JP4784170B2 - Power supply - Google Patents

Description

  The present invention relates to a power supply device having an inductance component such as a transformer or a choke coil such as a switching power supply, and in particular, heat radiation of an inductance component suitable for a relatively large output, such as an in-vehicle power supply device. It relates to a fixed structure.

  As a conventional transformer fixing structure, there is a structure in which a core is mounted in contact with a metal base plate, and the mounting bracket is placed on the core and the mounting bracket is fixed to the base plate (see Patent Document 1). There is also a structure in which a top plate portion of a case is brought into contact with a transformer via a heat dissipation sheet to radiate heat from a transformer attached to a printed circuit board (see Patent Document 2).

JP 2004-296818 A JP 2002-78212 A

  As described in Patent Document 1, in the structure in which the transformer is fixed by the mounting bracket, a mounting bracket dedicated to the transformer is required, resulting in high cost. In addition, although the upper surface of the core is in contact with the mounting bracket, heat radiation due to heat mounting bracket due to the energy of the core loss of the transformer cannot be expected so much. For this reason, the temperature of the upper part of the core rises, and this temperature rise further increases the loss, creating a vicious circle that causes a further temperature rise. Further, when an inductive heat generating component such as a transformer is accommodated in a base plate fixed to the vehicle body and a cover combined therewith, such as an in-vehicle power supply device, the heat at the top of the core is substantially Must rely on heat dissipation by heat conduction to the internal air. For this reason, there is a problem that the temperature of the internal air is increased, the temperature of not only this transformer but also other components such as a choke coil is increased, and the loss of the entire power supply device is also increased.

  On the other hand, as described in Patent Document 2, a transformer mounted on a printed board has a structure that can be used for a relatively small transformer of about several tens of watts. For example, in an in-vehicle power supply device exceeding 1 kW. When this conventional structure is applied, the printed circuit board cannot withstand the weight and vibration of the transformer and cannot be employed. Further, the heat dissipation of the core mainly depends on the heat dissipation to the case, so that the heat dissipation of the core from the printed circuit board side becomes insufficient, which also increases the loss.

  SUMMARY OF THE INVENTION In view of the above problems, the present invention provides a power supply device that does not require a dedicated mounting bracket, has good heat dissipation, and has an inductance component fixing structure that can be used in a relatively large power supply device. With the goal.

The power supply device of the present invention is provided with a columnar protrusion on a metal base plate ,
An inductance component having a split core on the base plate is placed in contact with the surface of the core on one side,
On the top plate portion of the metal cover that covers the components of the power supply device including the inductance component combined with the base plate, a protruding portion protruding inward is formed,
The cover is combined with the base plate, and the columnar protrusion is fastened to the cover, whereby the protruding portion of the cover is pressed against the surface of the core on the other side of the inductance component, and the inductance component is placed on the base plate and the base plate. It is characterized by being sandwiched between the cover.

Further, the power supply device of the present invention forms a recessed surface recessed inwardly in the top plate portion of the cover,
The protrusion is formed on the concave surface.

Further, the power supply device of the present invention is characterized in that a radiator having a radiation fin is fixed to an outer surface of a portion of the cover top plate portion where the projecting portion is formed in contact with the top plate portion.

  Since the power supply device of the present invention has a structure in which the core of the inductance component is sandwiched between the metal base plate and the metal cover, heat is dissipated from the surface on the base plate side of the core (hereinafter referred to as the lower surface), and the opposite side. Heat is dissipated from the surface (hereinafter referred to as the upper surface), and the heat dissipating performance is improved. For this reason, the temperature rise of a core is suppressed and an inductance component with little core loss can be provided.

  Further, since the temperature rise of the core is suppressed, an inductance component having the same performance as the conventional one can be employed even when a smaller core than the conventional one is used, which contributes to the miniaturization of the inductance component or the power supply device. In addition, the internal space temperature can be lowered, and the loss of other components can be reduced, so that the loss and size reduction of the power supply device are promoted.

  Further, since a dedicated mounting bracket for fixing the inductance component is not necessary, coupled with the downsizing, it contributes to a reduction in the number of inductance components or power supply components and a cost reduction.

