JP7106697B2 - power board - Google Patents

Description

Embodiments of the present invention relate to power boards.

An uninterruptible power supply system (UPS) is a system that supplies power of the same standard to a load for a predetermined period of time even if a power supply trouble occurs. An uninterruptible power supply system usually includes a main body and its peripheral board, and is installed in a data center or the like. The main unit is a main part of the uninterruptible power supply, and includes a rectifier that converts alternating current to direct current, and an inverter that converts direct current to alternating current. The peripheral board is an input transformer board, a storage battery board, or the like.

The main body and the peripheral board are generally housed in a substantially rectangular parallelepiped housing. These enclosures are often arranged in a row along the wall of a data center or the like. In addition, the housing of the main body and the housing of the peripheral board have the same depth dimension and height dimension from the viewpoint of aesthetics. The dimensions of these housings are, for example, about a little less than 100 cm in depth and about 190 cm in height.

A housing such as the main body has a door attached to the front, and the door is opened to perform maintenance and inspection of the inside of the main body or the inside of the peripheral board. Therefore, a working space is provided in front of the main body and the peripheral board. In addition, the main body and the peripheral board are renewed when their expected life ends. Updating the main body and the peripheral board means replacing the main body and the peripheral board with new ones as a whole.

The length of expected life is different between the main body and the peripheral board, and the replacement work of the main body and the replacement work of the peripheral board are carried out at different times. Specifically, the expected life of the main body is about 15 years, and the guideline for replacement of the main body is 15 years after delivery of the uninterruptible power supply system. On the other hand, the expected life of the peripheral disc is about 25 years, which is about 10 years later than the replacement time of the main body.

JP 2014-222982 A

As mentioned above, replacement work for the main body must be carried out 10 years earlier than for the peripheral board. Therefore, when the main body is replaced, the peripheral board itself remains installed although the connection between the main body and the peripheral board is removed. Therefore, in the replacement work of the main unit, only the main unit to be replaced is removed from the fixed installation place from among the group of housings lined up in a row, and the new main unit is installed in the same place. become.

Since such replacement work of the main body extends to the entire main body, many construction facilities are indispensable, such as a gate-shaped construction facility that covers the main body and a horizontal pull hook that hangs on the main body. . Therefore, the replacement work of the main body is a large-scale work, and the work time is long.

In addition, since data centers do not have enough space, the work space provided in front of the main unit is originally narrow. In addition, considering the installation of construction equipment, the space that can be used for the replacement work of the housing is considerably reduced. Therefore, it is extremely difficult to replace the main body in the state of the housing, and the problem is that the work efficiency of the construction work is low.

Furthermore, considering the role of the UPS, the shorter the work period for replacing the main unit, the better. For this reason, it was necessary to concentrate a large number of workers in the replacement work of the main unit, and labor costs soared. As a result, replacement work for the main body increases construction costs, including labor costs, increasing the replacement cost of the main body.

It goes without saying that there is a desire to suppress an increase in the renewal cost of the main body, but there is also a desire to extend the renewal time of the main body as much as possible. However, continuing to use the main body beyond the expected life expectancy increases the possibility of malfunctions occurring in the main body. If a malfunction occurs in the main body, the effect may extend to the peripheral board connected to the main body.

For this reason, for example, if the main body is used much longer than its expected life of 15 years, it may be necessary to replace not only the main body, but also the peripheral board that has not reached its expected life of 25 years. . The scale of the replacement work of the peripheral board becomes very large, and extending the replacement period of the main body may rather increase the economic burden.

In view of the above situation, it can be said that reliably updating the main body before its expected life leads to a total reduction in the running cost of the entire system. Therefore, conventionally, there is a strong demand to reduce the replacement cost of the main body. Especially in recent years, when the main unit renewal market is expanding with the spread of data centers, etc., there is an urgent need to reduce the renewal cost of the main unit.

In addition to the above-mentioned problems when updating the main unit, when carrying out work such as maintenance of the main unit and replacement with an alternative machine, a considerable construction period is required and construction costs are high. The point is the issue. In addition, it is often difficult to secure a space for these works because the work is carried out while the peripheral board is left untouched.

In the uninterruptible power supply system, as mentioned above, there is a difference in the expected life between the main unit and the peripheral board, but there are many other power boards with different expected lifespans from the peripheral board. Therefore, there are similar issues.

The present embodiment has been proposed to solve the above problems, and the object thereof is to facilitate the replacement work of the main body by attaching and detaching the main body to and from the frame as it is. Another object of the present invention is to provide an electric power panel in which the replacement cost of the main body is reduced.

In order to achieve the above object, the power board according to the embodiment of the present invention has the following components (1) and (2).
(1) A main body portion having a housing in which power equipment is housed and placed in a direction upright with respect to an installation surface (2) Among the front portion, rear portion and both side portions of the housing, A frame body portion that surrounds the side portions and that is detachable by pushing and pulling the housing.

The front view of 1st Embodiment. 1 is a perspective view of the first embodiment; FIG. 1 is a side view of the first embodiment; FIG. FIG. 2 is a perspective view of essential parts of the first embodiment; 1 is a circuit diagram of an uninterruptible power supply system including the first embodiment; FIG. The circuit diagram of 1st Embodiment. A circuit diagram of another embodiment. The front view of the uninterruptible power supply system which adopted 2nd Embodiment. 9 is a perspective view of FIG. 8; FIG. Circuit diagram of the main body. FIG. 9 is a perspective view of a main portion of FIG. 8; The side view which shows the UPS unloading state which employ|adopted 2nd Embodiment. The side view which shows the UPS unloading state which employ|adopted 2nd Embodiment. The side view which shows the UPS unloading state which employ|adopted 2nd Embodiment. The top view which shows the UPS unloading state which employ|adopted 2nd Embodiment. The side view which shows the UPS unloading state which employ|adopted 2nd Embodiment. The top view which shows the UPS unloading state which employ|adopted 2nd Embodiment. The top view which shows the UPS unloading state which employ|adopted 2nd Embodiment. The top view which shows the UPS unloading state which employ|adopted 2nd Embodiment. The top view which shows the UPS carrying-in state which employ|adopted 2nd Embodiment. The top view which shows the UPS carrying-in state which employ|adopted 2nd Embodiment. The top view which shows the UPS carrying-in state which employ|adopted 2nd Embodiment. The front view of 3rd Embodiment. The perspective view of 3rd Embodiment. 4 is a circuit diagram of a common backup UPS system including the third embodiment; FIG. The side view of 3rd Embodiment. The principal part perspective view of 3rd Embodiment. The side view of 3rd Embodiment. The side view of 3rd Embodiment. The principal part side view of 3rd Embodiment. 4 is a circuit diagram of a parallel redundant UPS system including a third embodiment; FIG. The perspective view of 4th Embodiment. The perspective view which shows the pulled-out state of the main-body part of 4th Embodiment, and a pushing-in state. The front side perspective view which shows the main-body part of 4th Embodiment. The back side perspective view which shows the main-body part of 4th Embodiment. FIG. 4 is a rear side perspective view showing a main body side connection portion; FIG. 4 is a front side perspective view showing a pressing portion of the main body side connection portion; The front side perspective view which shows the frame part of 4th Embodiment. The perspective view which shows the state divided|segmented into the upper surrounding part and the lower surrounding part. The perspective view which shows a frame side connection part. FIG. 4 is a perspective view showing a guide roller of the frame body; The bottom side perspective view which shows a base part. Front view of the power board. Rear view of the power board. A plan view of the power board. Right side view of the power board. Left side view of the power board. A bottom view of the power board. Front view of the power board. Front view of the power board. Rear view of the power board. Rear view of the power board. Right side view of the power board. Left side view of the power board. Front view of the power board. Rear view of the power board. A plan view of the power board. Right side view of the power board. Left side view of the power board. A bottom view of the power board. Front view of the power board. The front view of a main-body part. Rear view of the main body. The top view of a main-body part. The right side view of a main-body part. The left side view of a main-body part. The bottom view of a main-body part. The front view of a main-body part. The front view of a frame body part. The back view of a frame body part. The top view of a frame body part. The right side view of a frame part. The left view of a frame body part. The bottom view of a frame body part.

(1) First embodiment (configuration)
The power board of the first embodiment will be specifically described with reference to FIGS. 1 to 6. FIG. This power board is a board applied to an uninterruptible power supply system (UPS). As shown in the front view of FIG. 1 and the perspective view of FIG. 2, the uninterruptible power supply system includes a main body 1, an input transformer board 6, a storage battery board 7, and a branch board 8. As shown in FIG. The input transformer board 6, storage battery board 7, and branch board 8 are also referred to as peripheral boards 6-8.

The main body 1 and the peripheral boards 6 to 8 are housed in a substantially rectangular parallelepiped housing and arranged in a line along the wall surface of a data center or the like. Main body 1 and peripheral boards 6-8 are provided with doors on the front of each housing, which are opened to perform maintenance and inspection of main body 1 or peripheral boards 6-7.

In FIG. 1, the input transformer board 6, the main body 1, the branch board 8, and the storage battery board 7 are installed in this order from the left side of the drawing. Further, the main body UPS 1 is provided with a display section 10 at a height of 100 cm or more from the bottom. In FIGS. 1 and 2, the main body 1 is shown lower than the peripheral discs 6 to 8, but this is to clarify the difference between the main body 1 and the peripheral discs 6 to 8. The height dimensions of the peripheral discs 6 to 7 may be made uniform.

The power panel according to the first embodiment is provided with a frame portion 4 that surrounds and supports the main body portion 1 from the left, right, and below. In FIGS. 1 and 2 , the inner portion indicated by the dotted line is the main body portion 1 and the outer portion indicated by the dotted line is the frame portion 4 . As shown in the side view of FIG. 3, the body portion 1 is arranged in a housing state with respect to the frame body portion 4, that is, the entire housing can be pulled out without disassembling the housing. . As shown in the perspective view of the main part in FIG. 4, the frame body part 4 does not have a top part, but has a bottom part, left and right side parts, and a back part connecting the side parts.

As shown in FIGS. 3 and 4, a body-side connecting portion 5a is provided on the upper back portion of the main body portion 1, and a frame-side connecting portion 5b is provided on the upper back portion of the frame portion 4. As shown in FIGS. These connecting portions 5a and 5b are arranged so as to face each other, and are electrically connected by being joined. Further, the frame-side connecting portion 5b is electrically connected to predetermined portions of the peripheral boards 6 to 8 (not shown). The body-side connection portion 5a and the frame-side connection portion 5b are configured to be arranged at positions where the connection portions 5a and 5b can be joined together by pushing the body portion 1 into the frame body portion 4 .

