JP5596389B2 - Power supply - Google Patents

Description

  The present invention relates to a power supply device for welding, for example, and more particularly to a power supply device provided with a fan for air cooling.

  Conventional power supply devices for welding include a plurality of electronic components, a longitudinally extending air passage, and a fan that sends air into the air passage (see, for example, Patent Document 1). In the power supply device disclosed in this document, a plurality of electronic components are arranged along the side wall of one air passage, and a fan is provided at one end in the longitudinal direction of the air passage. The wind sent into the air passage by the fan blows out from the outlet at the other end in the longitudinal direction of the air passage while taking heat from the electronic components. In particular, electronic components that tend to generate heat are arranged in the vicinity of the fan so as to be efficiently air-cooled. Such a power supply device incorporates a component that easily generates heat, such as a semiconductor element, such as a semiconductor element, for example, an electrical component such as a transformer or a reactor. Generally, these electronic components and electrical components are greatly different in heat generation characteristics such as the degree and tendency of heat generation.

  However, in the above-described conventional power supply device, since there is only one air path, the more parts with different heat generation characteristics, the more appropriately they must be arranged along the longitudinal direction of the air path, and the parts to be cooled Since this arrangement greatly affects the temperature and flow of the wind, it has been difficult to air-cool a plurality of parts efficiently.

JP 2008-229644 A

  The present invention has been conceived under the above circumstances, and an object thereof is to provide a power supply device that can efficiently cool a plurality of parts by separating them.

  In order to solve the above problems, the present invention takes the following technical means.

A power supply device provided by the present invention is separated in a vertical direction by a partition with respect to a first air passage extending in a horizontal longitudinal direction and a partition wall with respect to the first air passage, and is parallel to the first air passage and has a horizontal longitudinal direction. a second air passage extending Jo, the first feeding the air to the first air passage fan and, the second feeding a wind to the second air passage fan and, the first and the second comprising a plurality of components arranged along the air passage, and by the wind passing through the first and second air passage to a power source device constructed as the plurality of component cooling, said first Each of the first and second air passages is surrounded by a pair of vertical walls arranged perpendicular to the partition wall and facing each other, and an upper wall or a bottom wall facing the partition wall, and in the longitudinal direction. Both ends are outlets for wind, and the first and second fans The first and second air passages are located in the middle in the longitudinal direction and are arranged so as to send wind in the direction intersecting the longitudinal direction of the air passage from one inner surface of the pair of vertical walls. And a housing cover for protecting the inside of the apparatus, wherein the first and second fans are arranged in a space adjacent to each of the first and second air passages and surrounded by the housing cover. In addition, the housing cover has an intake hole portion that faces the first and second fans and guides outside air into the space, and the first and second air passages. And a vertical fan-facing wall extending in parallel with a predetermined interval, and the air intake hole portion is in front of the first and second fans with respect to the region facing the front. Horizontal direction displaced in the in-plane direction of the fan facing wall It is characterized in that provided in the region of the end portion closer.

  In a preferred embodiment of the present invention, the first and second fans have different air volumes, and the fan having the larger air volume is the upper air path of the first and second air paths. It is arranged corresponding to.

  In a preferred embodiment of the present invention, the intake hole portion is provided in a region in the vertical direction middle portion or upper portion of the fan facing wall.

  In preferable embodiment of this invention, the said housing | casing cover has the front part and back part which face each exit of the said 1st and 2nd air path, In the front part and back part, , Ventilation holes for guiding the wind from each outlet to the outside are provided.

  In a preferred embodiment of the present invention, the plurality of parts include an electric part such as a reactor or a transformer, an electronic part, and a heat sink, and the lower air path of the first and second air paths. The electrical component is disposed through the other of the pair of vertical walls, and the coil portion of the electrical component is located in the air passage, while the upper air passage has the other of the pair of vertical walls. And the electronic component is disposed so as to penetrate the other of the pair of vertical walls and come into contact with the heat sink.

  In a preferred embodiment of the present invention, the first and second air passages are provided with first and second temperature sensors for detecting respective internal temperatures, and the first and second temperature sensors are provided. The fan is configured to be independently controlled based on signals from the first and second temperature sensors.

In the above structure, first and second air passage is arranged at the bottom on the wind sent into the air path by the first and second fans. According to such a configuration, a plurality of parts to be cooled can be arranged in the first and second air passages, and these parts can be efficiently air-cooled in each air passage. .