  In the power supply device of the present invention, a concave surface that is recessed inward is formed on the top plate portion of the cover, and the protruding portion is formed on the concave surface, thereby projecting upward from the inductance component that performs heat dissipation by the cover. Even if there is a component to be performed, the inductance component can be radiated without hindering the mounting of the component. Further, by forming a concave surface on the cover, the rigidity of the cover is increased, and the core can be reliably contacted.

  In the power supply device of the present invention, further, by fixing the radiator having the radiation fins in contact with the top plate portion on the outer surface of the portion of the top plate portion of the cover where the protruding portion is formed, Heat dissipation can be performed even better.

  FIG. 1 is an exploded perspective view showing an embodiment of a power supply device of the present invention, FIG. 2 is an exploded perspective view showing only the power supply device with its cover removed, and FIG. FIG. 4 is a sectional view showing a mounting structure of the inductance component. The power supply device of this embodiment constitutes a vehicle-mounted DC-DC converter. However, the power supply device of the present invention is not limited to being mounted on a vehicle.

  1 is a base frame made of a metal such as aluminum or copper, 2 is a cover made of a metal such as aluminum or iron, 3 is a printed circuit board, and 4 is a component to be radiated through the base frame 1 and the cover 2 in this embodiment. It is a transformer. Note that this heat radiation target component is not a transformer but may be another inductance component having a core such as a choke coil, or both the transformer and other inductance components such as a choke coil may be heat radiation target components. .

  The base frame 1 has radiating fins 5 on the bottom surface, which is the surface on the attachment target body 9 (see FIG. 4) side such as the vehicle body. As shown in FIGS. 1 and 2, the base frame 1 and the cover 2 have mounting holes 6 and 7 in the periphery thereof, and screws 8 are inserted into the mounting holes 6 and 7 as shown in FIG. Then, it is fixedly attached to the attachment object 9.

  A plurality of screw cylinders 10 for attaching the printed circuit board 3 are integrally provided on the upper surface of the base frame 1. The printed circuit board 3 is fixed to the base frame 1 by screwing screws 11 inserted into holes provided in the printed circuit board 3 into the screw cylinders 10.

  As shown in FIGS. 1 and 2, a plurality of rectifying diodes 12 are mounted on the base frame 1. A plurality of switching elements 14 such as FETs are mounted on a base plate 13 fixed to the base frame 1. The terminals of the switching elements 14 are soldered to the conductor pattern on the printed circuit board 3 and are pressed and fixed to the base plate 13 by springs 16 fixed to the base frame 1 by screws 15. As shown in FIG. 2, the resonance inductor 17, the choke coil 19, and the output terminal block 20 are mounted on the base frame 1.

  As shown in FIGS. 1 and 2, a line filter 22, a plurality of capacitors 23, a plurality of pulse transformers 24, a plurality of ICs 25, connectors 26 and 27, etc. are mounted on the printed circuit board 3.

  As shown in FIG. 1, the transformer 4 includes upper and lower E-shaped cores 31 and 32, upper and lower secondary windings 33 and 34 formed by punching a metal plate, and a bobbin 35 wound with a primary winding. The upper and lower secondary windings 33 and 34 are connected to each other by screws 36 and 37 to form a total of two turns. The bobbin 35 has a primary winding wound in a spiral shape and is sandwiched between the secondary windings 33 and 34. The primary winding may be a conductor pattern formed on the printed circuit board 3.

  Reference numeral 39 denotes a female screw piece fixed on the printed circuit board 3. The upper secondary winding 33 is fixed and positioned on the printed circuit board 3 by a screw 40 whose two corners are screwed into the female screw piece 39. A female screw 41 is fixed to the base frame 1 together with the rectifying diode 12. The lower secondary winding 34 is fixed to the base frame 1 by a screw 42 screwed into the female screw 41 and connected to the diode 12.

