is, when the anode-side lead frame 2 and the cathode-side lead frame 3 are connected to the metal electrode 12 and the metal electrode 13, respectively, it is possible to energize the metal electrode 12 and the metal electrode 13 in the front and back directions. A path with low electrical resistance is formed. A part of the electrodes can be exposed so that current can flow in the front and back directions of the metal electrode 12 and the metal electrode 13, and the thickness of the metal electrode 12 and the metal electrode 13 can be reduced.
[0037]
Furthermore, the housing base 10 of the LED lamp device of the first embodiment is provided with a housing cover 20 in which the metal electrodes 12 and 13 are inserted to increase the outer surface area. The housing cover 20 is formed integrally with the housing base 10.
[0038]
Outside the housing cover 20, a lamp guide hole 21 including a rising guide that holds the periphery of the LED lamp 1 and accurately positions it, a connection portion between the anode side lead frame 2 of the LED lamp 1 and the metal electrode 12, Confirmation holes 22 and 23 for confirming a connection portion between the cathode side lead frame 3 and the metal electrode 13 are formed. Lead wire insertion holes 24a and 25a and lead wire insertion holes 24b and 25b are formed at the lower opening end. Further, engaging projections 26 and 27 for engaging with the casing cover 30 are provided. The engagement protrusion 28 is for engagement with a mating member (not shown).
[0039]
When the housing base 10 is integrally formed inside the housing cover 20, both have a structure in which the metal electrode 12 and the metal electrode 13 are sandwiched as shown in the sectional view of FIG. 4.
[0040]
The casing cover 30 holds the outside of the housing base 10 to which the LED lamp 1 is attached, and also has an electrode fixing groove 31 parallel to the long side for fixing the ends of the metal electrodes 12 and 13 formed by insert molding on the housing base 10. And the terminal groove | channel 32 parallel to the short side which fixes the lower end part of the connecting terminal 12a which provided the substantially V-shaped slit 12b, and the connecting terminal 13a which provided the V-shaped slit 13b is formed. Further, lead wire insertion holes 34 a and 35 a and lead wire insertion holes 34 b and 35 b through which lead wires (not shown) are inserted are formed on the short sides on both sides of the casing cover 30. A lead wire guide groove 34 is formed between the lead wire insertion hole 34a and the lead wire insertion hole 34b, and a lead wire guide groove 35 is formed between the lead wire insertion hole 35a and the lead wire insertion hole 35b. Even if the lead wire passes from the lead wire insertion hole 34a to the lead wire insertion hole 34b and from the lead wire insertion hole 35a to the lead wire insertion hole 35b, it can be mounted without being cut, and the housing cover 20 can be mounted. The lead wire can be firmly fixed by sandwiching between the two.
[0041]
Engagement recesses 36 and 37 that engage with the engagement protrusions 26 and 27 of the housing cover 20 are formed on the long sides on both sides of the casing cover 30. The engagement protrusions 26 and 27 and the engagement recesses 36 and 37 are engaged with each other so that they are integrally joined.
[0042]
On the opposite surface of the casing cover 30, heat radiation fins 38 are formed in an uneven shape by a plurality of grooves. Since the heat dissipating fin 38 has a casing cover made up of the housing cover 20 and the casing cover 30 that cover the metal electrodes 12 and 13 of the housing base 10 and has a large outer surface area, the cooling area can be further increased. Cooling capacity can be increased, insulation can be maintained, and adjacent assembly is easy. In particular, by increasing the outer surface area of the casing cover, heat is efficiently released quickly from the housing base 10 and heat transfer is promoted.
[0043]
Further, the connection terminal 12 a provided with a substantially V-shaped slit 12 b at the end of the metal electrode 12 and the connection terminal 13 a provided with a substantially V-shaped slit 13 b at the end of the metal electrode 13 are provided on the housing base 10. It is desirable to provide the center at a point-symmetrical position. With this configuration, even if the end of the lead wire sandwiched between the substantially V-shaped slit 12b at the end of the metal electrode 12 and the substantially V-shaped slit 13b at the end of the metal electrode 13 is long, Or even if it continues, there is no possibility of causing a short circuit between each other. Moreover, wiring and attachment can be simplified by attaching to the lead wire which is mechanically linear matrix wiring.
[0044]
In this way, the metal electrodes 12 and 13 that connect the anode-side lead frame 2 and the cathode-side lead frame 3, respectively, have lead wires (not shown) interposed therebetween, and are electrically and mechanically connected connection terminals 12 a and 13 a. Therefore, electrical connection and / or mechanical connection with others is easy, and mechanical / electrical connection can be made as required, so that the LED lamp 1 can be used as a socket.