  Other features and advantages of the present invention will become more apparent from the detailed description given below with reference to the accompanying drawings.

It is a disassembled perspective view which shows one Embodiment of the power supply device which concerns on this invention. It is the disassembled perspective view which showed the power supply device of FIG. 1 from another angle. It is sectional drawing which follows the III-III line of FIG. It is sectional drawing which follows the IV-IV line of FIG. It is a side view of the power supply device shown in FIG. It is a front view of the VI arrow direction of FIG. It is sectional drawing which follows the VII-VII line of FIG. It is sectional drawing which follows the IIX-IIX line | wire of FIG. It is sectional drawing which follows the IX-IX line of FIG. It is sectional drawing which shows other embodiment of the power supply device which concerns on this invention. It is a side view which shows other embodiment of the power supply device which concerns on this invention.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

  1 to 9 show an embodiment of a power supply device according to the present invention. The power supply device A of this embodiment is used, for example, to output a large current and a high voltage necessary for arc welding. The power supply device A is generally used in an atmosphere environment with a lot of dust such as a factory.

  The power supply device A includes a base member 1, a housing cover 2, an electronic component 30 and an electrical component 31 constituting a power circuit, a heat sink 5, a first partition plate 6, second partition plates 7A and 7B, and a third partition. A plate 7C, first and second fans 8, 8 ′, and first and second temperature sensors S, S ′ (see FIGS. 3 and 4) are provided. In the apparatus, a hollow first air passage 9 surrounded by a lower portion of the second partition plate 7A, the third partition plate 7C, and a part of the base member 1 is provided, Above the first air passage 9, it is surrounded by a part of the first partition plate 6, the upper part of the second partition plate 7A, the second partition plate 7B, and a part of the third partition plate 7C. A broken hollow second air passage 9 'is provided. These air passages 9 and 9 ′ extend in the longitudinal direction in the front-rear direction of the power supply device A (hereinafter referred to as “F direction”). Further, in the apparatus, on the outer side of the first and second air passages 9 and 9 ′, a part of the base member 1, a part of the housing cover 2, the first partition plate 6, and the second partition An arrangement space B1 such as an electronic component 30 surrounded by the plate 7A is provided, a part of the base member 1, a part of the housing cover 2, a part of the first partition plate 6, and a second partition plate 7B. And an arrangement space B2 for the fans 8, 8 ′ surrounded by the third partition plate 7C. The arrangement space B1 for the electronic component 30 or the like is continuous with the space above the first partition plate 6.

  The base member 1 is a long rectangular flat plate member that is long in the F direction. A plurality of wheels 10 are pivotally supported on the lower surface of the base member 1 via brackets. The base member 1 can move on the floor surface by these wheels 10. As shown in FIG. 7, a second partition plate 7 </ b> A is disposed at the center of the upper surface of the base member 1 perpendicular to the upper surface. A third partition plate 7C is arranged so as to surround the lower partial one surface of the second partition plate 7A and a part of the upper surface of the base member 1.

  The housing cover 2 is made of, for example, metal and is for protecting the inside of the apparatus. The housing cover 2 has a box shape that can be attached to and detached from the base member 1, and has two side surfaces 2 </ b> A and 2 </ b> B that form a vertical surface along both sides of the base member 1, and the front end and the rear of the base member 1. It has the front part 2C and back part 2D which make a vertical surface along an edge part. As shown in FIG. 4, the side surface portion 2A of the housing cover 2 serves as a wall facing the first and second fans 8 and 8 '. In the side surface portion 2A, an intake hole portion 20 for guiding outside air to the arrangement space B2 is provided in a region near both ends in the F direction (see FIGS. 3 and 4). The intake hole 20 is composed of a large number of relatively small slit holes. As shown in FIG. 3 and FIG. 4, in the area corresponding to the first and second air passages 9 and 9 ′ in the front portion 2C and the back surface portion 2D, the wind from these air passages 9 and 9 ′ is externally applied. Ventilation hole 21 is provided to guide the air. The ventilation hole portion 21 is composed of a relatively large number of holes for good ventilation.