  A concave portion 44 that is slightly wider than the bridge portion of the lower core 32 is provided on the upper surface of the base frame 1, and the lower surface (bridge portion) of the core 32 is mounted on the concave portion 44 in contact therewith. As shown in FIG. 1, the printed circuit board 3 is provided with through holes 45 and 46 that match the center leg of the core 32 and the side legs on both sides, and as shown in FIG. The center leg and the side leg of 32 are inserted and fixed so that the core 32 does not shift laterally.

  As shown in FIG. 4, the center legs of the upper and lower cores 31 and 32 are inserted into the central opening of the primary windings 33 and 34 and the central opening of the bobbin 35 between the primary windings 33 and 34, The upper and lower cores 31 and 32 are bonded to each other.

  Then, a plurality of (two in the present embodiment) protruding portions 47 provided so that the upper surface (bridge portion) of the upper core 31 protrudes inwardly from the top plate portion 2a of the cover 2 are brought into contact with each other. In this embodiment, the protruding portion 47 is provided in a recessed surface 48 in which the top plate portion 2a of the cover 2 is recessed. The protrusion 47 is formed in a long shape in a direction perpendicular to the longitudinal direction of the core 31. The protrusion 47 may be formed so that the planar shape is circular or the like.

  Further, in order to firmly fix the cores 31 and 32 between the cover 3 and the base frame 1, the screws 50 are inserted into the through holes 49 provided in the vicinity of the projecting portions 47 so as to be integrated with the base frame 1. The screw 50 is screwed into the screw hole at the top of the columnar protrusion 51 and fastened. Accordingly, the protrusion 47 of the cover 2 is pressed against the upper surface of the core 31 with some deformation due to the elasticity of the cover 2, and the cores 31 and 32 are sandwiched and fixed between the base frame 1 and the cover 2. In this embodiment, the cores 31 and 32 have the same ground potential as the base frame 1 and the cover 2. The cores 31 and 32 and the secondary windings 33 and 34 are relatively fixed by the fixing structure of the secondary windings 33 and 34 to the printed circuit board 3 and the base frame 1 and the fixing structure of the cores 31 and 32 to the printed circuit board 3. Positioned in a non-contact state.

  Moreover, in this Embodiment, in order to perform the heat transfer from the core 31 to the cover 2 more favorably, the heat-transfer sheet | seat 52 which has the elasticity which consists of silicon | silicone etc. is interposed between the protrusion parts 47 and 47. FIG.

  As described above, the present invention has a structure in which the transformer 4 is fixed by sandwiching the cores 31 and 32 of the transformer 4 between the metal base plate 1 and the metal cover 2. The heat radiation from the top and the heat from the top surface are both performed, and the heat radiation performance is improved. Specifically, in a DC-DC converter with an output of 1.5 kW, the temperature of the upper core 31 rose by about 80K in the conventional product that does not dissipate heat from the cover 2, but in this embodiment, this temperature rise is 55K. As a result, the temperature rise of the core was greatly suppressed. The suppression of the temperature rise of the upper core 31 also leads to the temperature suppression of the lower core 32. Thus, since the temperature rise of the cores 31 and 32 is suppressed, the core loss of the transformer 4 is reduced.

  Moreover, since the temperature rise of the cores 31 and 32 is suppressed, the internal space temperature of the cover 2 is also lowered, which contributes to prevention of temperature rise and loss reduction of other components. In addition, even when a smaller core than the conventional one is used, the transformer 4 having the same performance as the conventional one can be realized, which contributes to downsizing of the transformer 4 or the power supply device.

  Further, since a dedicated mounting bracket for fixing the transformer 4 is not necessary, coupled with the downsizing, it contributes to the reduction in the number of parts of the transformer 4 or the power supply device and the cost reduction.

  Moreover, in the said embodiment, since the thermal radiation fin 5 was provided in the baseplate 1, the thermal radiation performance goes up further and the temperature rise of the cores 31 and 32 is suppressed more effectively.

  In the above embodiment, the printed circuit board 3 is provided with the through holes 45 and 46, and the core 32 is fitted into the through holes 45 and 46 so that the core is fixed. 3 can be reliably prevented from being displaced in the direction parallel to 3, that is, in the lateral direction.