FIG. 5 is a circuit diagram of an uninterruptible power supply system incorporating this embodiment. The uninterruptible power supply system shown in FIG. 5 is a common standby uninterruptible power supply system, and as a main unit 1, one standby machine 1a and a plurality of regular machines 1b (three in FIG. 5) are provided. . As shown in the circuit diagram of FIG. 6, the main body 1 is provided with a rectifier 2 that converts alternating current to direct current, and an inverter 3 that converts direct current to alternating current.

(Main body replacement work)
In the first embodiment as described above, it is possible to replace the main body 1 by pulling out and pushing the main body 1 in the housing from the frame 4 . When removing the body portion 1 from the frame body portion 4, for example, as shown in FIG. ), the bottom surface of the main body 1 is lifted from the frame 4. Subsequently, the operator slides the lower part of the housing of the main body 1 to the front side (left side in FIG. 3) and stands the main body 1 upright on the floor. Then, while maintaining the vertical state of the main body 1 , the operator slides the entire main body 1 toward the front side and pulls out the entire main body 1 from the frame body 4 .

When the body portion 1 is attached to the frame portion 4, for example, as shown in FIG. It is pushed into the frame body part 4 . When performing the replacement work, a member (not shown), such as a roller, is installed on the bottom surface of the main body 1 to allow the main body 1 to slide smoothly.

(action and effect)
In the present embodiment as described above, the main body portion 1 having a housing that accommodates the rectifier 2 that converts alternating current to direct current and the inverter 3 that converts direct current to alternating current and is placed in a direction upright with respect to the installation surface. A frame portion 4 surrounds the rear portion and the side portions of the front portion, the rear portion, and the side portions of the housing, and is attached and detached by pushing and pulling the housing.

Therefore, since the main body 1 can be easily attached to and detached from the frame body 4 in the state of a housing, the replacement work of the main body 1 can be easily performed. In addition, since maintenance of the main body 1 can be carried out by pulling it out of the frame 4, work efficiency is improved.

Further, in the present embodiment, the body portion 1 and the frame portion 4 are provided with the body side connection portion 5a and the frame side connection portion 5b, respectively. By pulling out 1, the jointed state between the two is released, and by pushing the body portion 1 into the frame portion 4, the two are joined together.

Therefore, when replacing the main body 1, the work of removing and joining the connection parts 5a and 5b can be performed simultaneously with the work of attaching and detaching the main body to and from the frame body 4. FIG. Moreover, since the body-side connection portion 5a and the frame-side connection portion 5b are provided on the upper portions of the body portion 1 and the frame portion 4, the connection portions 5a and 5b do not interfere with attachment and detachment of the body portion. Therefore, the replacement work of the main body portion 1 can exhibit excellent work efficiency.

In addition, when replacing the main body 1, there is no need for construction equipment such as a portal or a hook for horizontal pulling, so that a large space can be secured for replacing the main body 1.例文帳に追加Therefore, it is possible to replace the main body 1 as it is, and the replacement work can be performed quickly and easily. As a result, a significant reduction in construction costs for the main body 1 is realized.

That is, according to the present embodiment, the replacement of the main body 1 can be promoted by reducing the economic burden of updating the main body 1, and the replacement of the main body 1 can be facilitated. It is possible to prevent problems that occur As a result, the input transformer board 6, the storage battery board 7, and the branch board 8, which are peripheral boards, are not affected by the malfunction of the main body 1, and can fulfill their expected life. As a result, the total running cost of the entire uninterruptible power supply system is reduced, improving economic efficiency.

Furthermore, in this embodiment, the display section 10 is arranged at a height of 100 cm or more from the bottom surface of the main body section 1 . Therefore, when the body portion 1 is pushed into the frame body portion 4, the operator's hand or the like does not hit the easily damaged display portion 10. - 特許庁Therefore, damage to the display section 10 can be reliably prevented, and the replacement work of the main body section 1 can be performed safely.

(2) Other Aspects (a) For example, although the first embodiment is applied to a common standby uninterruptible power supply system, it may be applied to a parallel redundant uninterruptible power supply system as shown in FIG. In FIG. 7, reference numeral 13 denotes a parallel board to which a plurality of main bodies 1 are connected. According to this embodiment, the effects of the first embodiment can be obtained even in the parallel redundant uninterruptible power supply system.

(b) In the first embodiment, the frame side connection portion 5b electrically connected to the main body portion 1 and the peripheral boards 6 to 8 is provided on the frame portion 4 side. It may be omitted, and the body-side connection portion 5a on the side of the body portion 1 may be directly and electrically connected to the side of the peripheral boards 6-8. According to this embodiment, since it is not necessary to provide the frame-side connecting portion 5b, the configuration of the frame body portion 4 can be further simplified.

(c) A jig for fixing the body portion 1 may be installed on the body portion 1 or the frame body portion 4 . By installing the jig, the stability of the main body part 1 is enhanced, so excellent safety can be obtained.
(d) The body portion 1 or the frame body portion 4 may be provided with an auxiliary mechanism for assisting the work of pulling out or pushing in the body portion 1 . The provision of the work assisting mechanism has the advantage of improving workability.

(e) The main body 1 or the frame 4 may be provided with an electric shock preventing mechanism for preventing an electric shock during the replacement work of the main body 1 . With respect to the above-described jigs, auxiliary mechanisms for replacement work, or electric shock prevention mechanisms, the configuration, shape, material, arrangement location, number of arrangements, etc. can be appropriately selected.

(f) A guide member, such as a guide rail portion, may be provided for pulling out or pushing the body portion 1 from the frame portion 4 . The guide member may be provided on the side surface portion or the bottom surface portion of the main body portion 1 or may be provided on the side surface portion or the bottom surface portion of the frame portion 4 . The configuration, shape, material, location and number of arrangement of such guide members can also be changed as appropriate.

(g) When the body portion 1 is removed from the frame portion 4, a strong stress may be applied to the frame portion 4 from the input TR board 6 and the storage battery board 7 arranged on the left and right. In the first embodiment, since the back surface portion is provided in the frame portion 4, the stress can be resisted by the back surface portion.

According to this embodiment, even if a strong stress is applied to the frame portion 4 from the left and right directions after the main body portion 1 is removed, the frame portion 4 is not deformed because the reinforcing portion is provided on the back portion. do not have. Therefore, the new main body portion 1 can be smoothly pushed into the frame portion 4, and there is no fear of lowering work efficiency.

(h) The shape of the housing of the main body 1 may be generalized regardless of type. When the uninterruptible power supply system has a plurality of main units 1, if the replacement timing of the main unit 1 is off, the old main unit 1 waiting for replacement and the new main unit 1 just replaced are stored in the uninterruptible power supply system. are mixed. Therefore, by generalizing the shape of the housing of the main body 1, the main body 1 can be smoothly inserted into the frame body 4 even if two types of new and old main bodies 1 are mixed in the uninterruptible power supply system. be able to.

(i) The arrangement and configuration of the main body side connection portion 5a on the main body portion 1 side may be generalized. As a result, even if the type of the main body 1 is different, it is possible to deal with the frame-side connecting portion 5b, and the replacement work of the main body 1 can be efficiently performed.

(j) An adapter may be interposed between the main body portion 1 and the frame portion 4 when the arrangement and configuration of the main body side connecting portion 5a on the main body portion 1 side are different for each type of the main body portion 1. FIG. In this embodiment, replacement work of the main body 1 can be easily carried out only by using an adapter.

(3) Second embodiment (configuration)
A power board according to the second embodiment will be specifically described with reference to FIGS. 8 to 22. FIG. This power board is also a board applied to an uninterruptible power supply system (UPS). An uninterruptible power supply system including a UPS will be described using the front view of FIG. 8 and the perspective view of FIG. As shown in FIGS. 8 and 9, the uninterruptible power supply system is provided with an input transformer board 6M, a storage battery board 8M and a main body 9M.

The input transformer board 6M and the storage battery board 8M are external devices of the main unit 9M and are also called peripheral boards. 8 and 9, the input transformer board 6M, the main body part 9M, and the storage battery board 8M are installed in this order from the left side of the drawing. That is, the body portion 9M is sandwiched from the left and right by the input transformer board 6 and the storage battery board 8M. The input transformer board 6M, the storage battery board 8M and the main body part 9M are arranged in a line along the wall surface of a data center or the like, and the base part 7M is installed at the bottom.

FIG. 10 shows a circuit diagram of a UPS main circuit 11M provided in the main body 9M. As shown in FIG. 10, the main circuit 11M includes a rectifier 12M that converts AC to DC, and an inverter 13M that converts DC to AC. Such a main circuit 11M is electrically connected to an input transformer board 6M and a storage battery board 8M, which are external devices.

A drawer structure of an uninterruptible power supply according to the second embodiment will be described with reference to FIGS. 11 to 22. FIG. As shown in FIGS. 11 to 22, the body portion 9M is provided with a housing 10M. The housing 10M is installed in the form of the housing 10M after the electrical connection between the input transformer board 6M and the storage battery board 8M and the main circuit 11M is disconnected, that is, without disassembling the housing 10M at all. It should be configured so that it can be carried out from the position where it is placed.

In this embodiment, the housing 10M is removed from the base portion 7M while maintaining the form of the housing 10M. It is a drawer structure for pulling out the main body 9M from the position sandwiched between the 8M to the loading/unloading space S of the main body 9M spreading in front of the uninterruptible power supply system. The width dimension of the loading/unloading space S of the main body portion 9M is about 1200 mm.

As shown in FIGS. 11 to 15, the housing 10M of the body portion 9M is provided with a front portion 10Ma, a rear portion 10Mb and a side portion 10Mc. 11 to 15, the right side of the drawing is the front side, and the left side is the rear side. A handle 14M is notched near the center of the side portion 10Mc of the housing 10M. Further, a first mounting hole 1M is provided in the side surface portion 10Mc of the housing 10M near the front surface portion 10Ma. The first mounting hole 1M is provided at a position of about 200 mm toward the rear portion 10Mb when viewed from the front portion 10Ma (see FIG. 12).

A side surface portion 10Mc of the housing 10M is provided with a second mounting hole 2M near the rear surface portion 10Mb. The second mounting hole 2M is provided at a position of about 300 mm toward the front portion 10Ma when viewed from the rear portion 10Mb (see FIG. 12).

