BR102013005047A2 - Semiconductor power converter hood support structure - Google Patents

Abstract

Semiconductor power converter hood support structure. The present invention relates to a semiconductor power converter hood support structure that allows a hood body to be pulled out in a horizontal direction without providing a maintenance space above an exhaust unit, i.e. structure supporting a centrifugal exhaust hood (18) through an exhaust unit mounting plate (ii) in an opening portion which is formed on a top of a housing of a semiconductor power converter, the centrifugal exhaust hood comprised of an exhaust body (15) having an exhaust mounting plate secured to its top and an inlet nozzle (13) with a front end inserted into a suction part of the exhaust body, the exhaust plate exhaust unit assembly (11) comprising a pair of side guide support plates (31, 32) guiding a pair of guide parts facing the exhaust body exhaust mounting plate r in a horizontal direction and a pair of side plates, at least one of which is separable, forming a top surface plate in a top portion, having air holes in at least one of the guide support side plates, and on the side plates and supporting an inlet nozzle mounting plate, which secures and supports the inlet nozzle at a bottom, to be lifted in a vertical direction.

Description

Report of the Invention Patent for "SEMI-CONDUCTOR POWER CONVERTER EXHAUST SUPPORT STRUCTURE".

Technical Field The present invention relates to a fan support structure of a semiconductor power converter, which is designed to support an exhaust vent that discharges hot air into an outside semiconductor power converter housing. Prior Art In this type of hood support structure of a semiconductor power converter, for example, one is known which is described in Patent Document 1. In this semiconductor power converter, as heat generating parts, bipolar isolated gate transistors (IGBT), included in switching modules, rectifier modules, electrolytic capacitors, etc., are contained in the housing. In this semiconductor power converter, hoods that are arranged at the top of the housing are used to discharge hot air upwards. Cold air, which is thus collected from the bottom, is used to cool the switching modules, rectifier modules, electrolytic capacitors, etc.

In the prior art, which is described in that Patent Document 1, since the hoods are used to discharge hot air inside the housing upwards, the space where the secondary conductor converter is installed requires ample exhaust space. on the top side of the semiconductor power converter. However, when a large exhaust space cannot be trapped in the space above the semiconductor power converter, centrifugal type exhaust fans that discharge hot air in the centrifugal direction are used as the exhaust fans.

As a semiconductor power converter having such centrifugal type hoods attached, for example, one configured as described in Figures 7 to Figure 9 has been described. In this prior art, as shown in Figure 7, for example, exhaust units 101 are secured to the top of a housing 100 that holds the electrolytic capacitors at the bottom and is provided with switching modules and rectifier modules at the top. Here, each exhaust unit 101, as shown in Figures 8A and 8B and Figure 9, is provided with an inlet nozzle 102 on an inlet nozzle mounting plate 103, is provided with surface plates 104 107 of the front, rear, left and right sides on the circumferential sides of the top surface of that inlet nozzle mounting plate 103 and is provided with support posts 108 to 111 on the inner sides of these side surface plates 104 a 107. Further, the top ends of the support columns 108 to 111 support an exhaust mounting plate 113, which supports an exhaust body 112. The top surface of that exhaust mounting plate 113 is covered by a plate. of top surface 114.

List of Citations Patent Documents Patent Document 1: JP 2004 - 180424 A

Summary of the Invention Problem to be solved. In this respect, in the exhaust support structure of a semiconductor power converter, which is shown in Figures 7 to 9, due to the use of centrifugal type exhaust fans, exhaust exhaust is discharged in the horizontal direction due to centrifugal force. For this reason, there is no need for an exhaust space at the tops of the exhaust units 101. It is possible to provide the semiconductor power converter even in an installation space without extra space. However, in the prior art above, once centrifugal hoods are used, they are secured in a state with the front ends of the inlet nozzles inserted into the suction holes of the exhaust bodies.