  When carrying out the present invention, a configuration may be adopted in which a bobbin is fitted to the center leg portion of the cores 31 and 32, and a primary winding and a secondary winding are mounted on the bobbin. It is good also as a structure fitted in the through-hole 45 of the printed circuit board 3. FIG.

  Moreover, in the said embodiment, since the heat-transfer sheet | seat 52 which has elasticity was interposed between the top-plate part 2a of the cover 2 and the core 31 between the protrusion parts 47 and 47 of the cover 2, the core 31's Heat dissipation from the upper surface is promoted, and the temperature rise of the core 31 is further suppressed satisfactorily.

  Moreover, in the said embodiment, since the concave surface 48 is formed in the top-plate part 2a of the cover 2, and the protrusion part 47 is formed in the concave surface 48, it is above the transformer 4 which performs the heat radiation by the cover 2. Even when there is a protruding capacitor 23 or the like, the transformer 4 can dissipate heat without hindering the mounting of the component. Further, by forming the concave surface 48 on the cover 2, the rigidity of the cover 2 is increased and the contact with the core 31 can be reliably performed.

  FIG. 5 shows another embodiment of the present invention, in which the radiating fins are brought into contact with the recessed surface 48 of the top plate portion 2a on the outer surface of the portion of the top plate portion 2a of the cover 2 where the protrusions 47 are formed. By fixing the heat dissipator 53, the heat dissipating from the upper surface of the core 31 can be performed more satisfactorily. In this embodiment, since the heat radiator 53 is provided on the recessed surface 48, the heat radiation performance can be improved without increasing the height of the power supply device. The radiator 53 is fixed by using a screw 50 for pressing the protruding portion 47 against the core 31 to reduce the number of parts.

  As the division type conveyor constituting the inductance component of the present invention, not only the EE type core but also the UU type, the EI type, the UI type, and the like can be used.

It is a disassembled perspective view which shows one Embodiment of the power supply device of this invention. In the power supply device of this Embodiment, it is a disassembled perspective view which shows the state which fixed the printed circuit board which mounted components to the base frame. In the state which assembled the whole this Embodiment, it is a perspective view which cuts off and shows a part of cover. It is sectional drawing which shows the attachment structure of the trans | transformer in this Embodiment. It is a perspective view which shows other embodiment of this invention.

1: Base frame, 2: Cover, 2a: Top plate part, 3: Printed circuit board, 4: Transformer, 5: Radiation fin, 6, 7: Mounting hole, 8: Screw, 9: Vehicle body, 10: Screw cylinder, 11 : Screw, 12: Rectifier diode, 13: Base plate, 14: Switching element, 15: Screw, 16: Spring, 17: Resonant inductor, 19: Choke coil, 20: Output terminal block, 22: Line filter, 23 : Capacitor, 24: Pulse transformer, 25: IC, 26, 27: Connector, 31, 32: Core, 33, 34: Secondary winding, 35: Bobbin, 36, 37: Screw, 39: Female screw piece, 40: Screw, 41: Female screw, 42: Screw, 44: Recess, 45, 46: Through hole, 47: Projection, 48: Recessed surface, 49: Through hole, 50: Screw, 51: Columnar protrusion, 52: Heat transfer sheet , 53: radiator

Claims (3)

Columnar projections are provided on a metal base plate ,
An inductance component having a split core on the base plate is placed in contact with the surface of the core on one side,
On the top plate portion of the metal cover that covers the components of the power supply device including the inductance component combined with the base plate, a protruding portion protruding inward is formed,
The cover is combined with the base plate, and the columnar protrusion is fastened to the cover, whereby the protruding portion of the cover is pressed against the surface of the core on the other side of the inductance component, and the inductance component is placed on the base plate and the base plate. A power supply device characterized by being sandwiched between the cover and the cover. The power supply device according to claim 1,
Form a recessed surface recessed inward on the top plate of the cover,
The projecting portion is formed on the concave surface. The power supply device according to claim 1 or 2 ,
The power supply device characterized by fixing the radiator which has a radiation fin to the outer surface of the part which formed the said protrusion part in the top plate part of the said cover in contact with the top plate part.

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