  As shown in FIGS. 4, 7, and 9, the electronic component 30 is a switching element, a diode, a capacitor, or a microcomputer. These electronic components 30 are directly attached to the heat sink 5 through the upper part of the second partition plate 7A. Thereby, the heat from the electronic component 30 is quickly transmitted to the heat sink 5. As shown in FIGS. 3, 7, and 9, the electrical component 31 is a transformer or a reactor, and includes a coil portion 31A and a terminal portion 31B. The coil portion 31 </ b> A has at least a tip portion located in the first air passage 9, and the terminal portion 31 </ b> B is arranged in the same arrangement space B <b> 1 as the electronic component 30. That is, the electrical component 31 is disposed so as to penetrate the lower part of the second partition plate 7 </ b> A and face the placement space B <b> 1 and the first air passage 9. Such an electrical component 31 is relatively large and heavy. For this reason, the electric component 31 is weight balanced when passing through and fixing the second partition plate 7A, and the amount of protrusion of the coil portion 31A facing the first air passage 9 is adjusted. The coil portion 31A of the electrical component 31 may have a winding exposed or may be sealed with a mold resin. The microcomputer may be incorporated in a control circuit different from the power supply circuit, for example.

  As shown in FIGS. 4 and 7, the heat sink 5 is a heat radiating member made of, for example, aluminum, and has a base 50 fixed to the second partition plate 7 </ b> A, and extends from the base 50 in the F direction and vertically. And a plurality of fins 51 arranged in a row. The electronic component 30 is directly attached to a part of the base 50 facing the second partition plate 7A via a screw (not shown) or the like. The plurality of fins 51 are portions that efficiently dissipate heat transferred from the base 50 into the air, and have a large surface area in order to enhance the heat dissipation effect. In the present embodiment, the heat sink 5 is also a cooling target. In addition, the heat sink 5 may be arrange | positioned so that two or more may be located in a line with the 2nd partition plate 7A.

  As shown in FIG. 7, the first partition plate 6 is made of, for example, metal, and includes a space such as the arrangement space B2 of the fans 8 and 8 ′ and the second air passage 9 ′ and the arrangement space B1 of the electronic component 30. Divide into top and bottom. The first partition plate 6 has the same length as that of the base member 1 in the F direction, and one end in the short-side direction is vertically joined to the upper end of the second partition plate 7A. As a result, the first partition plate 6 is positioned horizontally at the middle portion in the vertical direction of the housing cover 2. The first partition plate 6 forms an upper wall of the arrangement space B2 of the fans 8, 8 'and the second air passage 9'.

  The second partition plate 7A is made of, for example, metal, and partitions the first and second air paths 9, 9 'from the arrangement space B1. The second partition plate 7 </ b> A also has the same size in the F direction as the base member 1. The second partition plate 7 </ b> A is disposed perpendicular to the base member 1 and the first partition plate 6. Accordingly, the second partition plate 7A forms a vertical wall of the first and second air passages 9 and 9 '. A square window 70 is provided on the upper part of the second partition plate 7A so that a part of the base 50 of the heat sink 5 is exposed to the arrangement space B1, and the electronic component 30 can be attached to that part. The square window 70 is formed slightly smaller than the base portion 50 and is closed by the base portion 50. The lower part of the second partition plate 7A is provided with an opening through which the electrical component 31 can be fitted (reference numeral omitted).

  The second partition plate 7B is made of, for example, metal, and partitions the second air passage 9 'and the arrangement space B2. The second partition plate 7 </ b> B also has the same size in the F direction as the base member 1. The second partition plate 7B is disposed so as to face the upper portion of the second partition plate 7A, and the upper end and the lower end thereof are perpendicular to the first partition plate 6 and the third partition plate 7C. Be joined. Thus, the second partition plate 7B forms a vertical wall of the second air passage 9 '. An opening 71 'for allowing the second fan 8' to face the second air passage 9 'is provided in the intermediate portion in the F direction of the second partition plate 7B (see FIG. 4).

  The third partition plate 7 </ b> C is made of, for example, metal, and is formed in an L-shaped cross section so as to surround the first air passage 9. The third partition plate 7 </ b> C also has the same dimension in the F direction as the base member 1. The distal end of the horizontal portion of the third partition plate 7C is joined perpendicularly to the central portion of the second partition plate 7A, while the proximal end of the vertical portion is joined perpendicularly to the base member 1. Thereby, the horizontal portion of the third partition plate 7C forms the upper wall of the first air passage 9 and the bottom wall of the second air passage 9 ', and the vertical portion thereof is below the second partition plate 7A. A vertical wall of the first air passage 9 facing the side portion is formed. An opening 71 for allowing the first fan 8 to face the first air passage 9 is provided in an intermediate portion in the F direction in the vertical portion of the third partition plate 7C (see FIG. 3).