For this reason, when inspecting or replacing a hood body, it is necessary to pull the hood body upwards to separate the suction hole from the hood body and the front end of the inlet nozzle, then pull the exhaust body out of the front, etc. There was therefore the unresolved problem of predetermined maintenance space being required above the exhaust units. Therefore, the present invention is focusing on this unresolved prior art problem. The objective is to provide a semiconductor power converter exhaust support structure, which does not provide a maintenance space above the exhaust unit and allows the exhaust body to be pulled out in a horizontal direction.

Solution to the Problem To achieve this goal, a first aspect of the exhaust support structure of a semiconductor power converter in accordance with the present invention supports a centrifugal type exhaust through an exhaust unit mounting plate in a portion of opening, which is formed in a housing top of the semiconductor power converter. The centrifugal exhaust hood is comprised of an exhaust body that has an exhaust mounting plate attached to its top and an inlet nozzle with a front end inserted into a suction portion of the exhaust body. In addition, the exhaust unit mounting plate is comprised of a pair of side guide support plates guiding a pair of guide parts facing the exhaust body exhaust mounting plate in a horizontal direction and a pair of side plates, at least one of which is separable, form a top surface plate in a top portion, have air holes at least in one of the guide support side plates and side plates and supports an inlet nozzle mounting plate, which secures and supports the inlet nozzle on a bottom portion to be liftable! in a vertical direction.

In accordance with this first aspect, the inlet nozzle mounting plate securing and supporting the inlet nozzle is releasably supported on the bottom surface side of the exhaust unit mounting plate forming the body covering portion. hood on top. For this reason, when inspecting or repairing the hood, it is possible to lower the inlet nozzle mounting plate to separate the front end of the inlet nozzle from the exhaust body suction hole. In this state, the hood body can be pulled in the horizontal direction.

Further, a second aspect of the exhaust support structure of a semiconductor power converter according to the present invention is characterized in that the exhaust unit mounting plate is provided with a nozzle support member, which supports the inlet nozzle mounting plate liftably between a mounting position that inserts a front end of the inlet nozzle into a suction port of the exhaust body and an exhaust separation position where the end front of the inlet nozzle descends from the position of the exhaust body suction port.

In accordance with this second aspect, the nozzle support member, which is provided on the exhaust unit mounting plate, is used to support the inlet nozzle mounting plate which lifts the inlet nozzle in a thus, the nozzle support member can be used to make the inlet nozzle mounting plate move from the clamping position to the separation position, whereby the inlet nozzle is separated from the suction hole exhaust body downward and can be moved in the horizontal direction of the exhaust body.

Further, a third aspect of the exhaust support structure of a semiconductor power converter according to the present invention is characterized in that the nozzle support member is provided with at least one nut which is secured to the mounting plate. inlet nozzle assembly and a position adjustment screw that is inserted through an outer circumferential side of the exhaust unit mounting plate to engage with the nut. According to this third aspect, the bolted position of the position adjustment screw with the nut can be used to make the inlet nozzle mounting plate move up and down between the clamping position and the separation position.

Furthermore, a fourth aspect of the exhaust support structure of a semiconductor power converter according to the present invention is characterized in that the nozzle support member is further provided with a locking nut which is engaged with the front end of the position adjustment screw and prevents separation of the position adjustment screw. According to this fourth aspect, since the front end of the set screw is provided with a locking nut, the position adjusting nut can be safely prevented from detaching from the set screw and fall.

Furthermore, a fifth aspect of the exhaust support structure of a semiconductor power converter according to the present invention is characterized in that the nozzle support member is further provided with a spring washer which is inserted between a screw head position adjustment plate and the exhaust unit mounting plate. According to this fifth aspect, by inserting a spring washer between the position adjusting screw head and the eu mounting plate, it is possible to stop loosening the position adjusting nut.

A further sixth aspect of the exhaust support structure of a semiconductor power converter in accordance with the present invention is characterized in that the inlet nozzle mounting plate is provided with a nozzle holder that protrudes from the bottom surface and holds inlet nozzle. According to this sixth aspect, it is possible to hold the inlet nozzle in a low position and to keep the hood height as low as possible.