As shown in FIG. 11, third mounting holes 3M are provided near the left and right ends of the front portion 10Ma of the housing 10M. The third mounting hole 3M is provided at a height of about 70 mm from the floor surface when the housing 10M is placed on the base portion 7M. As shown in FIG. 12, the first and second mounting holes 1M and 2M are also provided at a height of about 70 mm from the floor surface when the housing 10M is placed on the base portion 7M. The center of gravity of the body portion 9M is lower than the middle height of the body portion 9M. Therefore, all of the first to third mounting holes 1M to 3M have a height equal to or lower than the center of gravity of the body portion 9M.

Nuts are accommodated in the first to third mounting holes 1M to 3M, and as shown in FIGS. . Further, a detachable anchor 15M is installed near the floor surface of the space S for loading/unloading during loading/unloading work of the main body portion 9M. The anchor 15M is arranged orthogonally to the longitudinal direction of the loading/unloading space S. A lever block (registered trademark) 5M, which is a traction tool, is attached to the anchor 15M. A hook portion for hooking the eyebolt 4M is provided on the lever block 5M.

As shown in FIGS. 16 to 18, 21 and 22, a rail portion 16M on which the housing 10M can be placed is laid. The rail portion 16M is arranged parallel to the anchor 15M. Reference numeral 17M shown in FIG. 21 denotes a square member for receiving the corner of the housing 10M.

(Work to carry out the main body)
Next, the carrying out operation of the main body portion 9M will be described with reference to FIGS. 12 to 19. FIG. As shown in FIG. 16, two parallel rail portions 16M are installed in front of the front portion 10Ma of the housing 10M. Although not shown, it is assumed that a protective sheet or the like is laid on the floor of the loading/unloading space S as a prerequisite for performing such work.

An eyebolt 4M is attached to the third attachment hole 3M of the front portion 10Ma of the housing 10. As shown in FIG. Further, an anchor 15M is fixed near the floor surface of the loading/unloading space S, and the lever block 5 is attached to the anchor 15. - 特許庁Then, the hook portion of the lever block 5 is hooked on the eyebolt 4M attached to the third mounting hole 3M, and the lever block 5M is operated to pull out the housing 10M rightward in FIG. 8 (from FIG. 12 to FIG. 13). state to transition).

As shown in FIG. 17, when the housing 10M is pulled out to reveal the first mounting hole 1M in the side surface portion 10Mc of the housing 10M, the work of pulling out the housing 10M is temporarily stopped. Then, the hook portion of the lever block 5M is removed from the eyebolt 4M on the side of the third mounting hole 3M, and the eyebolt 4M is attached to the first mounting hole 1M of the side surface portion 10Mc. By hooking the hook portion of the lever block 5M on the eyebolt 4M and operating the lever block 5M, the housing 10 is further pulled out to the right in FIG. 16 (state of transition from FIG. 13 to FIG. 14).

As shown in FIG. 18, when the housing 10M is further pulled out to reveal the second mounting hole 2M of the side surface portion 10Mc of the housing 10M, the pull-out operation is once stopped. Then, the hook portion of the lever block 5M is removed from the eyebolt 4M on the side of the first mounting hole 1M, and the eyebolt 4M is mounted in the second mounting hole 2M. By hooking the hook portion of the lever block 5 on the eyebolt 4M and operating the lever block 5M, the housing 10M is further pulled out to the right in FIG. As a result, the housing 10M is completely lowered from the base portion 7M, and the entire housing 10M is pulled out to the loading/unloading space S (state shifted from FIG. 14 to FIG. 15).

As shown in FIG. 19, the housing 10M pulled out to the loading/unloading space S is lifted by a jack or the like, and the hand lift 18M is inserted. Finally, using the hand lift 18M, the worker H carries out the housing 10M outside through the loading/unloading space S, and the work of carrying out the main body 9M is completed.

(Carrying in the main body)
The second embodiment is a drawer structure for an uninterruptible power supply, but it can be used not only for carrying out the main body 9M as described above, but also for carrying in the main body 9M. Therefore, the carrying-in operation of the main body portion 9M will be described with reference to FIGS. 20 to 22. FIG. As shown in FIG. 20, a plurality of workers H use a hand lift 18M to carry the housing 10M of the main body 9M to the front of a predetermined installation position through the loading/unloading space S.

As shown in FIG. 21, four square timbers 17 are installed in front of the front part 10Ma of the housing 10M. Place on top of 17M. From the viewpoint of safety, the size of the square material 17M is set to 100 mm, for example. Two parallel rail portions 16M are arranged between the square members 17M, and the housing 10M is placed on the rail portions 16M.

As shown in FIG. 22, an eyebolt 4M is attached to the first attachment hole 1M of the side surface portion 10Mc of the housing 10M. Further, an anchor 15M is fixed near the floor surface of the loading/unloading space S, and the lever block 5M is attached to the anchor 15M. Then, the hook portion of the lever block 5M is hooked on the eyebolt 4M attached to the first mounting hole 1M, and the lever block 5M is operated to push the housing 10M leftward in FIG. Then, when the entire housing 10M is placed on the base portion 7M, the carrying-in operation of the main body portion 9M is completed.

(Effect)
The second embodiment as described above includes a housing 10M having a front portion 10Ma, a rear portion 10Mb, and a side portion 10Mc, and a drawer of the main body portion 9M that can be carried out from a position where the housing 10M is installed as it is. In the side surface portion 10Mc, a first mounting hole 1M is provided near the front portion 10Ma, and a second mounting hole 2M is provided near the rear portion 10Mb.

In the above-described second embodiment, in the first half of carrying out the main body portion 9M, the eyebolt 4M is attached to the first mounting hole 1M positioned about 200 mm from the front portion 10Ma toward the back portion 10Mb, and the lever is Hook the block 5M and operate the lever block 5M. As a result, the housing 10M is drawn forward about halfway.

In the second half of carrying out the main body portion 9M, an eyebolt 4M is attached to the second mounting hole 2M positioned about 300 mm from the rear portion 10Mb toward the front portion 10Ma, and the lever block 5M is hooked again. to operate. As a result, the entire housing 10M is pulled out to the loading/unloading space S.

According to the second embodiment, two types of mounting holes, ie, first and second mounting holes 1M and 2M are used to pull out the housing 10M of the main body 9M step by step. The entire housing 9M can be reliably carried out to the carrying-in/out space S without being difficult to pull out. Moreover, the main body portion 9M can be carried in and out simply by hooking the lever block 5M on the eyebolt 4M attached to the mounting holes 1M to 3M and operating it. Therefore, large-scale construction equipment and the like are not required. As a result, the work for updating the main body 9M can be performed efficiently, and the work cost can be greatly reduced.

In addition, in the second embodiment, the first to third mounting holes 1M to 3M are all positioned at a height of about 70 mm from the floor surface, so they are provided at a height below the center of gravity of the main body 9M. It will be. Therefore, the housing 10M can be stably moved when the main body portion 9M is carried in and out, and safety during work is improved. Furthermore, in the second embodiment, since the third mounting hole 3M is provided in the front portion 10Ma of the housing 10M, the housing 10 can be pulled out reliably from the initial stage of carrying out the main body portion 9M. .

Moreover, in the second embodiment, since all of the first to third mounting holes 1M to 3M are provided near 70 mm from the floor surface, the eye bolts 4M attached to these mounting holes 1M to 3M are also installed on the floor surface. It is located in the vicinity of 70 mm from the There is an advantage that the lever block 5M can be easily attached to the eyebolt 4M at such a height.

In addition, in the second embodiment, by sliding the housing 10M on the rail portion 16M, it is possible to carry out the carry-in/out operation of the main body portion 9M quickly. Furthermore, since the handle 14M is provided on the side surface portion 10Mc of the housing 10M, the worker H can use the handle 14M to manually carry in and out the main body 9M. Therefore, it is possible to cope with the loading/unloading work of the main body portion 9M under all conditions.

(4) Other Aspects For example, the configuration, shape, arrangement location, etc. of the first to third mounting holes 1M to 3M can be changed as appropriate. Further, in the above-described embodiment, the lever block 5M is used for loading/unloading the body portion 9M, but the power for loading/unloading the body portion 9M can be appropriately selected. Alternatively, a sliding sheet may be pasted on the rail portion 16M so that the housing 10M can be easily slid on the rail portion 16M. In this embodiment, it is possible to carry out the loading/unloading operation of the main body portion 9M more easily.

Furthermore, similarly to the first embodiment and the third and fourth embodiments described later, the housing 10M is detachably installed with respect to a frame portion surrounding the rear surface portion and both side portions thereof. You may make it pull out the housing|casing 10M from. In this embodiment, even after the housing 10M of the main body 9M is pulled out, the frame remains between the input transformer board 6M and the storage battery board 8M. can be received by the frame.

Therefore, when the housing 10M is drawn out, pressure is not applied to the housing 10M from the input transformer board 6M and the storage battery board 8M, and the carry-out operation of the main body 9M can be carried out smoothly. In addition, there is no concern that the input transformer board 6M and the storage battery board 8M will fall even slightly into the space after the housing 10M is drawn out and the space will be narrowed. Therefore, it is possible to reliably carry in the main body portion 9M.

(5) Third embodiment (configuration)
A power board according to the third embodiment will be specifically described with reference to FIGS. 23 to 30. FIG. This power board is also a board applied to an uninterruptible power supply system (UPS). As shown in the front view of FIG. 23 and the perspective view of FIG. 24, the uninterruptible power supply system includes a main body 1N, an input transformer board 6N, a storage battery board 7N, and a branch board 8N. An input transformer board 6N, a storage battery board 7N, and a branch board 8N are peripheral boards 6N to 8N of the main body 1N and are external devices of the main body 1N.

The main body 1N and the peripheral boards 6N to 8N, which are the main body, are accommodated in a substantially rectangular parallelepiped housing, and are arranged in a line along the wall surface of a data center or the like. The main unit 1N and the peripheral boards 6N to 8N are provided with a door in front of each housing, which is opened to perform maintenance and inspection of the main unit 1N or the peripheral boards 6N to 8N.

In FIG. 23, the input transformer board 6N, the main body 1N, the branch board 8N, and the storage battery board 7N are installed in this order from the left side of the drawing. In FIGS. 23 and 24, the main body 1N is shown lower than the peripheral discs 6N to 8N, but this is to clarify the difference between the main body 1 and the peripheral discs 6N to 8N. The peripheral discs 6N to 8N may have the same height dimension.

FIG. 25 is a circuit diagram of an uninterruptible power supply system incorporating this embodiment. The uninterruptible power supply system shown in FIG. 25 is a common standby UPS system, and includes one standby device 10Na and a plurality of (two in FIG. 25) regular devices 10Nb and 10Nc as the main unit 1N. . That is, the third embodiment is applied to a common standby UPS system. The main body 1N is provided with a rectifier 2N for converting AC to DC and an inverter 3N for converting DC to AC. In FIG. 25, the portion surrounded by the thick two-dot chain line is the main body portion 1N, and the portion surrounded by the one-dot chain line is the frame portion 4N.