[0045]
The metal electrode 12 and the metal electrode 13 are formed so that the area of the metal electrode 12 corresponding to the cup 2a at the upper end of the anode side lead frame 2 is wide and the area of the metal electrode 13 connecting the cathode side lead frame 3 is narrow. However, according to the experiments by the inventors, the metal electrodes 12 and 13 that connect the anode-side lead frame 2 and the cathode-side lead frame 3 of the LED lamp 1 of the housing base 10 have an area between the anode side and the cathode side. When the ratio is within the range of 7: 3 to 9: 1, the heat dissipation capability of the LED lamp 1 is made to correspond to the heat receiving capability of each metal electrode, and the upper end of the anode-side lead frame 2 is within the range of the normal metal electrode thickness. There is a technical significance in that the area corresponding to the cup 2a is widened and the other area is narrowed. Of course, this also changes depending on the light emission output, light emission efficiency, and energization current, and also changes depending on the thickness of the metal electrodes 12 and 13.
[0046]
However, in consideration of the heat energy transmission state of the anode-side lead frame 2 and the cathode-side lead frame 3 of the LED lamp 1, the design conditions of the embodiment, and the heat generation amount of the embodiment, it is insert-molded into the housing base 10 made of synthetic resin. The metal electrodes 12 and 13 are preferably as thick as possible, but may be any thickness as long as the anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1 can be mechanically and electrically joined. Accordingly, the area ratio between the anode side and the cathode side of the metal electrodes 12 and 13 is preferably in the range of 7: 3 to 9: 1. Even in the range of 7: 3 to 9: 1, the metal electrode 13 on the cathode side lead frame 3 side generates heat from the LED lamp 1 mounted on the cup 2a at the upper end of the anode side lead frame 2. It has a heat receiving capability that exceeds the heat transferred to the cathode lead frame 3 via the bonding wire 3a and the heat transferred from the metal electrode 12 on the anode lead frame 2 side through the synthetic resin of the housing base 10. Thereby, heat generated from the LED lamp 1 mounted on the cup 2a at the upper end of the anode side lead frame 2 is easily transmitted to the metal electrode 13 on the cathode side lead frame 3 side, and heat dissipation of the LED lamp 1 is promoted. The
[0047]
At this time, in order to increase the surface area of the metal electrode 13 from the metal electrode 12, the plate material may be bent, or a plurality of pieces may be folded, or plate-like pieces may be joined. In any case, the area ratio between the anode side and the cathode side of the metal electrodes 12 and 13 may be set within a range of 7: 3 to 9: 1 while being inserted in the synthetic resin of the housing base 10.
[0048]
As described above, the housing base 10 according to the first embodiment is configured such that the metal electrodes 12 and 13 that connect the anode-side lead frame 2 and the cathode-side lead frame 3 of the LED lamp 1 are the cups at the upper end of the anode-side lead frame 2. Since the area of the metal electrode 12 corresponding to 2a is wide and the other metal electrode 13 is formed to have a small area, the heat dissipation capability of the LED chip 1a corresponds to the heat reception capability of the metal electrodes 12, 13 and the heat dissipation capability thereof. Since it is not necessary to secure a useless heat radiation area, the overall shape can be reduced in size.
[0049]
By the way, radiating fins (not shown) can be formed around the housing base 10 of the first embodiment, thereby increasing the cooling capacity. In particular, by providing the radiation fins, heat is quickly released from the housing base 10 and heat transfer is promoted.
[0050]
Also, In the first to third embodiments, the housing base 10 having the metal electrodes 12 and 13 to which the anode-side lead frame 2 and the cathode-side lead frame 3 of the LED lamp 1 are connected is housed in the housing cover 20. 10 is covered with a casing cover 30. When the present invention is implemented, a housing having metal electrodes 12 and 13 to which the anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1 are connected, respectively. The base 10 can be covered only with the housing cover 20. At this time, the exposed portion can be eliminated by reducing the protrusions below the metal electrodes 12 and 13 of the above-described Embodiments 11 to 3. When the present invention is carried out, the metal electrodes 12 and 13 respectively connecting the anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1 are insert-molded so as to be embedded in the housing base 10, and the housing The cover 20 and the casing cover 30 can be omitted. At this time, the exposed portion can be eliminated by reducing the protrusions below the metal electrodes 12 and 13 of the first embodiment.
[0051]
FIG. 10 is an overall configuration diagram of an LED lamp device according to Embodiment 4 of the present invention. In addition, the same code | symbol or the same symbol as the said Embodiment 1 thru | or 3 in a figure shows the component which is the same or corresponds.