In addition, a seventh aspect of the exhaust support structure of a semiconductor power converter according to the present invention is characterized in that the pair of guide parts of the exhaust mounting plate are formed by guide slots. in the shape of an inverted recessed cross section that open on the bottom surface. In accordance with this seventh aspect, by making the guide grooves of the exhaust mounting plate mate with the top surfaces of the side guide plate para, it is possible to make the exhaust mounting plate move in a horizontal direction. .

Furthermore, an eighth aspect of the exhaust support structure of a semiconductor power converter in accordance with the present invention is characterized in that the exhaust mounting plate is formed with hook engaging portions that engage with crane hooks in the external surfaces where guide grooves are formed. According to this eighth aspect, since the hood mounting plate is formed with hook engaging portions that engage directly with the crane hooks, it is possible to engage the crane hooks and use a crane to lift the mounting plate. and the exhaust body, without having to form hook-fitting parts separately on the top surface of the exhaust mounting plate.

Furthermore, a ninth aspect of the exhaust support structure of a semiconductor power converter according to the present invention is characterized in that the exhaust unit mounting plate is comprised of a separable front surface side plate between the pair of side plates. According to this ninth aspect, it is possible to separate the front surface side plate to pull the exhaust mounting plate and the exhaust body to the front surface side and to maintain the serviceability.

Advantageous Effects of the Invention In accordance with the present invention, the advantageous effect is obtained that, when using centrifugal exhaust hood, the work of fixing and separating the exhaust body can be carried out easily, without providing maintenance space. on the top side of the housing.

Brief Description of the Drawings Figure 1 is an overall configuration view showing one embodiment of the present invention.

Figures 2A and 2B sound views showing an exhaust unit, wherein Figure 2A is a front view and Figure 2B is a perspective view. Figure 3 is a disassembled perspective view of an exhaust unit. Figure 4 is a cross-sectional view showing, in enlarged view, the main parts of the exhaust unit in condition with an inlet nozzle mounting plate in an attached position. Figure 5 is a cross-sectional view showing, in enlarged view, the main parts of the exhaust unit in the state with an inlet nozzle mounting plate in a separate position. Figure 6 is a perspective view showing the exhaust unit in condition with the separate exhaust mounting plate. Figure 7 is a view of the overall configuration showing a prior art.

Figures 8A and 2B are views showing a prior art exhaust unit, wherein Figure 8A is a front view and Figure 8B is a perspective view. Figure 9 is a disassembled perspective view of a prior art exhaust unit.

Description of Modalities Below, one embodiment of the present invention will be explained based on the drawings. Figure 1 is a view of the overall configuration showing one embodiment of the present invention. In Figure, reference numeral 1 is a semiconductor power converter. Such a semiconductor power converter 1 is, for example, provided with a bottom housing 2 having electrolytic capacitors and a top housing 3 having bipolar isolated gate transistors (IGBT) included in the switching modules, rectifier modules, etc. Bottom housing 2 and top housing 3 are communicated internally. The bottom housing 2 is formed with air holes 5 in the opening doors 4 on the front surface through substantially the entire area in the vertical direction. The top housing 3 is formed with air holes 7 on one top side of opening doors 6 on the front surface. In opening portions 8 which are formed at the top, exhaust units 9 are arranged.