As shown in FIGS. 26 to 30, the main body 1 is a rectangular parallelepiped housing having a front surface, a rear surface, a top surface, a bottom surface, and left and right side surfaces. The body portion 1N is detachably installed on the frame portion 4N. The frame portion 4N does not have a front portion and a top portion, but has a bottom portion, left and right side portions, and a rear portion connecting the side portions, and supports the main body portion 1 from the left, right, and below. When the body portion 1 is attached to the frame portion 4N, the rear portion of the body portion 1N and the rear portion of the frame portion 4N are in contact with each other. The contact surfaces 11N and 41N of the body portion 1N and the frame portion 4N are used as the contacting back portions.

As shown in FIGS. 26 to 30, the body portion 1N is provided with a body side connection portion 5Na above the contact surface 11N. The body-side connection portion 5Na is an internal connection portion that is electrically connected to the rectifier 2 or the inverter 3, and is a movable connection portion that is movable along the attachment/detachment direction of the body portion 1N with respect to the frame portion 4N.

Further, the frame body portion 4N is provided with two connection portions, a frame side connection portion 5Nb and an external connection portion 5Nc. The frame-side connecting portion 5Nb is fixedly provided on the upper portion of the contact surface 41N of the frame portion 4N, and is for electrically connecting to the body-side connecting portion 5Na. The external connection portion 5Nc is an external wire terminal for connecting an external wire cable to be connected to the peripheral boards 6N to 8N, and is accommodated inside the frame portion 4N. Regarding the positional relationship between the frame-side connection portion 5Nb and the external connection portion 5Nc, in the present embodiment, the external connection portion 5Nc is installed below the frame-side connection portion 5Nb, but may be installed above. . When the external cable connecting to the peripheral boards 6N to 8N is extended from above the frame portion 4N, the external connection portion 5Nc is installed above the frame side connection portion 5Nb, and the external cable is extended from below. In this case, by installing the external connection portion 5Nc under the frame-side connection portion 5Nb, the connection at each connection portion is simplified.

(Body side connection part and frame side connection part)
The body-side connection portion 5Na and the frame-side connection portion 5Nb are arranged to face each other. The body-side connecting portion 5Na is arranged at a retracted position P1 sufficiently distant from the frame-side connecting portion 5Nb so as not to contact the frame-side connecting portion 5Nb on the side of the frame portion 4N when it is not joined to the frame-side connecting portion 5Nb. It is The retracted position P1 is provided near the front of the main body 1N.

Also, the position where the body-side connection portion 5Na and the frame-side connection portion 5Nb are joined together is defined as a joining position P2. FIG. 30 shows a state in which the body-side connection portion 5Na has moved to the joining position P2. The body-side connecting portion 5Na is adapted to move linearly between the retracted position P1 and the joining position P2. When the body-side connecting portion 5Na separates from the frame-side connecting portion 5Nb, the two are electrically disconnected.

By the way, in the circuit diagram of FIG. 25, the connecting portion composed of the main body side connecting portion 5Na and the frame side connecting portion 5Nb is designated as the first connecting portion A (indicated by a black circle), and the frame side connecting portion 5Nb and the external connecting portion 5Nc is shown as a second connection B (indicated by a white circle). Four first connection portions A are provided on the contact surfaces 11N and 41N between the main body portion 1N and the frame portion 4N, and four second connection portions B are provided inside the frame portion 4N.

The four connection parts A and B are provided two on the input side of the main body part 1N, one on the output side of the main body part 1N, and one on the storage battery board 7N side. The fact that there are four first connection portions A means that there are also four body-side connection portions 5Na. Although the four body-side connecting portions 5Na are located at different positions in the circuit diagram, they are attached to the same member so as to move integrally.

In FIG. 25, reference numerals 12Nb and 13Nb denote upper-side circuit breakers in the regular machine 10Nb, and reference numerals 14Nb and 15Nb denote lower-side circuit breakers in the regular machine 10Nb. Furthermore, reference numerals 12Nc and 13Nc denote upper-side wiring breakers in the regular machine 10Nc, and reference numerals 14Nc and 15Nc denote lower-side wiring breakers in the regular machine 10Nc. The circuit breakers 12Nb to 14Nb and 12Nc to 14Nc for wiring are connected to the second connection portion B, that is, the frame side connection portion 5Nb and the external connection portion 5Nc. In addition, circuit breakers 15Nb and 15Nc for wiring are connected to the spare unit 10Na side.

Further, as shown in FIGS. 26 to 30, a working space 9N is provided near the front of the main body 1N when viewed from the retracted position P1 of the main body side connecting portion 5Na. The working space 9N is used for joining or separating the body-side connecting portion 5Na and the frame-side connecting portion 5Nb.

(Updating the main unit)
In the above-described third embodiment, an operation for removing the main body portion 1N from the frame portion 4N will be described. For example, when removing the regular machine 10Nb from the frame portion 4N, the wiring circuit breakers 12Nb to 14Nb are opened and the wiring circuit breaker 15Nb is turned on. As a result, the main unit 1N of the regular machine 10Nb becomes detachable because the supply of power from the commercial power source and the backup machine 10Na to the regular machine 10Nb is stopped. Also, the standby machine 10Na supplies UPS power to the load to which the regular machine 10Nb has supplied power.

On the other hand, when removing the regular machine 10Nc from the frame portion 4, the wiring circuit breakers 12Nc to 14Nc are opened and the wiring circuit breaker 15Nc is turned on. As a result, the supply of power from the commercial power source and the standby device 10Na to the regular device 10Nc is stopped, so that the main unit 1N of the regular device 10Nc can be removed. Also, the standby machine 10Na supplies UPS power to the load to which the regular machine 10Nc has been supplying power.

After performing the above operation, the update worker uses the work space 9N to perform the detachment work between the main body side connection portion 5Na on the side of the main body portion 1N and the frame side connection portion 5Nb on the side of the frame portion 4N. . Therefore, the body-side connection portion 5Na and the frame-side connection portion 5Nb are separated from each other and electrically disconnected. After the body-side connection portion 5Na and the frame-side connection portion 5Nb are detached, the body portion 1N is removed from the frame portion 4N by pulling out the body portion 1N from the frame portion 4N.

Next, an operation for attaching a new main body portion 1N to the frame portion 4N will be described. A new main body portion 1N is pushed into the frame portion 4N, and the abutting surface 11N of the rear portion of the main portion 1N and the abutting surface 41N of the rear portion of the frame portion 4N are brought into contact with each other, thereby positioning them. is done. At this time, the body-side connecting portion 5a is positioned at the retracted position P1 and does not collide with the frame-side connecting portion 5Nb on the side of the frame portion 4N.

Subsequently, the update worker uses the work space 9N to move the body side connection portion 5Na from the retracted position P1 to the joining position P2, and the body side connection portion 5Na and the frame side connection portion of the frame body portion 4N side Joining work with 5Nb is performed. As a result, the body-side connection portion 5Na and the frame-side connection portion 5Nb are joined and electrically connected to each other. The frame-side connection portion 5Nb and the external connection portion 5Nc are held regardless of whether the main body portion 1N is attached or detached. 1N is electrically connected to peripheral boards 6N to 8N, which are external devices.

Therefore, for example, when the regular machine 10Nb is attached to the frame portion 4, the wiring circuit breakers 12Nb to 14Nb are turned on and the wiring circuit breaker 15Nb is opened and turned on. On the other hand, when the regular machine 10Nc is attached to the frame portion 4N, the wiring circuit breakers 12Nc to 14Nc are turned on and the wiring circuit breaker 15Nc is opened. As a result, power supply from the commercial power source and the backup device 10Na to the regular machines 10Nb and 10Nc is resumed, returning to the UPS power feeding state to the load by the regular machines 10Nb and 10Nc.

(Effect)
In the third embodiment, a body portion 1N housing a rectifier 2N for converting AC to DC and an inverter 3N for converting DC to AC inside a housing, and a frame portion 4N detachably installed with the body portion 1N. A movable contact portion 5Na is provided on the main body portion 1N side, and a frame side connection portion 5Nb that can be electrically connected to and separated from the main body side connection portion 5Na and an external device are provided on the frame body portion 4N side. and an external connection portion 5Nc electrically connected to the .

(a) According to the third embodiment, when the main body portion 1N is removed from the frame portion 4N, the frame side connection portion 5Nb and the external connection portion 5Nc installed on the side of the frame portion 4N are The bonded state can be maintained. Therefore, there is no need to remove the electrical connection between the peripheral boards 6N to 8N, which are external devices, and the frame portion 4N, and the update work can be easily performed.

The external cables that electrically connect the main unit 1N side and the peripheral boards 6N to 8N are deformed by heat after the start of operation, so it is almost impossible to reconnect them once they are disconnected. Therefore, in the conventional technology in which the electrical connections with the peripheral boards 6N to 8N, which are external devices, are removed when the main unit 1N is updated, the replacement of the external cable is also indispensable, increasing the update cost. .

In contrast, in the third embodiment, the electrical connection between the peripheral boards 6N to 8N and the frame portion 4N is never disconnected. Therefore, even after the main unit 1N is updated, the existing external cable, which is the external connection unit 5Nc, can still be used, and replacement is unnecessary. As a result, the update cost can be greatly reduced, which is economically advantageous.

(b) Normally, the weight of the body portion 1N is considerably heavy. may be damaged. Therefore, in the third embodiment, if the body portion 1N is detached from the frame portion 4N, the body-side connection portion 5a is positioned at the retracted position P1.

Therefore, even if the body portion 1N is strongly pushed into the frame portion 4N during the operation of attaching the body portion 1N to the frame portion 4N, the contact surfaces 11N and 41N of the body portion 1N and the frame portion 4N are The body-side connection portion 5Na and the frame-side connection portion 5Nb do not collide directly with each other. Therefore, in the third embodiment, it is possible to prevent damage to the body-side connection portion 5Na and the frame-side connection portion 5Nb, and to exhibit excellent safety in updating work.

(c) In the third embodiment, the body portion N1 is provided with the work space 9N for joining or separating the body-side connection portion 5Na and the frame-side connection portion 5Nb. It is possible to efficiently perform joining or detachment work between the side connection portion 5Na and the frame side connection portion 5b. Moreover, since the plurality of body-side connection portions 5Na are integrally movable along the direction of attachment and detachment of the body portion 1N, the updating worker can quickly join the body-side connection portions 5Na and the frame-side connection portions 5Nb. It is possible. According to such a third embodiment, it is possible to further improve the efficiency of update work.