  As shown in FIGS. 3 and 7, the first fan 8 on the lower side is an axial-flow type in which a plurality of blades (not shown) and an electric motor are integrated. It has a suction port 80 and a discharge port 81. The first fan 8 is arranged such that the discharge port 81 coincides with the opening 71 of the third partition plate 7C. That is, the first fan 8 is disposed in the middle in the longitudinal direction of the first air passage 9 and is positioned so that the discharge port 81 faces the inside of the air passage 9. Thereby, the blowing direction of the first fan 8 is a direction that intersects the longitudinal direction of the first air passage 9 in the horizontal plane. The suction port 80 is located in the arrangement space B2 and faces the inner surface of the side surface portion 2A with a predetermined interval. The suction hole 20 is not provided in the front area of the suction port 80 in the side surface portion 2A. That is, the suction port 80 is located at a certain distance from the suction hole 20 located near both ends of the side surface 2A in the F direction.

  As shown in FIGS. 4 and 7, the upper second fan 8 ′ is of the axial flow type like the first fan 8, and has an air suction port 80 ′ and a discharge port at both ends in the axial direction. 81 '. The second fan 8 'is disposed with the discharge port 81' aligned with the opening 71 'of the second partition plate 7B. That is, the second fan 8 'is disposed in the middle portion in the longitudinal direction of the second air passage 9', and is positioned so that the discharge port 81 'faces the inside of the air passage 9'. As a result, the blowing direction of the second fan 8 'is a direction that intersects the longitudinal direction of the second air passage 9' in the horizontal plane. The suction port 80 'is located in the arrangement space B2, and is opposed to the inner surface of the side surface portion 2A with a predetermined interval. The suction hole 20 is not provided in the front area of the suction port 80 ′ in the side surface 2 </ b> A. That is, the suction port 80 ′ is positioned to some extent with respect to the suction hole 20 positioned near both ends in the F direction of the side surface 2 </ b> A. In the present embodiment, the first and second fans 8 and 8 ′ have different air volumes, and the upper second fan 8 ′ has a larger air volume than the lower first fan 8. .

  As shown in FIG. 3, the first air passage 9 directly cools the electrical component 31 with the wind from the first fan 8 and guides the wind to both ends in the longitudinal direction. The first air passage 9 has a lower portion of the second partition plate 7A and a vertical portion of the third partition plate 7C as a pair of vertical walls opposed in the width direction, and further a horizontal portion of the third partition plate 7C. A part of the base member 1 is surrounded as an upper wall and a bottom wall facing each other in the vertical direction, and is formed in a rectangular cross section. Both ends in the longitudinal direction of the first air passage 9 serve as outlets 90 from which the wind blows. The wind sent from the first fan 8 into the first air passage 9 directly hits the coil portion 31A of the electrical component 31 and is split into two ends at both ends in the longitudinal direction of the first air passage 9. It blows out from the outlet 90 while taking a lot of heat from the portion 31A. This wind quickly blows out through the ventilation hole 21 provided in the front part 2C and the back part 2D of the housing cover 2. The average distance that the wind flows from the first fan 8 to the outlet 90 in the first air passage 9 is about half of the entire length of the air passage 9. As a result, the wind from the first fan 8 quickly flows through the first air passage 9 and is discharged to the outside, and the electric component 31 is efficiently air-cooled by the wind flowing through the first air passage 9. The

  The first air passage 9 is provided with a first temperature sensor S for detecting the internal temperature. The first temperature sensor S is installed on the surface of the second partition plate 7A, for example. Note that the first temperature sensor S may be directly attached to the electrical component 31, for example. The first temperature sensor S outputs a signal to the microcomputer. Based on the signal from the first temperature sensor S, the microcomputer does not operate the first fan 8 when the internal temperature of the first air passage 9 is less than 50 ° C., for example. When the internal temperature of the first air passage 9 is 50 ° C. or higher and lower than 70 ° C., the microcomputer rotates the first fan 8 at a low speed, and when the internal temperature reaches 70 ° C. or higher, the microcomputer 10 rotates the first fan 8 at a high speed. Rotate. When the internal temperature of the first air passage 9 further rises above 70 ° C. and reaches a predetermined temperature, the microcomputer stops the operation of the entire power supply circuit constituted by the electronic component 30 and the electrical component 31.