[0052]
In FIG. 10, the housing 40 is formed with radiating fins 41 around the periphery thereof, and connects the anode-side lead frame 2 and the cathode-side lead frame 3 of the LED lamp 1 of both metal electrodes 12, 13, respectively. Except for the part, it is insert molded embedded in a synthetic resin. The surface side (upper side) of the metal electrode 12 and the metal electrode 13 which are insert-molded in the housing 40 is an exposed hole so that at least a portion where the anode side lead frame 2 and the cathode side lead frame 3 are connected becomes an exposed surface. 42 is formed. The number of the exposed holes 42 may be one or two as in the first embodiment.
[0053]
Although not shown, the opposite side (lower side) of the metal electrode 12 and the metal electrode 13 which are insert-molded in the housing 40 is at least a portion where the anode-side lead frame 2 and the cathode-side lead frame 3 are connected. Has an exposed hole so as to be an exposed surface.
[0054]
In the above embodiment, the case where the housing bases 10 and 40 are substantially rectangular parallelepiped has been described. However, when the present invention is implemented, the housing bases 10 and 40 can be formed in a substantially cylindrical shape, a substantially triangular shape, or a substantially polygonal shape.
[0055]
As described above, the LED lamp device according to the first and second embodiments includes the LED lamp 1 having the anode side lead frame 2 and the cathode side lead frame 3, and the anode side lead frame 2 and the cathode side lead frame of the LED lamp 1. 3 is an insulator formed by insert-molding metal electrodes 12 and 13 respectively connected to the housing 3 and includes a housing base 10 made of a synthetic resin having a thermal conductivity of 0.4 W / m · K or more.
[0056]
Since the metal electrodes 12 and 13 are insert-molded in the housing base 10 made of synthetic resin, the thermal energy from the LED lamp 1 is respectively transmitted through the anode-side lead frame 2 and the cathode-side lead frame 3 of the LED lamp 1. Further, heat energy is efficiently transmitted from the metal electrodes 12 and 13 to the housing base 10 made of a synthetic resin to the connected metal electrodes 12 and 13, and efficient heat dissipation is performed. In particular, the housing base 10 made of a synthetic resin having a thermal conductivity of 0.4 W / m · K or more can be expected to have a sufficient heat dissipation effect to the extent of thermal energy generated by the LED lamp 1. The synthetic resin having a thermal conductivity of 0.4 W / m · K or higher does not change drastically depending on whether the thermal conductivity is 0.4 W / m · K or lower. That is, it is experimentally derived from the heat generation state of the LED lamp 1. As a matter of course, the effect is more remarkable in a synthetic resin having a thermal conductivity of 0.7 W / m · K or more, and further a thermal conductivity of 0.9 W / m · K or more. there were.
[0057]
Here, the anode-side lead frame 2 and the cathode-side lead frame 3 of the LED lamp 1 are preferably manufactured with good heat conduction, and are usually round copper wires or square copper wires and have a relatively large cross-sectional area. Therefore, materials and structures having low heat transfer resistance are used.
[0058]
Further, the metal electrodes 12 and 13 which are insert-molded on the housing base 10 made of synthetic resin preferably have better heat conduction as the thickness increases. However, the anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1 are preferable. Any thickness that can be mechanically and electrically bonded is acceptable.
[0059]
In the LED lamp devices according to the first to fourth embodiments, the metal electrodes 12 and 13 that connect the anode-side lead frame 2 and the cathode-side lead frame 3 of the LED lamp 1 of the housing base 10 are arranged at the upper end of the anode-side lead frame 2. Since the area corresponding to the cup 2a is wide and the other area is narrow, the heat dissipation capability can be made to correspond to the heat receiving capability and heat conduction, and it is not necessary to secure a useless heat dissipation area. The overall shape can be reduced.
[0060]
In the LED lamp devices of the first to fourth embodiments, the opposite surfaces of the metal electrodes 12 and 13 that connect the anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1 are also exposed from the housing base 10. Therefore, when the lead frames such as the anode side lead frame 2 and the cathode side lead frame 3 are welded, an efficient current path in the thickness direction of the metal electrodes 12 and 13 is formed. The thickness of 13 can be reduced and welded. In the case of implementing the present invention, the anode side metal electrode 12 and the cathode side metal electrode 13 which are insert-molded in the housing are connected so that the anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1 can be connected. It is sufficient that at least a part of both surfaces of the metal electrode is exposed without being covered with the synthetic resin.