Each exhaust unit 9, as shown in Figures 2A and 2B to Figure 4, is formed in a box shape that has a square top transverse sectional surface. This exhaust unit 9, as particularly shown in Figure 3, is comprised of an exhaust unit mounting plate 11 which is to be secured to an opening part 8 of the top housing 3, a cover part 12 which Attached to an outer circumference of the top of this mounting plate 11 is an inlet nozzle mounting plate 14, which is supported on a bottom surface of the exhaust unit mounting plate 11 in an elevatable manner in which a inlet nozzle 13, an exhaust mounting plate 16, which is supported on a top surface of the cover portion 12 on which a centrifugal type exhaust body 15 and a top surface plate 17 which closes are mounted. the top surface. The exhaust unit mounting plate 11 as shown in Figure 3 and Figure 4 is comprised of a rectangular horizontal plate part 22 which is formed with an opening part 21 in the center of which the inlet nozzle 13 is and the curved plate portions 23 which are curved upwardly from the outer circumferential sides of that horizontal plate portion 22. Still at the four corner positions of the horizontal plate portion 22 within the curved plate portions 23 as shown in Figure 4, screw insert holes 24 are formed. The cover portion 12 is comprised of a pair of guide support side plates 31 and 32 which are positioned on the left and right side on the top surface of the horizontal plate portion 22 of the mounting plate 11 of the mounting unit. a rear surface side plate 33, which is connected to the rear end faces of these guide support side plates 31 and 32 and is secured in a rear surface position to the top surface of the mounting unit 11 mounting plate 11. - Shaft and a front surface side plate 34, which is connected to the front end faces of the guide support side plates 31 and 32 and is securely attached to a front surface position of the mounting plate 11 of the unit. of exhaustion. The side plates 31 to 34 are formed, for example, with grid-shaped air holes 35, which discharge the exhaust outwards. Further, the left and right guide support side plates 31 and 32 are formed of flat rectangular plate portions 36 with four sides curved inwardly to form curved portions 37, whereby they are increased in stiffness. . The rear surface side plate 33 and the front surface side plate 34 at the front and rear are formed by flat plates. The inlet nozzle mounting plate 14, as shown in Figure 3 and Figure 4, is provided with a horizontal plate portion 41, which can contact the outer circumference side of opening 21 in the horizontal plate portion. 22 of the exhaust unit mounting plate 11 and an inlet nozzle support portion 42, which is comprised of a recessed portion that is formed from the bottom to the inside of the outer circumferential edge of that portion. horizontal plate 41. Horizontal plate part 41 is formed with screw insertion holes 43 in positions facing screw insertion holes 24, which are formed on the horizontal plate part 22 of the mounting unit 11 of the exhaust unit. . Further, in the inlet nozzle support portion 42, the inlet nozzle 13 is secured opening to the side of the top housing 3. The front end of that inlet nozzle 13 exits the horizontal plate portion 41. The exhaust assembly 16, as shown in Figure 3 and Figure 4, is provided with a horizontal plate portion 51 which contacts the inner circumferential surfaces of the left and right guide support side plates 31 and 32 explained above. and recessed and inverted guide slots 52, 53 which are formed by the curvature of the left and right ends of that horizontal plate part 51. On the front and rear extreme faces of the horizontal plate part 51. On the extreme faces front and rear of the horizontal plate part 51, curved parts 54 which are curved downwards are formed. Also, on the bottom surface side of the horizontal plate portion 51, an exhaust body 15 of a centrifugal type exhaust, which has a suction port 15a at the bottom end and which discharges the exhaust which is aspirated from the orifice suction cup 15a of the cylindrical outer circumferential surface is secured. Also, as shown in Figure 4, by inserting a front end of the inlet nozzle 13 into the inner circumferential surface of the suction port 15a, which is formed on the bottom surface of the exhaust body 15, an exhaust of the type centrifuge 18 is formed.

Note that the left and right side surfaces of the exhaust body 15, as shown in Figure 4, are preferably formed as tapered surfaces so that they are narrowed wider than the front ends. By making the left and right side surfaces of the exhaust body 15 tapered surfaces in this way, it is possible to reduce the slip resistance between the left and right guide support plates 31 and 32 when sliding the cor- It is possible to facilitate removal and attachment of the exhaust body 15. However, the left and right side surfaces of the exhaust body 15 can also be formed as surface shapes other than tapered surfaces.

Further, as shown in Figure 4, the bottom surface side of the exhaust body 15 is preferably formed with guide ridges 39, which engage with notches 38, which are formed in curved portions 37 of the side plates. left and right guide support 31 and 32.