  As shown in FIG. 4, the second air passage 9 ′ cools the heat sink 5 with the wind from the second fan 8 ′ and guides the wind to both ends in the longitudinal direction. The second air passage 9 ′ has a pair of vertical walls opposed to each other in the width direction in the upper part of the second partition plate 7A and the second partition plate 7B, and a part of the first partition plate 6 and the third partition plate 7B. The horizontal portion of the partition plate 7C is surrounded as an upper wall and a bottom wall facing in the vertical direction, and is formed in a rectangular cross section. That is, the second air passage 9 ′ is partitioned from the first air passage 9 with the horizontal portion of the third partition plate 7 </ b> C as a partition, and is disposed above the first air passage 9. Both ends in the longitudinal direction of the second air passage 9 'serve as outlets 90' from which the wind blows. The wind sent from the second fan 8 ′ into the second air passage 9 ′ directly hits the heat sink 5 and splits into two ends in the longitudinal direction of the second air passage 9 ′. It blows out from the exit 90 'taking a lot of heat. The average distance that the wind flows from the second fan 8 'to the outlet 90' in the second air passage 9 'is also about half of the entire length of the air passage 9'. As a result, the wind from the second fan 8 ′ quickly flows through the second air passage 9 ′ and is discharged to the outside, and the heat sink 5 is efficiently air by the wind flowing through the second air passage 9 ′. To be cooled. As a result, the electronic component 30 is efficiently cooled via the heat sink 5.

  The second air passage 9 'is provided with a second temperature sensor S' for detecting the internal temperature. The second temperature sensor S ′ is installed on the surface of the second partition plate 7A, for example. Note that the second temperature sensor S ′ may be directly attached to the heat sink 5, for example. The second temperature sensor S 'outputs a signal to the microcomputer. Based on the signal from the second temperature sensor S ′, the microcomputer does not operate the second fan 8 ′ when the internal temperature of the second air passage 9 ′ is, for example, less than 40 ° C. When the internal temperature of the second air passage 9 ′ is 40 ° C. or higher and lower than 60 ° C., the microcomputer rotates the second fan 8 ′ at a low speed, and when the internal temperature reaches 60 ° C. or higher, the second fan 8 ′ Rotate 8 'at high speed. When the internal temperature of the second air passage 9 ′ further rises above 60 ° C. and reaches a predetermined temperature, the microcomputer stops the operation of the entire power supply circuit constituted by the electronic component 30 and the electrical component 31.

  Next, the operation of the power supply device A will be described.

  During operation, the power supply device A generates a large current and a high voltage for welding, and the electronic component 30 and the electrical component 31 generate heat to increase their temperature. The heat of the electronic component 30 is directly transmitted to the heat sink 5 in addition to being transmitted to the air in the arrangement space B1. The heat transmitted to the heat sink 5 is efficiently radiated into the air of the second air passage 9 ′ by the plurality of fins 51. On the other hand, in the electrical component 31, the coil portion 31A is most likely to generate heat, and the heat of the coil portion 31A is transmitted to the air in the first air passage 9 '.

When the first and second fans 8 and 8 ′ are operated, the air around the suction ports 80 and 80 ′ is taken into the first and second fans 8 and 8 ′, and the air is used as the wind for the first and second fans. Are sent out from the discharge ports 81 , 81 ′ into the air paths 9, 9 ′ in a direction intersecting the longitudinal direction of the air paths 9, 9 ′. Accordingly, outside air flows from the intake hole 20 into the arrangement space B2.