[0061]
In the LED lamp devices of the first to fourth embodiments, lead wires (not shown) are sandwiched between the metal electrodes 12 and 13 that connect the anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1, respectively. Since the connection terminals 12a and 13a to be electrically and mechanically connected are formed, electrical connection with other electric circuit components is easy, and mechanical connection to a rod-shaped or plate-shaped electrode is performed as necessary. At the same time, since it can be electrically connected, it can be used as a socket for the LED lamp 1.
[0062]
In the LED lamp devices of Embodiments 1 to 4, the metal electrodes 12 and 13 that connect the anode side lead frame 2 and the cathode side lead frame 3 of the LED lamp 1 of the housing base 10 are respectively connected to the anode side and the cathode side. When the area ratio is in the range of 7: 3 to 9: 1, the heat dissipation capability of the LED lamp 1 is made to correspond to the heat reception capability of each metal electrode, and the upper end of the lead frame is within the range of the thickness of the normal metal electrodes 12 and 13. The area corresponding to the cup 2a can be widened and the other area can be narrowed. In particular, the metal electrode 12 on the anode lead frame 2 side with a large amount of generated heat is transferred to the metal electrode 13 on the cathode lead frame 3 side in close proximity to the cathode substrate via a highly heat-conductive resin, so that the cathode The side can also dissipate heat. In addition, a heat transfer path that has conventionally reduced the temperature difference between the anode and the cathode of the LED 1a through the bonding wire 3a can be performed between the metal electrodes 12 and 13, thereby improving the reliability at the wire contact point. Can be increased. Furthermore, since the metal electrode 13 on the cathode lead frame 3 side can also dissipate heat, the area of the metal electrode 12 on the anode lead frame 2 side can be reduced without reducing the heat dissipating ability in the LED lamp device, Miniaturization is possible.
[0063]
The LED lamp devices according to the first to third embodiments are not formed with heat radiating fins around the housing base 10, but when the present invention is implemented, like the LED lamp device according to the fourth embodiment, The heat radiation fins 41 can be formed around the housing 40 to increase the cooling capacity. In particular, by providing the radiation fins 41, heat is quickly released from the housing 40, and heat transfer from the anode side lead frame 2 and the cathode side lead frame 3 is promoted.
[0064]
Since the housing base 10 of the LED lamp devices according to the first to third embodiments includes a casing cover made up of the housing cover 20 and the casing cover 30 with a large outer surface area covering the metal electrodes 12 and 13, the cooling area. Therefore, the cooling capacity can be increased, the insulation can be maintained, and the adjacent assembly can be easily performed. In particular, by increasing the outer surface area of the casing cover including the housing cover 20 and the casing cover 30, heat is quickly released from the housing base 10 and heat transfer is promoted.
[0065]
The housing base 10 of the LED lamp devices of the first to third embodiments includes a housing cover 20 that covers the metal electrodes 12 and 13 that increase the outer surface area, and a casing cover 30 that is integrally fixed to the housing cover 20. Therefore, since the metal electrodes 12 and 13 are covered with the housing cover 20 and the casing cover 30, the cooling area can be increased, the cooling capacity can be increased, and the insulation can be maintained. Easy to assemble. In particular, by increasing the outer surface areas of the housing cover 20 and the casing cover 30, heat is quickly released from the housing base 10 and heat transfer is promoted.
[0066]
【The invention's effect】
As described above, the LED lamp device according to claim 1 is an LED lamp having an anode side lead frame and a cathode side lead frame, and a metal electrode that connects the anode side lead frame and the cathode side lead frame of the LED lamp. And a housing made of an insulating synthetic resin having a thermal conductivity of 0.4 W / m · K or more, and the anode side metal electrode insert-molded in the housing has a large area, and the cathode side The metal electrode is formed to have a small area, and at least a part of both surfaces of the metal electrode is not covered with the synthetic resin so that the anode side lead frame and the cathode side lead frame of the light emitting diode lamp can be connected. Exposed on the surface side and placed in close proximity via the synthetic resin A.
[0067]
Therefore, the metal electrode is insert-molded, so that the heat energy from the LED lamp is connected to the anode-side metal electrode and the cathode-side metal via the anode-side lead frame and the cathode-side lead frame of the LED lamp, respectively. Further, efficient heat transfer is performed on the electrode and the housing made of synthetic resin in which the metal electrode is insert-molded. In particular, by using a synthetic resin with high thermal conductivity, heat generated in the LED on the anode side lead frame can be efficiently transferred from the anode side metal electrode to the cathode side metal electrode via the synthetic resin. it can. Further, the anode side metal electrode insert-molded in the housing is widened, the cathode-side metal electrode insert-molded in the housing is also narrowed, and the anode-side metal electrode and the cathode-side metal electrode Is insert-molded in close proximity through the synthetic resin, so that the heat of the anode-side metal electrode can be efficiently transferred to the cathode-side metal electrode. The anode-side metal electrode and the cathode-side metal electrode, which are insert-molded in the housing, are at least part of both surfaces of the metal electrode so that the anode-side lead frame and the cathode-side lead frame of the light-emitting diode lamp can be connected. Is exposed without being covered with the synthetic resin, it is possible to join the lead frame of the LED and the electrode, such as welding or caulking, even with a metal electrode which is insert-molded in the housing.