By forming the guide ridges 39 on the bottom surface side of the exhaust body 15 in this manner, it is possible to use the guide ridges 39 and the guide slots 52 and 53 of the exhaust mounting plate 16 to define, precisely the exhaust body mounting plate 15. Therefore, it is possible to adjust the insertion amount of the front end of the inlet nozzle 13 into the suction hole 15a of the exhaust body 15 with high precision.

Further, the outer plate portions 55 and 56, where the guide grooves are formed 52 and 53 are formed, as shown in Figure 3, with hook engaging portions 57, which engage with crane hooks, not shown in two. locations, each on the sides of the front and rear ends. Further, in the screw insertion holes 24 of the mounting plate 11, nozzle support members 60 are secured.

Each nozzle support member 60, as is particularly clear from the enlarged view of Figure 4, has a position adjusting screw 61 which is inserted into a top surface side of the screw insert hole 24 of the mounting plate. Exhaust unit 11 through the screw insert hole 24 and a screw insert hole 43 of the inlet nozzle mounting plate 14. Further, the nozzle support member 60 has a spring washer 62 and a washer 63, which are inserted between a position adjusting screw head 61a and the top surface of the exhaust unit mounting plate 11. In addition, the mouth support member 60 has a nut 64 which engages with the position adjusting screw 61 on the bottom surface side of the inlet nozzle mounting plate 14 and is secured to the surface side. bottom of the bolt insertion hole 43 by welding or other fastening means and a locking nut 65, which is comprised of two adjusting nuts, which engage with the position adjusting screw below that nut 64 .

Here, the bolted position of the locking nut 65 with position adjusting screw 61 is adjusted by rotating the position adjusting screw 61 to move upwards (when a right-hand thread rotates it in the direction counterclockwise to make at least the top surface of the lock nut 65 contact the bottom surface of the nut 64. In that position, the inlet nozzle mounting plate 14 becomes the separation position, where the end front of the inlet nozzle 13 separates below the suction port 15a of the exhaust body 15.

Further, it is set by turning position adjusting screw 61 so as to move inversely downward (when turning right, turning it clockwise) to make the top surface of the mounting plate 14. nozzle contact the bottom surface of the exhaust unit mounting plate 11. When in that position, the inlet nozzle mounting plate 14 becomes the mounting position where the front end of the inlet nozzle 13 is inserted into the suction hole 15a of the exhaust body 15. Next, operation of the embodiment above will be explained. Now, as shown in Figure 1, each exhaust unit 9 is supposed to be secured to the position of an opening portion 8 of the top housing 3.

In this state, as shown in Figure 4, the position adjusting screws 61 which are secured with the nuts 64 of the nozzle support members 60 are tightened. Because of this, by the position adjusting screw heads 61a and nuts 64, the inlet nozzle mounting plate 14 is locked in position with the top surface of the horizontal plate portion 41 41 of the mounting plate 14 inlet nozzle contacting the bottom surface of the horizontal plate portion 22 of the exhaust unit mounting plate 11.

At that time, as shown in Figure 4, the front end of the inlet nozzle 13, which is secured to the bottom surface of the horizontal plate portion 51 of the exhaust mounting plate 16, which is supported on the left guide support side plates. and right 31 and 32 of the covering part 12. A centrifugal exhaust hood is therefore configured. By actuating a fan (not shown) in the hood body 15 to rotate in this state, hot air inside the top housing 3 passes through the inlet nozzle 13 to be drawn into the hood body 15, then, it is blown in the circumferential direction and passes through the air holes 35 of the cover portion 12 to be discharged outwards.

At that time, the bottom housing 2 and the top housing 3 have negative pressures, thus, in the bottom housing 2, cold air is drawn through the air holes 5, while in the top housing 3 cold air is drawn through the holes 7. Cold air, which is drawn in, cools the electrolytic capacitors and still cools the switching modules and rectifier modules, then passes through the opening portion 8, which is formed on the top surface of the top housing 3 and it is sucked through the inlet nozzle 13 into the exhaust housing 15. For this reason, the electrolytic heat generating capacitors, switching modules and rectifier modules can be cooled efficiently by cold air. In this state, the exhaust which is discharged from the exhaust unit 9 is discharged through the cover portion 12 in the horizontal direction, thus there is no need to provide an exhaust space on the top side of the exhaust unit 9.