  At this time, as shown in FIGS. 3 and 4, the air near the suction ports 80 and 80 ′ in the arrangement space B <b> 2 is sucked into the first and second fans 8 and 8 ′. The air is sucked into the arrangement space B <b> 2 through the intake hole portion 20 formed of a large number of slits. This is because the intake hole 20 at a position distant from the suction ports 80 and 80 'becomes an inflow resistance of air, and a sufficient pressure difference is generated between the vicinity of the suction ports 80 and 80' and the vicinity of the suction hole 20. This is because the arrangement space B2 has a negative pressure. Thereby, the air containing the dust sucked into the arrangement space B2 from the intake hole 20 flows while decelerating to the intake ports 80 and 80 ′ located away from the intake hole 20 in the F direction, and the air Most of the dust inside is easily separated from the air by gravity falling or hitting the inner wall surface of the arrangement space B2. As a result, the first and second fans 8 and 8 ′ take in air from which dust is effectively removed via the arrangement space B2, and the air is taken into the first and second air passages 9 and 9 ′. To send.

  The wind sent from the first fan 8 into the first air passage 9 is divided into two hands and strikes the electrical component 31 while flowing to both longitudinal ends of the air passage 9. At that time, since the wind directly hits the coil portion 31A of the electrical component 31, heat is efficiently removed from the coil portion 31A. The wind from the first fan 8 is split into two ends in the longitudinal direction of the first air passage 9, flows through a relatively short distance, and is discharged to the outside from the outlets 90 on both sides. Therefore, the resistance of the wind flowing through the first air passage 9 is reduced, and the wind is quickly discharged from the outlet 90. Thereby, the electrical component 31 is efficiently air-cooled.

  The wind sent from the second fan 8 ′ into the second air passage 9 ′ directly hits the heat sink 5 and flows along the fins 51 to both ends in the longitudinal direction of the air passage 9 ′. At that time, since the wind efficiently hits a large number of fins 51, a lot of heat is taken from the surface of each fin 51. The wind from the second fan 8 ′ is split into two ends in the longitudinal direction of the second air passage 9 ′, flows through a relatively short distance, and is discharged to the outside from the outlets 90 ′ on both sides. . Therefore, the resistance of the wind flowing through the second air passage 9 'is reduced, and the wind is quickly discharged from the outlet 90'. Thereby, the heat sink 5 is efficiently air-cooled, and the electronic component 30 is efficiently cooled via the heat sink 5.

The first and second air passages 9, 9 ′ are divided into an upper stage and a lower stage by a horizontal portion of the third partition plate 7C. Therefore, for example, the air in the lower first air passage 9 heated by the heat from the electrical component 31 tends to rise as the temperature rises, but enters the upper second air passage 9 ′. It is quickly discharged outside. Thereby, the heat sink 5 located in the upper stage and the electrical component 31 located in the lower stage are efficiently cooled by the wind from the first and second fans 8 and 8 'without being affected by heat.

  In the present embodiment, the first and second fans 8 and 8 ′ have different air volumes, and the first and second fans 8 and 8 depend on the temperature in the first and second air passages 9 and 9 ′. The rotation speed of 'is variably controlled. As a result, the wind flowing in the first and second air passages 9 and 9 ′ is set to an appropriate wind speed according to the respective cooling target and temperature rise characteristics, and is located in the upper portion of the heat sink 5 and the lower portion. The electrical component 31 is efficiently cooled by winds having different wind speeds. In the present embodiment, the air volume of the upper second fan 8 ′ is larger than that of the lower first fan 8 in particular, so that the heat sink 5 located in the upper stage is more easily cooled by air, and thus The electronic component 30 is efficiently cooled via the heat sink 5. Further, the first and second fans 8 and 8 ′ are individually controlled, and the operation is stopped until the temperature in the first and second air passages 9 and 9 ′ reaches a predetermined temperature. It also contributes to power saving and noise reduction.

The power supply device A is disposed, for example, on a floor surface in a factory, and dust is easily collected near the floor surface, and air containing more dust exists. In such a state, when the first and second fans 8 and 8 ′ are operated, the first fan 8 below the upper side tends to suck air closer to the floor surface than the upper side. On the other hand, the lower first fan 8 has a smaller air volume and a smaller intake force than the upper second fan 8 '. Thereby, the amount of dust sucked in by the lower first fan 8 is suppressed, and intrusion of dust from the first fan 8 is effective even in the lower first air passage 9 close to the floor surface. It is suppressed.