(d) In the third embodiment, the body-side connection portion 5Na and the frame-side connection portion 5Nb are arranged so as to be freely contactable and separable even when the body portion 1N is pushed into the frame portion 4N. Therefore, the main body side connection portion 5Na functions as a disconnector, and safe work is possible by releasing the connection between the main body side connection portion 5Na and the frame side connection portion 5Nb during maintenance of the main body portion N1.
(e) In the third embodiment, the above effects can be obtained in the common standby UPS system.

(6) Other Aspects For example, although the third embodiment is applied to a common backup UPS system, it may be applied to a parallel redundant uninterruptible power supply system as shown in FIG. In FIG. 31, reference numeral 16 denotes a parallel board to which a plurality of main units 1N are connected, reference numeral 17 denotes a circuit breaker on the upper side, and reference numeral 18 denotes a circuit breaker on the lower side.

In this embodiment, after opening the circuit breakers 17N and 18N connected to the body portion 1N to be removed, the body portion 1N is removed from the frame portion 4. FIG. Further, when the body portion 1N is attached to the frame portion 4N, the circuit breakers 17N and 18N are turned on after the body portion 1N is attached to the frame portion 4N. According to the above embodiment, the effects of the third embodiment can be obtained in the parallel redundant uninterruptible power supply system.

A guide member, such as a guide rail portion, may be provided for pulling out or pushing the body portion 1N from the frame portion 4N. The guide member may be provided on the side surface or bottom surface of the main body portion 1N, or may be provided on the side surface or bottom surface of the frame portion 4N. The configuration, shape, material, location and number of arrangement of such guide members can also be changed as appropriate.

In the third embodiment, the body side connection portion 5Na, which is a movable connection portion, is used as the internal connection portion on the side of the main body portion 1N, but the frame side connection portion 5Nb on the side of the frame portion 4N may be used as a movable connection portion. The movable directions of these movable connecting portions are not limited to the attachment/detachment direction of the main body portion 1N with respect to the frame portion 4N. For example, one connecting portion may be arranged facing upward, and the other connecting portion may be moved to cover this connecting portion from above.

(7) Fourth Embodiment A power panel according to a fourth embodiment will be specifically described with reference to FIGS. 32 to 42. FIG. This power board is also a board applied to an uninterruptible power supply system (UPS). The fourth embodiment, as shown in FIG. 32, has a main body portion 100, a frame body portion 400, and a base portion 800 (see FIG. 42). In this embodiment, as shown in FIG. 33, the housing 200 of the main body 100 is attached and detached by pushing it into the frame 400 and pulling it out.

[Body part]
A configuration of the main body 100 will be described. The body portion 100 has a housing 200 and a body-side connection portion 300 .

[Chassis]
As shown in FIG. 34, the housing 200 is a substantially rectangular parallelepiped container that accommodates power equipment that constitutes an uninterruptible power supply (UPS) and that is placed in an upright direction with respect to the installation surface. Hereinafter, the front surface of the housing 200 is referred to as a front surface portion 201, the rear surface as a back surface portion 202, and the left and right surfaces as viewed from the front as side surface portions 203 and 204. As shown in FIG. Furthermore, let the upper surface be the upper surface portion 205 and the lower surface be the bottom surface portion 206 . Also, the horizontal lateral direction of the housing 200 is defined as the width direction, and the front-rear direction is defined as the depth direction.

The front part 201 of the housing 200 is open, and as shown in FIG. 35, a door 210 for opening and closing it is provided. A plurality of lead terminals 220 are provided on the rear surface portion 202 of the housing 200, as shown in FIG. A cable pulled out from the power equipment is connected to the inner side of the housing 200 of each lead-out terminal 220 . A plurality of lead terminals 220 are arranged side by side in the width direction on the upper part of the back surface. These lead-out terminals 220 are divided into a plurality of types of input/output sections (see FIG. 35), as will be described later.

As shown in FIG. 34, the front portion 201 and the side portion 202 of the housing 200 are provided with first to third mounting holes 1M to 3M at the same positions as in the second embodiment. . The first to third mounting holes 1M to 3M are provided so that the eyebolts 4 can be mounted as described above.

[Body side connection part]
The body-side connection portion 300 is a component that electrically connects with an external line connection portion 600, which will be described later. The body-side connection portion 300 has an electrode portion 310, a support portion 320, and a pressing portion 330, as shown in FIGS.

(Electrode part)
The electrode section 310 has an electrode plate 311 and a flexible conductor 312, as shown in FIG.

The electrode plate 311 is a conductive plate and arranged parallel to the side surface of the housing 200 . The electrode plate 311 constitutes a connector portion 630 and a fitting portion, which will be described later. A lower portion of the electrode plate 311 is a vertical support surface 311a extending downward from the upper portion of the housing 200 to the rear side. The upper portion of the electrode plate 311 is a vertical contact/separation surface 311 b that protrudes upward from the housing 200 . Since the support surface 311a and the contact/separation surface 311b form a continuous plate surface through the front-rear direction relay surface 311c, the electrode plate 311 as a whole has a crank shape.

The flexible conductor 312 is a member in which a pair of conductive terminals 312a and 312b are connected by a flexible member 312c, which is a flexible conductor. One terminal 312 a of the flexible conductor 312 is connected to the lead terminal 220 on the rear surface portion 202 of the housing 200 . The other terminal 312 b of the flexible conductor 312 is connected to the support surface 311 a of the electrode plate 311 .

(support part)
The support portion 320 is a component that supports the electrode plate 311 on the housing 200 while allowing movement in the depth direction and the width direction. The support portion 320 has a guide rail 321, a slider 322, a movable portion 323, and an elastic member 324, as shown in FIG.

The guide rail 321 is an elongated member having a substantially U-shaped cross section with an opening on the rear side of the housing 200 . The guide rails 321 are attached in the width direction of the housing 200 . The slider 322 is an elongated prismatic member inserted into the guide rail 321 and slides in the width direction of the housing 200 along the guide rail 321 .

The movable portion 323 has a moving plate 323a and a support plate 323b. The moving plate 323 a is a flat plate that is attached to the slider 322 and slides parallel to the rear surface of the housing 200 . The support plate 323b is a member having an L-shaped cross section, and a portion parallel to the back surface portion 202 is attached to the moving plate 323a. A pair of guide holes 323c extending in the depth direction are formed in upper and lower portions of the support plate 323b in parallel with the side portions 203 and 204. As shown in FIG.

The elastic member 324 is a compression coil spring that expands and contracts in the width direction. Two elastic members 324 are provided vertically in the width direction of the housing 200 . One end of each elastic member 324 is inserted through the guide hole 323c of the support plate 323b and is configured to be slidable in the depth direction. The other end of each elastic member 324 is fixed to the support surface 311 a of the electrode plate 311 .

The configuration of the support portion 320 described above enables the electrode plate 311 to move in the width direction of the housing 200 together with the slider 322 that moves along the guide rail 321 . Further, it becomes possible to move in the depth direction of the housing 200 together with the elastic member 324 that moves along the guide hole 323c. When the electrode plate 311 is urged toward the rear side, the contact/separation surface 311b is fitted to the holding member 632 described later. Even if the position of the electrode plate 311 is shifted with respect to the lead terminal 220, the deformation of the flexible conductor 312 ensures continuity.

As shown in FIG. 35, a plurality of electrode plates 311 are prepared for each section. For example, four are provided in the DC input section E1, three in the AC input section E2, three in the bypass input section E3, and four in the AC output section E4. For DC input, two positive electrodes and two negative electrodes are supported. AC input and bypass input are compatible with three phases. For AC output, it corresponds to 3 phases and a ground wire.

(Presser)
As shown in FIGS. 36 and 37, the holding portion 330 is a member that presses the electrode plate 311 of the electrode portion 310 toward the back side and pushes it into the frame-side connection portion 600 described later. The holding portion 330 has an urging plate 331 , a handle 332 and a holding portion 333 . The biasing plate 331 is a plate that partially covers the connector portion 630 . The biasing plate 331 is parallel to the rear surface of the housing 200 and has a rectangular shape elongated in the width direction. The urging plate 331 is made of a transparent material so that the inserted state of the electrode plate 311 can be visually recognized. A punched steel plate may be used for the electrode plate 311 .

36, a plurality of elastic members 331a interposed between the biasing plate 331 and the electrode plate 311 are attached. The elastic member 331a is a compression coil spring that expands and contracts in the depth direction. One end of the elastic member 331 a is attached to the front edge of each electrode plate 311 via a plate or the like, and the other end is attached to the back surface of the urging plate 331 . Two elastic members 331a are provided corresponding to each electrode plate 311, and these two elastic members 331a are arranged vertically.

The handle 332, as shown in FIG. 37, is a substantially U-shaped bar member. Both ends of the handle 332 are fixed to the front surface of the urging plate 331 so that the longitudinal direction is the width direction of the housing 200 . Mounting holes 331a are formed in the vicinity of both ends of the biasing plate 331 for bolting to fixing legs 640 of the frame-side connecting portion 600, which will be described later.

The holding portion 333 is a member that holds the pressing portion 330 at a distance such that the electrode plate 331 is electrically insulated from the connector portion 630, as shown in FIG. The holding portion 333 is a latch having a claw fixed to the front side of the biasing plate 331 . The holding part 333 holds the position of the biasing plate 331 at a position where the electrode plate 331 is separated from the clamping body 632 by engaging claws with holes (not shown) provided in the upper surface part 205 of the housing 200 . do.

The holding portion 330 as described above is provided for each of the input/output sections E1 to E4. That is, as shown in FIG. 35, the four biasing plates 331 are configured to collectively bias a plurality of electrode plates 331 for each of the sections E1 to E4.

[Frame part]
The frame body part 400 is a member in which the housing 200 is accommodated, as shown in FIGS. 32 and 33 . The frame body part 400 has an enclosing part 500 , a frame-side connection part 600 and a guide part 700 .

(surrounding part)
The surrounding part 500 is a member that surrounds both side surfaces and the rear surface of the housing 200 in a U-shape. The enclosing part 500 has a vertical body 510 and side bodies 520 .

The upright body 510 is a thin housing that stands upright on the installation surface. The height of the three-dimensional body 510 is formed to be 20 to 25% higher than that of the housing 200 . The front surface of this elevated portion serves as a protruding portion 511 that protrudes upward when the housing 200 is accommodated. The three-dimensional body 510 is provided so as to be vertically separable with a straight line in the width direction as a boundary.