When servicing or replacing the state-of-the-art centrifugal exhaust hood of that power converter 1, at least first and the front surface side plate 34 is separated. Thereafter or prior to that, the position adjustment screws 61, which are positioned within the curved plate portions 23 on the outer circumferential sides of the horizontal plate portion 22 of the exhaust unit mounting plate 11, are loosened. Accordingly, the distances between the heads 61a of the position adjusting screws 61 and the nuts 64 are increased, whereby the inlet nozzle mounting plate 14 descends relative to the exhaust unit mounting plate 11 and the Inlet nozzle 13 drops. Further, as shown in Figure 5, if in a state where the bottom surfaces of the nuts 64 contact the top surfaces of the locking nuts 65, the inlet nozzle mounting plate 14 reaches the separation position where the front end of the inlet nozzle 13 separates from the suction port 15a of the exhaust body 15 downwards. Therefore, viewed from the horizontal direction, the front end of the inlet nozzle 13 and the exhaust body suction port 15 become positioned, not interfering with each other.

In this state, the exhaust mounting plate 16 as shown in Figure 6 can be pulled forward (front surface side) while making the guide slots 32 and 33 engage with the top surfaces of the guide support side plates. left and right 31 and 32.

Because of this, the exhaust body 15 may be maintained or replaced.

In such a case, it is not necessary to provide a maintenance space above the exhaust unit 9 in order to separate the inlet nozzle 13 and the exhaust body 15 which form the centrifugal type exhaust.

In addition, by sliding the hood mounting plate 16 in the state with the guide support side plates 31 and 32 engaged with the guide slots 32 and 33, the hood mounting plate 16 can easily be pulled outwards. . Therefore, body maintenance work or replacement work can be performed easily in a short time. Further, the exhaust mounting plate 16 has the horizontal plate portion 51, the guide grooves 52 and 53 formed by the curvature of the left and right ends were formed by the curvature of the left and right ends of that horizontal plate portion 51 and the curved portions 54, which are formed at the front and rear ends of the horizontal plate portion 51, thus, the stiffness of the exhaust mounting plate 16 can be ensured and the thickness of the plate members 33 can be thinner.

Further, the left and right outer plate parts 55 and 56, where the guide grooves 52 and 53 are formed, are formed with hook engaging portions 57 that engage with crane hooks, so that it is possible to engage directly with each other. crane hooks with the hook engaging parts, thus, it is possible to directly engage crane hooks with the hook engaging parts 57 and it is possible to lift the hood mounting plate 16 and the hood body 15, without using hook members. snap-off to fit the crane hooks.

Incidentally, in the prior art, which is shown in Figure 7 through Figure 9, the hook engaging portions for engaging with the crane hooks could not be formed. For this reason, for example, it was necessary to form female bolts on the top surface plate 114, screw and secure separate hook engaging portions to these female bolts, then engage the crane hooks with the hook engaging portions and lift the hook. set. Therefore, when the movement of the hood mounting plate and the hood body is complete, if we leave the hook engaging parts as they are, another top space of the heights of the hook engaging parts would still be necessary, so the hook-fitting parts had to be separated. However, in the above embodiment, the hook engaging portions 57 have been integrally formed with the hood mounting plate 16 and, furthermore, the hook engaging portions 57 do not come up, thus the above drawback does not exist. originates.

Further, in the present embodiment, the configuration for raising and lowering the inlet nozzle mounting plate 14 between the locking position and the separation position need only be the simple configuration of providing nozzle support members 60 having the position adjusting screws 61 and are secured to the sides of the bottom surface of the screw insertion holes 43 in the horizontal plate portion 41 of the inlet nozzle mounting plate 14. If the inlet nozzle mounting plate 14 has reached the clamping position and the separation position it may appear that the position adjustment screws 61 are no longer capable of being rotated. For this reason, it is possible to safely stop movement of the mounting plate 14 and the opening into the fixing position and the separation position, even in an obscure state.