[0068]
Therefore, since heat can be radiated not only by the anode side metal electrode but also by the cathode side metal electrode, heat can be radiated by the metal electrode near the LED, and the anode side metal electrode can be reduced in size.
[0069]
Also, The closest distance in the close arrangement of the anode side metal electrode and the cathode side metal electrode is formed to be 0.3 mm to 1.0 mm. From the anode side It has an insulating function to prevent a short circuit between the metal electrode and the cathode side metal electrode, and heat of the anode side metal electrode can be efficiently transferred to the cathode side metal electrode.
[0070]
And A connection terminal for electrically and mechanically connecting the lead frame wire to each of the metal electrodes connecting the anode side lead frame and the cathode side lead frame of the LED lamp is formed. From other Therefore, it can be used as a socket for an LED lamp.
[0071]
Furthermore, The metal electrode connecting the anode side lead frame and the cathode side lead frame of the LED lamp of the housing has an area ratio of 7: 3 to 9: 1 between the anode side and the cathode side, and the anode side metal electrode Heat was positively transferred to the cathode side metal electrode through a highly heat-conductive synthetic resin to dissipate heat at both electrodes. So the anode side The size of the metal electrode can be reduced, and the LED lamp device can be miniaturized.
[0072]
Furthermore, It is a radiating fin. From heat dissipation fin By providing, heat is quickly released from the housing, and heat transfer is promoted.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram of a general LED lamp.
FIG. 2 is an exploded view of the entire components of the LED lamp device according to Embodiment 1 of the present invention.
3 (a) is a plan view of FIG. 2, FIG. 3 (b) is a front view of FIG. 2, and FIG. 3 (c) is a right side view of FIG.
4 is a cross-sectional view taken along a cutting line AA in FIG.
FIG. 5 is an overall assembly diagram of the LED lamp device according to the first embodiment of the present invention.
6A is a perspective view of only a metal electrode inserted in the LED lamp device of Embodiment 1 of the present invention, and FIG. 6B is a cross-sectional view taken along line XX along the cutting line XX.
7A is a perspective view of only a metal electrode inserted in the LED lamp device according to Embodiment 2 of the present invention, and FIG. 7B is a YY cross-sectional view taken along the cutting line YY.
8A is a perspective view of only a metal electrode inserted in the LED lamp device according to Embodiment 3 of the present invention, and FIG. 8B is a ZZ cross-sectional view taken along the cutting line ZZ.
9 is an LED lamp device according to Embodiment 3 of the present invention, and is a cross-sectional view corresponding to a cross-sectional view taken along line AA in FIG.
FIG. 10 is an overall configuration diagram of an LED lamp device according to a fourth embodiment of the present invention.
[Explanation of symbols]
1 LED lamp
2 Anode-side lead frame
2a cup
3 Cathode side lead frame
3a Bonding wire
10 Housing base
12,13 Metal electrode
12a, 13a connection terminal
20 Housing cover
30 Casing cover
40 housing

Claims (1)

A light emitting diode lamp having an anode side lead frame and a cathode side lead frame;
A metal having a connection terminal that connects the anode-side lead frame and the cathode-side lead frame, and forms a V-shaped slit for electrically and mechanically connecting the lead frame wire from the outside. Electrodes,
An anode-side metal electrode connected to the cathode-side lead frame, and an anode-side metal electrode formed with a notch for preventing contact with the cathode-side lead frame at a substantially upper central portion connected to the anode-side lead frame And a housing made of an insulating synthetic resin having a thermal conductivity of 0.4 W / m · K or more formed by insert molding.
The metal ratio is set such that the area ratio of the anode side metal electrode and the cathode side metal electrode is within a range of 7: 3 to 9: 1, and the anode side lead frame and the cathode side lead frame of the light emitting diode lamp can be connected. At least a part of both surfaces of the electrode is exposed to the front and back two surfaces without being covered with the synthetic resin, and the closest distance between the anode side metal electrode and the cathode side metal electrode is 0. A light-emitting diode lamp device, characterized in that the light-emitting diode lamp device is disposed close to 3 mm to 1.0 mm.

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