The side bodies 520 are members that cover the side surfaces of the housing 200 that is accommodated by extending from both side edges of the three-dimensional body 510 to the front side perpendicular to the three-dimensional body 500 . The side body 520 is configured by vertically stacking two rectangular U-shaped frames 521 and 522 . The central portions of the upper and lower horizontal portions of the frames 521 and 522 are connected by vertical columns 521a and 522a. It is provided so as to be vertically separable at a height that matches the boundary between the frames 521 and 522 and the boundary of the three-dimensional body 510 .

The side body 520 has side plates 523 and 524 attached so as to cover the outer surfaces of the frames 521 and 522 . Further, the side body 529 has a front panel 525 that continuously covers the front surfaces of the frames 521 and 522 and fills the gap between adjacent boards.

As described above, since the enclosing part 500 is divided at the boundary between the vertical body 510 and the side body 520, as shown in FIG. there is Bolt holes 521b and 522b to which hanging bolts R can be fastened are formed in the upper surface of the frame 521 of the upper enclosing portion 500A and the upper surface of the frame 522 of the lower enclosing portion 500B.

(Frame side connection)
The frame-side connection portion 600 is a component that electrically connects to an external cable via the body-side connection portion 300 . As shown in FIGS. 38 and 39, the frame-side connecting portions 600 are arranged side by side in the width direction in front of the projecting portion 511 . The frame-side connection portion 600 has a fixing plate 610, an external wire terminal 620, a connector portion 630, and a fixing leg 640 (see FIG. 38). In addition, as shown in FIG. 32, by providing a cover CB on the frame body part 400 so that the connecting part between the frame-side connecting part 600 and the main-body-side connecting part 300 is not exposed, the worker can touch the connecting part while the power is on. It is possible to ensure safety so that The cover CB can be made of an insulating material such as resin to increase the insulating distance, but it may be made of a metal material.

Also, after the start of operation, there is a case where an inspection is carried out to check whether the temperature has reached an abnormal temperature by imaging the connection part with a thermo camera. Therefore, by providing a hinge or the like at the connecting portion between the frame portion 400 and the cover CB, the cover CB can be easily opened and closed at the time of inspection, thereby improving working efficiency. Further, by providing a hole in the cover CB so that the connecting portion can be seen from the front of the main body 100, inspection using a thermo camera is facilitated.

The fixed plate 610 is a conductive rectangular plate. The fixing plate 610 is supported and fixed to the front surface of the projecting portion 511 via a plurality of elastic members 611 so that the long side direction is vertical. The elastic member 611 is a compression coil spring that expands and contracts in the depth direction.

The external line terminal 620 is a conductive plate having an L-shaped cross section consisting of two orthogonal surfaces. One surface of the external line terminal 620 is fixed to the top of the fixed plate 610 . The other surface of the external line terminal 620 protrudes toward the front side, and has a hole 621 for connection with a terminal of an external line cable.

The connector part 630 is a member into which the electrode plate 311 is inserted and removed. In other words, the electrode plate 311 and the connector portion 630 constitute a fitting portion that is electrically connected by moving from the body-side connection portion 300 toward the frame-side connection portion 600 and fitting into each other. The connector section 630 has a mounting plate 631 , a clamping body 632 and a contact electrode 633 . The mounting plate 631 is a conductive plate and is attached to the fixed plate 610 below the external terminal 610 . The holding member 632 has a recess 632a into which the electrode plate 311 is inserted. The recessed portion 632a is formed in the height direction of the housing 200 and sandwiches the inserted electrode plate 311 in the width direction.

The holding member 632 is attached to the mounting plate 631 so as to be movable in the height direction and the width direction of the housing 200, and is biased to a fixed position by an elastic member (not shown). This guide width can be, for example, a few millimeters in height and width. Thus, the clamping body 632 constitutes a floating connector that allows the concave portion 611 to follow the position of the electrode plate 311 when the electrode plate 311 is inserted, thereby absorbing positional deviation between the electrode plate 311 and the concave portion 632a.

The contact electrode 633 is a conductor that contacts and is electrically connected to the electrode plate 311 inserted into the recess 611 . The contact electrode 633 is electrically connected to the external line terminal 620 via the mounting plate 631 and the fixing plate 610 .

A plurality of clamping bodies 632 of such a connector section 630 are arranged for one electrode plate 311 . In this embodiment, three clamps 632 are provided. The contact electrodes 633 of the holding member 632 equally share the rated current. For example, if the rated current is 300A, a current of about 100A can be passed. However, it may be a single clamp 632 that carries the rated current.

As shown in FIGS. 38 and 39, the fixing leg 640 is fixed to the three-dimensional body 510, and the biasing plate 331 that presses the electrode plate 311 is attached to the fixing leg 640 to prevent the electrode plate 311 from coming off. It is the plate that holds.

The fixed leg 640 is attached to the front of the protruding portion 511 of the three-dimensional body 510 at its rear end and extends forward. A front end of the fixing leg 640 is bent in a direction parallel to the rear surface and has a mounting hole 641 for mounting the biasing plate 331 .

The number of frame-side connection portions 600 arranged as described above corresponds to the number of lead terminals 220 divided into a plurality of types of input/output sections. For example, four are provided in the DC input section E1, three in the AC input section E2, three in the bypass input section E3, and four in the AC output section E4.

(Guide part)
The guide portion 700 is a component that guides the movement of the body portion 100 that is inserted into and ejected from the frame portion 400 . The guide section 700 has a guide roller 710 as shown in FIG. The guide roller 710 has a shaft 711 and rollers 712 . The shaft member 711 is a rod-shaped member erected in the height direction at the lower portion of the side body 520 . The roller 712 is a columnar member made of resin and having the shaft member 711 fixed to its central axis. A plurality of guide rollers 710 are arranged in the depth direction inside the side body 520 . The side surface of the roller 710 protrudes inward and contacts and separates from the side surface portions 203 and 204 of the body portion 100 to be inserted and ejected.

[Base part]
The base portion 800 is a member interposed between the main body portion 100 and the installation surface to support the main body portion 100 . As shown in FIG. 42, the base portion 800 is a rectangular frame-shaped plate, and is inserted into the bottom portion of the frame portion 400 with the short side direction as the depth direction. A plurality of strip-shaped bridging plates 810 are arranged in the short side direction of the base portion 800 .

Smooth sheets 820 are attached to the bottom surfaces of both short sides of the base portion 800 and the bottom surface of the bridging plate 810 . As the sheet 820, for example, an ultra-high molecular weight polyethylene tape is used. The surface of the base portion 800 to which the sheet 820 is attached is in contact with the installation surface, and the housing 200 of the main body portion 100 is placed on the opposite surface. A smooth sheet similar to the sheet 820 is also attached to the bottom surface of the housing 200 .

(Installation work)
The operation of installing the frame body part 400 and the main body part 100 as described above will be described. First, the frame body part 400 is installed between adjacent boards as shown in the above embodiment. When carrying in and out the frame body part 400, as shown in FIG. 39, it can be carried by being divided into an upper enclosing part 500A and a lower enclosing part 500B. At this time, the suspension bolts R can be fastened to the bolt holes 521b and 522b of the upper enclosing part 500A and the lower enclosing part 500B, respectively, so that the upper enclosing part 500A can be lifted. This makes it possible to move even in places with height restrictions such as elevators.

The work of attaching and detaching the body portion 100 to and from the frame portion 400 is the same as in the second embodiment. In other words, the housing 200 can be taken in and out of the frame portion 400 using the base portion 800 and the eyebolts 4M attached to the first to third attachment holes 1M to 3M. Note that when the housing 200 placed on the base portion 800 is taken in and out, the sheet 820 provided on the base portion 800 allows the base portion 800 to slide on the installation surface, thereby facilitating the taking in and out. In addition, since the rollers 712 of the guide rollers 710 rotate in contact with the lower portions of the side portions 203 and 204 of the housing 200, the housing 200 can be smoothly taken in and out.

After mounting the body portion 100 on the frame body portion 400 , an external cable is connected to the frame side connection portion 600 . A bolt is passed through the hole of the terminal provided at the tip of the external wire cable and the hole 611 of the external wire terminal 620, and the bolt is tightened and fixed with the nut.

(Electrical connection work)
The operation of connecting the body-side connection portion 300 to the frame-side connection portion 600 will be described. As shown in FIG. 33, when the body portion 100 is attached to the frame portion 400, the electrode plate 311 of the electrode portion 310 and the holding member 632 of the connector portion 630 face each other.

The operator holds the handle 332 of the urging plate 331 of the pressing portion 330 and moves it in the width direction to adjust the width direction positions of the electrode plate 311 and the holding member 632, and then, as shown in FIG. Then, the urging plate 331 is pushed toward the rear side. The pressure during pushing is relieved by the elastic members 331a and 611. FIG. Then, as shown in FIG. 41, the contact/separation surface 311b of the electrode plate 311 fits into the concave portion 632a of the clamping body 632, contacts the contact electrode 633, and is electrically connected.

At this time, a slight deviation between the electrode plate 311 and the concave portion 632a is absorbed by the expansion and contraction of the elastic member 324 on the electrode plate 311 side and the movement of the holding member 632 configured as a floating connector. The operator uses the mounting holes 331a to fix the biasing plate 331 to the fixed leg 640 with bolts, as shown in FIG. As a result, the external cable is connected to the UPS via the main body side connection section 300 and the frame side connection section 600 .

When disconnecting the body-side connection portion 300 and the frame-side connection portion 600, the urging plate 331 and the fixed leg 640 are unbolted, and the handle 332 is held and pulled to the front side. Then, the plate 311 is removed from the recess 632a of the holding member 632, and the electrical connection is released.

By engaging the holding portion 333 of the pressing portion 330 with a claw in a hole provided on the upper surface of the housing 200, the biasing plate 331 is placed in a disconnected state in which the electrode plate 331 is separated from the holding member 632. can hold.

(Effect)
(1) In the present embodiment, the body-side connection portion 300 and the frame-side connection portion 600 are electrically connected by moving the body-side connection portion 300 toward the frame-side connection portion 600 and fitting them into each other. It has a fitting part that fits.

For this reason, when removing the main body 100, by removing the main body-side connecting portion 300 of the fitting portion from the frame-side connecting portion 600, it is not necessary to disconnect the external cable. Further, when attaching the body portion 100, by fitting the body-side connection portion 300 in the fitting portion to the frame-side connection portion 600, wiring work of the external cable becomes unnecessary.