Further, the nozzle support members 60 are provided with locking nuts 65 which bolt with the bottom ends of the position adjusting screws 61, so that the nuts 64 can be safely prevented from detaching from the adjusting screws. 61, and therefore the inlet nozzle mounting plate 14, prevented from falling, and the inlet nozzle mounting plate 14 can be raised and lowered smoothly without concern. . In addition, the nozzle support members 60 are provided with spring washers 62 between the position adjusting screw heads 61a and the exhaust unit mounting plate 11, thus loosening the position adjusting nuts 64 can be provided. prevented.

Note that in the above embodiment, the insertion of position adjustment screws 61 forming parts of the nozzle support members 60 on the top side of the exhaust unit mounting plate 11 has been explained. However, the present invention is not limited to the above configuration. Position adjusting screws 61, nuts 64 and locking nuts can be reversed in the vertical and horizontal direction and position adjustment screws 61 can be secured to the horizontal plate portion 41 41 of the mounting plate 14 of the inlet nozzle. In that case, nuts 84 which are bolted with position adjusting screws 61 are provided on the top surface side of the horizontal plate portion 41 22 of the exhaust unit mounting plate 11, so nuts 64 can be turned to raise and lower the exhaust unit mounting plate 14. Still, in the above embodiment, the case of fixing the nuts 64 to the exhaust unit mounting plate 14 has been explained, but the invention is not limited thereto. Nuts 64 may also be able to pivot relative to the inlet nozzle mounting plate 14 and, for example, nuts 64 may be rotated from inside the top housing 3 to raise and lower the mounting plate 14 from the inlet nozzle.

Still, in the above embodiment, the case of supplying the lock nuts 65 to the nozzle support members has been explained, but the lock nuts 65 can also be omitted and the position adjusting screws 61 can be bolted with the nuts 64, then the bottom ends of the additionally fastened position adjusting screws 61 or locking parts may be welded. In addition, spring washers may be interposed between position adjusting screws 64 and inlet nozzle mounting plate 14.

Still, in the above embodiment, the case of configuring the nozzle support members 60 by position adjusting screws 61 and nuts 64 has been explained. However, the present invention is not limited to the above configuration. The horizontal plate portion 22 of the exhaust unit mounting plate 11 or the horizontal plate portion 41 of the inlet nozzle mounting plate 14 may be formed with a spiral-shaped slanted surface and a rotary shaft which is provided with a locking surface engaging with that spiral-shaped inclined surface may be provided to be able to rotate on the top surface side of the horizontal plate portion 22 of the exhaust unit mounting plate 11. In this case, it is possible to rotate this rotary axis to change the locking position of the locking surface with the spiral-shaped inclined surface in the up-down direction and thereby raise or lower the mounting plate 14 of the inlet nozzle. At this time, a locking means for locking the rotary shaft is preferably provided in a state where, for example, the horizontal plate portion 22 of the exhaust unit mounting plate 11 and the horizontal plate portion 41 of the plate nozzle mounting brackets 14 contact each other. Such locking means, for example, may be comprised of a locking part which is formed on the rotary shaft and exits in the radial direction and a detachable locking pin that engages therewith. Further, the top surface of the horizontal plate portion 41 of the horizontal plate portion 22 of the exhaust unit mounting plate 11 is formed with a tapered surface extending in the horizontal direction. This snap roller can be connected with the exhaust unit mounting plate 14. In this case, a locking means for locking the locking roller is preferably provided in the state where, for example, the horizontal plate portion 22 of the exhaust unit mounting plate 11 and the horizontal plate portion 41 of the plate nozzle mounting brackets 14 contact each other. As an example of such locking means, a locking recess that engages with the locking roller on top of the tapering surface can be considered.