  During operation of the power supply device A, the first and second fans 8 and 8 'are in a state where the air volume is reduced or the air flow is stopped due to a failure or the like, or the electric component 31 and the heat sink 5 are cooled by the wind of the fans 8 and 8'. When the overheated state is exceeded beyond the capacity, the internal temperatures of the first and second air passages 9 and 9 'rise. In these first and second air passages 9 and 9 ′, the internal temperatures are individually detected by the first and second temperature sensors S and S ′, and when one of the internal temperatures reaches a predetermined value or more, The operation of the entire power supply circuit constituted by the electronic component 30 and the electrical component 31 is stopped. As a result, the power supply device A has a fail-safe function in which the entire operation is urgently stopped only when the cooling capacity of one of the first and second air passages 9 and 9 ′ is suddenly reduced. Therefore, it is possible to safely output a large current and a high voltage necessary for arc welding and the like.

  For example, when the temperature of the lower electrical component 31 is higher than that of the upper heat sink 5 due to heat generation, the lower first fan 8 may have a large air volume. Further, for example, when the operations of the electronic component 30 and the electrical component 31 are temporally different, the timings at which the first and second fans 8 and 8 ′ are operated can be made different accordingly.

  The electronic component 30 and the electrical component 31 to be cooled have the first and second fans 8 and 8 'located in the middle in the longitudinal direction of the first and second air passages 9 and 9'. The fan is located around the fans 8 and 8 '. That is, in the F direction, the distance between the first fan 8 and each electrical component 31 and the distance between the second fan 8 ′ and each electronic component 30 are the entire first and second air paths 9, 9 ′. The electronic component 30 and the electrical component 31 are disposed at positions relatively close to the fans 8 and 8 '. The electronic component 30 and the electrical component 31 are also efficiently cooled by such a positional relationship in the F direction. Therefore, the electronic component 30 and the electrical component 31 do not need to be determined in the F direction according to their heat generation characteristics, and can be freely arranged to some extent.

  During operation of the power supply device A, a dust removal operation using an air blow gun is performed. At that time, for example, the compressed air is injected from one outlet 90 of the first air passage 9 toward the air outlet of the air blow gun. The compressed air becomes a jet along the longitudinal direction of the first air passage 9, and blows off dust adhering to the coil portion 31 </ b> A of the electrical component 31 toward the other outlet 90. The injection direction of the compressed air injected from the air blow gun is a direction along the longitudinal direction of the first air passage 9, that is, a direction crossing the blowing direction of the first fan 8. Thus, during the dust removal operation using the air blow gun, the first fan 8 is not reversed at a high speed by a strong jet of compressed air, and there is no possibility of damaging the blades or the rotary bearing of the fan 8. Similarly, the dust removal operation can be performed on the second air passage 9 'using an air blow gun, and there is no possibility of damaging the blades or the rotary bearing of the second fan 8'. Moreover, since dust entering the first and second air passages 9 and 9 ′ together with the wind from the first and second fans 8 and 8 ′ is suppressed, the period until the dust removal operation is performed is extended, and the operation efficiency is increased. Can be increased.

  10 and 11 show another embodiment of the power supply device according to the present invention. The power supply device A1 shown in FIG. 10 is obtained by adding an electric component 32 different from that according to the above-described embodiment and arranging it at a predetermined position. The power supply device A2 shown in FIG. 11 differs from that according to the above-described embodiment in the position of the intake hole 20. Constituent elements that are the same or similar to those according to the above-described embodiment are given the same or similar reference numerals, and descriptions thereof are omitted.

In the power supply device A1 shown in FIG. 10, the electric component 32 penetrates the first partition plate 6 that becomes the upper wall of the second air passage 9 ′, for example, and the coil portion 32A is positioned in the second air passage 9 ′. Are arranged to be. The wind from the second fan 8 ′ flows to both ends in the longitudinal direction of the second air passage 9 ′ and blows outside while hitting the coil portion 32 A of the electrical component 32 and the fins 51 of the heat sink 5. According to such a configuration, a plurality of components arranged along different walls of one air passage 9 ′ can be efficiently air-cooled. In addition, the same effect can be obtained by arranging parts on the vertical wall on which the fan is arranged or on the bottom wall facing the top wall.

In the power supply device A2 shown in FIG. 11, the intake hole 20 in the side surface portion 2A of the housing cover 2 is provided in a region near both ends in the F direction of the side surface portion 2A and in the vicinity of the middle portion in the vertical direction. When this power supply device A2 is arranged on the floor surface in the factory, the intake hole 20 is positioned away from the vicinity of the floor surface where dust is accumulated. Therefore, the amount of dust sucked together with the air through the intake hole 20 is suppressed in the arrangement space B2, and as a result, from the first and second fans 8, 8 ′ with respect to the first and second air passages 9, 9 ′ . Intrusion of dust is more effectively suppressed. The effect of suppressing such dust intrusion can be further enhanced as the intake hole 20 is positioned closer to the upper part in the vertical direction.