(2) The fitting portion is provided in the body-side connection portion 300 and is provided in the electrode plate 311, which is a conductive plate movable between the frame-side connection portion 600 and the frame-side connection portion 600. and a connector portion 630 into which the plate 311 is inserted and removed. Therefore, it is not necessary to wire and disconnect the external cable by inserting and removing the electrode plate 311 .

(3) The electrode plate 311 is provided movably in the width direction of the housing 200 . Therefore, it is possible to adjust the displacement of the electrode plate 311 with respect to the connector portion 630 in the width direction and perform accurate positioning and fitting.

(4) The electrode plate 311 is supported by an elastic member. Therefore, the elastic member 324 absorbs the displacement of the electrode plate 311 .

(5) The connector portion 630 is provided movably in the width direction and the height direction of the frame portion 400 . Therefore, slight misalignment when the electrode plate 311 is inserted into the connector portion 630 is absorbed.

The electrode plate 311 and the connector portion 630 are divided into sections for input and output. Therefore, the operator can easily determine which fitting portion is to be brought into contact with or separated from the connector, thereby facilitating the connection work. Furthermore, by configuring the electrode plate 311 and the connector portion 630 related to grounding to be independently connectable and detachable, it is possible to maintain the grounding even during replacement and maintenance work of the main body portion 100 and the like, thereby preventing an electric shock accident for the operator. can be suppressed.

It has a pressing portion 330 that biases the electrode plate 311 toward the connector portion 630 . Therefore, it is possible to connect to the connector portion 630 without directly touching the electrode plate 311 .

The pressing portion 330 is provided for each input/output section so that a plurality of electrode plates 311 can be collectively biased. Therefore, the electrode plate 311 can be removed and inserted collectively in units of sections, and the burden is reduced compared to the case of inserting and removing the whole.

The electrode plate 311 has a holding portion 333 that holds the pressing portion 330 at a distance that ensures electrical insulation from the connector portion 630 . For this reason, at the time of inspection or the like, the state in which the power equipment is reliably disconnected from the power supply is maintained, so that inspection work can be carried out more safely. The holding portion 333 has a simple latch for engaging a claw and is easy to work with, but may be fixed with a bolt or the like.

The pressing portion 330 has an urging plate 331 that partially covers the front surface of the connector portion 630 , and the urging plate 331 is made of a material that allows the insertion state of the electrode plate 311 into the connector portion 630 to be visually recognized. Therefore, the connection state of the electrode plate 311 can be easily confirmed.

It has a guide portion 700 that guides the movement of the body portion 100 that is inserted into and ejected from the frame portion 400 . Therefore, the movement of the main body 100 during insertion and ejection is guided, and smooth movement, absorption of errors, and alignment are possible.

having a base portion interposed between the main body portion 100 and the installation surface and supporting the main body portion 100,
A smooth sheet is attached to the base portion. Therefore, the movement of the body portion 100 becomes smooth.

A frame body portion 400 is provided so as to be vertically divisible. Therefore, even if there are restrictions on the space and mass for carrying in, it can be carried in by dividing it into upper and lower parts and lifting each of them using hanging bolts.

(Appearance shape)
Various shapes are conceivable as the external shape of the power board. The power board shown below can be regarded as an uninterruptible power supply board and an uninterruptible power supply. Also, the main body having the housing 200 can be regarded as a power panel, an uninterruptible power supply panel, or an uninterruptible power supply. Further, the frame body part 400 can also be regarded as a power panel installation table, a power panel support table, an uninterruptible power supply panel installation table, and an uninterruptible power supply panel support table.

Any of the front view, rear view, plan view, right side view, left side view, and bottom view shown below can be selectively combined to configure the power board, housing 200, and frame portion 400. FIG. It should be noted that the lead lines and reference numerals in each figure correspond to the names of members in the above embodiments, and do not constitute the appearance of the power board.

For example, the front view of FIG. 43, the rear view of FIG. 44, the plan view of FIG. 45, the right side view of FIG. 46, the left side view of FIG. 47, and the bottom view of FIG. It is an example of a power board. As shown by the dotted line in the front view of FIG. 49, a display, a handle, etc. can be arranged on the front door. Also, as shown in the front view of FIG. 50, the door may be a single one-sided opening. Also, as shown in the rear view of FIG. 51, the rear plate may be divided into left and right. As shown in the rear view of FIG. 52, the right side view of FIG. 53, and the left side view of FIG.

The front view of FIG. 55, the rear view of FIG. 56, the plan view of FIG. 57, the right side view of FIG. 58, the left side view of FIG. 59, and the bottom view of FIG. . As shown in the front view of FIG. 61, portions indicated by dotted lines, such as the display and the handle, are not limited to specific positions and shapes.

The front view of FIG. 62, the rear view of FIG. 63, the plan view of FIG. 64, the right side view of FIG. 65, the left side view of FIG. 66, and the bottom view of FIG. . As shown in the front view of FIG. 68, portions indicated by dotted lines, such as the display and the handle, are not limited to specific positions and shapes.

The front view of FIG. 69, the rear view of FIG. 70, the plan view of FIG. 71, the right side view of FIG. 72, the left side view of FIG. 73, and the bottom view of FIG. be.

Each of the embodiments and aspects described above is presented herein as an example and is not intended to limit the scope of the invention. That is, it can be embodied in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof. For example, in each of the above-described embodiments, the applicable power equipment is not limited to UPS, but UPS is suitable for reasons such as replacement timing as described above.
(1) a main body having a housing in which power equipment is housed and placed in an upright direction with respect to an installation surface;
a body-side connection portion electrically connected to the power device and arranged at a position that can be joined to the facing connection portion by pushing the body portion;
has
At least one of the main body-side connecting portion and the connecting portion is movable between a non-contact retracted position and a joined position.
(2) a main body having a housing in which power equipment is housed and placed in an upright direction with respect to an installation surface;
a body-side connection portion having an electrode plate that is a conductive plate electrically connected to the electric power device, and arranged at a position that can be joined to the facing connection portion by pushing the body portion;
A power board having a
(3) At least one of the main body side connecting portion and the connecting portion has a handle.
(4) A power board having a holding portion that holds at least one of the body-side connecting portion and the connecting portion in a retracted position.

Moreover, the following aspects can also be configured.
(1) a main body that accommodates power equipment including at least a rectifier and an inverter and that is placed in an upright direction with respect to an installation surface;
a body-side connection portion provided in the body portion and electrically connected to the power device;
a connecting portion arranged so as to be connectable to the main body-side connecting portion in a state where the main body portion is placed on the installation surface;
a peripheral board electrically connected to the connecting portion and installed adjacent to the main body placed on the installation surface;
uninterruptible power supply system.
(2) The uninterruptible power supply system, wherein the peripheral panel is at least one of an input transformer panel, a storage battery panel and a branch panel.
(3) An uninterruptible power supply system in which the main body and the peripheral board are arranged in a line with other peripheral boards.
(4) An uninterruptible power supply system in which the main body is arranged between the two peripheral boards.
(5) The uninterruptible power supply system in which the peripheral board and the connecting portion are electrically connected via an external cable.
(6) An uninterruptible power supply system in which the two peripheral boards are arranged on both sides of the installation surface.
(7) An uninterruptible power supply system having a base portion that is interposed between the main body portion and the installation surface and supports the main body portion.

Furthermore, the following aspects can also be configured.
(1) a main body provided with a rectifier and an inverter and placed in an upright direction with respect to an installation surface;
a body-side connection portion provided in the body portion and electrically connected to the rectifier and the inverter;
a connecting portion arranged so as to be connectable to the main body-side connecting portion in a state where the main body portion is placed on the installation surface;
a peripheral board, which is at least one of an input transformer board, a storage battery board, and a branch board, is electrically connected to the connecting portion and is installed adjacent to the main body portion placed on the installation surface;
uninterruptible power supply system.
(2) An uninterruptible power supply system in which the main body and the peripheral board are arranged in a line with other peripheral boards.
(3) An uninterruptible power supply system in which the main body is arranged between the two peripheral boards.
(4) An uninterruptible power supply system in which the peripheral board and the connecting portion are electrically connected via an external cable.
(5) An uninterruptible power supply system in which the two peripheral boards are arranged on both sides of the installation surface.
(6) An uninterruptible power supply system having a base portion interposed between the main body portion and the installation surface and supporting the main body portion.

REFERENCE SIGNS LIST 1 Main unit 1a Standby unit 1b Common unit 2 Rectifier 3 Inverter 4 Frame unit 5a Main unit side connection unit 5b Frame side connection unit 6 Input transformer board 7 Storage battery board 8 Branch board 10 Display unit 11 AC circuit breaker 12 DC circuit breaker 13 Parallel board 1M First mounting hole 2M Second mounting hole 3M Third mounting hole 4M Eyebolt 5M Lever block 6M Input transformer board 7M ... Base part 8M ... Storage battery board 9M ... UPS
10M...Case 11M...Main body part 12M...Rectifier 13M...Inverter 14M...Handle 15M...Removable anchor 16M...Rail part 17M...Square bar 18M...Hand lift H...Worker S...Space for loading/unloading 1N...Main body part 2N... Rectifier 3N Inverter 4N Frame body portion 5Na Body side connection portion 5Nb Frame side connection portion 5Nc External connection portion 6N Input transformer panel 7N Storage battery panel 8N Branch panel 9N Working space 10Na Spare device 10Nb , 10Nc... Common machines 11N, 41N... Contact surfaces 12Nb to 15Nb, 12Nc to 15Nc, 17N, 18N... Circuit breakers for wiring 16N... Parallel board A... First connection part B... Second connection part P1... Retracted position P2... Joining position 100... Main body part 200... Housing 201... Front part 202... Rear parts 203, 204... Side view 206... Bottom part 210... Door 220... Lead electrode 300... Main body side connection part 310... Electrode part 311... Electrode Plate 311a... Supporting surface 311b... Connecting surface 311c... Relay surface 312... Flexible conductors 312a, 312b... Terminals 312c... Flexible member 320... Supporting part 321... Guide rail 322... Slider 323... Movable part 323a... Moving plate 323b... Supporting plate 323c... Guide hole 324 Elastic member 330... Pressing part 331... Biasing plate 331a... Elastic member 332... Handle 333... Holding part 400... Frame body part 500... Enclosing part 500A... Upper enclosing part 500B... Lower enclosing part 510... Elevated surface Body 511 Projecting portion 520 Side body 521, 522 Frames 521a, 522a Columns 521b, 522b Bolt holes 523, 524 Side plate 525 Front plate 600 Frame-side connecting portion 610 Fixed plate 611 Elastic member 620 External terminal 621 Hole 630 Connector portion 631 Mounting plate 632 Holding body 632a Recess 633 Contact electrode 640 Fixed leg 641 Mounting hole 700 Guide portion 710 Guide roller 712 Roller 711 Shaft member 800 Base Part 810 Bridge plate 820 Sheet CB Covers E1 to E4 Section