Still, in the above embodiments, the case where the exhaust mounting plate 16 was formed with guide slots 52 and 53 has been explained. However, the present invention is not limited to such a configuration. It is also possible to form downwardly extending ridges on both right and left extreme sides of the exhaust mounting plate 16 and to guide grooves at the top ends of the left and right guide support side plates 31 and 32.

Industrial Applicability According to the present invention, it is possible to provide an exhaust support structure of a semiconductor power converter that allows the exhaust body to be pulled out in a horizontal direction without providing a maintenance space above one unit. of exhaustion.

Reference Signal Ratio 1 ... semiconductor power converter, 2 ... bottom housing, 3 ... top housing, 9 ... exhaust unit. 11 ... inlet nozzle mounting plate, 12 ... cover part, 13 ... inlet nozzle. 14 .... Exhaust unit mounting plate, 15 ... exhaust body. 16 ... hood assembly plate, 21 ... opening part, 22 ... plate part, 23 ... bent part, 24 ... screw insertion hole, 31, 32 ... side plate guide plate, 33 ... rear surface side plate, 34 ... and front surface side plate, 41 .. horizontal plate part, 42 ... inlet nozzle support plate, 43 .. screw insertion hole, 51 ... horizontal plate part, 52.53 ... guide grooves, 54 ... curved part. 55, 56 ... side plate part, 57 ... hook fitting part, 60 ... nozzle support member, 61 ... position adjustment screw,, 62 ... spring washer, 63 ... washer, 64 ... nut, 65 ... lock nut.

Claims (9)

1. Exhaust support structure of a semiconductor power converter characterized in that it supports a centrifugal type exhaust fan through an exhaust unit mounting plate in an opening portion formed on a housing top of the semiconductor power converter, - the centrifugal type hood being comprised of an exhaust body having an exhaust mounting plate attached to its top and an inlet nozzle with a front end inserted into a suction part of the exhaust body, exhaust unit assembly comprising a pair of side guide support plates which guide a pair of guide parts facing each other in a horizontal direction and a pair of side plates, at least one of which is separable with one top surface plate formed into a top portion, having air holes in at least one of the guide support side plates and side plates and supporting a Inlet nozzle mounting tab, which secures and supports the inlet nozzle on a bottom portion, to be lifted in a vertical direction. Exhaust support structure of a semiconductor power converter according to claim 1, wherein the exhaust unit mounting plate is provided with a nozzle support member supporting the inlet nozzle mounting plate in an elevatable manner between a clamping position where a front end of the inlet nozzle is inserted into a suction port of the exhaust body and an exhaust separation position where the front end of the inlet nozzle descends from the clamping position of the hole suction hood. Exhaust support structure of a semiconductor power converter according to claim 2, wherein the nozzle support member is provided with at least one nut attached to the inlet nozzle mounting plate and an adjusting screw position position through an outer circumferential side of the exhaust unit mounting plate to engage with the nut. Exhaust support structure of a semiconductor power converter according to claim 3, wherein the nozzle support member is further provided with a locking nut engaged with the front end of the position adjusting screw to prevent the separation of the position adjustment screw. Exhaust support structure of a semiconductor power converter according to any one of claims 3 or 4, wherein the nozzle support member is further provided with a spring washer inserted between a set screw head. position and the exhaust unit mounting plate. Exhaust support structure of a converter of a semiconductor power converter according to any one of claims 1 to 5, wherein the inlet nozzle mounting plate is provided with a nozzle holder that exits from the surface of a bottom and holds the inlet nozzle. Exhaust support structure of a semiconductor power converter according to any one of claims 1 to 5, wherein the pair of guide parts of the exhaust mounting plate is formed by section-shaped guide slot inverted cross-section opening at the bottom surface. Exhaust support structure of a semiconductor power converter according to claim 7, wherein the exhaust mounting plate is formed with hook engaging portions that engage with crane hooks on the outer surfaces, forming the guide slots. Exhaust support structure of a semiconductor power converter according to any one of claims 1 to 8, wherein the exhaust unit mounting plate is comprised of a separable front surface side plate between the pair of side plates.