  In addition, this invention is not limited to said embodiment.

  The configuration shown in each of the above embodiments is merely an example, and all changes in each part within the scope of the matters described in each claim are included in the scope of the present invention.

  You may arrange | position so that an electronic component may face a wind path directly.

  For example, the fan may be arranged at one end portion in the longitudinal direction of the air passage and configured to send air from one end portion in the longitudinal direction to the other end portion. In this case, the other end portion in the longitudinal direction of the air passage serves as a wind outlet.

  For example, the first and second air paths may be arranged so as to be adjacent in the horizontal direction.

  The number of air paths is not limited to two, and three or more air paths may be provided. In that case, a fan is provided corresponding to each air path.

A, A1, A2 Power supply device 1 Base member 2 Housing cover 2A, 2B Side surface portion 2C Front surface portion 2D Rear surface portion 20 Air intake hole portion 21 Ventilation hole portion 30 Electronic component 31 Electrical component 5 Heat sink 6 First partition plate 7A, 7B Second partition plate 7C Third partition plate 8 First fan 8 'Second fan 80, 80' Suction port 81, 81 'Discharge port 9 First air channel 9' Second air channel 90, 90 'Outlet (of airway) S 1st temperature sensor S' 2nd temperature sensor

Claims (6)

A first air passage extending in a horizontal longitudinal shape;
A second air passage that is vertically separated by a partition wall with respect to the first air passage, and extends parallel to the first air passage and in a horizontal longitudinal shape ;
A first fan for sending wind to the first air passage;
A second fan for sending wind to the second air path;
A plurality of components disposed along the first and second air paths;
With
A power supply unit configured to be cooled by the plurality of components by wind passing through the first and second air paths,
Each of the first and second air passages is surrounded by a pair of vertical walls arranged perpendicular to the partition and facing each other, and an upper wall or a bottom wall facing the partition, Both ends in the longitudinal direction are outlets for wind,
The first and second fans are located in the longitudinal middle portion of the first and second air passages, in a direction intersecting the longitudinal direction of the air passage from one inner surface of the pair of vertical walls. It is arranged to send in the wind,
A housing cover for protecting the inside of the apparatus is further provided.
The first and second fans are arranged in a space adjacent to each of the first and second air passages and surrounded by the housing cover,
The housing cover has an intake hole portion that faces the first and second fans and guides outside air into the space, and is predetermined with respect to the first and second air paths. Having a vertical fan facing wall extending in parallel with an interval; and
The intake hole portion is provided in a region near a horizontal end that is displaced in the in-plane direction of the fan facing wall with respect to a region that is a front surface with respect to the first and second fans. A power supply device. The first and second fans have different air volumes, and the fan having the larger air volume is arranged corresponding to the upper air path of the first and second air paths. Item 2. The power supply device according to Item 1 . 3. The power supply device according to claim 1, wherein the intake hole portion is provided in a region in an up-down direction intermediate portion or an upper portion of the fan facing wall. The housing cover has a front part and a rear part facing the outlets of the first and second air passages, and the wind from the outlets is externally provided on the front part and the rear part. The power supply device according to any one of claims 1 to 3, wherein a ventilation hole portion for guiding is provided. The plurality of components include electrical components such as reactors or transformers, as well as electronic components and heat sinks,
Of the first and second air passages, the lower air passage has the electric component disposed through the other of the pair of vertical walls, and the coil portion of the electric component is positioned in the air passage. On the other hand, the heat sink is arranged on the inner side along the other of the pair of vertical walls in the upper air passage,
5. The power supply device according to claim 1, wherein the electronic component is disposed so as to pass through the other of the pair of vertical walls and to contact the heat sink. The first and second air passages are provided with first and second temperature sensors for detecting respective internal temperatures,
The said 1st and 2nd fan is a structure in any one of Claim 1 thru | or 5 comprised so that it might each be controlled independently based on the signal from the said 1st and 2nd temperature sensor. Power supply.

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