Claims (27)

a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The power device is provided with a main body side connection portion for connecting between internal devices,
The frame body portion is provided with a frame side connection portion that can be electrically connected to and separated from the main body side connection portion, and an external connection portion that is electrically connected to an external device,
At least one of the body-side connection portion and the frame-side connection portion is movable between a retracted position where the body-side connection portion and the frame-side connection portion do not contact each other and a joining position where the body-side connection portion and the frame side connection portion contact each other. . a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The power device is provided with a main body side connection portion for connecting between internal devices,
The frame body portion is provided with a frame side connection portion that can be electrically connected to and separated from the main body side connection portion, and an external connection portion that is electrically connected to an external device,
At least one of the main body-side connecting portion and the frame-side connecting portion is in contact with a retracted position in which the main body-side connecting portion and the frame-side connecting portion are not in contact with each other along the mounting/dismounting direction of the power device with respect to the frame portion. A power board that is moveable between connecting positions . a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The power device is provided with a main body side connection portion for connecting between internal devices,
The frame body portion is provided with a frame side connection portion that can be electrically connected to and separated from the main body side connection portion, and an external connection portion that is electrically connected to an external device,
A power panel provided with a plurality of movable body-side connection portions or frame-side connection portions, wherein the plurality of body-side connection portions or frame-side connection portions are attached to the same member and movable integrally . 3. The apparatus according to claim 1 or 2 , wherein a plurality of movable body-side connection portions or frame-side connection portions are provided, and the plurality of body-side connection portions or frame-side connection portions are attached to the same member and move integrally. A power board according to any one of the preceding claims. a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The power device is provided with a main body side connection portion for connecting between internal devices,
The frame body portion is provided with a frame side connection portion that can be electrically connected to and separated from the main body side connection portion, and an external connection portion that is electrically connected to an external device,
The main body-side connecting portion and the frame-side connecting portion are arranged in a retracted position where the main body-side connecting portion and the frame-side connecting portion do not come into contact with each other . The power board according to claim 1 or 2 , wherein the body-side connection portion and the frame-side connection portion are arranged at the retracted position. a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The power device is provided with a main body side connection portion for connecting between internal devices,
The frame body portion is provided with a frame side connection portion that can be electrically connected to and separated from the main body side connection portion, and an external connection portion that is electrically connected to an external device,
A power board provided with a working space for joining or separating the body-side connecting portion and the frame-side connecting portion in the power equipment. The power board according to any one of claims 1 to 6 , wherein the power equipment is provided with a working space for joining or separating the body-side connecting portion and the frame-side connecting portion. a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The frame body portion is provided with a frame side connection portion electrically connected to an external device,
The body portion is provided with a body side connection portion for electrically connecting to the frame side connection portion,
The frame-side connection portion and the body-side connection portion are arranged at positions that can be connected to each other by pushing the body portion into the frame body portion,
the body-side connection portion and the frame-side connection portion have a fitting portion that is electrically connected by moving from the body-side connection portion toward the frame-side connection portion and fitting into each other;
The fitting portion is
an electrode plate, which is a conductive plate provided in the body-side connection portion and movable between the frame-side connection portion;
a connector portion provided in the frame-side connection portion, into which the electrode plate is inserted and removed;
has
The electrode plate is fixed to the other end of the elastic body,
A power board in which one end of the elastic body is inserted through a guide hole of a support plate of the movable part . a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The frame body portion is provided with a frame side connection portion electrically connected to an external device,
The body portion is provided with a body side connection portion for electrically connecting to the frame side connection portion,
The frame-side connection portion and the body-side connection portion are arranged at positions that can be connected to each other by pushing the body portion into the frame body portion,
The frame-side connecting portion is provided on the upper portion of the frame body portion,
The body-side connection part is provided on the upper part of the body part,
the body-side connection portion and the frame-side connection portion have a fitting portion that is electrically connected by moving from the body-side connection portion toward the frame-side connection portion and fitting into each other;
The fitting portion is
an electrode plate, which is a conductive plate provided in the body-side connection portion and movable between the frame-side connection portion;
a connector portion provided in the frame-side connection portion, into which the electrode plate is inserted and removed;
has
The electrode plate is fixed to the other end of the elastic body,
A power board in which one end of the elastic body is inserted through a guide hole of a support plate of the movable part . 11. The power board according to claim 9 , wherein said electrode plate is movable in the width direction of said housing. a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The frame body portion is provided with a frame side connection portion electrically connected to an external device,
The body portion is provided with a body side connection portion for electrically connecting to the frame side connection portion,
The frame-side connection portion and the body-side connection portion are arranged at positions that can be connected to each other by pushing the body portion into the frame body portion,
the body-side connection portion and the frame-side connection portion have a fitting portion that is electrically connected by moving from the body-side connection portion toward the frame-side connection portion and fitting into each other;
The fitting portion is
an electrode plate, which is a conductive plate provided in the body-side connection portion and movable between the frame-side connection portion;
a connector portion provided in the frame-side connection portion, into which the electrode plate is inserted and removed;
has
The connector section has a clamping body,
The electric power board , wherein the clamping body is movably attached to the mounting plate, so that the connector section is movable in the width direction and the height direction of the frame body section . a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The frame body portion is provided with a frame side connection portion electrically connected to an external device,
The body portion is provided with a body side connection portion for electrically connecting to the frame side connection portion,
The frame-side connection portion and the body-side connection portion are arranged at positions that can be connected to each other by pushing the body portion into the frame body portion,
The frame-side connecting portion is provided on the upper portion of the frame body portion,
The body-side connection part is provided on the upper part of the body part,
the body-side connection portion and the frame-side connection portion have a fitting portion that is electrically connected by moving from the body-side connection portion toward the frame-side connection portion and fitting into each other;
The fitting portion is
an electrode plate, which is a conductive plate provided in the body-side connection portion and movable between the frame-side connection portion;
a connector portion provided in the frame-side connection portion, into which the electrode plate is inserted and removed;
has
The connector section has a clamping body,
The electric power board , wherein the clamping body is movably attached to the mounting plate, so that the connector section is movable in the width direction and the height direction of the frame body section . The connector section has a holding body, and the holding body is movably attached to the mounting plate so that the connector section can move in the width direction and the height direction of the frame body section. A power board according to any one of 9 to 11 . a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The frame body portion is provided with a frame side connection portion electrically connected to an external device,
The body portion is provided with a body side connection portion for electrically connecting to the frame side connection portion,
The frame-side connection portion and the body-side connection portion are arranged at positions that can be connected to each other by pushing the body portion into the frame body portion,
the body-side connection portion and the frame-side connection portion have a fitting portion that is electrically connected by moving from the body-side connection portion toward the frame-side connection portion and fitting into each other;
The fitting portion is
an electrode plate, which is a conductive plate provided in the body-side connection portion and movable between the frame-side connection portion;
a connector portion provided in the frame-side connection portion, into which the electrode plate is inserted and removed;
has
The body-side connecting portion has a pressing portion,
The holding portion has a biasing plate and an elastic member,
one end of the elastic member is attached to the electrode plate and the other end is attached to the biasing plate;
The power board, wherein the elastic member biases the electrode plate toward the connector section when the biasing plate is pressed . a main body having a housing in which the power device is housed and placed in an upright direction with respect to the installation surface;
a frame body portion that surrounds the back portion and the side portions of the front portion, the back portion, and the side portions of the housing and is detachable by pushing and pulling the housing;
has
The frame body portion is provided with a frame side connection portion electrically connected to an external device,
The body portion is provided with a body side connection portion for electrically connecting to the frame side connection portion,
The frame-side connection portion and the body-side connection portion are arranged at positions that can be connected to each other by pushing the body portion into the frame body portion,
The frame-side connecting portion is provided on the upper portion of the frame body portion,
The body-side connection part is provided on the upper part of the body part,
the body-side connection portion and the frame-side connection portion have a fitting portion that is electrically connected by moving from the body-side connection portion toward the frame-side connection portion and fitting into each other;
The fitting portion is
an electrode plate, which is a conductive plate provided in the body-side connection portion and movable between the frame-side connection portion;
a connector portion provided in the frame-side connection portion, into which the electrode plate is inserted and removed;
has
The body-side connecting portion has a pressing portion,
The holding portion has a biasing plate and an elastic member,
one end of the elastic member is attached to the electrode plate and the other end is attached to the biasing plate;
The power board, wherein the elastic member biases the electrode plate toward the connector section when the biasing plate is pressed . The body-side connecting portion has a pressing portion,
The holding portion has a biasing plate and an elastic member,
one end of the elastic member is attached to the electrode plate and the other end is attached to the biasing plate;
The electric power board according to any one of claims 9 to 14 , wherein the elastic member biases the electrode plate toward the connector portion when the biasing plate is pressed . The power board according to any one of claims 9 to 17 , wherein the electrode plate and the connector section are provided separately for input/output. The power board according to any one of claims 15 to 17 , wherein the pressing portion is provided for each input/output section so that a plurality of the electrode plates can be collectively energized. The body-side connecting portion has a holding portion that holds the pressing portion,
The holding part has a claw,
the claw is engaged with a hole in the housing,
17. The power board according to claim 15 or 16, wherein the holding portion holds the holding portion such that the electrode plate is at a distance that ensures electrical insulation from the connector portion . The holding portion has a biasing plate that covers a part of the front surface of the connector portion,
The power board according to any one of claims 15 to 17 , wherein the biasing plate is made of a material that allows the state of insertion of the electrode plate into the connector portion to be visually recognized. The power board according to any one of claims 1 to 21 , further comprising a guide portion for guiding movement of said body portion inserted into and ejected from said frame portion. a base portion interposed between the main body portion and the installation surface for supporting the main body portion;
The power board according to any one of claims 1 to 22 , wherein a smooth sheet is attached to said base portion. The electric power board according to any one of claims 1 to 23 , wherein the frame portion is provided so as to be vertically divisible. The power board according to any one of claims 1 to 24 , wherein the power equipment is a UPS body containing a rectifier for converting AC to DC and an inverter for converting DC to AC. A power board according to any one of claims 1 to 25 provided in a common standby UPS system. A power panel according to any one of claims 1 to 25 provided in a parallel redundant UPS system

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